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ISSN 1977-0677 doi:10.3000/19770677.L_2012.070.eng |
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Official Journal of the European Union |
L 70 |
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English edition |
Legislation |
Volume 55 |
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(1) Text with EEA relevance |
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EN |
Acts whose titles are printed in light type are those relating to day-to-day management of agricultural matters, and are generally valid for a limited period. The titles of all other Acts are printed in bold type and preceded by an asterisk. |
II Non-legislative acts
DECISIONS
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8.3.2012 |
EN |
Official Journal of the European Union |
L 70/1 |
COMMISSION IMPLEMENTING DECISION
of 28 February 2012
establishing the best available techniques (BAT) conclusions under Directive 2010/75/EU of the European Parliament and of the Council on industrial emissions for the manufacture of glass
(notified under document C(2012) 865)
(Text with EEA relevance)
(2012/134/EU)
THE EUROPEAN COMMISSION,
Having regard to the Treaty on the Functioning of the European Union,
Having regard to Directive 2010/75/EU of the European Parliament and of the Council of 24 November 2010 on industrial emissions (integrated pollution prevention and control) (1) and in particular Article 13(5) thereof,
Whereas:
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(1) |
Article 13(1) of Directive 2010/75/EU requires the Commission to organise an exchange of information on industrial emissions between it and Member States, the industries concerned and non-governmental organisations promoting environmental protection in order to facilitate the drawing up of best available techniques (BAT) reference documents as defined in Article 3(11) of that Directive. |
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(2) |
In accordance with Article 13(2) of Directive 2010/75/EU, the exchange of information is to address the performance of installations and techniques in terms of emissions, expressed as short- and long-term averages, where appropriate, and the associated reference conditions, consumption and nature of raw materials, water consumption, use of energy and generation of waste and the techniques used, associated monitoring, cross-media effects, economic and technical viability and developments therein and best available techniques and emerging techniques identified after considering the issues mentioned in points (a) and (b) of Article 13(2) of that Directive. |
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(3) |
‘BAT conclusions’ as defined in Article 3(12) of Directive 2010/75/EU are the key element of BAT reference documents and lay down the conclusions on best available techniques, their description, information to assess their applicability, the emission levels associated with the best available techniques, associated monitoring, associated consumption levels and, where appropriate, relevant site remediation measures. |
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(4) |
In accordance with Article 14(3) of Directive 2010/75/EU, BAT conclusions are to be the reference for setting permit conditions for installations covered by Chapter 2 of that Directive. |
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(5) |
Article 15(3) of Directive 2010/75/EU requires the competent authority to set emission limit values that ensure that, under normal operating conditions, emissions do not exceed the emission levels associated with the best available techniques as laid down in the decisions on BAT conclusions referred to in Article 13(5) of Directive 2010/75/EU. |
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(6) |
Article 15(4) of Directive 2010/75/EU provides for derogations from the requirement laid down in Article 15(3) only where the costs associated with the achievement of emissions levels disproportionately outweigh the environmental benefits due to the geographical location, the local environmental conditions or the technical characteristics of the installation concerned. |
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(7) |
Article 16(1) of Directive 2010/75/EU provides that the monitoring requirements in the permit referred to in point (c) of Article 14(1) of the Directive are to be based on the conclusions on monitoring as described in the BAT conclusions. |
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(8) |
In accordance with Article 21(3) of Directive 2010/75/EU, within 4 years of publication of decisions on BAT conclusions, the competent authority is to reconsider and, if necessary, update all the permit conditions and ensure that the installation complies with those permit conditions. |
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(9) |
Commission Decision of 16 May 2011 establishing a forum for the exchange of information pursuant to Article 13 of Directive 2010/75/EU on industrial emissions (2) established a forum composed of representatives of Member States, the industries concerned and non-governmental organisations promoting environmental protection. |
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(10) |
In accordance with Article 13(4) of Directive 2010/75/EU, the Commission obtained the opinion (3) of that forum on the proposed content of the BAT reference document for the manufacture of glass on 13 September 2011 and made it publicly available. |
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(11) |
The measures provided for in this Decision are in accordance with the opinion of the Committee established by Article 75(1) of Directive 2010/75/EU, |
HAS ADOPTED THIS DECISION:
Article 1
The BAT conclusions for the manufacture of glass are set out in the Annex to this Decision.
Article 2
This Decision is addressed to the Member States.
Done at Brussels, 28 February 2012.
For the Commission
Janez POTOČNIK
Member of the Commission
(1) OJ L 334, 17.12.2010, p. 17.
(2) OJ C 146, 17.5.2011, p. 3.
(3) http://circa.europa.eu/Public/irc/env/ied/library?l=/ied_art_13_forum/opinions_article
ANNEX
BAT CONCLUSIONS FOR THE MANUFACTURE OF GLASS
| SCOPE | 6 |
| DEFINITIONS | 6 |
| GENERAL CONSIDERATIONS | 6 |
| Averaging periods and reference conditions for air emissions | 6 |
| Conversion to reference oxygen concentration | 7 |
| Conversion from concentrations to specific mass emissions | 8 |
| Definitions for certain air pollutants | 9 |
| Averaging periods for waste water discharges | 9 |
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1.1. |
General BAT conclusions for the glass manufacturing industry | 9 |
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1.1.1. |
Environmental management systems | 9 |
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1.1.2. |
Energy efficiency | 10 |
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1.1.3. |
Materials storage and handling | 11 |
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1.1.4. |
General primary techniques | 12 |
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1.1.5. |
Emissions to water from glass manufacturing processes | 14 |
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1.1.6. |
Waste from the glass manufacturing processes | 16 |
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1.1.7. |
Noise from the glass manufacturing processes | 17 |
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1.2. |
BAT conclusions for container glass manufacturing | 17 |
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1.2.1. |
Dust emissions from melting furnaces | 17 |
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1.2.2. |
Nitrogen oxides (NOX) from melting furnaces | 17 |
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1.2.3. |
Sulphur oxides (SOX) from melting furnaces | 20 |
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1.2.4. |
Hydrogen chloride (HCl) and hydrogen fluoride (HF) from melting furnaces | 20 |
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1.2.5. |
Metals from melting furnaces | 21 |
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1.2.6. |
Emissions from downstream processes | 21 |
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1.3. |
BAT conclusions for flat glass manufacturing | 23 |
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1.3.1. |
Dust emissions from melting furnaces | 23 |
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1.3.2. |
Nitrogen oxides (NOX) from melting furnaces | 23 |
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1.3.3. |
Sulphur oxides (SOX) from melting furnaces | 25 |
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1.3.4. |
Hydrogen chloride (HCl) and hydrogen fluoride (HF) from melting furnaces | 26 |
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1.3.5. |
Metals from melting furnaces | 26 |
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1.3.6. |
Emissions from downstream processes | 27 |
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1.4. |
BAT conclusions for continuous filament glass fibre manufacturing | 28 |
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1.4.1. |
Dust emissions from melting furnaces | 28 |
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1.4.2. |
Nitrogen oxides (NOX) from melting furnaces | 29 |
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1.4.3. |
Sulphur oxides (SOX) from melting furnaces | 29 |
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1.4.4. |
Hydrogen chloride (HCl) and hydrogen fluoride (HF) from melting furnaces | 30 |
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1.4.5. |
Metals from melting furnaces | 31 |
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1.4.6. |
Emissions from downstream processes | 31 |
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1.5. |
BAT conclusions for domestic glass manufacturing | 32 |
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1.5.1. |
Dust emissions from melting furnaces | 32 |
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1.5.2. |
Nitrogen oxides (NOX) from melting furnaces | 33 |
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1.5.3. |
Sulphur oxides (SOX) from melting furnaces | 35 |
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1.5.4. |
Hydrogen chloride (HCl) and hydrogen fluoride (HF) from melting furnaces | 35 |
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1.5.5. |
Metals from melting furnaces | 36 |
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1.5.6. |
Emissions from downstream processes | 38 |
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1.6. |
BAT conclusions for special glass manufacturing | 39 |
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1.6.1. |
Dust emissions from melting furnaces | 39 |
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1.6.2. |
Nitrogen oxides (NOX) from melting furnaces | 39 |
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1.6.3. |
Sulphur oxides (SOX) from melting furnaces | 42 |
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1.6.4. |
Hydrogen chloride (HCl) and hydrogen fluoride (HF) from melting furnaces | 42 |
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1.6.5. |
Metals from melting furnaces | 43 |
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1.6.6. |
Emissions from downstream processes | 43 |
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1.7. |
BAT conclusions for mineral wool manufacturing | 44 |
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1.7.1. |
Dust emissions from melting furnaces | 44 |
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1.7.2. |
Nitrogen oxides (NOX) from melting furnaces | 45 |
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1.7.3. |
Sulphur oxides (SOX) from melting furnaces | 46 |
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1.7.4. |
Hydrogen chloride (HCl) and hydrogen fluoride (HF) from melting furnaces | 47 |
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1.7.5. |
Hydrogen sulphide (H2S) from stone wool melting furnaces | 48 |
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1.7.6. |
Metals from melting furnaces | 48 |
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1.7.7. |
Emissions from downstream processes | 49 |
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1.8. |
BAT conclusions for high temperature insulation wools (HTIW) manufacturing | 50 |
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1.8.1. |
Dust emissions from melting and downstream processes | 50 |
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1.8.2. |
Nitrogen oxides (NOX) from melting and downstream processes | 51 |
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1.8.3. |
Sulphur oxides (SOX) from melting and downstream processes | 52 |
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1.8.4. |
Hydrogen chloride (HCl) and hydrogen fluoride (HF) from melting furnaces | 52 |
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1.8.5. |
Metals from melting furnaces and downstream processes | 53 |
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1.8.6. |
Volatile organic compounds from downstream processes | 53 |
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1.9. |
BAT conclusions for frits manufacturing | 54 |
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1.9.1. |
Dust emissions from melting furnaces | 54 |
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1.9.2. |
Nitrogen oxides (NOX) from melting furnaces | 54 |
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1.9.3. |
Sulphur oxides (SOX) from melting furnaces | 55 |
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1.9.4. |
Hydrogen chloride (HCl) and hydrogen fluoride (HF) from melting furnaces | 56 |
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1.9.5. |
Metals from melting furnaces | 56 |
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1.9.6. |
Emissions from downstream processes | 57 |
| Glossary: | 58 |
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1.10. |
Description of techniques | 58 |
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1.10.1. |
Dust emissions | 58 |
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1.10.2. |
NOX emissions | 58 |
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1.10.3. |
SOX emissions | 60 |
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1.10.4. |
HCl, HF emissions | 60 |
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1.10.5. |
Metal emissions | 60 |
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1.10.6. |
Combined gaseous emissions (e.g. SOX, HCl, HF, boron compounds) | 61 |
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1.10.7. |
Combined emissions (solid + gaseous) | 61 |
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1.10.8. |
Emissions from cutting, grinding, polishing operations | 61 |
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1.10.9. |
H2S, VOC emissions | 62 |
SCOPE
These BAT conclusions concern the industrial activities specified in Annex I to Directive 2010/75/EU, namely:
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These BAT conclusions do not address the following activities:
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Production of water glass, covered by the reference document Large Volume Inorganic Chemicals – Solids and Other Industry (LVIC-S) |
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Production of polycrystalline wool |
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Production of mirrors, covered by the reference document Surface Treatment Using Organic Solvents (STS) |
Other reference documents which are of relevance for the activities covered by these BAT conclusions are the following:
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Reference documents |
Activity |
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Emissions from Storage (EFS) |
Storage and handling of raw materials |
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Energy Efficiency (ENE) |
General energy efficiency |
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Economic and Cross-Media Effects (ECM) |
Economics and cross-media effects of techniques |
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General Principles of Monitoring (MON) |
Emissions and consumption monitoring |
The techniques listed and described in these BAT conclusions are neither prescriptive nor exhaustive. Other techniques may be used that ensure at least an equivalent level of environmental protection.
DEFINITIONS
For the purposes of these BAT conclusions, the following definitions apply:
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Term used |
Definition |
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New plant |
A plant introduced on the site of the installation following the publication of these BAT conclusions or a complete replacement of a plant on the existing foundations of the installation following the publication of these BAT conclusions |
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Existing plant |
A plant which is not a new plant |
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New furnace |
A furnace introduced on the site of the installation following the publication of these BAT conclusions or a complete rebuild of a furnace following the publication of these BAT conclusions |
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Normal furnace rebuild |
A rebuild between campaigns without a significant change in furnace requirements or technology and in which the furnace frame is not significantly adjusted and the furnace dimensions remain basically unchanged. The refractory of the furnace and, where appropriate, the regenerators are repaired by the full or partial replacement of the material. |
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Complete furnace rebuild |
A rebuild involving a major change in the furnace requirements or technology and with major adjustment or replacement of the furnace and associated equipments. |
GENERAL CONSIDERATIONS
Averaging periods and reference conditions for air emissions
Unless stated otherwise, emission levels associated with the best available techniques (BAT-AELs) for air emissions given in these BAT conclusions apply under the reference conditions shown in Table 1. All values for concentrations in waste gases refer to standard conditions: dry gas, temperature 273,15 K, pressure 101,3 kPa.
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For discontinuous measurements |
BAT-AELs refer to the average value of three spot samples of at least 30 minutes each; for regenerative furnaces the measuring period should cover a minimum of two firing reversals of the regenerator chambers |
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For continuous measurements |
BAT-AELs refer to daily average values |
Table 1
Reference conditions for BAT-AELs concerning air emissions
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Activities |
Unit |
Reference conditions |
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Melting activities |
Conventional melting furnace in continuous melters |
mg/Nm3 |
8 % oxygen by volume |
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Conventional melting furnace in discontinuous melters |
mg/Nm3 |
13 % oxygen by volume |
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Oxy-fuel-fired furnaces |
kg/tonne melted glass |
The expression of emission levels measured as mg/Nm3 to a reference oxygen concentration is not applicable |
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Electric furnaces |
mg/Nm3 or kg/tonne melted glass |
The expression of emission levels measured as mg/Nm3 to a reference oxygen concentration is not applicable |
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Frit melting furnaces |
mg/Nm3 or kg/tonne melted frit |
Concentrations refer to 15 % oxygen by volume. When air-gas firing is used, BAT AELs expressed as emission concentration (mg/Nm3) apply. When only oxy-fuel firing is employed, BAT AELs expressed as specific mass emissions (kg/tonne melted frit) apply. When oxygen-enriched air-fuel firing is used, BAT AELs expressed as either emission concentration (mg/Nm3) or as specific mass emissions (kg/tonne melted frit) apply |
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All type of furnaces |
kg/tonne melted glass |
The specific mass emissions refer to 1 tonne of melted glass |
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Non-melting activities, including downstream processes |
All processes |
mg/Nm3 |
No correction for oxygen |
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All processes |
kg/tonne glass |
The specific mass emissions refer to 1 tonne of produced glass |
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Conversion to reference oxygen concentration
The formula for calculating the emissions concentration at a reference oxygen level (see Table 1) is shown below.
Where:
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ER (mg/Nm3) |
: |
emissions concentration corrected to the reference oxygen level OR |
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OR (vol %) |
: |
reference oxygen level |
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EM (mg/Nm3) |
: |
emissions concentration referred to the measured oxygen level OM |
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OM (vol %) |
: |
measured oxygen level. |
Conversion from concentrations to specific mass emissions
BAT-AELs given in Sections 1.2 to 1.9 as specific mass emissions (kg/tonne melted glass) are based on the calculation reported below except for oxy-fuel fired furnaces and, in a limited number of cases, for electric melting where BAT-AELs given in kg/tonne melted glass were derived from specific reported data.
The calculation procedure used for the conversion from concentrations to specific mass emissions is shown below.
Specific mass emission (kg/tonne of melted glass) = conversion factor × emissions concentration (mg/Nm3)
Where: conversion factor = (Q/P) × 10–6
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with |
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The waste gas volume (Q) is determined by the specific energy consumption, type of fuel, and the oxidant (air, air enriched by oxygen and oxygen with purity depending on the production process). The energy consumption is a complex function of (predominantly) the type of furnace, the type of glass and the cullet percentage.
However, a range of factors can influence the relationship between concentration and specific mass flow, including:
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type of furnace (air preheating temperature, melting technique) |
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type of glass produced (energy requirement for melting) |
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energy mix (fossil fuel/electric boosting) |
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type of fossil fuel (oil, gas) |
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type of oxidant (oxygen, air, oxygen-enriched air) |
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cullet percentage |
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batch composition |
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age of the furnace |
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furnace size. |
The conversion factors given in Table 2 have been used for converting BAT-AELs from concentrations into specific mass emissions.
The conversion factors have been determined on the basis of energy efficient furnaces and relate only to full air/fuel-fired furnaces.
Table 2
Indicative factors used for converting mg/Nm3 into kg/tonne of melted glass based on energy efficient fuel-air furnaces
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Sectors |
Factors to convert mg/Nm3 into kg/tonne of melted glass |
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Flat glass |
2,5 × 10–3 |
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Container glass |
General case |
1,5 × 10–3 |
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Specific cases (1) |
Case-by-case study (often 3,0 × 10–3) |
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Continuous filament glass fibre |
4,5 × 10–3 |
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Domestic glass |
Soda lime |
2,5 × 10–3 |
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Specific cases (2) |
Case-by-case study (between 2,5 and > 10 × 10–3; often 3,0 × 10–3) |
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Mineral wool |
Glass wool |
2 × 10–3 |
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Stone wool cupola |
2,5 × 10–3 |
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Special glass |
TV glass (panels) |
3 × 10–3 |
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TV glass (funnel) |
2,5 × 10–3 |
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Borosilicate (tube) |
4 × 10–3 |
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Glass ceramics |
6,5 × 10–3 |
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Lighting glass (soda-lime) |
2,5 × 10–3 |
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Frits |
Case-by-case study (between 5 – 7,5 × 10–3) |
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DEFINITIONS FOR CERTAIN AIR POLLUTANTS
For the purpose of these BAT conclusions and for the BAT-AELs reported in Sections 1.2 to 1.9, the following definitions apply:
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NOX expressed as NO2 |
The sum of nitrogen oxide (NO) and nitrogen dioxide (NO2) expressed as NO2 |
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SOX expressed as SO2 |
The sum of sulphur dioxide (SO2) and sulphur trioxide (SO3) expressed as SO2 |
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Hydrogen chloride expressed as HCl |
All gaseous chlorides expressed as HCl |
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Hydrogen fluoride expressed as HF |
All gaseous fluorides expressed as HF |
AVERAGING PERIODS FOR WASTE WATER DISCHARGES
Unless stated otherwise, emission levels associated with the best available techniques (BAT-AELs) for waste water emissions given in these BAT conclusions refer to the average value of a composite sample taken over a period of 2 hours or 24 hours.
1.1. General BAT conclusions for the manufacture of glass
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all installations.
The process-specific BAT included in Sections 1.2 – 1.9 apply in addition to the general BAT mentioned in this section.
1.1.1.
1. BAT is to implement and adhere to an environmental management system (EMS) that incorporates all of the following features:
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(i) |
commitment of the management, including senior management; |
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(ii) |
definition of an environmental policy that includes the continuous improvement for the installation by the management; |
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(iii) |
planning and establishing the necessary procedures, objectives and targets, in conjunction with financial planning and investment; |
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(iv) |
implementation of the procedures paying particular attention to:
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(v) |
checking performance and taking corrective action, paying particular attention to:
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(vi) |
review of the EMS and its continuing suitability, adequacy and effectiveness by senior management; |
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(vii) |
following the development of cleaner technologies; |
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(viii) |
consideration for the environmental impacts from the eventual decommissioning of the installation at the stage of designing a new plant, and throughout its operating life; |
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(ix) |
application of sectoral benchmarking on a regular basis. |
Applicability
The scope (e.g. level of details) and nature of the EMS (e.g. standardised or non-standardised) will generally be related to the nature, scale and complexity of the installation, and the range of environmental impacts it may have.
1.1.2.
2. BAT is to reduce the specific energy consumption by using one or a combination of the following techniques:
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Technique |
Applicability |
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The techniques are generally applicable |
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Applicable for new plants. For existing plants, the implementation requires a complete rebuild of the furnace |
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Applicable to fuel/air and oxy-fuel fired furnaces |
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Not applicable to the continuous filament glass fibre, high temperature insulation wool and frits sectors |
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Applicable to fuel/air and oxy-fuel fired furnaces. The applicability and economic viability of the technique is dictated by the overall efficiency that may be obtained, including the effective use of the steam generated |
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Applicable to fuel/air and oxy-fuel fired furnaces. The applicability is normally restricted to batch compositions with more than 50 % cullet |
1.1.3.
3. BAT is to prevent, or where that is not practicable, to reduce diffuse dust emissions from the storage and handling of solid materials by using one or a combination of the following techniques:
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I. |
Storage of raw materials
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II. |
Handling of raw materials
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4. BAT is to prevent, or where that is not practicable, to reduce diffuse gaseous emissions from the storage and handling of volatile raw materials by using one or a combination of the following techniques:
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(i) |
Use of tank paint with low solar absorbency for bulk storage subject to temperature changes due to solar heating. |
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(ii) |
Control of temperature in the storage of volatile raw materials. |
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(iii) |
Tank insulation in the storage of volatile raw materials. |
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(iv) |
Inventory management |
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(v) |
Use of floating roof tanks in the storage of large quantities of volatile petroleum products. |
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(vi) |
Use of vapour return transfer systems in the transfer of volatile fluids (e.g. from tank trucks to storage tank). |
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(vii) |
Use of bladder roof tanks in the storage of liquid raw materials. |
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(viii) |
Use of pressure/vacuum valves in tanks designed to withstand pressure fluctuations. |
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(ix) |
Application of a release treatment (e.g. adsorption, absorption, condensation) in the storage of hazardous materials. |
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(x) |
Application of subsurface filling in the storage of liquids that tend to foam. |
1.1.4.
5. BAT is to reduce energy consumption and emissions to air by carrying out a constant monitoring of the operational parameters and a programmed maintenance of the melting furnace.
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Technique |
Applicability |
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The technique consists of a series of monitoring and maintenance operations which can be used individually or in combination appropriate to the type of furnace, with the aim of minimising the ageing effects on the furnace, such as sealing the furnace and burner blocks, keep the maximum insulation, control the stabilised flame conditions, control the fuel/air ratio, etc. |
Applicable to regenerative, recuperative, and oxy-fuel fired furnaces. The applicability to other types of furnaces requires an installation-specific assessment |
6. BAT is to carry out a careful selection and control of all substances and raw materials entering the melting furnace in order to reduce or prevent emissions to air by using one or a combination of the following techniques.
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Technique |
Applicability |
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Applicable within the constraints of the type of glass produced at the installation and the availability of raw materials and fuels |
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7. BAT is to carry out monitoring of emissions and/or other relevant process parameters on a regular basis, including the following:
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Technique |
Applicability |
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The techniques are generally applicable |
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The techniques are generally applicable |
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The techniques are generally applicable |
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8. BAT is to operate the waste gas treatment systems during normal operating conditions at optimal capacity and availability in order to prevent or reduce emissions
Applicability
Special procedures can be defined for specific operating conditions, in particular:
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(i) |
during start-up and shutdown operations |
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(ii) |
during other special operations which could affect the proper functioning of the systems (e.g. regular and extraordinary maintenance work and cleaning operations of the furnace and/or of the waste gas treatment system, or severe production change) |
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(iii) |
in the case of insufficient waste gas flow or temperature which prevents the use of the system at full capacity. |
9. BAT is to limit carbon monoxide (CO) emissions from the melting furnace, when applying primary techniques or chemical reduction by fuel, for the reduction of NOX emissions
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Technique |
Applicability |
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Primary techniques for the reduction of NOX emissions are based on combustion modifications (e.g. reduction of air/fuel ratio, staged combustion low-NOX burners, etc.). Chemical reduction by fuel consists of the addition of hydrocarbon fuel to the waste gas stream to reduce the NOX formed in the furnace. The increase in CO emissions due to the application of these techniques can be limited by a careful control of the operational parameters |
Applicable to conventional air/fuel fired furnaces. |
Table 3
BAT-AELs for carbon monoxide emissions from melting furnaces
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Parameter |
BAT-AEL |
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Carbon monoxide, expressed as CO |
< 100 mg/Nm3 |
10. BAT is to limit ammonia (NH3) emissions, when applying selective catalytic reduction (SCR) or selective non-catalytic reduction (SNCR) techniques for a high efficiency NOX emissions reduction
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Technique |
Applicability |
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The technique consists of adopting and maintaining suitable operating conditions of the SCR or SNCR waste gas treatment systems, with the aim of limiting emissions of unreacted ammonia |
Applicable to melting furnaces fitted with SCR or SNCR |
Table 4
BAT-AELs for ammonia emissions, when SCR or SNCR techniques are applied
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Parameter |
BAT-AELs (3) |
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Ammonia, expressed as NH3 |
< 5 – 30 mg/Nm3 |
11. BAT is to reduce boron emissions from the melting furnace, when boron compounds are used in the batch formulation, by using one or a combination of the following techniques:
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Technique (4) |
Applicability |
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The applicability to existing plants may be limited by technical constraints associated with the position and characteristics of the existing filter system |
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The applicability may be limited by a decreased removal efficiency of other gaseous pollutants (SOX, HCl, HF) caused by the deposition of boron compounds on the surface of the dry alkaline reagent |
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The applicability to existing plants may be limited by the need of a specific waste water treatment |
Monitoring
The monitoring of boron emissions should be carried out according to a specific methodology which allows measurement of both solid and gaseous forms and to determine the effective removal of these species from the flue gases.
1.1.5.
12. BAT is to reduce water consumption by using one or a combination of the following techniques:
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Technique |
Applicability |
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The technique is generally applicable |
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The technique is generally applicable. Recirculation of scrubbing water is applicable to most scrubbing systems; however, periodic discharge and replacement of the scrubbing medium may be necessary |
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The applicability of this technique may be limited by the constraints associated with the safety management of the production process. In particular:
|
13. BAT is to reduce the emission load of pollutants in the waste water discharges by using one or a combination of the following waste water treatment systems:
|
Technique |
Applicability |
||
|
The techniques are generally applicable |
||
|
The applicability is limited to the sectors which use organic substances in the production process (e.g. continuous filament glass fibre and mineral wool sectors) |
||
|
Applicable to installations where further reduction of pollutants is necessary |
||
|
The applicability is generally limited to the frits sector (possible reuse in the ceramic industry) |
Table 5
BAT-AELs for waste water discharges to surface waters from the manufacture of glass
|
Parameter (5) |
Unit |
BAT-AEL (6) (composite sample) |
|
pH |
— |
6,5 – 9 |
|
Total suspended solids |
mg/l |
< 30 |
|
Chemical oxygen demand (COD) |
mg/l |
< 5 – 130 (7) |
|
Sulphates, expressed as SO4 2– |
mg/l |
< 1 000 |
|
Fluorides, expressed as F– |
mg/l |
< 6 (8) |
|
Total hydrocarbons |
mg/l |
< 15 (9) |
|
Lead, expressed as Pb |
mg/l |
< 0,05 – 0,3 (10) |
|
Antimony, expressed as Sb |
mg/l |
< 0,5 |
|
Arsenic, expressed as As |
mg/l |
< 0,3 |
|
Barium, expressed as Ba |
mg/l |
< 3,0 |
|
Zinc, expressed as Zn |
mg/l |
< 0,5 |
|
Copper, expressed as Cu |
mg/l |
< 0,3 |
|
Chromium, expressed as Cr |
mg/l |
< 0,3 |
|
Cadmium, expressed as Cd |
mg/l |
< 0,05 |
|
Tin, expressed as Sn |
mg/l |
< 0,5 |
|
Nickel, expressed as Ni |
mg/l |
< 0,5 |
|
Ammonia, expressed as NH4 |
mg/l |
< 10 |
|
Boron, expressed as B |
mg/l |
< 1 – 3 |
|
Phenol |
mg/l |
< 1 |
1.1.6.
14. BAT is to reduce the production of solid waste to be disposed of by using one or a combination of the following techniques:
|
Technique |
Applicability |
||||||||||
|
The applicability may be limited by the constraints associated with the quality of the final glass product |
||||||||||
|
The technique is generally applicable |
||||||||||
|
Generally, not applicable to the continuous filament glass fibre, high temperature insulation wool and frits sectors |
||||||||||
|
The applicability may be limited by different factors:
|
||||||||||
|
Generally applicable to the domestic glass sector (for lead crystal cutting sludge) and to the container glass sector (fine particles of glass mixed with oil). Limited applicability to other glass manufacturing sectors due to unpredictable, contaminated composition, low volumes and economic viability |
||||||||||
|
The applicability is limited by the constraints imposed by the refractory manufacturers and potential end-users |
||||||||||
|
The applicability of cement bonded briquetting of waste is limited to the stone wool sector. A trade-off approach between air emissions and the generation of solid waste stream should be undertaken |
1.1.7.
15. BAT is to reduce noise emissions by using one or a combination of the following techniques:
|
(i) |
Make an environmental noise assessment and formulate a noise management plan as appropriate to the local environment |
|
(ii) |
Enclose noisy equipment/operation in a separate structure/unit |
|
(iii) |
Use embankments to screen the source of noise |
|
(iv) |
Carry out noisy outdoor activities during the day |
|
(v) |
Use noise protection walls or natural barriers (trees, bushes) between the installation and the protected area, on the basis of local conditions. |
1.2. BAT conclusions for container glass manufacturing
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all container glass manufacturing installations.
1.2.1.
16. BAT is to reduce dust emissions from the waste gases of the melting furnace by applying a flue-gas cleaning system such as an electrostatic precipitator or a bag filter.
|
Technique (11) |
Applicability |
|
The flue-gas cleaning systems consist of end-of-pipe techniques based on the filtration of all materials that are solid at the point of measurement |
The technique is generally applicable |
Table 6
BAT-AELs for dust emissions from the melting furnace in the container glass sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (12) |
|
|
Dust |
< 10 – 20 |
< 0,015 – 0,06 |
1.2.2.
17. BAT is to reduce NOX emissions from the melting furnace by using one or a combination of the following techniques:
|
I. |
primary techniques, such as:
|
|
II. |
secondary techniques, such as:
|
Table 7
BAT-AELs for NOX emissions from the melting furnace in the container glass sector
|
Parameter |
BAT |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (15) |
||
|
NOX expressed as NO2 |
500 – 800 |
0,75 – 1,2 |
|
|
Electric melting |
< 100 |
< 0,3 |
|
|
Oxy-fuel melting (18) |
Not applicable |
< 0,5 – 0,8 |
|
|
Secondary techniques |
< 500 |
< 0,75 |
|
18. When nitrates are used in the batch formulation and/or special oxidising combustion conditions are required in the melting furnace for ensuring the quality of the final product, BAT is to reduce NOX emissions by minimising the use of these raw materials, in combination with primary or secondary techniques
The BAT-AELs are set out in Table 7.
If nitrates are used in the batch formulation for short campaigns or for melting furnaces with a capacity of < 100 t/day, the BAT-AEL is set out in Table 8.
|
Technique (19) |
Applicability |
||
|
Primary techniques:
|
The substitution of nitrates in the batch formulation may be limited by the high costs and/or higher environmental impact of the alternative materials |
Table 8
BAT-AEL for NOX emissions from the melting furnace in the container glass sector, when nitrates are used in the batch formulation and/or special oxidising combustion conditions in cases of short campaigns or for melting furnaces with a capacity of < 100 t/day
|
Parameter |
BAT |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (20) |
||
|
NOX expressed as NO2 |
Primary techniques |
< 1 000 |
< 3 |
1.2.3.
19. BAT is to reduce SOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (21) |
Applicability |
||
|
The technique is generally applicable |
||
|
The minimisation of the sulphur content in the batch formulation is generally applicable within the constraints of quality requirements of the final glass product. The application of sulphur balance optimisation requires a trade-off approach between the removal of SOX emissions and the management of the solid waste (filter dust). The effective reduction of SOX emissions depends on the retention of sulphur compounds in the glass which may vary significantly depending on the glass type |
||
|
The applicability may be limited by the constraints associated with the availability of low sulphur fuels, which may be impacted by the energy policy of the Member State |
Table 9
BAT-AELs for SOX emissions from the melting furnace in the container glass sector
|
Parameter |
Fuel |
||
|
mg/Nm3 |
kg/tonne melted glass (24) |
||
|
SOX expressed as SO2 |
Natural gas |
< 200 – 500 |
< 0,3 – 0,75 |
|
Fuel oil (25) |
< 500 – 1 200 |
< 0,75 – 1,8 |
|
1.2.4.
20. BAT is to reduce HCl and HF emissions from the melting furnace (possibly combined with flue-gases from hot-end coating activities) by using one or a combination of the following techniques:
|
Technique (26) |
Applicability |
||
|
The applicability may be limited by the constraints of the type of glass produced at the installation and the availability of raw materials |
||
|
The technique is generally applicable |
Table 10
BAT-AELs for HCl and HF emissions from the melting furnace in the container glass sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (27) |
|
|
Hydrogen chloride, expressed as HCl (28) |
< 10 – 20 |
< 0,02 – 0,03 |
|
Hydrogen fluoride, expressed as HF |
< 1 – 5 |
< 0,001 – 0,008 |
1.2.5.
21. BAT is to reduce metal emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (29) |
Applicability |
||
|
The applicability may be limited by the constraints imposed by the type of glass produced at the installation and the availability of the raw materials |
||
|
|||
|
The techniques are generally applicable |
||
|
Table 11
BAT-AELs for metal emissions from the melting furnace in the container glass sector
|
Parameter |
||
|
mg/Nm3 |
kg/tonne melted glass (33) |
|
|
Σ (As, Co, Ni, Cd, Se, CrVI) |
< 0,2 – 1 (34) |
< 0,3 – 1,5 × 10–3 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) |
< 1 – 5 |
< 1,5 – 7,5 × 10–3 |
1.2.6.
22. When tin, organotin or titanium compounds are used for hot-end coating operations, BAT is to reduce emissions by using one or a combination of the following techniques:
|
Technique |
Applicability |
||||||
|
The technique is generally applicable |
||||||
|
The combination with flue gases from the melting furnace is generally applicable. The combination with combustion air may be affected by technical constraints due to some potential effects on the glass chemistry and on the regenerator materials |
||||||
|
The techniques are generally applicable |
Table 12
BAT-AELs for air emissions from hot-end coating activities in the container glass sector when the flue-gases from downstream operations are treated separately
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
Dust |
< 10 |
|
Titanium compounds expressed as Ti |
< 5 |
|
Tin compounds, including organotin, expressed as Sn |
< 5 |
|
Hydrogen chloride, expressed as HCl |
< 30 |
23. When SO3 is used for surface treatment operations, BAT is to reduce SOX emissions by using one or a combination of the following techniques:
|
Technique (36) |
Applicability |
||
|
The techniques are generally applicable |
||
|
Table 13
BAT-AEL for SOX emissions from downstream activities when SO3 is used for surface treatment operations in the container glass sector, when treated separately
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
SOx, expressed as SO2 |
< 100 – 200 |
1.3. BAT conclusions for flat glass manufacturing
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all flat glass manufacturing installations.
1.3.1.
24. BAT is to reduce dust emissions from the waste gases of the melting furnace by applying an electrostatic precipitator or a bag filter system
A description of the techniques is given in Section 1.10.1.
Table 14
BAT-AELs for dust emissions from the melting furnace in the flat glass sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (37) |
|
|
Dust |
< 10 – 20 |
< 0,025 – 0,05 |
1.3.2.
25. BAT is to reduce NOX emissions from the melting furnace by using one or a combination of the following techniques:
|
I. |
primary techniques, such as:
|
|
II. |
secondary techniques, such as:
|
Table 15
BAT-AELs for NOX emissions from the melting furnace in the flat glass sector
|
Parameter |
BAT |
BAT-AEL (40) |
|
|
mg/Nm3 |
kg/tonne melted glass (41) |
||
|
NOX expressed as NO2 |
Combustion modifications, Fenix process (42) |
700 – 800 |
1,75 – 2,0 |
|
Oxy-fuel melting (43) |
Not applicable |
< 1,25 – 2,0 |
|
|
Secondary techniques (44) |
400 – 700 |
1,0 – 1,75 |
|
26. When nitrates are used in the batch formulation, BAT is to reduce NOX emissions by minimising the use of these raw materials, in combination with primary or secondary techniques. If secondary techniques are applied, the BAT-AELs reported in Table 15 are applicable.
If nitrates are used in the batch formulation for the production of special glasses in a limited number of short campaigns, the BAT-AELs are set out in Table 16.
|
Technique (45) |
Applicability |
||||||
|
Primary techniques:
|
The substitution of nitrates in the batch formulation may be limited by the high costs and/or higher environmental impact of the alternative materials |
Table 16
BAT-AEL for NOX emissions from the melting furnace in the flat glass sector, when nitrates are used in the batch formulation for the production of special glasses in a limited number of short campaigns
|
Parameter |
BAT |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (46) |
||
|
NOX expressed as NO2 |
Primary techniques |
< 1 200 |
< 3 |
1.3.3.
27. BAT is to reduce SOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (47) |
Applicability |
||
|
The technique is generally applicable |
||
|
The minimisation of the sulphur content in the batch formulation is generally applicable within the constraints of quality requirements of the final glass product. The application of sulphur balance optimisation requires a trade-off approach between the removal of SOX emissions and the management of the solid waste (filter dust) |
||
|
The applicability may be limited by the constraints associated with the availability of low sulphur fuels, which may be impacted by the energy policy of the Member State |
Table 17
BAT-AELs for SOX emissions from the melting furnace in the flat glass sector
|
Parameter |
Fuel |
BAT-AEL (48) |
|
|
mg/Nm3 |
kg/tonne melted glass (49) |
||
|
SOx expressedas SO2 |
Natural gas |
< 300 – 500 |
< 0,75 – 1,25 |
|
500 – 1 300 |
1,25 – 3,25 |
||
1.3.4.
28. BAT is to reduce HCl and HF emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (52) |
Applicability |
||
|
The applicability may be limited by the constraints of the type of glass produced at the installation and the availability of raw materials |
||
|
The technique is generally applicable |
Table 18
BAT-AELs for HCl and HF emissions from the melting furnace in the flat glass sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (53) |
|
|
Hydrogen chloride, expressed as HCl (54) |
< 10 – 25 |
< 0,025 – 0,0625 |
|
Hydrogen fluoride, expressed as HF |
< 1 – 4 |
< 0,0025 – 0,010 |
1.3.5.
29. BAT is to reduce metal emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (55) |
Applicability |
||
|
The applicability may be limited by the constraints imposed by the type of glass produced at the installation and the availability of the raw materials. |
||
|
The technique is generally applicable |
||
|
Table 19
BAT-AELs for metal emissions from the melting furnace in the flat glass sector, with the exception of selenium coloured glasses
|
Parameter |
BAT-AEL (56) |
|
|
mg/Nm3 |
kg/tonne melted glass (57) |
|
|
Σ (As, Co, Ni, Cd, Se, CrVI) |
< 0,2 – 1 |
< 0,5 – 2,5 × 10–3 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) |
< 1 – 5 |
< 2,5 – 12,5 × 10–3 |
30. When selenium compounds are used for colouring the glass, BAT is to reduce selenium emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (58) |
Applicability |
||
|
The applicability may be limited by the constraints imposed by the type of glass produced at the installation and the availability of the raw materials |
||
|
The technique is generally applicable |
||
|
Table 20
BAT-AELs for selenium emissions from the melting furnace in the flat glass sector for the production of coloured glass
|
Parameter |
||
|
mg/Nm3 |
kg/tonne melted glass (61) |
|
|
Selenium compounds, expressed as Se |
1 – 3 |
2,5 – 7,5 × 10–3 |
1.3.6.
31. BAT is to reduce emissions to air from the downstream processes by using one or a combination of the following techniques:
|
Technique (62) |
Applicability |
||
|
The techniques are generally applicable |
||
|
|||
|
|||
|
The techniques are generally applicable. The selection of the technique and its performance will depend on the inlet waste gas composition |
Table 21
BAT-AELs for air emissions from downstream processes in the flat glass sector, when treated separately
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
Dust |
< 15 – 20 |
|
Hydrogen chloride, expressed as HCl |
< 10 |
|
Hydrogen fluoride, expressed as HF |
< 1 – 5 |
|
SOX, expressed as SO2 |
< 200 |
|
Σ (As, Co, Ni, Cd, Se, CrVI) |
< 1 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) |
< 5 |
1.4. BAT conclusions for continuous filament glass fibre manufacturing
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all continuous filament glass fibre manufacturing installations.
1.4.1.
The BAT-AELs reported in this section for dust refer to all materials that are solid at the point of measurement, including solid boron compounds. Gaseous boron compounds at the point of measurement are not included.
32. BAT is to reduce dust emissions from the waste gases of the melting furnace by using one or a combination of the following techniques:
|
Technique (63) |
Applicability |
||
|
The application of the technique is limited by proprietary issues, since the boron-free or low-boron batch formulations are covered by a patent |
||
|
The technique is generally applicable. The maximum environmental benefits are achieved for applications on new plants where the positioning and characteristics of the filter may be decided without restrictions |
||
|
The application to existing plants may be limited by technical constraints; i.e. need for a specific waste water treatment plant |
Table 22
BAT-AELs for dust emissions from the melting furnace in the continuous filament glass fibre sector
|
Parameter |
BAT-AEL (64) |
|
|
mg/Nm3 |
kg/tonne melted glass (65) |
|
|
Dust |
< 10 – 20 |
< 0,045 – 0,09 |
1.4.2.
33. BAT is to reduce NOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (66) |
Applicability |
||||||
| (i) Combustion modifications |
|||||||
|
Applicable to air/fuel conventional furnaces. Full benefits are achieved at normal or complete furnace rebuild, when combined with optimum furnace design and geometry |
||||||
|
Applicable to air/fuel conventional furnaces within the constraints of the furnace energy efficiency and higher fuel demand. Most furnaces are already of the recuperative type. |
||||||
|
Fuel staging is applicable to most air/fuel, oxy-fuel furnaces. Air staging has very limited applicability due to its technical complexity |
||||||
|
The applicability of this technique is limited to the use of special burners with automatic recirculation of the waste gas |
||||||
|
The technique is generally applicable. Full benefits are achieved at normal or complete furnace rebuild, when combined with optimum furnace design and geometry |
||||||
|
The applicability is limited by the constraints associated with the availability of different types of fuel, which may be impacted by the energy policy of the Member State |
||||||
|
The maximum environmental benefits are achieved for applications at the time of a complete furnace rebuild |
Table 23
BAT-AELs for NOX emissions from the melting furnace in the continuous filament glass fibre sector
|
Parameter |
BAT |
BAT-AEL |
|
|
|
mg/Nm3 |
kg/tonne melted glass |
|
|
NOX expressed as NO2 |
Combustion modifications |
< 600 – 1 000 |
< 2,7 – 4,5 (67) |
|
Oxy-fuel melting (68) |
Not applicable |
< 0,5 – 1,5 |
|
1.4.3.
34. BAT is to reduce SOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (69) |
Applicability |
||
|
The technique is generally applicable within the constraints of quality requirements of the final glass product. The application of sulphur balance optimisation requires a trade-off approach between the removal of SOX emissions and the management of the solid waste (filter dust), which needs to be disposed of |
||
|
The applicability may be limited by the constraints associated with the availability of low sulphur fuels, which may be impacted by the energy policy of the Member State |
||
|
The technique is generally applicable. The presence of high concentrations of boron compounds in the flue-gases may limit the abatement efficiency of the reagent used in the dry or semi-dry scrubbing systems |
||
|
The technique is generally applicable within technical constraints; i.e. need for a specific waste water treatment plant |
Table 24
BAT-AELs for SOX emissions from the melting furnace in the continuous filament glass fibre sector
|
Parameter |
Fuel |
BAT-AEL (70) |
|
|
mg/Nm3 |
kg/tonne melted glass (71) |
||
|
SOx expressed as SO2 |
Natural gas (72) |
< 200 – 800 |
< 0,9 – 3,6 |
|
< 500 – 1 000 |
< 2,25 – 4,5 |
||
1.4.4.
35. BAT is to reduce HCl and HF emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (75) |
Applicability |
||||||
|
The technique is generally applicable within the constraints of the batch formulation and the availability of raw materials |
||||||
|
The substitution of fluorine compounds with alternative materials is limited by quality requirements of the product |
||||||
|
The technique is generally applicable |
||||||
|
The technique is generally applicable within technical constraints; i.e. need for a specific waste water treatment plant. |
Table 25
BAT-AELs for HCl and HF emissions from the melting furnace in the continuous filament glass fibre sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (76) |
|
|
Hydrogen chloride, expressed as HCl |
< 10 |
< 0,05 |
|
Hydrogen fluoride, expressed as HF (77) |
< 5 – 15 |
< 0,02 – 0,07 |
1.4.5.
36. BAT is to reduce metal emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (78) |
Applicability |
||
|
The technique is generally applicable within the constraints of the availability of raw materials |
||
|
The technique is generally applicable |
||
|
The technique is generally applicable within technical constraints; i.e. need for a specific waste water treatment plant. |
Table 26
BAT-AELs for metal emissions from the melting furnace in the continuous filament glass fibre sector
|
Parameter |
BAT-AEL (79) |
|
|
mg/Nm3 |
kg/tonne melted glass (80) |
|
|
Σ (As, Co, Ni, Cd, Se, CrVI) |
< 0,2 – 1 |
< 0,9 – 4,5 × 10–3 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) |
< 1 – 3 |
< 4,5 – 13,5 × 10–3 |
1.4.6.
37. BAT is to reduce emissions from downstream processes by using one or a combination of the following techniques:
|
Technique (81) |
Applicability |
||
|
The techniques are generally applicable for the treatment of waste gases from the forming process (application of the coating to the fibres) or secondary processes which involve the use of binder that must be cured or dried |
||
|
|||
|
The technique is generally applicable for the treatment of waste gases from cutting and milling operations of the products |
Table 27
BAT-AELs for air emissions from downstream processes in the continuous filament glass fibre sector, when treated separately
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
Emissions from forming and coating |
|
|
Dust |
< 5 – 20 |
|
Formaldehyde |
< 10 |
|
Ammonia |
< 30 |
|
Total volatile organic compounds, expressed as C |
< 20 |
|
Emissions from cutting and milling |
|
|
Dust |
< 5 – 20 |
1.5. BAT conclusions for domestic glass manufacturing
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all domestic glass manufacturing installations.
1.5.1.
38. BAT is to reduce dust emissions from the waste gases of the melting furnace by using one or a combination of the following techniques:
|
Technique (82) |
Applicability |
||
|
The technique is generally applicable within the constraints of the type of glass produced and the availability of substitute raw materials |
||
|
Not applicable for large volume glass productions (> 300 tonnes/day). Not applicable for productions requiring large pull variations The implementation requires a complete furnace rebuild |
||
|
The maximum environmental benefits are achieved for applications made at the time of a complete furnace rebuild |
||
|
The techniques are generally applicable |
||
|
The applicability is limited to specific cases, in particular to electric melting furnaces, where flue-gas volumes and dust emissions are generally low and related to carryover of the batch formulation |
Table 28
BAT-AELs for dust emissions from the melting furnace in the domestic glass sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (83) |
|
|
Dust |
< 10 – 20 (84) |
< 0,03 – 0,06 |
|
< 1 – 10 (85) |
< 0,003 – 0,03 |
|
1.5.2.
39. BAT is to reduce NOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (86) |
Applicability |
||||||
| (i) Combustion modifications |
|||||||
|
Applicable to air/fuel conventional furnaces. Full benefits are achieved at normal or complete furnace rebuild, when combined with optimum furnace design and geometry |
||||||
|
Applicable only under installation-specific circumstances due to a lower furnace efficiency and higher fuel demand (i.e. use of recuperative furnaces in place of regenerative furnaces) |
||||||
|
Fuel staging is applicable to most conventional air/fuel furnaces. Air staging has very limited applicability due to its technical complexity |
||||||
|
The applicability of this technique is limited to the use of special burners with automatic recirculation of the waste gas |
||||||
|
The technique is generally applicable. The achieved environmental benefits are generally lower for applications to cross-fired, gas-fired furnaces due to technical constraints and a lower degree of flexibility of the furnace. Full benefits are achieved at normal or complete furnace rebuild, when combined with optimum furnace design and geometry |
||||||
|
The applicability is limited by the constraints associated with the availability of different types of fuel, which may be impacted by the energy policy of the Member State |
||||||
|
The applicability is limited to batch formulations that contain high levels of external cullet (> 70 %). The application requires a complete rebuild of the melting furnace. The shape of the furnace (long and narrow) may pose space restrictions |
||||||
|
Not applicable for large volume glass productions (> 300 tonnes/day). Not applicable for productions requiring large pull variations. The implementation requires a complete furnace rebuild |
||||||
|
The maximum environmental benefits are achieved for applications at the time of a complete furnace rebuild |
Table 29
BAT-AELs for NOX emissions from the melting furnace in the domestic glass sector
|
Parameter |
BAT |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (87) |
||
|
NOx expressed as NO2 |
Combustion modifications, special furnace designs |
< 500 – 1 000 |
< 1,25 – 2,5 |
|
Electric melting |
< 100 |
< 0,3 |
|
|
Oxy-fuel melting (88) |
Not applicable |
< 0,5 – 1,5 |
|
40. When nitrates are used in the batch formulation, BAT is to reduce NOX emissions by minimising the use of these raw materials, in combination with primary or secondary techniques.
The BAT-AELs are set out in Table 29.
If nitrates are used in the batch formulation for a limited number of short campaigns or for melting furnaces with a capacity < 100 t/day producing special types of soda-lime glasses (clear/ultra-clear glass or coloured glass using selenium) and other special glasses (i.e. borosilicate, glass ceramics, opal glass, crystal and lead crystal), the BAT-AELs are set out in Table 30.
|
Technique (89) |
Applicability |
||
|
Primary techniques: |
|||
|
The substitution of nitrates in the batch formulation may be limited by the high costs and/or higher environmental impact of the alternative materials |
Table 30
BAT-AELs for NOX emissions from the melting furnace in the domestic glass sector, when nitrates are used in the batch formulation for a limited number of short campaigns or for melting furnaces with a capacity < 100 t/day producing special types of soda-lime glasses (clear/ultra-clear glass or coloured glass using selenium) and other special glasses (i.e. borosilicate, glass ceramics, opal glass, crystal and lead crystal
|
Parameter |
Type of furnace |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass |
||
|
NOX expressed as NO2 |
Fuel/air conventional furnaces |
< 500 – 1 500 |
< 1,25 – 3,75 (90) |
|
Electric melting |
< 300 – 500 |
< 8 – 10 |
|
1.5.3.
41. BAT is to reduce SOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (91) |
Applicability |
||
|
The minimisation of the sulphur content in the batch formulation is generally applicable within the constraints of quality requirements of the final glass product. The application of sulphur balance optimisation requires a trade-off approach between the removal of SOX emissions and the management of the solid waste (filter dust) |
||
|
The applicability may be limited by the constraints associated with the availability of low sulphur fuels, which may be impacted by the energy policy of the Member State |
||
|
The technique is generally applicable |
Table 31
BAT-AELs for SOX emissions from the melting furnace in the domestic glass sector
|
Parameter |
Fuel/melting technique |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (92) |
||
|
SOx expressed as SO2 |
Natural gas |
< 200 – 300 |
< 0,5 – 0,75 |
|
Fuel oil (93) |
< 1 000 |
< 2,5 |
|
|
Electric melting |
< 100 |
< 0,25 |
|
1.5.4.
42. BAT is to reduce HCl and HF emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (94) |
Applicability |
||
|
The applicability may be limited by the constraints of the batch formulation for the type of glass produced at the installation and the availability of raw materials |
||
|
The technique is generally applicable within the constraints of the quality requirements for the final product |
||
|
The technique is generally applicable |
||
|
The technique is generally applicable within technical constraints; i.e. need for a specific waste water treatment plant. High costs, waste water treatment aspects, including restrictions in the recycle of sludge or solid residues from the water treatment, may limit the applicability of this technique |
Table 32
BAT-AELs for HCl and HF emissions from the melting furnace in the domestic glass sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (95) |
|
|
< 10 – 20 |
< 0,03 – 0,06 |
|
|
Hydrogen fluoride, expressed as HF (98) |
< 1 – 5 |
< 0,003 – 0,015 |
1.5.5.
43. BAT is to reduce metal emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (99) |
Applicability |
||
|
The applicability may be limited by the constraints imposed by the type of glass produced at the installation and the availability of raw materials |
||
|
For the production of crystal and lead crystal glasses the minimisation of metal compounds in the batch formulation is restricted by the limits defined in Directive 69/493/EEC which classifies the chemical composition of the final glass products. |
||
|
The technique is generally applicable |
Table 33
BAT-AELs for metal emissions from the melting furnace in the domestic glass sector with the exception of glasses where selenium is used for decolourising
|
Parameter |
BAT-AEL (100) |
|
|
mg/Nm3 |
kg/tonne melted glass (101) |
|
|
Σ (As, Co, Ni, Cd, Se, CrVI) |
< 0,2 – 1 |
< 0,6 – 3 × 10–3 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) |
< 1 – 5 |
< 3 – 15 × 10–3 |
44. When selenium compounds are used for decolourising the glass, BAT is to reduce selenium emissions from the melting furnace by using one or a combination of the following techniques
|
Technique (102) |
Applicability |
||
|
The applicability may be limited by the constraints imposed by the type of glass produced at the installation and the availability of raw materials |
||
|
The technique is generally applicable |
Table 34
BAT-AELs for selenium emissions from the melting furnace in the domestic glass sector when selenium compounds are used for decolourising the glass
|
Parameter |
BAT-AEL (103) |
|
|
mg/Nm3 |
kg/tonne melted glass (104) |
|
|
Selenium compounds, as Se |
< 1 |
< 3 × 10–3 |
45. When lead compounds are used for the manufacturing of lead crystal glass, BAT is to reduce lead emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (105) |
Applicability |
||
|
Not applicable for large volume glass productions (> 300 tonnes/day). Not applicable for productions requiring large pull variations. The implementation requires a complete furnace rebuild |
||
|
The technique is generally applicable |
||
|
|||
|
Table 35
BAT-AELs for lead emissions from the melting furnace in the domestic glass sector when lead compounds are used for manufacturing lead crystal glass
|
Parameter |
BAT-AEL (106) |
|
|
mg/Nm3 |
kg/tonne melted glass (107) |
|
|
Lead compounds, expressed as Pb |
< 0,5 – 1 |
< 1 – 3 × 10–3 |
1.5.6.
46. For downstream dusty processes, BAT is to reduce emissions of dust and metals by using one or a combination of the following techniques:
|
Technique (108) |
Applicability |
||
|
The techniques are generally applicable |
||
|
Table 36
BAT-AELs for air emissions from dusty downstream processes in the domestic glass sector, when treated separately
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
Dust |
< 1 – 10 |
|
Σ (As, Co, Ni, Cd, Se, CrVI) (109) |
< 1 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) (109) |
< 1 – 5 |
|
Lead compounds, expressed as Pb (110) |
< 1 – 1,5 |
47. For acid polishing processes, BAT is to reduce HF emissions by using one or a combination of the following techniques:
|
Technique (111) |
Applicability |
||
|
The techniques are generally applicable |
||
|
Table 37
BAT-AELs for HF emissions from acid polishing processes in the domestic glass sector, when treated separately
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
Hydrogen fluoride, expressed as HF |
< 5 |
1.6. BAT conclusions for special glass manufacturing
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all special glass manufacturing installations.
1.6.1.
48. BAT is to reduce dust emissions from the waste gases of the melting furnace by using one or a combination of the following techniques:
|
Technique (112) |
Applicability |
||
|
The technique is generally applicable within the constraints of the quality of the glass produced |
||
|
Not applicable for large volume glass productions (> 300 tonnes/day) Not applicable for productions requiring large pull variations The implementation requires a complete furnace rebuild |
||
|
The technique is generally applicable |
Table 38
BAT-AELs for dust emissions from the melting furnace in the special glass sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (113) |
|
|
Dust |
< 10 – 20 |
< 0,03 – 0,13 |
|
< 1 – 10 (114) |
< 0,003 – 0,065 |
|
1.6.2.
49. BAT is to reduce NOX emissions from the melting furnace by using one or a combination of the following techniques:
|
I. |
primary techniques, such as:
|
|
II. |
secondary techniques, such as:
|
Table 39
BAT-AELs for NOX emissions from the melting furnace in the special glass sector
|
Parameter |
BAT |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (117) |
||
|
NOX expressed as NO2 |
Combustion modifications |
600 – 800 |
1,5 – 3,2 |
|
Electric melting |
< 100 |
< 0,25 – 0,4 |
|
|
Not applicable |
< 1 – 3 |
||
|
Secondary techniques |
< 500 |
< 1 – 3 |
|
50. When nitrates are used in the batch formulation, BAT is to reduce NOX emissions by minimising the use of these raw materials, in combination with either primary or secondary techniques
|
Technique (120) |
Applicability |
||
|
Primary techniques |
|||
|
The substitution of nitrates in the batch formulation may be limited by the high costs and/or higher environmental impact of the alternative materials |
Table 40
BAT-AELs for NOX emissions from the melting furnace in the special glass sector when nitrates are used in the batch formulation
|
Parameter |
BAT |
BAT-AEL (121) |
|
|
mg/Nm3 |
kg/tonne melted glass (122) |
||
|
NOX expressed as NO2 |
Minimisation of nitrate input in the batch formulation combined with primary or secondary techniques |
< 500 – 1 000 |
< 1 – 6 |
1.6.3.
51. BAT is to reduce SOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (123) |
Applicability |
||
|
The technique is generally applicable within the constraints of quality requirements of the final glass product |
||
|
The applicability may be limited by the constraints associated with the availability of low sulphur fuels, which may be impacted by the energy policy of the Member State |
||
|
The technique is generally applicable |
Table 41
BAT-AELs for SOX emissions from the melting furnace in the special glass sector
|
Parameter |
Fuel/melting technique |
BAT-AEL (124) |
|
|
mg/Nm3 |
kg/tonne melted glass (125) |
||
|
SOX expressed as SO2 |
Natural gas, electric melting (126) |
< 30 – 200 |
< 0,08 – 0,5 |
|
Fuel oil (127) |
500 – 800 |
1,25 – 2 |
|
1.6.4.
52. BAT is to reduce HCl and HF emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (128) |
Applicability |
||
|
The applicability may be limited by the constraints of the batch formulation for the type of glass produced at the installation and the availability of raw materials |
||
|
The technique is generally applicable within the constraints of the quality requirements for the final product. |
||
|
The technique is generally applicable |
Table 42
BAT-AELs for HCl and HF emissions from the melting furnace in the special glass sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (129) |
|
|
Hydrogen chloride, expressed as HCl (130) |
< 10 – 20 |
< 0,03 – 0,05 |
|
Hydrogen fluoride, expressed as HF |
< 1 – 5 |
< 0,003 – 0,04 (131) |
1.6.5.
53. BAT is to reduce metal emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (132) |
Applicability |
||
|
The applicability may be limited by the constraints imposed by the type of glass produced at the installation and the availability of raw materials |
||
|
The techniques are generally applicable |
||
|
Table 43
BAT-AELs for metal emissions from the melting furnace in the special glass sector
|
Parameter |
||
|
mg/Nm3 |
kg/tonne melted glass (135) |
|
|
Σ (As, Co, Ni, Cd, Se, CrVI) |
< 0,1 – 1 |
< 0,3 – 3 × 10–3 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) |
< 1 – 5 |
< 3 – 15 × 10–3 |
1.6.6.
54. For downstream dusty processes, BAT is to reduce emissions of dust and metals by using one or a combination of the following techniques:
|
Technique (136) |
Applicability |
||
|
The techniques are generally applicable |
||
|
Table 44
BAT-AELs for dust and metal emissions from downstream processes in the special glass sector, when treated separately
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
Dust |
1 – 10 |
|
Σ (As, Co, Ni, Cd, Se, CrVI) (137) |
< 1 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) (137) |
< 1 – 5 |
55. For acid polishing processes, BAT is to reduce HF emissions by using one or a combination of the following techniques:
|
Technique (138) |
Description |
||
|
The techniques are generally applicable |
||
|
Table 45
BAT-AELs for HF emissions from acid polishing processes in the special glass sector, when treated separately
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
Hydrogen fluoride, expressed as HF |
< 5 |
1.7. BAT conclusions for mineral wool manufacturing
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all mineral wool manufacturing installations.
1.7.1.
56. BAT is to reduce dust emissions from the waste gases of the melting furnace by applying an electrostatic precipitator or a bag filter system
|
Technique (139) |
Applicability |
|
Filtration system: electrostatic precipitator or bag filter |
The technique is generally applicable. Electrostatic precipitators are not applicable to cupola furnaces for stone wool production, due to the risk of explosion from the ignition of carbon monoxide produced within the furnace |
Table 46
BAT-AELs for dust emissions from the melting furnace in the mineral wool sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (140) |
|
|
Dust |
< 10 – 20 |
< 0,02 – 0,050 |
1.7.2.
57. BAT is to reduce NOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (141) |
Applicability |
||||||
| (i) Combustion modifications |
|||||||
|
Applicable to air/fuel conventional furnaces. Full benefits are achieved at normal or complete furnace rebuild, when combined with optimum furnace design and geometry |
||||||
|
Applicable only under installation-specific circumstances due to a lower furnace efficiency and higher fuel demand (i.e. use of recuperative furnaces in place of regenerative furnaces) |
||||||
|
Fuel staging is applicable to most conventional air/fuel furnaces. Air staging has very limited applicability due to the technical complexity |
||||||
|
The applicability of this technique is limited to the use of special burners with automatic recirculation of the waste gas |
||||||
|
The technique is generally applicable. The achieved environmental benefits are generally lower for applications to cross-fired, gas-fired furnaces due to technical constraints and a lower degree of flexibility of the furnace. Full benefits are achieved at normal or complete furnace rebuild, when combined with optimum furnace design and geometry |
||||||
|
The applicability is limited by the constraints associated with the availability of different types of fuel, which may be impacted by the energy policy of the Member State |
||||||
|
Not applicable for large volume glass productions (> 300 tonnes/day). Not applicable for productions requiring large pull variations. The implementation requires a complete furnace rebuild |
||||||
|
The maximum environmental benefits are achieved for applications at the time of a complete furnace rebuild |
Table 47
BAT-AELs for NOX emissions from the melting furnace in the mineral wool sector
|
Parameter |
Product |
Melting technique |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (142) |
|||
|
NOX expressed as NO2 |
Glass wool |
Fuel/air and electric furnaces |
< 200 – 500 |
< 0,4 – 1,0 |
|
Oxy-fuel melting (143) |
Not applicable |
< 0,5 |
||
|
Stone wool |
All types of furnaces |
< 400 – 500 |
< 1,0 – 1,25 |
|
58. When nitrates are used in the batch formulation for glass wool production, BAT is to reduce NOX emissions by using one or a combination of the following techniques:
|
Technique (144) |
Applicability |
||
|
The technique is generally applicable within the constraints of the quality requirements for the final product |
||
|
The technique is generally applicable. The implementation of electric melting requires a complete furnace rebuild |
||
|
The technique is generally applicable. The maximum environmental benefits are achieved for applications made at the time of a complete furnace rebuild |
Table 48
BAT-AELs for NOX emissions from the melting furnace in glass wool production when nitrates are used in the batch formulation
|
Parameter |
BAT |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (145) |
||
|
NOX expressed as NO2 |
Minimisation of nitrate input in the batch formulation, combined with primary techniques |
< 500 – 700 |
< 1,0 – 1,4 (146) |
1.7.3.
59. BAT is to reduce SOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (147) |
Applicability |
||
|
In glass wool production, the technique is generally applicable within the constraints of the availability of low-sulphur raw materials, in particular external cullet. High levels of external cullet in the batch formulation limit the possibility of optimising the sulphur balance due to a variable sulphur content. In the stone wool production, the optimisation of the sulphur balance may require a trade-off approach between the removal of SOX emissions from the flue-gases and the management of the solid waste, deriving from the treatment of the flue-gases (filter dust) and/or from the fiberising process, which may be recycled into the batch formulation (cement briquettes) or may need to be disposed of |
||
|
The applicability may be limited by the constraints associated with the availability of low sulphur fuels, which may be impacted by the energy policy of the Member State |
||
|
Electrostatic precipitators are not applicable to cupola furnaces for stone wool production (see BAT 56) |
||
|
The technique is generally applicable within technical constraints; i.e. need for a specific waste water treatment plant |
Table 49
BAT-AELs for SOX emissions from the melting furnace in the mineral wool sector
|
Parameter |
Product/conditions |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (148) |
||
|
SOX expressed as SO2 |
Glass wool |
||
|
Gas-fired and electric furnaces (149) |
< 50 – 150 |
< 0,1 – 0,3 |
|
|
Stone wool |
|||
|
Gas-fired and electric furnaces |
< 350 |
< 0,9 |
|
|
Cupola furnaces, no briquettes or slag recycling (150) |
< 400 |
< 1,0 |
|
|
Cupola furnaces, with cement briquettes or slag recycling (151) |
< 1 400 |
< 3,5 |
|
1.7.4.
60. BAT is to reduce HCl and HF emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (152) |
Description |
||
|
The technique is generally applicable within the constraints of the batch formulation and the availability of raw materials |
||
|
Electrostatic precipitators are not applicable to cupola furnaces for stone wool production (see BAT 56) |
Table 50
BAT-AELs for HCl and HF emissions from the melting furnace in the mineral wool sector
|
Parameter |
Product |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (153) |
||
|
Hydrogen chloride, expressed as HCl |
Glass wool |
< 5 – 10 |
< 0,01 – 0,02 |
|
Stone wool |
< 10 – 30 |
< 0,025 – 0,075 |
|
|
Hydrogen fluoride, expressed as HF |
All products |
< 1 – 5 |
< 0,002 – 0,013 (154) |
1.7.5.
61. BAT is to reduce H2S emissions from the melting furnace by applying a waste gas incineration system to oxidise hydrogen sulphide to SO2
|
Technique (155) |
Applicability |
|
Waste gas incinerator system |
The technique is generally applicable to stone wool cupola furnaces |
Table 51
BAT-AELs for H2S emissions from the melting furnace in stone wool production
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (156) |
|
|
Hydrogen sulphide, expressed as H2S |
< 2 |
< 0,005 |
1.7.6.
62. BAT is to reduce metal emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (157) |
Applicability |
||
|
The technique is generally applicable within the constraints of the availability of raw materials. In glass wool production, the use of manganese in the batch formulation as an oxidising agent depends on the quantity and quality of external cullet employed in the batch formulation and may be minimised accordingly |
||
|
Electrostatic precipitators are not applicable to cupola furnaces for stone wool production (see BAT 56) |
Table 52
BAT-AELs for metal emissions from the melting furnace in the mineral wool sector
|
Parameter |
BAT-AEL (158) |
|
|
mg/Nm3 |
kg/tonne melted glass (159) |
|
|
Σ (As, Co, Ni, Cd, Se, CrVI) |
< 0,2 – 1 (160) |
< 0,4 – 2,5 × 10–3 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) |
< 1 – 2 (160) |
< 2 – 5 × 10–3 |
1.7.7.
63. BAT is to reduce emissions from downstream processes by using one or a combination of the following techniques:
|
Technique (161) |
Applicability |
||
|
The technique is generally applicable to the mineral wool sector, in particular to glass wool processes for the treatment of emissions from the forming area (application of the coating to the fibres). Limited applicability to stone wool processes since it could adversely affect other abatement techniques being used. |
||
|
The technique is generally applicable for the treatment of waste gases from the forming process (application of the coating to the fibres) or for combined waste gases (forming plus curing) |
||
|
The technique is generally applicable for the treatment of waste gases from the forming process (application of the coating to the fibres), from curing ovens or for combined waste gases (forming plus curing) |
||
|
The applicability is mainly limited to stone wool processes for waste gases from the forming area and/or curing ovens |
||
|
The technique is generally applicable for the treatment of waste gases from curing ovens, in particular in the stone wool processes. The application to combined waste gases (forming plus curing) is not economically viable because of the high volume, low concentration, low temperature of the waste gases |
Table 53
BAT-AELs for air emissions from downstream processes in the mineral wool sector, when treated separately
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne finished product |
|
|
Forming area – Combined forming and curing emissions-Combined forming, curing and cooling emissions |
||
|
Total particulate matter |
< 20 – 50 |
— |
|
Phenol |
< 5 – 10 |
— |
|
Formaldehyde |
< 2 – 5 |
— |
|
Ammonia |
30 – 60 |
— |
|
Amines |
< 3 |
— |
|
Total volatile organic compounds expressed as C |
10 – 30 |
— |
|
Total particulate matter |
< 5 – 30 |
< 0,2 |
|
Phenol |
< 2 – 5 |
< 0,03 |
|
Formaldehyde |
< 2 – 5 |
< 0,03 |
|
Ammonia |
< 20 – 60 |
< 0,4 |
|
Amines |
< 2 |
< 0,01 |
|
Total volatile organic compounds expressed as C |
< 10 |
< 0,065 |
|
NOX, expressed as NO2 |
< 100 – 200 |
< 1 |
1.8. BAT conclusions for high temperature insulation wools (HTIW) manufacturing
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all HTIW manufacturing installations.
1.8.1.
64. BAT is to reduce dust emissions from the waste gases of the melting furnace by applying a filtration system.
|
Technique (164) |
Applicability |
|
The filtration system usually consists of a bag filter |
The technique is generally applicable |
Table 54
BAT-AELs for dust emissions from the melting furnace in the HTIW sector
|
Parameter |
BAT |
BAT-AEL |
|
mg/Nm3 |
||
|
Dust |
Flue-gas cleaning by filtration systems |
< 5 – 20 (165) |
65. For downstream dusty processes, BAT is to reduce emissions using one or a combination of the following techniques:
|
Technique (166) |
Applicability |
||||||||||
|
The techniques are generally applicable |
||||||||||
|
|||||||||||
|
Table 55
BAT-AELs from dusty downstream processes in the HTIW sector, when treated separately
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
Dust (167) |
1 – 5 |
1.8.2.
66. BAT is to reduce NOX emissions from the lubricant burn-off oven by applying combustion control and/or modifications
|
Technique |
Applicability |
||||||
|
Combustion control and/or modifications Techniques to reduce the formation of thermal NOX emissions include a control of the main combustion parameters:
A good combustion control consists of generating those conditions which are least favourable for NOX formation |
The technique is generally applicable |
Table 56
BAT-AELs for NOX from the lubricant burn-off oven in the HTIW sector
|
Parameter |
BAT |
BAT-AEL |
|
mg/Nm3 |
||
|
NOX expressed as NO2 |
Combustion control and/or modifications |
100 – 200 |
1.8.3.
67. BAT is to reduce SOX emissions from the melting furnaces and downstream processes by using one or a combination of the following techniques:
|
Technique (168) |
Applicability |
||
|
The technique is generally applicable within the constraints of the availability of raw materials |
||
|
The applicability may be limited by the constraints associated with the availability of low sulphur fuels, which may be impacted by the energy policy of the Member State |
Table 57
BAT-AELs for SOX emissions from the melting furnaces and downstream processes in the HTIW sector
|
Parameter |
BAT |
BAT-AEL |
|
mg/Nm3 |
||
|
SOx expressed as SO2 |
Primary techniques |
< 50 |
1.8.4.
68. BAT is to reduce HCl and HF emissions from the melting furnace by selecting raw materials for the batch formulation with a low content of chlorine and fluorine
|
Technique (169) |
Applicability |
|
Selection of raw materials for the batch formulation with a low content of chlorine and fluorine |
The technique is generally applicable |
Table 58
BAT-AELs for HCl and HF emissions from the melting furnace in the HTIW sector
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
Hydrogen chloride, expressed as HCl |
< 10 |
|
Hydrogen fluoride, expressed as HF |
< 5 |
1.8.5.
69. BAT is to reduce metal emissions from the melting furnace and/or downstream processes by using one or a combination of the following techniques:
|
Technique (170) |
Applicability |
||
|
The techniques are generally applicable |
||
|
Table 59
BAT-AELs for metal emissions from the melting furnace and/or downstream processes in the HTIW sector
|
Parameter |
BAT-AEL (171) |
|
mg/Nm3 |
|
|
Σ (As, Co, Ni, Cd, Se, CrVI) |
< 1 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) |
< 5 |
1.8.6.
70. BAT is to reduce volatile organic compound (VOC) emissions from the lubricant burn-off oven by using one or a combination of the following techniques:
|
Technique (172) |
Applicability |
||
|
The technique is generally applicable |
||
|
The economic viability may limit the applicability of these techniques because of low waste gas volumes and VOC concentrations |
||
|
Table 60
BAT-AELs for VOC emissions from the lubricant burn-off oven in the HTIW sector, when treated separately
|
Parameter |
BAT |
BAT-AEL |
|
mg/Nm3 |
||
|
Volatile organic compounds expressed as C |
Primary and/or secondary techniques |
10 – 20 |
1.9. BAT conclusions for frits manufacturing
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all frits glass manufacturing installations.
1.9.1.
71. BAT is to reduce dust emissions from the waste gases of the melting furnace by means of an electrostatic precipitator or a bag filter system.
|
Technique (173) |
Applicability |
|
Filtration system: electrostatic precipitator or bag filter |
The technique is generally applicable |
Table 61
BAT-AELs for dust emissions from the melting furnace in the frits sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (174) |
|
|
Dust |
< 10 – 20 |
< 0,05 – 0,15 |
1.9.2.
72. BAT is to reduce NOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (175) |
Applicability |
||||||
|
The substitution of nitrates in the batch formulation may be limited by the high costs and/or higher environmental impact of the alternative materials and/or the quality requirements of the final product |
||||||
|
The technique is generally applicable |
||||||
| (iii) Combustion modifications |
|||||||
|
Applicable to air/fuel conventional furnaces. Full benefits are achieved at normal or complete furnace rebuild, when combined with optimum furnace design and geometry |
||||||
|
Applicable only under installation-specific circumstances due to a lower furnace efficiency and higher fuel demand |
||||||
|
Fuel staging is applicable to most conventional air/fuel furnaces. Air staging has very limited applicability due to its technical complexity |
||||||
|
The applicability of this technique is limited to the use of special burners with automatic recirculation of the waste gas |
||||||
|
The technique is generally applicable. Full benefits are achieved at normal or complete furnace rebuild, when combined with optimum furnace design and geometry |
||||||
|
The applicability is limited by the constraints associated with the availability of different types of fuel, which may be impacted by the energy policy of the Member State |
||||||
|
The maximum environmental benefits are achieved for applications at the time of a complete furnace rebuild |
Table 62
BAT-AELs for NOX emissions from the melting furnace in the frits glass sector
|
Parameter |
BAT |
Operating conditions |
BAT-AEL (176) |
|
|
mg/Nm3 |
kg/tonne melted glass (177) |
|||
|
NOX expressed as NO2 |
Primary techniques |
Oxy-fuel firing, without nitrates (178) |
Not applicable |
< 2,5 – 5 |
|
Oxy-fuel firing, with use of nitrates |
Not applicable |
5 – 10 |
||
|
Fuel/air, fuel/oxygen-enriched air combustion, without nitrates |
500 – 1 000 |
2,5 – 7,5 |
||
|
Fuel/air, fuel/oxygen-enriched air combustion, with use of nitrates |
< 1 600 |
< 12 |
||
1.9.3.
73. BAT is to control SOX emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (179) |
Applicability |
||
|
The technique is generally applicable within the constraints of the availability of raw materials |
||
|
The technique is generally applicable |
||
|
The applicability may be limited by the constraints associated with the availability of low sulphur fuels, which may be impacted by the energy policy of the Member State |
Table 63
BAT-AELs for SOX emissions from the melting furnace in the frits sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (180) |
|
|
SOX, expressed as SO2 |
< 50 – 200 |
< 0,25 – 1,5 |
1.9.4.
74. BAT is to reduce HCl and HF emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (181) |
Applicability |
||
|
The technique is generally applicable within the constraints of the batch formulation and the availability of raw materials |
||
|
The minimisation or substitution of fluorine compounds with alternative materials is limited by quality requirements of the product |
||
|
The technique is generally applicable |
Table 64
BAT-AELs for HCl and HF emissions from the melting furnace in the frits sector
|
Parameter |
BAT-AEL |
|
|
mg/Nm3 |
kg/tonne melted glass (182) |
|
|
Hydrogen chloride, expressed as HCl |
< 10 |
< 0,05 |
|
Hydrogen fluoride, expressed as HF |
< 5 |
< 0,03 |
1.9.5.
75. BAT is to reduce metal emissions from the melting furnace by using one or a combination of the following techniques:
|
Technique (183) |
Applicability |
||
|
The technique is generally applicable within the constraints of the type of frit produced at the installation and the availability of raw materials |
||
|
The techniques are generally applicable |
||
|
Table 65
BAT-AELs for metal emissions from the melting furnace in the frits sector
|
Parameter |
BAT-AEL (184) |
|
|
mg/Nm3 |
kg/tonne melted glass (185) |
|
|
Σ (As, Co, Ni, Cd, Se, CrVI) |
< 1 |
< 7,5 × 10–3 |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) |
< 5 |
< 37 × 10–3 |
1.9.6.
76. For downstream dusty processes, BAT is to reduce emissions by using one or a combination of the following techniques:
|
Technique (186) |
Applicability |
||
|
The techniques are generally applicable |
||
|
|||
|
Table 66
BAT-AELs for air emissions from downstream processes in the frits sector, when treated separately
|
Parameter |
BAT-AEL |
|
mg/Nm3 |
|
|
Dust |
5 – 10 |
|
Σ (As, Co, Ni, Cd, Se, CrVI) |
< 1 (187) |
|
Σ (As, Co, Ni, Cd, Se, CrVI, Sb, Pb, CrIII, Cu, Mn, V, Sn) |
< 5 (187) |
Glossary
1.10. Description of techniques
1.10.1.
|
Technique |
Description |
|
Electrostatic precipitator |
Electrostatic precipitators operate such that particles are charged and separated under the influence of an electrical field. Electrostatic precipitators are capable of operating over a wide range of conditions |
|
Bag filter |
Bag filters are constructed from porous woven or felted fabric through which gases are flowed to remove particles. The use of a bag filter requires a fabric material selection adequate to the characteristics of the waste gases and the maximum operating temperature |
|
Reduction of the volatile components by raw material modifications |
The formulation of batch compositions might contain very volatile components (e.g. boron compounds) which could be minimised or substituted for reducing dust emissions mainly generated by volatilisation phenomena |
|
Electric melting |
The technique consists of a melting furnace where the energy is provided by resistive heating. In the cold-top furnaces (where the electrodes are generally inserted at the bottom of the furnace) the batch blanket covers the surface of the melt with a consequent, significant reduction of the volatilisation of batch components (i.e. lead compounds) |
1.10.2.
|
Technique |
Description |
||||||||
|
Combustion modifications |
|||||||||
|
The technique is mainly based on the following features:
|
||||||||
|
The use of recuperative furnaces, in place of regenerative furnaces, results in a reduced air preheat temperature and, consequently, a lower flame temperature. However, this is associated with a lower furnace efficiency (lower specific pull), lower fuel efficiency and higher fuel demand, resulting in potentially higher emissions (kg/tonne of glass) |
||||||||
|
— Air staging– involves substoichiometric firing and the addition of the remaining air or oxygen into the furnace to complete combustion. — Fuel staging– a low impulse primary flame is developed in the port neck (10 % of total energy); a secondary flame covers the root of the primary flame reducing its core temperature |
||||||||
|
Implies the reinjection of waste gas from the furnace into the flame to reduce the oxygen content and therefore the temperature of the flame. The use of special burners is based on internal recirculation of combustion gases which cool the root of the flames and reduce the oxygen content in the hottest part of the flames |
||||||||
|
The technique is based on the principles of reducing peak flame temperatures, delaying but completing the combustion and increasing the heat transfer (increased emissivity of the flame). It may be associated with a modified design of the furnace combustion chamber |
||||||||
|
In general, oil-fired furnaces show lower NOX emissions than gas-fired furnaces due to better thermal emissivity and lower flame temperatures |
||||||||
|
Special furnace design |
Recuperative type furnace that integrates various features, allowing for lower flame temperatures. The main features are:
|
||||||||
|
Electric melting |
The technique consists of a melting furnace where the energy is provided by resistive heating. The main features are:
|
||||||||
|
Oxy-fuel melting |
The technique involves the replacement of the combustion air with oxygen (> 90 % purity), with consequent elimination/reduction of thermal NOX formation from nitrogen entering the furnace. The residual nitrogen content in the furnace depends on the purity of the oxygen supplied, on the quality of the fuel (% N2 in natural gas) and on the potential air inlet |
||||||||
|
Chemical reduction by fuel |
The technique is based on the injection of fossil fuel to the waste gas with chemical reduction of NOX to N2 through a series of reactions. In the 3R process, the fuel (natural gas or oil) is injected at the regenerator entrance. The technology is designed for use in regenerative furnaces |
||||||||
|
Selective catalytic reduction (SCR) |
The technique is based on the reduction of NOX to nitrogen in a catalytic bed by reaction with ammonia (in general aqueous solution) at an optimum operating temperature of around 300 – 450 °C. One or two layers of catalyst may be applied. A higher NOX reduction is achieved with the use of higher amounts of catalyst (two layers) |
||||||||
|
Selective non-catalytic reduction (SNCR) |
The technique is based on the reduction of NOX to nitrogen by reaction with ammonia or urea at a high temperature. The operating temperature window must be maintained between 900 and 1 050 °C |
||||||||
|
Minimising the use of nitrates in the batch formulation |
The minimisation of nitrates is used to reduce NOX emissions deriving from the decomposition of these raw materials when applied as an oxidising agent for very high quality products where a very colourless (clear) glass is required or for other glasses to provide the required characteristics. The following options may be applied:
|
||||||||
1.10.3.
|
Technique |
Description |
|
Dry or semi-dry scrubbing, in combination with a filtration system |
Dry powder or a suspension/solution of alkaline reagent are introduced and dispersed in the waste gas stream. The material reacts with the sulphur gaseous species to form a solid which has to be removed by filtration (bag filter or electrostatic precipitator). In general, the use of a reaction tower improves the removal efficiency of the scrubbing system |
|
Minimisation of the sulphur content in the batch formulation and optimisation of the sulphur balance |
The minimisation of sulphur content in the batch formulation is applied to reduce SOX emissions deriving from the decomposition of sulphur-containing raw materials (in general, sulphates) used as fining agents. The effective reduction of SOX emissions depends on the retention of sulphur compounds in the glass, which may vary significantly depending on the glass type, and on the optimisation of the sulphur balance |
|
Use of low sulphur content fuels |
The use of natural gas or low sulphur fuel oil is applied to reduce the amount of SOX emissions deriving from the oxidation of sulphur contained in the fuel during combustion |
1.10.4.
|
Technique |
Description |
|
Selection of raw materials for the batch formulation with a low content of chlorine and fluorine |
The technique consists of a careful selection of raw materials that may contain chlorides and fluorides as impurities (e.g. synthetic soda ash, dolomite, external cullet, recycled filter dust) in order to reduce at source HCl and HF emissions which arise from the decomposition of these materials during the melting process |
|
Minimisation of the fluorine and/or chlorine compounds in the batch formulation and optimisation of the fluorine and/or chlorine mass balance |
The minimisation of fluorine and/or chlorine emissions from the melting process may be achieved by minimising/reducing the quantity of these substances used in the batch formulation to the minimum commensurate with the quality of the final product. Fluorine compounds (e.g. fluorspar, cryolite, fluorsilicate) are used to confer particular characteristics to special glasses (e.g. opaque glass, optical glass). Chlorine compounds may be used as fining agents |
|
Dry or semi-dry scrubbing, in combination with a filtration system |
Dry powder or a suspension/solution of alkaline reagent are introduced and dispersed in the waste gas stream. The material reacts with the gaseous chlorides and fluorides to form a solid which has to be removed by filtration (electrostatic precipitator or bag filter) |
1.10.5.
|
Technique |
Description |
||||
|
Selection of raw materials for the batch formulation with a low content of metals |
The technique consists of a careful selection of batch materials that may contain metals as impurities (e.g. external cullet), in order to reduce at source metal emissions which arise from the decomposition of these materials during the melting process |
||||
|
Minimising the use of metal compounds in the batch formulation, where colouring and decolourising of glass is needed, subject to consumer glass quality requirements |
The minimisation of metal emissions from the melting process may be achieved as follows:
|
||||
|
Minimising the use of selenium compounds in the batch formulation, through a suitable selection of the raw materials |
The minimisation of selenium emissions from the melting process may be achieved by:
|
||||
|
Application of a filtration system |
Dust abatement systems (bag filter and electrostatic precipitator) can reduce both dust and metal emissions since the emissions to air of metals from glass melting processes are largely contained in particulate form. However, for some metals presenting extremely volatile compounds (e.g. selenium) the removal efficiency may vary significantly with the filtration temperature |
||||
|
Dry or semi-dry scrubbing, in combination with a filtration system |
Gaseous metals can be substantially reduced by the use of a dry or semi-dry scrubbing technique with an alkaline reagent. The alkaline reagent reacts with the gaseous species to form a solid which has to be removed by filtration (bag filter or electrostatic precipitator) |
1.10.6.
|
Wet scrubbing |
In the wet scrubbing process, gaseous compounds are dissolved in a suitable liquid (water or alkaline solution). Downstream of the wet scrubber, the flue-gases are saturated with water and a separation of the droplets is required before discharging the flue-gases. The resulting liquid has to be treated by a waste water process and the insoluble matter is collected by sedimentation or filtration |
1.10.7.
|
Technique |
Description |
||||
|
Wet scrubbing |
In a wet scrubbing process (by a suitable liquid: water or alkaline solution), the simultaneous removal of solid and gaseous compounds may be achieved. The design criteria for particulate or gas removal are different; therefore, the design is often a compromise between the two options. The resulting liquid has to be treated by a waste water process and the insoluble matter (solid emissions and products from chemical reactions) is collected by sedimentation or filtration. In the mineral wool and continuous filament glass fibre sector, the most common systems applied are:
|
||||
|
Wet electrostatic precipitator |
The technique consists of an electrostatic precipitator in which the collected material is removed from the plates of the collectors by flushing with a suitable liquid, usually water. Some mechanism is usually installed to remove water droplets before discharge of the waste gas (demister or a last dry field) |
1.10.8.
|
Technique |
Description |
|
Performing dusty operations (e.g. cutting, grinding, polishing) under liquid |
Water is generally used as a coolant for cutting, grinding and polishing operations and for preventing dust emissions. An extraction system equipped with a mist eliminator may be necessary |
|
Applying a bag filter system |
The use of bag filters is suitable for the reduction of both dust and metal emissions since metals from downstream processes are largely contained in particulate form |
|
Minimising the losses of polishing product by ensuring a good sealing of the application system |
Acid polishing is performed by immersion of the glass articles in a polishing bath of hydrofluoric and sulphuric acids. The release of fumes may be minimised by a good design and maintenance of the application system in order to minimise losses |
|
Applying a secondary technique, e.g. wet scrubbing |
Wet scrubbing with water is used for the treatment of waste gases, due to the acidic nature of the emissions and the high solubility of the gaseous pollutants to be removed |
1.10.9.
|
Waste gas incineration |
The technique consists of an afterburner system which oxidises the hydrogen sulphide (generated by strong reducing conditions in the melting furnace) to sulphur dioxide and carbon monoxide to carbon dioxide. Volatile organic compounds are thermally incinerated with consequent oxidation to carbon dioxide, water and other combustion products (e.g. NOX, SOX) |
(1) Specific cases correspond to less favourable cases (i.e. small special furnaces with a production of generally below 100 tonnes/day and a cullet rate of below 30 %). This category represents only 1 or 2 % of the container glass production.
(2) Specific cases corresponding to less favourable cases and/or non-soda-lime glasses: borosilicates, glass ceramic, crystal glass and, less frequently, lead crystal glass.
(3) The higher levels are associated with higher inlet NOX concentrations, higher reduction rates and the ageing of the catalyst.
(4) A description of the techniques is given in Sections 1.10.1, 1.10.4 and 1.10.6.
(5) The relevance of the pollutants listed in the table depends on the sector of the glass industry and on the different activities carried out at the plant.
(6) The levels refer to a composite sample taken over a time period of 2 hours or 24 hours.
(7) For the continuous filament glass fibre sector, BAT-AEL is < 200 mg/l.
(8) The level refers to treated water coming from activities involving acid polishing.
(9) In general, total hydrocarbons are composed of mineral oils.
(10) The higher level of the range is associated with downstream processes for the production of lead crystal glass.
(11) A description of filtration systems (i.e. electrostatic precipitator, bag filter) is given in Section 1.10.1.
(12) The conversion factors of 1,5 × 10–3 and 3 × 10–3 have been used for the determination of the lower and higher value of the range respectively.
(13) A description of the techniques is given in Section 1.10.2.
(14) A description of the techniques is given in Section 1.10.2.
(15) The conversion factor reported in Table 2 for general cases (1,5 × 10–3) has been applied, with the exception of electric melting (specific cases: 3 × 10–3).
(16) The lower value refers to the use of special furnace designs, where applicable.
(17) These values should be reconsidered in the occasion of a normal or complete rebuild of the melting furnace.
(18) The achievable levels depend on the quality of the natural gas and oxygen available (nitrogen content).
(19) A description of the techniques is given in Section 1.10.2.
(20) The conversion factor reported in Table 2 for specific cases (3 × 10–3) has been applied.
(21) A description of the techniques is given in Section 1.10.3.
(22) For special types of coloured glasses (e.g. reduced green glasses), concerns related to the achievable emission levels may require investigating the sulphur balance. Values reported in the table may be difficult to achieve in combination with filter dust recycling and the rate of recycling of external cullet.
(23) The lower levels are associated with conditions where the reduction of SOX is a high priority over a lower production of solid waste corresponding to the sulphate-rich filter dust.
(24) The conversion factor reported in Table 2 for general cases (1,5 × 10–3) has been applied.
(25) The associated emission levels are related to the use of 1 % sulphur fuel oil in combination with secondary abatement techniques.
(26) A description of the techniques is given in Section 1.10.4.
(27) The conversion factor for general cases, reported in Table 2 (1,5 × 10–3) has been applied.
(28) The higher levels are associated with the simultaneous treatment of flue-gases from hot-end coating operations.
(29) A description of the techniques is given in Section 1.10.5.
(30) The levels refer to the sum of metals present in the flue-gases in both solid and gaseous phases.
(31) The lower levels are BAT-AELs when metal compounds are not intentionally used in the batch formulation.
(32) The upper levels are associated with the use of metals for colouring or decolourising the glass, or when the flue-gases from the hot-end coating operations are treated together with the melting furnace emissions.
(33) The conversion factor for general cases, reported in Table 2 (1,5 × 10–3) has been applied.
(34) In specific cases, when high quality flint glass is produced requiring higher amounts of selenium for decolourising (depending on the raw materials), higher values are reported, up to 3 mg/Nm3.
(35) A description of the techniques is given in Sections 1.10.4 and 1.10.7.
(36) A description of the techniques is given in Section 1.10.6.
(37) The conversion factor reported in Table 2 (2,5 × 10–3) has been applied.
(38) A description of the techniques is given in Section 1.10.2.
(39) A description of the techniques is given in Section 1.10.2.
(40) Higher emission levels are expected when nitrates are used occasionally for the production of special glasses.
(41) The conversion factor reported in Table 2 (2,5 × 10–3) has been applied.
(42) The lower levels of the range are associated with the application of the Fenix process.
(43) The achievable levels depend on the quality of the natural gas and oxygen available (nitrogen content).
(44) The higher levels of the range are associated with existing plants until a normal or complete rebuild of the melting furnace. The lower levels are associated with newer/retrofitted plants.
(45) A description of the technique is given in Section 1.10.2.
(46) The conversion factor reported in Table 2 for specific cases (2,5 × 10–3) has been applied
(47) A description of the techniques is given in Section 1.10.3.
(48) The lower levels are associated with conditions where the reduction of SOX has a high priority over a lower production of solid waste corresponding to the sulphate-rich filter dust.
(49) The conversion factor reported in Table 2 (2,5 × 10–3) has been applied.
(50) The associated emission levels are related to the use of 1 % sulphur fuel oil in combination with secondary abatement techniques.
(51) For large flat glass furnaces, concerns related to the achievable emission levels may require investigating the sulphur balance. Values reported in the table may be difficult to achieve in combination with filter dust recycling.
(52) A description of the techniques is given in Section 1.10.4.
(53) The conversion factor reported in Table 2 (2,5 × 10–3) has been applied.
(54) The higher levels of the range are associated with the recycling of filter dust in the batch formulation
(55) A description of the techniques is given in Section 1.10.5.
(56) The ranges refer to the sum of metals present in the flue-gases in both solid and gaseous phases.
(57) The conversion factor reported in Table 2 (2,5 × 10–3) has been applied
(58) A description of the techniques is given in Section 1.10.5.
(59) The values refer to the sum of selenium present in the flue-gases in both solid and gaseous phases.
(60) The lower levels correspond to conditions where the reduction of Se emissions is a priority over a lower production of solid waste from filter dust. In this case, a high stoichiometric ratio (reagent/pollutant) is applied and a significant solid waste stream is generated.
(61) The conversion factor reported in Table 2 (2,5 × 10–3) has been applied.
(62) A description of the secondary treatment systems is given in Sections 1.10.3 and 1.10.6.
(63) A description of the secondary treatment systems is given in Sections 1.10.1 and 1.10.7.
(64) Values at levels of < 30 mg/Nm3 (< 0,14 kg/tonne melted glass) have been reported for boron-free formulations, with the application of primary techniques.
(65) The conversion factor reported in Table 2 (4,5 × 10–3) has been applied.
(66) A description of the techniques is given in Section 1.10.2.
(67) The conversion factor reported in Table 2 (4,5 × 10–3) has been applied.
(68) The achievable levels depend on the quality of the natural gas and oxygen available (nitrogen content).
(69) A description of the techniques is given in Sections 1.10.3 and 1.10.6.
(70) The higher levels of the range are associated with the use of sulphates in the batch formulation for refining the glass.
(71) The conversion factor reported in Table 2 (4,5 × 10–3) has been applied.
(72) For oxy-fuel furnaces with the application of wet scrubbing, the BAT-AEL is reported to be < 0,1 kg/tonne melted glass of SOX, expressed as SO2.
(73) The associated emission levels are related to the use of 1 % sulphur fuel oil in combination with secondary abatement techniques.
(74) The lower levels correspond to conditions where the reduction of SOX is a priority over a lower production of solid waste corresponding to the sulphate-rich filter dust. In this case, the lower levels are associated with the use of a bag filter.
(75) A description of the techniques is given in Sections 1.10.4 and 1.10.6.
(76) The conversion factor reported in Table 2 (4,5 × 10–3) has been applied.
(77) The higher levels of the range are associated with the use of fluorine compounds in the batch formulation.
(78) A description of the techniques is given in Sections 1.10.5 and 1.10.6.
(79) The levels refer to the sum of metals present in the flue-gases in both solid and gaseous phases.
(80) The conversion factor reported in Table 2 (4,5 × 10–3) has been applied.
(81) A description of the techniques is given in Sections 1.10.7 and 1.10.8.
(82) A description of the techniques is given in Sections 1.10.5 and 1.10.7.
(83) A conversion factor of 3 × 10–3 has been applied (see Table 2). However, a case by case conversion factor may have to be applied for specific productions.
(84) Considerations concerning the economic viability for achieving the BAT-AELs in the case of furnaces with a capacity of < 80 t/d, producing soda-lime glass, are reported.
(85) This BAT-AEL applies to batch formulations containing significant amounts of constituents meeting the criteria as dangerous substances, in accordance with Regulation (EC) No 1272/2008 of the European Parliament and of the Council.
(86) A description of the techniques is given in Section 1.10.2.
(87) A conversion factor of 2,5 × 10–3 has been applied for combustion modifications and special furnace designs and a conversion factor of 3 × 10–3 has been applied for electric melting (see Table 2). However, a case-by-case conversion factor may have to be applied for specific productions.
(88) The achievable levels depend on the quality of the natural gas and oxygen available (nitrogen content).
(89) A description of the technique is given in Section 1.10.2.
(90) The conversion factor reported in Table 2 for soda-lime glass (2,5 × 10–3) has been applied.
(91) A description of the techniques is given in Section 1.10.3.
(92) A conversion factor of 2,5 × 10–3 has been applied (see Table 2). However, a case-by-case conversion factor may have to be applied for specific productions.
(93) The levels are related to the use of 1 % sulphur fuel oil in combination with secondary abatement techniques.
(94) A description of the techniques is given in Sections 1.10.4 and 1.10.6.
(95) A conversion factor of 3 × 10–3 has been applied (see Table 2). However, a case-by-case conversion factor may have to be applied for specific productions.
(96) The lower levels are associated with the use of electric melting.
(97) In cases where KCl or NaCl are used as a refining agents, the BAT-AEL is < 30 mg/Nm3 or < 0,09 kg/tonne melted glass.
(98) The lower levels are associated with the use of electric melting. The higher levels are associated with the production of opal glass, the recycling of filter dust or where high levels of external cullet are used in the batch formulation.
(99) A description of the techniques is given in Section 1.10.5.
(100) The levels refer to the sum of metals present in the flue-gases in both solid and gaseous phases.
(101) A conversion factor of 3 × 10–3 has been applied (see Table 2). However, a case-by-case conversion factor may have to be applied for specific productions.
(102) A description of the techniques is given in Section 1.10.5.
(103) The values refer to the sum of selenium present in the flue-gases in both solid and gaseous phases.
(104) A conversion factor of 3 × 10–3 has been applied (see Table 2). However, a case-by-case conversion factor may have to be applied for specific productions.
(105) A description of the technique is given in Sections 1.10.1 and 1.10.5.
(106) The values refer to the sum of lead present in the flue-gases in both solid and gaseous phases.
(107) A conversion factor of 3 × 10–3 has been applied (see Table 2). However, a case-by-case conversion factor may have to be applied for specific productions.
(108) A description of the techniques is given in Section 1.10.8.
(109) The levels refer to the sum of metals present in the waste gas.
(110) The levels refer to downstream operations on lead crystal glass.
(111) A description of the techniques is given in Section 1.10.6.
(112) A description of the techniques is given in Section 1.10.1.
(113) The conversions factors of 2,5 × 10–3 and 6,5 × 10–3 have been used for the determination of the lower and upper value of the BAT-AELs range (see Table 2), with some values being approximated. However, a-case-by-case conversion factor needs to be applied, depending on the type of glass produced (see Table 2).
(114) The BAT-AELs apply to batch formulations containing significant amounts of constituents meeting the criteria as dangerous substances, in accordance with Regulation (EC) No 1272/2008.
(115) A description of the techniques is given in Section 1.10.2.
(116) A description of the techniques is given in Section 1.10.2.
(117) The conversion factors of 2,5 × 10–3 and 4 × 10–3 have been used for the determination of the lower and upper value of the BAT-AEL range (see Table 2), with some values being approximated. However, a case-by-case conversion factor needs to be applied based on the type of production (see Table 2).
(118) The higher values are related to a special production of borosilicate glass tubes for pharmaceutical use.
(119) The achievable levels depend on the quality of the natural gas and oxygen available (nitrogen content).
(120) A description of the technique is given in Section 1.10.2.
(121) The lower levels are associated with the use of electric melting.
(122) The conversion factors of 2,5 × 10–3 and 6,5 × 10–3 have been used for the determination of the lower and upper value of the BAT-AEL range respectively, with values being approximated. A case-by-case conversion factor may have to be applied based on the type of production (see Table 2).
(123) A description of the techniques is given in Section 1.10.3.
(124) The ranges take into account the variable sulphur balances associated with the type of glass produced.
(125) The conversion factor of 2,5 × 10–3 (see Table 2) has been used. However, a case-by-case conversion factor may have to be applied based on the type of production.
(126) The lower levels are associated with the use of electric melting and batch formulations without sulphates.
(127) The associated emission levels are related to the use of 1 % sulphur fuel oil in combination with secondary abatement techniques.
(128) A description of the techniques is given in Section 1.10.4.
(129) The conversion factor of 2,5 × 10–3 (see Table 2) has been used; with some values being approximated. A case-by-case conversion factor may have to be applied based on the type of production.
(130) The higher levels are associated with the use of materials containing chlorine in the batch formulation.
(131) The upper value of the range has been derived from specific reported data.
(132) A description of the techniques is given in Section 1.10.5.
(133) The levels refer to the sum of metals present in the flue-gases in both solid and gaseous phases.
(134) The lower levels are BAT-AELs when metal compounds are not intentionally used in the batch formulation.
(135) The conversion factor of 2,5 × 10–3 (see Table 2) has been used, with some values indicated in the table having been approximated. A case-by-case conversion factor may have to be applied based on the type of production.
(136) A description of the techniques is given in Section 1.10.8.
(137) The levels refer to the sum of metals present in the waste gas.
(138) A description of the techniques is given in Section 1.10.6.
(139) A description of the techniques is given in Section 1.10.1.
(140) The conversion factors of 2 × 10–3 and 2,5 × 10–3 have been used for the determination of the lower and upper value of the BAT-AELs range (see Table 2), in order to cover both the production of glass wool and stone wool.
(141) A description of the techniques is given in Section 1.10.2.
(142) The conversion factors of 2 × 10–3 for glass wool and 2,5 × 10–3 for stone wool have been used (see Table 2).
(143) The achievable levels depend on the quality of the natural gas and oxygen available (nitrogen content).
(144) A description of the techniques is given in Section 1.10.2.
(145) The conversion factor of 2 × 10–3 has been used (see Table 2).
(146) The lower levels of the ranges are associated with the application of oxy-fuel melting.
(147) A description of the techniques is given in Sections 1.10.3 and 1.10.6.
(148) The conversion factors of 2 × 10–3 for glass wool and 2,5 × 10–3 for stone wool have been used (see Table 2).
(149) The lower levels of the ranges are associated with the use of electric melting. The higher levels are associated with high levels of cullet recycling.
(150) The BAT-AEL is associated with conditions where the reduction of SOX emissions has a high priority over a lower production of solid waste.
(151) When reduction of waste has a high priority over SOX emissions, higher emission values may be expected. The achievable levels should be based on a sulphur balance.
(152) A description of the techniques is given in Section 1.10.4.
(153) The conversion factors of 2 × 10–3 for glass wool and 2,5 × 10–3 for stone wool have been used (see Table 2).
(154) The conversion factors of 2 × 10–3 and 2,5 × 10–3 have been used for the determination of the lower and upper values of the BAT-AELs range (see Table 2).
(155) A description of the technique is given in Section 1.10.9.
(156) The conversion factor of 2,5 × 10–3 for stone wool has been applied (see Table 2).
(157) A description of the techniques is given in Section 1.10.5.
(158) The ranges refer to the sum of metals present in the flue-gases in both solid and gaseous phases.
(159) The conversion factors of 2 × 10–3 and 2,5 × 10–3 have been used for the determination of the lower and upper values of the BAT-AELs range (see Table 2).
(160) Higher values are associated with the use of cupola furnaces for the production of stone wool.
(161) A description of the techniques is given in Sections 1.10.7 and 1.10.9.
(162) Emission levels expressed in kg/tonne of finished product are not affected by the thickness of the mineral wool mat produced nor by extreme concentration or dilution of the flue-gases. A conversion factor of 6,5 × 10–3 has been used.
(163) If high density or high binder content mineral wools are produced, the emission levels associated with the techniques listed as BAT for the sector could be significantly higher than these BAT-AELs. If these types of products represent the majority of the production from a given installation, then consideration should be given to other techniques.
(164) A description of the technique is given in Section 1.10.1.
(165) The values are associated with the use of a bag filter system.
(166) A description of the technique is given in Section 1.10.1.
(167) The lower level of the range is associated with emissions of aluminium silicate glass wool/refractory ceramic fibres (ASW/RCF).
(168) A description of the technique is given in Section 1.10.3.
(169) A description of the technique is given in Section 1.10.4.
(170) A description of the technique is given in Section 1.10.5.
(171) The levels refer to the sum of metals present in the flue-gases in both solid and gaseous phases.
(172) A description of the techniques is given in Sections 1.10.6 and 1.10.9.
(173) A description of the technique is given in Section 1.10.1.
(174) The conversion factors of 5 × 10–3 and 7,5 × 10–3 have been used for the determination of the lower and upper value of the BAT-AELs range (see Table 2). However, a case-by-case conversion factor may have to be applied based on the type of combustion.
(175) A description of the technique is given in Section 1.10.2.
(176) The ranges take into account the combination of flue-gases from furnaces applying different melting techniques and producing a variety of frit types, with or without nitrates in the batch formulations, which may be conveyed to a single stack, precluding the possibility of characterising each applied melting technique and the different products.
(177) The conversion factors of 5 × 10–3 and 7,5 × 10–3 have been used for the determination of the lower and higher values of the range. However, a case-by-case conversion factor may have to be applied based on the type of combustion (see Table 2).
(178) The achievable levels depend on the quality of the natural gas and oxygen available (nitrogen content).
(179) A description of the techniques is given in Section 1.10.3.
(180) The conversion factors of 5 × 10–3 and 7,5 × 10–3 have been used; however, the values indicated in the table may have been approximated. A case-by-case conversion factor may have to be applied based on the type of combustion (see Table 2).
(181) A description of the techniques is given in Section 1.10.4.
(182) The conversion factor of 5 × 10–3 has been used with some values being approximated. A case-by-case conversion factor may have to be applied based on the type of combustion (see Table 2).
(183) A description of the techniques is given in Section 1.10.5.
(184) The levels refer to the sum of metals present in the flue-gases in both solid and gaseous phases.
(185) The conversion factor of 7,5 × 10–3 has been used. A case-by-case conversion factor may have to be applied based on the type of combustion (see Table 2).
(186) A description of the techniques is given in Section 1.10.1.
(187) The levels refer to the sum of metals present in the waste gas.
|
8.3.2012 |
EN |
Official Journal of the European Union |
L 70/63 |
COMMISSION IMPLEMENTING DECISION
of 28 February 2012
establishing the best available techniques (BAT) conclusions under Directive 2010/75/EU of the European Parliament and of the Council on industrial emissions for iron and steel production
(notified under document C(2012) 903)
(Text with EEA relevance)
(2012/135/EU)
THE EUROPEAN COMMISSION,
Having regard to the Treaty on the Functioning of the European Union,
Having regard to Directive 2010/75/EU of the European Parliament and of the Council of 24 November 2010 on industrial emissions (integrated pollution prevention and control) (1), and in particular Article 13(5) thereof,
Whereas:
|
(1) |
Article 13(1) of Directive 2010/75/EU requires the Commission to organise an exchange of information on industrial emissions between it and Member States, the industries concerned and non-governmental organisations promoting environmental protection in order to facilitate the drawing up of best available techniques (BAT) reference documents as defined in Article 3(11) of that Directive. |
|
(2) |
In accordance with Article 13(2) of Directive 2010/75/EU, the exchange of information is to address the performance of installations and techniques in terms of emissions, expressed as short- and long-term averages, where appropriate, and the associated reference conditions, consumption and nature of raw materials, water consumption, use of energy and generation of waste and the techniques used, associated monitoring, cross-media effects, economic and technical viability and developments therein and also the best available techniques and emerging techniques identified after considering the issues mentioned in points (a) and (b) of Article 13(2) of that Directive. |
|
(3) |
‘BAT conclusions’ as defined in Article 3(12) of Directive 2010/75/EU are the key element of BAT reference documents and lay down the conclusions on best available techniques, their description, information to assess their applicability, the emission levels associated with the best available techniques, associated monitoring, associated consumption levels and, where appropriate, relevant site remediation measures. |
|
(4) |
In accordance with Article 14(3) of Directive 2010/75/EU, BAT conclusions are to be the reference for setting the permit conditions for installations covered by Chapter 2 of that Directive. |
|
(5) |
Article 15(3) of Directive 2010/75/EU requires the competent authority to set emission limit values that ensure that, under normal operating conditions, emissions do not exceed the emission levels associated with the best available techniques as laid down in the decisions on BAT conclusions referred to in Article 13(5) of that Directive. |
|
(6) |
Article 15(4) of Directive 2010/75 provides for derogations from the requirement laid down in Article 15(3) only where the costs associated with the achievement of emissions levels disproportionately outweigh the environmental benefits due to the geographical location, the local environmental conditions or the technical characteristics of the installation concerned. |
|
(7) |
Article 16(1) of Directive 2010/75/EU provides that the monitoring requirements in the permit referred to in point (c) of Article 14(1) are to be based on the conclusions on monitoring as described in the BAT conclusions. |
|
(8) |
In accordance with Article 21(3) of Directive 2010/75/EU, within four years of publication of decisions on BAT conclusions, the competent authority is to reconsider and, if necessary, update all the permit conditions and ensure that the installation complies with those permit conditions. |
|
(9) |
Commission Decision of 16 May 2011 establishing a forum for the exchange of information pursuant to Article 13 of the Directive 2010/75/EU on industrial emissions (2) established a forum composed of representatives of Member States, the industries concerned and non-governmental organisations promoting environmental protection. |
|
(10) |
In accordance with Article 13(4) of Directive 2010/75/EU, the Commission obtained the opinion (3) of that forum on the proposed content of the BAT reference document for iron and steel production on 13 September 2011 and made it publicly available. |
|
(11) |
The measures provided for in this Decision are in accordance with the opinion of the Committee established by Article 75(1) of Directive 2010/75/EU, |
HAS ADOPTED THIS DECISION:
Article 1
The BAT conclusions for iron and steel production are set out in the Annex to this Decision.
Article 2
This Decision is addressed to the Member States.
Done at Brussels, 28 February 2012.
For the Commission
Janez POTOČNIK
Member of the Commission
(1) OJ L 334, 17.12.2010, p. 17.
(2) OJ C 146, 17.5.2011, p. 3.
(3) http://circa.europa.eu/Public/irc/env/ied/library?l=/ied_art_13_forum/opinions_article
ANNEX
BAT CONCLUSIONS FOR IRON AND STEEL PRODUCTION
| SCOPE | 66 |
| GENERAL CONSIDERATIONS | 67 |
| DEFINITIONS | 67 |
|
1.1. |
General BAT Conclusions | 68 |
|
1.1.1. |
Environmental management systems | 68 |
|
1.1.2. |
Energy management | 69 |
|
1.1.3. |
Material management | 71 |
|
1.1.4. |
Management of process residues such as by-products and waste | 72 |
|
1.1.5. |
Diffuse dust emissions from materials storage, handling and transport of raw materials and (intermediate) products | 72 |
|
1.1.6. |
Water and waste water management | 75 |
|
1.1.7. |
Monitoring | 75 |
|
1.1.8. |
Decommissioning | 76 |
|
1.1.9. |
Noise | 77 |
|
1.2. |
BAT Conclusions For Sinter Plants | 77 |
|
1.3. |
BAT Conclusions For Pelletisation Plants | 83 |
|
1.4. |
BAT Conclusions For Coke Oven Plants | 85 |
|
1.5. |
BAT Conclusions For Blast Furnaces | 89 |
|
1.6. |
BAT Conclusions For Basic Oxygen Steelmaking And Casting | 92 |
|
1.7. |
BAT Conclusions For Electric Arc Furnace Steelmaking And Casting | 96 |
SCOPE
These BAT conclusions concern the following activities specified in Annex I to Directive 2010/75/EU, namely:
— activity 1.3: coke production
— activity 2.1: metal ore (including sulphide ore) roasting and sintering
— activity 2.2: production of pig iron or steel (primary or secondary fusion) including continuous casting, with a capacity exceeding 2,5 tonnes per hour.
In particular, the BAT conclusions cover the following processes:
|
— |
the loading, unloading and handling of bulk raw materials |
|
— |
the blending and mixing of raw materials |
|
— |
the sintering and pelletisation of iron ore |
|
— |
the production of coke from coking coal |
|
— |
the production of hot metal by the blast furnace route, including slag processing |
|
— |
the production and refining of steel using the basic oxygen process, including upstream ladle desulphurisation, downstream ladle metallurgy and slag processing |
|
— |
the production of steel by electric arc furnaces, including downstream ladle metallurgy and slag processing |
|
— |
continuous casting (thin slab/thin strip and direct sheet casting (near-shape)) |
These BAT conclusions do not address the following activities:
|
— |
production of lime in kilns, covered by the Cement, Lime and Magnesium Oxide Manufacturing Industries BREF (CLM) |
|
— |
the treatment of dusts to recover non-ferrous metals (e.g. electric arc furnace dust) and the production of ferroalloys, covered by the Non-Ferrous Metals Industries BREF (NFM) |
|
— |
sulphuric acid plants in coke ovens, covered by the Large Volume Inorganic Chemicals-Ammonia, Acids and Fertilisers Industries (LVIC-AAF BREF). |
Other reference documents which are of relevance for the activities covered by these BAT conclusions are the following:
|
Reference documents |
Activity |
|
Large Combustion Plants BREF (LCP) |
Combustion plants with a rated thermal input of 50 MW or more |
|
Ferrous Metals Processing Industry BREF (FMP) |
Downstream processes like rolling, pickling, coating, etc. |
|
Continuous casting to the thin slab/thin strip and direct sheet casting (near-shape) |
|
|
Emissions from Storage BREF (EFS) |
Storage and handling |
|
Industrial Cooling Systems BREF (ICS) |
Cooling systems |
|
General Principles of Monitoring (MON) |
Emissions and consumptions monitoring |
|
Energy Efficiency BREF (ENE) |
General energy efficiency |
|
Economic and Cross-Media Effects (ECM) |
Economic and cross-media effects of techniques |
The techniques listed and described in these BAT conclusions are neither prescriptive nor exhaustive. Other techniques may be used that ensure at least an equivalent level of environmental protection.
GENERAL CONSIDERATIONS
The environmental performance levels associated with BAT are expressed as ranges, rather than as single values. A range may reflect the differences within a given type of installation (e.g. differences in the grade/purity and quality of the final product, differences in design, construction, size and capacity of the installation) that result in variations in the environmental performances achieved when applying BAT
EXPRESSION OF EMISSION LEVELS ASSOCIATED WITH THE BEST AVAILABLE TECHNIQUES (BAT-AELs)
In these BAT conclusions, BAT-AELs for air emissions are expressed as either:
|
— |
mass of emitted substances per volume of waste gas under standard conditions (273,15 K, 101,3 kPa), after deduction of water vapour content, expressed in the units g/Nm3, mg/Nm3, μg/Nm3 or ng/Nm3; or |
|
— |
mass of emitted substances per unit of mass of products generated or processed (consumption or emission factors), expressed in the units kg/t, g/t, mg/t or μg/t. |
and BAT-AELs for emissions to water are expressed as:
|
— |
mass of emitted substances per volume of waste water, expressed in the units g/l, mg/l or μg/l. |
DEFINITIONS
For the purposes of these BAT conclusions:
— ‘new plant’ means: a plant introduced on the site of the installation following the publication of these BAT conclusions or a complete replacement of a plant on the existing foundations of the installation following the publication of these BAT conclusions
— ‘existing plant’ means: a plant which is not a new plant
— ‘NOX’ means: the sum of nitrogen oxide (NO) and nitrogen dioxide (NO2) expressed as NO2
— ‘SOX’ means: the sum of sulphur dioxide (SO2) and sulphur trioxide (SO3) expressed as SO2
— ‘HCl’ means: all gaseous chlorides expressed as HCl
— ‘HF’ means: all gaseous fluorides expressed as HF
1.1. General BAT Conclusions
Unless otherwise stated, the BAT conclusions presented in this section are generally applicable.
The process specific BAT included in the Sections 1.2 – 1.7 apply in addition to the general BAT mentioned in this Section.
1.1.1.
1. BAT is to implement and adhere to an environmental management system (EMS) that incorporates all of the following features:
|
I. |
commitment of management, including senior management; |
|
II. |
definition of an environmental policy that includes continuous improvement for the installation by the management; |
|
III. |
planning and establishing the necessary procedures, objectives and targets, in conjunction with financial planning and investment; |
|
IV. |
implementation of the procedures paying particular attention to:
|
|
V. |
checking performance and taking corrective action, paying particular attention to:
|
|
VI. |
review of the EMS and its continuing suitability, adequacy and effectiveness by senior management; |
|
VII. |
following the development of cleaner technologies; |
|
VIII. |
consideration for the environmental impacts from the eventual decommissioning of the installation at the stage of designing a new plant, and throughout its operating life; |
|
IX. |
application of sectoral benchmarking on a regular basis. |
Applicability
The scope (e.g. level of details) and nature of the EMS (e.g. standardised or non-standardised) will generally be related to the nature, scale and complexity of the installation, and the range of environmental impacts it may have.
1.1.2.
2. BAT is to reduce thermal energy consumption by using a combination of the following techniques:
|
I. |
improved and optimised systems to achieve smooth and stable processing, operating close to the process parameter set points by using
|
|
II. |
recovering excess heat from processes, especially from their cooling zones |
|
III. |
an optimised steam and heat management |
|
IV. |
applying process integrated reuse of sensible heat as much as possible. |
In the context of energy management, see the Energy Efficiency BREF (ENE).
Description of BAT I.i
The following items are important for integrated steelworks in order to improve the overall energy efficiency:
|
— |
optimising energy consumption |
|
— |
online monitoring for the most important energy flows and combustion processes at the site including the monitoring of all gas flares in order to prevent energy losses, enabling instant maintenance and achieving an undisrupted production process |
|
— |
reporting and analysing tools to check the average energy consumption of each process |
|
— |
defining specific energy consumption levels for relevant processes and comparing them on a long-term basis |
|
— |
carrying out energy audits as defined in the Energy Efficiency BREF, e.g. to identify cost-effective energy savings opportunities. |
Description of BAT II – IV
Process integrated techniques used to improve energy efficiency in steel manufacturing by improved heat recovery include:
|
— |
combined heat and power production with recovery of waste heat by heat exchangers and distribution either to other parts of the steelworks or to a district heating network |
|
— |
the installation of steam boilers or adequate systems in large reheating furnaces (furnaces can cover a part of the steam demand) |
|
— |
preheating of the combustion air in furnaces and other burning systems to save fuel, taking into consideration adverse effects, i.e. an increase of nitrogen oxides in the off-gas |
|
— |
the insulation of steam pipes and hot water pipes |
|
— |
recovery of heat from products, e.g. sinter |
|
— |
where steel needs to be cooled, the use of both heat pumps and solar panels |
|
— |
the use of flue-gas boilers in furnaces with high temperatures |
|
— |
the oxygen evaporation and compressor cooling to exchange energy across standard heat exchangers |
|
— |
the use of top recovery turbines to convert the kinetic energy of the gas produced in the blast furnace into electric power. |
Applicability of BAT II – IV
Combined heat and power generation is applicable for all iron and steel plants close to urban areas with a suitable heat demand. The specific energy consumption depends on the scope of the process, the product quality and the type of installation (e.g. the amount of vacuum treatment at the basic oxygen furnace (BOF), annealing temperature, thickness of products, etc.).
3. BAT is to reduce primary energy consumption by optimisation of energy flows and optimised utilisation of the extracted process gases such as coke oven gas, blast furnace gas and basic oxygen gas.
Description
Process integrated techniques to improve energy efficiency in an integrated steelworks by optimising process gas utilisation include:
|
— |
the use of gas holders for all by-product gases or other adequate systems for short-term storage and pressure holding facilities |
|
— |
increasing pressure in the gas grid if there are energy losses in the flares – in order to utilise more process gases with the resulting increase in the utilisation rate |
|
— |
gas enrichment with process gases and different calorific values for different consumers |
|
— |
heating fire furnaces with process gas |
|
— |
use of a computer-controlled calorific value control system |
|
— |
recording and using coke and flue-gas temperatures |
|
— |
adequate dimensioning of the capacity of the energy recovery installations for the process gases, in particular with regard to the variability of process gases. |
Applicability
The specific energy consumption depends on the scope of the process, the product quality and the type of installation (e.g. the amount of vacuum treatment at the BOF, annealing temperature, thickness of products, etc.).
4. BAT is to use desulphurised and dedusted surplus coke oven gas and dedusted blast furnace gas and basic oxygen gas (mixed or separate) in boilers or in combined heat and power plants to generate steam, electricity and/or heat using surplus waste heat for internal or external heating networks, if there is a demand from a third party.
Applicability
The cooperation and agreement of a third party may not be within the control of the operator, and therefore may not be within the scope of the permit.
5. BAT is to minimise electrical energy consumption by using one or a combination of the following techniques:
|
I. |
power management systems |
|
II. |
grinding, pumping, ventilation and conveying equipment and other electricity-based equipment with high energy efficiency. |
Applicability
Frequency controlled pumps cannot be used where the reliability of the pumps is of essential importance for the safety of the process.
1.1.3.
6. BAT is to optimise the management and control of internal material flows in order to prevent pollution, prevent deterioration, provide adequate input quality, allow reuse and recycling and to improve the process efficiency and optimisation of the metal yield.
Description
Appropriate storage and handling of input materials and production residues can help to minimise the airborne dust emissions from stockyards and conveyor belts, including transfer points, and to avoid soil, groundwater and runoff water pollution (see also BAT 11).
The application of an adequate management of integrated steelworks and residues, including wastes, from other installations and sectors allows for a maximised internal and/or external use as raw materials (see also BAT 8, 9 and 10).
Material management includes the controlled disposal of small parts of the overall quantity of residues from an integrated steelworks which have no economic use.
7. In order to achieve low emission levels for relevant pollutants, BAT is to select appropriate scrap qualities and other raw materials. Regarding scrap, BAT is to undertake an appropriate inspection for visible contaminants which might contain heavy metals, in particular mercury, or might lead to the formation of polychlorinated dibenzodioxins/furans (PCDD/F) and polychlorinated biphenyls (PCB).
To improve the use of scrap, the following techniques can be used individually or in combination:
|
— |
specification of acceptance criteria suited to the production profile in purchase orders of scrap |
|
— |
having a good knowledge of scrap composition by closely monitoring the origin of the scrap; in exceptional cases, a melt test might help characterise the composition of the scrap |
|
— |
having adequate reception facilities and check deliveries |
|
— |
having procedures to exclude scrap that is not suitable for use in the installation |
|
— |
storing the scrap according to different criteria (e.g. size, alloys, degree of cleanliness); storing of scrap with potential release of contaminants to the soil on impermeable surfaces with a drainage and collection system; using a roof which can reduce the need for such a system |
|
— |
putting together the scrap load for the different melts taking into account the knowledge of composition in order to use the most suitable scrap for the steel grade to be produced (this is essential in some cases to avoid the presence of undesired elements and in other cases to take advantage of alloy elements which are present in the scrap and needed for the steel grade to be produced) |
|
— |
prompt return of all internally-generated scrap to the scrapyard for recycling |
|
— |
having an operation and management plan |
|
— |
scrap sorting to minimise the risk of including hazardous or non-ferrous contaminants, particularly polychlorinated biphenyls (PCB) and oil or grease. This is normally done by the scrap supplier but the operator inspects all scrap loads in sealed containers for safety reasons. Therefore, at the same time, it is possible to check, as far as practicable, for contaminants. Evaluation of the small quantities of plastic (e.g. as plastic coated components) may be required |
|
— |
radioactivity control according to the United Nations Economic Commission for Europe (UNECE) Expert Group framework of recommendations |
|
— |
implementation of the mandatory removal of components which contain mercury from End-of-Life Vehicles and Waste Electrical and Electronic Equipment (WEEE) by the scrap processors can be improved by:
|
Applicability
The selection and sorting of scrap might not be entirely within the control of the operator.
1.1.4.
8. BAT for solid residues is to use integrated techniques and operational techniques for waste minimisation by internal use or by application of specialised recycling processes (internally or externally).
Description
Techniques for the recycling of iron-rich residues include specialised recycling techniques such as the OxyCup® shaft furnace, the DK process, smelting reduction processes or cold bonded pelletting/briquetting as well as techniques for production residues mentioned in Sections 9.2 – 9.7.
Applicability
As the mentioned processes may be carried out by a third party, the recycling itself may not be within the control of the operator of the iron and steel plant, and therefore may not be within the scope of the permit.
9. BAT is to maximise external use or recycling for solid residues which cannot be used or recycled according to BAT 8, wherever this is possible and in line with waste regulations. BAT is to manage in a controlled manner residues which can neither be avoided nor recycled.
10. BAT is to use the best operational and maintenance practices for the collection, handling, storage and transport of all solid residues and for the hooding of transfer points to avoid emissions to air and water.
1.1.5.
11. BAT is to prevent or reduce diffuse dust emissions from materials storage, handling and transport by using one or a combination of the techniques mentioned below.
If abatement techniques are used, BAT is to optimise the capture efficiency and subsequent cleaning through appropriate techniques such as those mentioned below. Preference is given to the collection of the dust emissions nearest to the source.
|
I. |
General techniques include:
|
|
II. |
Techniques for the prevention of dust releases during the handling and transport of bulk raw materials include:
|
|
III. |
Techniques for materials delivery, storage and reclamation activities include:
|
|
IV. |
Where fuel and raw materials are delivered by sea and dust releases could be significant, some techniques include:
|
|
V. |
Train or truck unloading techniques include:
|
|
VI. |
For highly drift-sensitive materials which may lead to significant dust release, some techniques include:
|
|
VII. |
Techniques for the handling and processing of slag include:
|
|
VIII. |
Techniques for handling scrap include:
|
|
IX. |
Techniques to consider during material transport include:
|
1.1.6.
12. BAT for waste water management is to prevent, collect and separate waste water types, maximising internal recycling and using an adequate treatment for each final flow. This includes techniques utilising, e.g. oil interceptors, filtration or sedimentation. In this context, the following techniques can be used where the prerequisites mentioned are present:
|
— |
avoiding the use of potable water for production lines |
|
— |
increasing the number and/or capacity of water circulating systems when building new plants or modernising/revamping existing plants |
|
— |
centralising the distribution of incoming fresh water |
|
— |
using the water in cascades until single parameters reach their legal or technical limits |
|
— |
using the water in other plants if only single parameters of the water are affected and further usage is possible |
|
— |
keeping treated and untreated waste water separated; by this measure it is possible to dispose of waste water in different ways at a reasonable cost |
|
— |
using rainwater whenever possible. |
Applicability
The water management in an integrated steelworks will primarily be constrained by the availability and quality of fresh water and local legal requirements. In existing plants the existing configuration of the water circuits may limit applicability.
1.1.7.
13. BAT is to measure or assess all relevant parameters necessary to steer the processes from control rooms by means of modern computer-based systems in order to adjust continuously and to optimise the processes online, to ensure stable and smooth processing, thus increasing energy efficiency and maximising the yield and improving maintenance practices.
14. BAT is to measure the stack emissions of pollutants from the main emission sources from all processes included in the Sections 1.2 – 1.7 whenever BAT-AELs are given and in process gas-fired power plants in iron and steel works.
BAT is to use continuous measurements at least for:
|
— |
primary emissions of dust, nitrogen oxides (NOX) and sulphur dioxide (SO2) from sinter strands |
|
— |
nitrogen oxides (NOX) and sulphur dioxide (SO2) emissions from induration strands of pelletisation plants |
|
— |
dust emissions from blast furnace cast houses |
|
— |
secondary emissions of dust from basic oxygen furnaces |
|
— |
emissions of nitrogen oxides (NOX) from power plants |
|
— |
dust emissions from large electric arc furnaces. |
For other emissions, BAT is to consider using continuous emission monitoring depending on the mass flow and emission characteristics.
15. For relevant emission sources not mentioned in BAT 14, BAT is to measure the emissions of pollutants from all processes included in the Sections 1.2 – 1.7 and from process gas-fired power plants within iron and steel works as well as all relevant process gas components/pollutants periodically and discontinuously. This includes the discontinuous monitoring of process gases, stack emissions, polychlorinated dibenzodioxins/furans (PCDD/F) and monitoring the discharge of waste water, but excludes diffuse emissions (see BAT 16).
Description (relevant for BAT 14 and 15)
The monitoring of process gases provides information about the composition of process gases and about indirect emissions from the combustion of process gases, such as emissions of dust, heavy metals and SOx.
Stack emissions can be measured by regular, periodic discontinuous measurements at relevant channelled emission sources over a sufficiently long period, to obtain representative emission values.
For monitoring the discharge of waste water a great variety of standardised procedures exist for sampling and analyzing water and waste water, including:
|
— |
a random sample which refers to a single sample taken from a waste water flow |
|
— |
a composite sample, which refers to a sample taken continuously over a given period, or a sample consisting of several samples taken either continuously or discontinuously over a given period and blended |
|
— |
a qualified random sample shall refer to a composite sample of at least five random samples taken over a maximum period of two hours at intervals of no less than two minutes, and blended. |
Monitoring should be done according to the relevant EN or ISO standards. If EN or ISO standards are not available, national or other international standards should be used that ensure the provision of data of an equivalent scientific quality.
16. BAT is to determine the order of magnitude of diffuse emissions from relevant sources by the methods mentioned below. Whenever possible, direct measurement methods are preferred over indirect methods or evaluations based on calculations with emission factors.
|
— |
Direct measurement methods where the emissions are measured at the source itself. In this case, concentrations and mass streams can be measured or determined. |
|
— |
Indirect measurement methods where the emission determination takes place at a certain distance from the source; a direct measurement of concentrations and mass stream is not possible. |
|
— |
Calculation with emission factors. |
Description
Direct or quasi-direct measurement
Examples for direct measurements are measurements in wind tunnels, with hoods or other methods like quasi-emissions measurements on the roof of an industrial installation. For the latter case, the wind velocity and the area of the roofline vent are measured and a flow rate is calculated. The cross-section of the measurement plane of the roofline vent is subdivided into sectors of identical surface area (grid measurement).
Indirect measurements
Examples of indirect measurements include the use of tracer gases, reverse dispersion modelling (RDM) methods and the mass balance method applying light detection and ranging (LIDAR).
Calculation of emissions with emission factors
Guidelines using emission factors for the estimation of diffuse dust emissions from storage and handling of bulk materials and for the suspension of dust from roadways due to traffic movements are:
|
— |
VDI 3790 Part 3 |
|
— |
US EPA AP 42 |
1.1.8.
17. BAT is to prevent pollution upon decommissioning by using necessary techniques as listed below.
Design considerations for end-of-life plant decommissioning:
|
I. |
giving consideration to the environmental impact from the eventual decommissioning of the installation at the stage of designing a new plant, as forethought makes decommissioning easier, cleaner and cheaper |
|
II. |
decommissioning poses environmental risks for the contamination of land (and groundwater) and generates large quantities of solid waste; preventive techniques are process-specific but general considerations may include:
|
1.1.9.
18. BAT is to reduce noise emissions from relevant sources in the iron and steel manufacturing processes by using one or more of the following techniques depending on and according to local conditions:
|
— |
implementation of a noise-reduction strategy |
|
— |
enclosure of the noisy operations/units |
|
— |
vibration insulation of operations/units |
|
— |
internal and external lining made of impact-absorbent material |
|
— |
soundproofing buildings to shelter any noisy operations involving material transformation equipment |
|
— |
building noise protection walls, e.g. the construction of buildings or natural barriers, such as growing trees and bushes between the protected area and the noisy activity |
|
— |
outlet silencers on exhaust stacks |
|
— |
lagging ducts and final blowers which are situated in soundproof buildings |
|
— |
closing doors and windows of covered areas. |
1.2. BAT Conclusions For Sinter Plants
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all sinter plants.
Air emissions
19. BAT for blending/mixing is to prevent or reduce diffuse dust emissions by agglomerating fine materials by adjusting the moisture content (see also BAT 11).
20. BAT for primary emissions from sinter plants is to reduce dust emissions from the sinter strand waste gas by means of a bag filter.
BAT for primary emissions for existing plants is to reduce dust emissions from the sinter strand waste gas by using advanced electrostatic precipitators when bag filters are not applicable.
The BAT-associated emission level for dust is < 1 – 15 mg/Nm3 for the bag filter and < 20 – 40 mg/Nm3 for the advanced electrostatic precipitator (which should be designed and operated to achieve these values), both determined as a daily mean value.
Description
Bag filters used in sinter plants are usually applied downstream of an existing electrostatic precipitator or cyclone but can also be operated as a standalone device.
Applicability
For existing plants requirements such as space for a downstream installation to the electrostatic precipitator can be relevant. Special regard should be given to the age and the performance of the existing electrostatic precipitator.
Description
Advanced electrostatic precipitators are characterised by one or a combination of the following features:
|
— |
good process control |
|
— |
additional electrical fields |
|
— |
adapted strength of the electric field |
|
— |
adapted moisture content |
|
— |
conditioning with additives |
|
— |
higher or variably pulsed voltages |
|
— |
rapid reaction voltage |
|
— |
high energy pulse superimposition |
|
— |
moving electrodes |
|
— |
enlarging the electrode plate distance or other features which improves the abatement efficiency. |
21. BAT for primary emissions from sinter strands is to prevent or reduce mercury emissions by selecting raw materials with a low mercury content (see BAT 7) or to treat waste gases in combination with activated carbon or activated lignite coke injection.
The BAT-associated emissions level for mercury is < 0,03 – 0,05 mg/Nm3, as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour).
22. BAT for primary emissions from sinter strands is to reduce sulphur oxide (SOX) emissions by using one or a combination of the following techniques:
|
I. |
lowering the sulphur input by using coke breeze with a low sulphur content |
|
II. |
lowering the sulphur input by minimisation of coke breeze consumption |
|
III. |
lowering the sulphur input by using iron ore with a low sulphur content |
|
IV. |
injection of adequate adsorption agents into the waste gas duct of the sinter strand before dedusting by bag filter (see BAT 20) |
|
V. |
wet desulphurisation or regenerative activated carbon (RAC) process (with particular consideration for the prerequisites for application). |
The BAT-associated emission level for sulphur oxides (SOX) using BAT I – IV is < 350 – 500 mg/Nm3, expressed as sulphur dioxide (SO2) and determined as a daily mean value, the lower value being associated with BAT IV.
The BAT-associated emission level for sulphur oxides (SOX) using BAT V is < 100 mg/Nm3, expressed as sulphur dioxide (SO2) and determined as a daily mean value.
Description of the RAC process mentioned under BAT V
Dry desulphurisation techniques are based on an adsorption of SO2 by activated carbon. When the SO2-laden activated carbon is regenerated, the process is called regenerated activated carbon (RAC). In this case, a high quality, expensive activated carbon type may be used and sulphuric acid (H2SO4) is yielded as a by-product. The bed is regenerated either with water or thermally. In some cases, for ‘fine-tuning’ downstream of an existing desulphurisation unit, lignite-based activated carbon is used. In this case, the SO2-laden activated carbon is usually incinerated under controlled conditions.
The RAC system can be developed as a single-stage or a two-stage process.
In the single-stage process, the waste gases are led through a bed of activated carbon and pollutants are adsorbed by the activated carbon. Additionally, NOX removal occurs when ammonia (NH3) is injected into the gas stream before the catalyst bed.
In the two-stage process, the waste gases are led through two beds of activated carbon. Ammonia can be injected before the bed to reduce NOX emissions.
Applicability of techniques mentioned under BAT V
Wet desulphurisation: The requirements of space may be of significance and may restrict the applicability. High investment and operational costs and significant cross-media effects such as slurry generation and disposal and additional waste water treatment measures, have to be taken into account. This technique is not used in Europe at the time of writing, but might be an option where environmental quality standards are unlikely to be met through the application of other techniques.
RAC: Dust abatement should be installed prior to the RAC process to reduce the inlet dust concentration. Generally the layout of the plant and space requirements are important factors when considering this technique, but especially for a site with more than one sinter strand.
High investment and operational costs, in particular when high quality, expensive, activated carbon types may be used and a sulphuric acid plant is needed, have to be taken into account. This technique is not used in Europe at the time of writing, but might be an option in new plants targeting SOX, NOX, dust and PCDD/F simultaneously and in circumstances where environmental quality standards are unlikely to be met through the application of other techniques.
23. BAT for primary emissions from sinter strands is to reduce total nitrogen oxides (NOX) emissions by using one or a combination of the following techniques:
|
I. |
process integrated measures which can include:
|
|
II. |
end-of-pipe techniques which can include
|
The BAT-associated emission level for nitrogen oxides (NOX) using process integrated measures is < 500 mg/Nm3, expressed as nitrogen dioxide (NO2) and determined as a daily mean value.
The BAT-associated emission level for nitrogen oxides (NOX) using RAC is < 250 mg/Nm3 and using SCR it is < 120 mg/Nm3, expressed as nitrogen dioxide (NO2), related to an oxygen content of 15 % and determined as daily mean values.
Description of waste gas recirculation under BAT I.i
In the partial recycling of waste gas, some portions of the sinter waste gas are recirculated to the sintering process. Partial recycling of waste gas from the whole strand was primarily developed to reduce waste gas flow and thus the mass emissions of major pollutants. Additionally it can lead to a decrease in energy consumption. The application of waste gas recirculation requires special efforts to ensure that the sinter quality and productivity are not affected negatively. Special attention needs to be paid to carbon monoxide (CO) in the recirculated waste gas in order to prevent carbon monoxide poisoning of employees. Various processes have been developed such as:
|
— |
partial recycling of waste gas from the whole strand |
|
— |
recycling of waste gas from the end sinter strand combined with heat exchange
|
Applicability of BAT I.i
The applicability of this technique is site specific. Accompanying measures to ensure that sinter quality (cold mechanical strength) and strand productivity are not negatively affected must be considered. Depending on local conditions, these can be relatively minor and easy to implement or, on the contrary, they can be of a more fundamental nature and may be costly and difficult to introduce. In any case, the operating conditions of the strand should be reviewed when this technique is introduced.
In existing plants, it may not be possible to install a partial recycling of waste gas due to space restrictions.
Important considerations in determining the applicability of this technique include:
|
— |
initial configuration of the strand (e.g. dual or single wind-box ducts, space available for new equipment and, when required, lengthening of the strand) |
|
— |
initial design of the existing equipment (e.g. fans, gas cleaning and sinter screening and cooling devices) |
|
— |
initial operating conditions (e.g. raw materials, layer height, suction pressure, percentage of quick lime in the mix, specific flow rate, percentage of in-plant reverts returned in the feed) |
|
— |
existing performance in terms of productivity and solid fuel consumption |
|
— |
basicity index of the sinter and composition of the burden at the blast furnace (e.g. percentage of sinter versus pellet in the burden, iron content of these components). |
Applicability of other primary measures under BAT I.ii
The use of anthracite depends on the availability of anthracites with a lower nitrogen content compared to coke breeze.
Description and applicability of the RAC process under BAT II.i see BAT 22.
Applicability of the SCR process under BAT II.ii
SCR can be applied within a high dust system, a low dust system and as a clean gas system. Until now, only clean gas systems (after dedusting and desulphurisation) have been applied at sinter plants. It is essential that the gas is low in dust (< 40 mg dust/Nm3) and heavy metals, because they can make the surface of the catalyst ineffective. Additionally, desulphurisation prior to the catalyst might be required. Another prerequisite is a minimum off-gas temperature of about 300 °C. This requires an energy input.
The high investment and operational costs, the need for catalyst revitalisation, NH3 consumption and slip, the accumulation of explosive ammonium nitrate (NH4NO3), the formation of corrosive SO3 and the additional energy required for reheating which can reduce the possibilities for recovery of sensible heat from the sinter process, all may constrain the applicability. This technique might be an option where environmental quality standards are unlikely to be met through the application of other techniques.
24. BAT for primary emissions from sinter strands is to prevent and/or reduce emissions of polychlorinated dibenzodioxins/furans (PCDD/F) and polychlorinated biphenyls (PCB) by using one or a combination of the following techniques:
|
I. |
avoidance of raw materials which contain polychlorinated dibenzodioxins/furans (PCDD/F) and polychlorinated biphenyls (PCB) or their precursors as much as possible (see BAT 7) |
|
II. |
suppression of polychlorinated dibenzodioxins/furans (PCDD/F) formation by addition of nitrogen compounds |
|
III. |
waste gas recirculation (see BAT 23 for description and applicability). |
25. BAT for primary emissions from sinter strands is to reduce emissions of polychlorinated dibenzodioxins/furans (PCDD/F) and polychlorinated biphenyls (PCB) by the injection of adequate adsorption agents into the waste gas duct of the sinter strand before dedusting with a bag filter or advanced electrostatic precipitators when bag filters are not applicable (see BAT 20).
The BAT- associated emission level for polychlorinated dibenzodioxins/furans (PCDD/F) is < 0,05 – 0,2 ng I-TEQ/Nm3 for the bag filter and < 0,2 – 0,4 ng-I-TEQ/Nm3 for the advanced electrostatic precipitator, both determined for a 6 – 8 hour random sample under steady-state conditions.
26. BAT for secondary emissions from sinter strand discharge, sinter crushing, cooling, screening and conveyor transfer points is to prevent dust emissions and/or to achieve an efficient extraction and subsequently to reduce dust emissions by using a combination of the following techniques:
|
I. |
hooding and/or enclosure |
|
II. |
an electrostatic precipitator or a bag filter. |
The BAT-associated emission level for dust is < 10 mg/Nm3 for the bag filter and < 30 mg/Nm3 for the electrostatic precipitator, both determined as a daily mean value.
Water and waste water
27. BAT is to minimise water consumption in sinter plants by recycling cooling water as much as possible unless once-through cooling systems are used.
28. BAT is to treat the effluent water from sinter plants where rinsing water is used or where a wet waste gas treatment system is applied, with the exception of cooling water prior to discharge by using a combination of the following techniques:
|
I. |
heavy metal precipitation |
|
II. |
neutralisation |
|
III. |
sand filtration. |
The BAT-associated emission levels, based on a qualified random sample or a 24-hour composite sample, are:
|
— |
suspended solids |
< 30 mg/l |
|
— |
chemical oxygen demand (COD (1)) |
< 100 mg/l |
|
— |
heavy metals |
< 0,1 mg/l |
|
(sum of arsenic (As), cadmium (Cd), chromium (Cr), copper (Cu), mercury (Hg), nickel (Ni), lead (Pb), and zinc (Zn)). |
||
Production residues
29. BAT is to prevent waste generation within sinter plants by using one or a combination of the following techniques (see BAT 8):
|
I. |
selective on-site recycling of residues back to the sinter process by excluding heavy metals, alkali or chloride-enriched fine dust fractions (e.g. the dust from the last electrostatic precipitator field) |
|
II. |
external recycling whenever on-site recycling is hampered. |
BAT is to manage in a controlled manner sinter plant process residues which can neither be avoided nor recycled.
30. BAT is to recycle residues that may contain oil, such as dust, sludge and mill scale which contain iron and carbon from the sinter strand and other processes in the integrated steelworks, as much as possible back to the sinter strand, taking into account the respective oil content.
31. BAT is to lower the hydrocarbon content of the sinter feed by appropriate selection and pretreatment of the recycled process residues.
In all cases, the oil content of the recycled process residues should be < 0,5 % and the content of the sinter feed < 0,1 %.
Description
The input of hydrocarbons can be minimised, especially by the reduction of the oil input. Oil enters the sinter feed mainly by addition of mill scale. The oil content of mill scales can vary significantly, depending on their origin.
Techniques to minimise oil input via dusts and mill scale include the following:
|
— |
limiting input of oil by segregating and then selecting only those dusts and mill scale with a low oil content |
|
— |
the use of ‘good housekeeping’ techniques in the rolling mills can result in a substantial reduction in the contaminant oil content of mill scale |
|
— |
de-oiling of mill scale by:
|
Energy
32. BAT is to reduce thermal energy consumption within sinter plants by using one or a combination of the following techniques:
|
I. |
recovering sensible heat from the sinter cooler waste gas |
|
II. |
recovering sensible heat, if feasible, from the sintering grate waste gas |
|
III. |
maximising the recirculation of waste gases to use sensible heat (see BAT 23 for description and applicability). |
Description
Two kinds of potentially reusable waste energies are discharged from the sinter plants:
|
— |
the sensible heat from the waste gases from the sintering machines |
|
— |
the sensible heat of the cooling air from the sinter cooler. |
Partial waste gas recirculation is a special case of heat recovery from waste gases from sintering machines and is dealt with in BAT 23. The sensible heat is transferred directly back to the sinter bed by the hot recirculated gases. At the time of writing (2010), this is the only practical method of recovering heat from the waste gases.
The sensible heat in the hot air from the sinter cooler can be recovered by one or more of the following ways:
|
— |
steam generation in a waste heat boiler for use in the iron and steel works |
|
— |
hot water generation for district heating |
|
— |
preheating combustion air in the ignition hood of the sinter plant |
|
— |
preheating the sinter raw mix |
|
— |
use of the sinter cooler gases in a waste gas recirculation system. |
Applicability
At some plants, the existing configuration may make costs of heat recovery from the sinter waste gases or sinter cooler waste gas very high.
The recovery of heat from the waste gases by means of a heat exchanger would lead to unacceptable condensation and corrosion problems.
1.3. BAT Conclusions For Pelletisation Plants
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all pelletisation plants.
Air emissions
33. BAT is to reduce the dust emissions in the waste gases from
|
— |
the raw materials pre-treatment, drying, grinding, wetting, mixing and the balling; |
|
— |
from the induration strand; and |
|
— |
from the pellet handling and screening |
by using one or a combination of the following techniques:
|
I. |
an electrostatic precipitator |
|
II. |
a bag filter |
|
III. |
a wet scrubber |
The BAT-associated emission level for dust is < 20 mg/Nm3 for the crushing, grinding and drying and < 10 – 15 mg/Nm3 for all other process steps or in cases where all waste gases are treated together, all determined as daily mean values.
34. BAT is to reduce the sulphur oxides (SOX), hydrogen chloride (HCl) and hydrogen fluoride (HF) emissions from the induration strand waste gas by using one of the following techniques:
|
I. |
a wet scrubber |
|
II. |
semi-dry absorption with a subsequent dedusting system |
The BAT-associated emission levels, determined as daily mean values, for these compounds are:
|
— |
sulphur oxides (SOX), expressed as sulphur dioxide (SO2) |
< 30 – 50 mg/Nm3 |
|
— |
hydrogen fluoride (HF) |
< 1 – 3 mg/Nm3 |
|
— |
hydrogen chloride (HCl) |
< 1 – 3 mg/Nm3. |
35. BAT is to reduce NOX emissions from the drying and grinding section and induration strand waste gases by applying process-integrated techniques.
Description
Plant design through tailor-made solutions should be optimised for low nitrogen oxides (NOX) emissions from all firing sections. The reduction of the formation of thermal NOX can be achieved by lowering the (peak) temperature in the burners and reducing the excess oxygen in the combustion air. Additionally, lower NOX emissions can be achieved by a combination of low energy use and low nitrogen content in the fuel (coal and oil).
36. BAT for existing plants is to reduce NOX emissions from the drying and grinding section and induration strand waste gases by applying one of the following techniques:
|
I. |
selective catalytic reduction (SCR) as an end-of-pipe technique |
|
II. |
any other technique with a NOX reduction efficiency of at least 80 %. |
Applicability
For existing plants, both straight grate and grate kiln systems, it is difficult to obtain the operating conditions necessary to suit an SCR reactor. Due to high costs, these end-of-pipe techniques should only be considered in circumstances where environmental quality standards are otherwise not likely to be met.
37. BAT for new plants is to reduce NOX emissions from the drying and grinding section and induration strand waste gases by applying selective catalytic reduction (SCR) as an end-of-pipe technique.
Water and waste water
38. BAT for pelletisation plants is to minimise the water consumption and discharge of scrubbing, wet rinsing and cooling water and reuse it as much as possible.
39. BAT for pelletisation plants is to treat the effluent water prior to discharge by using a combination of the following techniques:
|
I. |
neutralisation |
|
II. |
flocculation |
|
III. |
sedimentation |
|
IV. |
sand filtration |
|
V. |
heavy metal precipitation. |
The BAT-associated emission levels, based on a qualified random sample or a 24-hour composite sample, are:
|
— |
suspended solids |
< 50 mg/l |
|
— |
chemical oxygen demand (COD (2)) |
< 160 mg/l |
|
— |
Kjeldahl nitrogen |
< 45 mg/l |
|
— |
heavy metals |
< 0,55 mg/l |
|
(sum of arsenic (As), cadmium (Cd), chromium (Cr), copper (Cu), mercury (Hg), nickel (Ni), lead (Pb), zinc (Zn)). |
||
Production residues
40. BAT is to prevent waste generation from pelletisation plants by effective on-site recycling or the reuse of residues (i.e. undersized green and heat-treated pellets)
BAT is to manage in a controlled manner pellet plant process residues, i.e. sludge from waste water treatment, which can neither be avoided nor recycled.
Energy
41. BAT is to reduce/minimise thermal energy consumption in pelletisation plants by using one or a combination of the following techniques:
|
I. |
process integrated reuse of sensible heat as far as possible from the different sections of the induration strand |
|
II. |
using surplus waste heat for internal or external heating networks if there is demand from a third party. |
Description
Hot air from the primary cooling section can be used as secondary combustion air in the firing section. In turn, the heat from the firing section can be used in the drying section of the induration strand. Heat from the secondary cooling section can also be used in the drying section.
Excess heat from the cooling section can be used in the drying chambers of the drying and grinding unit. The hot air is transported through an insulated pipeline called a ‘hot air recirculation duct’.
Applicability
Recovery of sensible heat is a process integrated part of pelletisation plants. The ‘hot air recirculation duct’ can be applied at existing plants with a comparable design and a sufficient supply of sensible heat.
The cooperation and agreement of a third party may not be within the control of the operator, and therefore may not be within the scope of the permit.
1.4. BAT Conclusions For Coke Oven Plants
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all coke oven plants.
Air emissions
42. BAT for coal grinding plants (coal preparation including crushing, grinding, pulverising and screening) is to prevent or reduce dust emissions by using one or a combination of the following techniques:
|
I. |
building and/or device enclosure (crusher, pulveriser, sieves) and |
|
II. |
efficient extraction and use of a subsequent dry dedusting systems. |
The BAT-associated emission level for dust is < 10 – 20 mg/Nm3, as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour).
43. BAT for storage and handling of pulverised coal is to prevent or reduce diffuse dust emissions by using one or a combination of the following techniques:
|
I. |
storing pulverised materials in bunkers and warehouses |
|
II. |
using closed or enclosed conveyors |
|
III. |
minimising the drop heights depending on the plant size and construction |
|
IV. |
reducing emissions from charging of the coal tower and the charging car |
|
V. |
using efficient extraction and subsequent dedusting. |
When using BAT V, the BAT-associated emission level for dust is < 10 – 20 mg/Nm3, as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour).
44. BAT is to charge coke oven chambers with emission-reduced charging systems.
Description
From an integrated point of view, ‘smokeless’ charging or sequential charging with double ascension pipes or jumper pipes are the preferred types, because all gases and dust are treated as part of the coke oven gas treatment.
If, however, the gases are extracted and treated outside the coke oven, charging with a land-based treatment of the extracted gases is the preferred method. Treatment should consist of an efficient extraction of the emissions with subsequent combustion to reduce organic compounds and the use of a bag filter to reduce particulates.
The BAT-associated emission level for dust from coal charging systems with land-based treatment of extracted gases is < 5 g/t coke equivalent to < 50 mg/Nm3, as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour).
The duration associated with BAT of visible emissions from charging is < 30 seconds per charge as a monthly average using a monitoring method described in BAT 46.
45. BAT for coking is to extract the coke oven gas (COG) during coking as much as possible.
46. BAT for coke plants is to reduce the emissions through achieving continuous undisrupted coke production by using the following techniques:
|
I. |
extensive maintenance of oven chambers, oven doors and frame seals, ascension pipes, charging holes and other equipment (a systematic programme should be carried out by specially-trained detection and maintenance personnel) |
|
II. |
avoiding strong temperature fluctuations |
|
III. |
comprehensive observation and monitoring of the coke oven |
|
IV. |
cleaning of doors, frame seals, charging holes, lids and ascension pipes after handling (applicable at new and, in some cases, existing plants) |
|
V. |
maintaining a free gas-flow in the coke ovens |
|
VI. |
adequate pressure regulation during coking and application of spring-loaded flexible sealing doors or knife-edged doors (in cases of ovens ≤ 5 m high and in good working order) |
|
VII. |
using water-sealed ascension pipes to reduce visible emissions from the whole apparatus which provides a passage from the coke oven battery to the collecting main, gooseneck and stationary jumper pipes |
|
VIII. |
luting charging hole lids with a clay suspension (or other suitable sealing material), to reduce visible emissions from all holes |
|
IX. |
ensuring complete coking (avoiding green coke pushes) by application of adequate techniques |
|
X. |
installing larger coke oven chambers (applicable to new plants or in some cases of a complete replacement of the plant on the old foundations) |
|
XI. |
where possible, using variable pressure regulation to oven chambers during coking (applicable to new plants and can be an option for existing plants; the possibility of installing this technique in existing plants should be assessed carefully and is subject to the individual situation of every plant). |
The percentage of visible emissions from all doors associated with BAT is < 5 – 10 %.
The percentage of visible emissions for all source types associated with BAT VII and BAT VIII is < 1 %.
The percentages are related to the frequency of any leaks compared to the total number of doors, ascension pipes or charging hole lids as a monthly average using a monitoring method as described below.
For the estimation of diffuse emissions from coke ovens the following methods are in use:
|
— |
the EPA 303 method |
|
— |
the DMT (Deutsche Montan Technologie GmbH) methodology |
|
— |
the methodology developed by BCRA (British Carbonisation Research Association). |
|
— |
the methodology applied in the Netherlands, based on counting visible leaks of the ascension pipes and charging holes, while excluding visible emissions due to normal operations (coal charging, coke pushing). |
47. BAT for the gas treatment plant is to minimise fugitive gaseous emissions by using the following techniques:
|
I. |
minimising the number of flanges by welding piping connections wherever possible |
|
II. |
using appropriate sealings for flanges and valves |
|
III. |
using gas-tight pumps (e.g. magnetic pumps) |
|
IV. |
avoiding emissions from pressure valves in storage tanks by:
|
Applicability
The techniques can be applied to both new and existing plants. In new plants, a gas tight design might be easier to achieve than in existing plants.
48. BAT is to reduce the sulphur content of the coke oven gas (COG) by using one of the following techniques:
|
I. |
desulphurisation by absorption systems |
|
II. |
wet oxidative desulphurisation. |
The residual hydrogen sulphide (H2S) concentrations associated with BAT, determined as daily mean averages, are < 300 – 1 000 mg/Nm3 in the case of using BAT I (the higher values being associated with higher ambient temperature and the lower values being associated with lower ambient temperature) and < 10 mg/Nm3 in the case of using BAT II.
49. BAT for the coke oven underfiring is to reduce the emissions by using the following techniques:
|
I. |
preventing leakage between the oven chamber and the heating chamber by means of regular coke oven operation |
|
II. |
repairing leakage between the oven chamber and the heating chamber (only applicable to existing plants) |
|
III. |
incorporating low-nitrogen oxides (NOX) techniques in the construction of new batteries, such as staged combustion and the use of thinner bricks and refractory with a better thermal conductivity (only applicable to new plants) |
|
IV. |
using desulphurised coke oven gas (COG) process gases. |
The BAT-associated emission levels, determined as daily mean values and relating to an oxygen content of 5 % are:
|
— |
sulphur oxides (SOX), expressed as sulphur dioxide (SO2) < 200 – 500 mg/Nm3 |
|
— |
dust < 1 – 20 mg/Nm3 (3) |
|
— |
nitrogen oxides (NOX), expressed as nitrogen dioxide (NO2) < 350 – 500 mg/Nm3 for new or substantially revamped plants (less than 10 years old) and 500 – 650 mg/Nm3 for older plants with well maintained batteries and incorporated low- nitrogen oxides (NOX) techniques. |
50. BAT for coke pushing is to reduce dust emissions by using the following techniques:
|
I. |
extraction by means of an integrated coke transfer machine equipped with a hood |
|
II. |
using land-based extraction gas treatment with a bag filter or other abatement systems |
|
III. |
using a one point or a mobile quenching car. |
The BAT-associated emission level for dust from coke pushing is < 10 mg/Nm3 in the case of bag filters and of < 20 mg/Nm3 in other cases, determined as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour).
Applicability
At existing plants, lack of space may constrain the applicability.
51. BAT for coke quenching is to reduce dust emissions by using one of the following techniques:
|
I. |
using coke dry quenching (CDQ) with the recovery of sensible heat and the removal of dust from charging, handling and screening operations by means of a bag filter |
|
II. |
using emission-minimised conventional wet quenching |
|
III. |
using coke stabilisation quenching (CSQ). |
The BAT-associated emission levels for dust, determined as the average over the sampling period, are:
|
— |
< 20 mg/Nm3 in case of coke dry quenching |
|
— |
< 25 g/t coke in case of emission minimised conventional wet quenching (4) |
|
— |
< 10 g/t coke in case of coke stabilisation quenching (5). |
Description of BAT I
For the continuous operation of coke dry quenching plants, there are two options. In one case, the coke dry quenching unit comprises two to up to four chambers. One unit is always on stand by. Hence no wet quenching is necessary but the coke dry quenching unit needs an excess capacity against the coke oven plant with high costs. In the other case, an additional wet quenching system is necessary.
In case of modifying a wet quenching plant to a dry quenching plant, the existing wet quenching system can be retained for this purpose. Such a coke dry quenching unit has no excess processing capacity against the coke oven plant.
Applicability of BAT II
Existing quenching towers can be equipped with emissions reduction baffles. A minimum tower height of at least 30 m is necessary in order to ensure sufficient draught conditions.
Applicability of BAT III
As the system is larger than that necessary for conventional quenching, lack of space at the plant may be a constraint.
52. BAT for coke grading and handling is to prevent or reduce dust emissions by using the following techniques in combination:
|
I. |
use of building or device enclosures |
|
II. |
efficient extraction and subsequent dry dedusting. |
The BAT-associated emission level for dust is < 10 mg/Nm3, determined as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour).
Water and waste water
53. BAT is to minimise and reuse quenching water as much as possible.
54. BAT is to avoid the reuse of process water with a significant organic load (like raw coke oven waste water, waste water with a high content of hydrocarbons, etc.) as quenching water.
55. BAT is to pretreat waste water from the coking process and coke oven gas (COG) cleaning prior to discharge to a waste water treatment plant by using one or a combination of the following techniques:
|
I. |
using efficient tar and polycyclic aromatic hydrocarbons (PAH) removal by using flocculation and subsequent flotation, sedimentation and filtration individually or in combination |
|
II. |
using efficient ammonia stripping by using alkaline and steam. |
56. BAT for pretreated waste water from the coking process and coke oven gas (COG) cleaning is to use biological waste water treatment with integrated denitrification/nitrification stages.
The BAT-associated emission levels, based on a qualified random sample or a 24-hour composite sample and referring only to single coke oven water treatment plants, are:
|
< 220 mg/l |
||
|
< 20 mg/l |
||
|
< 0,1 mg/l |
||
|
< 4 mg/l |
||
|
< 0,1 mg/l |
||
|
< 0,05 mg/l |
||
|
< 0,5 mg/l |
||
|
< 15 – 50 mg/l. |
Regarding the sum of ammonia-nitrogen (NH4 +-N), nitrate-nitrogen (NO3 --N) and nitrite-nitrogen (NO2 --N), values of < 35 mg/l are usually associated with the application of advanced biological waste water treatment plants with predenitrification/nitrification and post-denitrification.
Production residues
57. BAT is to recycle production residues such as tar from the coal water and still effluent, and surplus activated sludge from the waste water treatment plant back to the coal feed of the coke oven plant.
Energy
58. BAT is to use the extracted coke oven gas (COG) as a fuel or reducing agent or for the production of chemicals.
1.5. BAT Conclusions For Blast Furnaces
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all blast furnaces.
Air emissions
59. BAT for displaced air during loading from the storage bunkers of the coal injection unit is to capture dust emissions and perform subsequent dry dedusting.
The BAT-associated emission level for dust is < 20 mg/Nm3, determined as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour).
60. BAT for burden preparation (mixing, blending) and conveying is to minimise dust emissions and, where relevant, extraction with subsequent dedusting by means of an electrostatic precipitator or bag filter.
61. BAT for casting house (tap holes, runners, torpedo ladles charging points, skimmers) is to prevent or reduce diffuse dust emissions by using the following techniques:
|
I. |
covering the runners |
|
II. |
optimising the capture efficiency for diffuse dust emissions and fumes with subsequent off-gas cleaning by means of an electrostatic precipitator or bag filter |
|
III. |
fume suppression using nitrogen while tapping, where applicable and where no collecting and dedusting system for tapping emissions is installed. |
When using BAT II, the BAT-associated emission level for dust is < 1 – 15 mg/Nm3, determined as a daily mean value.
62. BAT is to use tar-free runner linings.
63. BAT is to minimise the release of blast furnace gas during charging by using one or a combination of the following techniques:
|
I. |
bell-less top with primary and secondary equalising |
|
II. |
gas or ventilation recovery system |
|
III. |
use of blast furnace gas to pressurise the top bunkers. |
Applicability of BAT II
Applicable for new plants. Applicable for existing plants only where the furnace has a bell-less charging system. It is not applicable to plants where gases other than blast furnace gas (e.g. nitrogen) are used to pressurise the furnace top bunkers.
64. BAT is to reduce dust emissions from the blast furnace gas by using one or a combination of the following techniques:
|
I. |
using dry prededusting devices such as:
|
|
II. |
subsequent dust abatement such as:
|
For cleaned blast furnace (BF) gas, the residual dust concentration associated with BAT is < 10 mg/Nm3, determined as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour).
65. BAT for hot blast stoves is to reduce emissions by using desulphurised and dedusted surplus coke oven gas, dedusted blast furnace gas, dedusted basic oxygen furnace gas and natural gas, individually or in combination.
The BAT-associated emission levels, determined as daily mean values related to an oxygen content of 3 %, are:
|
— |
sulphur oxides (SOx) expressed as sulphur dioxide (SO2) < 200 mg/Nm3 |
|
— |
dust < 10 mg/Nm3 |
|
— |
nitrogen oxides (NOx), expressed as nitrogen dioxide (NO2) < 100 mg/Nm3. |
Water and waste water
66. BAT for water consumption and discharge from blast furnace gas treatment is to minimise and to reuse scrubbing water as much as possible, e.g. for slag granulation, if necessary after treatment with a gravel-bed filter.
67. BAT for treating waste water from blast furnace gas treatment is to use flocculation (coagulation) and sedimentation and the reduction of easily released cyanide, if necessary.
The BAT-associated emission levels, based on a qualified random sample or a 24-hour composite sample, are:
|
— |
suspended solids |
< 30 mg/l |
|
— |
iron |
< 5 mg/l |
|
— |
lead |
< 0,5 mg/l |
|
— |
zinc |
< 2 mg/l |
|
— |
cyanide (CN-), easily released (9) |
< 0,4 mg/l. |
Production residues
68. BAT is to prevent waste generation from blast furnaces by using one or a combination of the following techniques:
|
I. |
appropriate collection and storage to facilitate a specific treatment |
|
II. |
on-site recycling of coarse dust from the blast furnace (BF) gas treatment and dust from the cast house dedusting, with due regard for the effect of emissions from the plant where it is recycled |
|
III. |
hydrocyclonage of sludge with subsequent on-site recycling of the coarse fraction (applicable whenever wet dedusting is applied and where the zinc content distribution in the different grain sizes allows a reasonable separation) |
|
IV. |
slag treatment, preferably by means of granulation (where market conditions allow for it), for the external use of slag (e.g. in the cement industry or for road construction). |
BAT is to manage in a controlled manner blast furnace process residues which can neither be avoided nor recycled.
69. BAT for minimising slag treatment emissions is to condense fume if odour reduction is required.
Resource management
70. BAT for resource management of blast furnaces is to reduce coke consumption by directly injected reducing agents, such as pulverised coal, oil, heavy oil, tar, oil residues, coke oven gas (COG), natural gas and wastes such as metallic residues, used oils and emulsions, oily residues, fats and waste plastics individually or in combination.
Applicability
Coal injection: The method is applicable to all blast furnaces equipped with pulverised coal injection and oxygen enrichment.
Gas injection: Tuyère injection of coke oven gas (COG) is highly dependent upon the availability of the gas that may be effectively used elsewhere in the integrated steelworks.
Plastic injection: It should be noted that this technique is highly dependent on the local circumstances and market conditions. Plastics can contain Cl and heavy metals like Hg, Cd, Pb and Zn. Depending on the composition of the wastes used (e.g. shredder light fraction), the amount of Hg, Cr, Cu, Ni and Mo in the BF gas may increase.
Direct injection of used oils, fats and emulsions as reducing agents and of solid iron residues: The continuous operation of this system is reliant on the logistical concept of delivery and the storage of residues. Also, the conveying technology applied is of particular importance for a successful operation.
Energy
71. BAT is to maintain a smooth, continuous operation of the blast furnace at a steady state to minimise releases and to reduce the likelihood of burden slips.
72. BAT is to use the extracted blast furnace gas as a fuel.
73. BAT is to recover the energy of top blast furnace gas pressure where sufficient top gas pressure and low alkali concentrations are present.
Applicability
Top gas pressure recovery can be applied at new plants and in some circumstances at existing plants, albeit with more difficulties and additional costs. Fundamental to the application of this technique is an adequate top gas pressure in excess of 1.5 bar gauge.
At new plants, the top gas turbine and the blast furnace (BF) gas cleaning facility can be adapted to each other in order to achieve a high efficiency of both scrubbing and energy recovery.
74. BAT is to preheat the hot blast stove fuel gases or combustion air using the waste gas of the hot blast stove and to optimise the hot blast stove combustion process.
Description
For optimisation of the energy efficiency of the hot stove, one or a combination of the following techniques can be applied:
|
— |
the use of a computer-aided hot stove operation |
|
— |
preheating of the fuel or combustion air in conjunction with insulation of the cold blast line and waste gas flue |
|
— |
use of more suitable burners to improve combustion |
|
— |
rapid oxygen measurement and subsequent adaptation of combustion conditions. |
Applicability
The applicability of fuel preheating depends on the efficiency of the stoves as this determines the waste gas temperature (e.g. at waste gas temperatures below 250 °C, heat recovery may not be a technically or economically viable option).
The implementation of computer-aided control could require the construction of a fourth stove in the case of blast furnaces with three stoves (if possible) in order to maximise benefits.
1.6. BAT Conclusions For Basic Oxygen Steelmaking And Casting
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all basic oxygen steelmaking and casting.
Air emissions
75. BAT for basic oxygen furnace (BOF) gas recovery by suppressed combustion is to extract the BOF gas during blowing as much as possible and to clean it by using the following techniques in combination:
|
I. |
use of a suppressed combustion process |
|
II. |
prededusting to remove coarse dust by means of dry separation techniques (e.g. deflector, cyclone) or wet separators |
|
III. |
dust abatement by means of:
|
The residual dust concentrations associated with BAT, after buffering the BOF gas, are:
|
— |
10 – 30 mg/Nm3 for BAT III.i |
|
— |
< 50 mg/Nm3 for BAT III.ii. |
76. BAT for basic oxygen furnace (BOF) gas recovery during oxygen blowing in the case of full combustion is to reduce dust emissions by using one of the following techniques:
|
I. |
dry dedusting (e.g. ESP or bag filter) for new and existing plants |
|
II. |
wet dedusting (e.g. wet ESP or scrubber) for existing plants. |
The BAT-associated emission levels for dust, determined as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour), are:
|
— |
10 – 30 mg/Nm3 for BAT I |
|
— |
< 50 mg/Nm3 for BAT II. |
77. BAT is to minimise dust emissions from the oxygen lance hole by using one or a combination of the following techniques:
|
I. |
covering the lance hole during oxygen blowing |
|
II. |
inert gas or steam injection into the lance hole to dissipate the dust |
|
III. |
use of other alternative sealing designs combined with lance cleaning devices. |
78. BAT for secondary dedusting, including the emissions from the following processes:
|
— |
reladling of hot metal from the torpedo ladle (or hot metal mixer) to the charging ladle |
|
— |
hot metal pretreatment (i.e. the preheating of vessels, desulphurisation, dephosphorisation, deslagging, hot metal transfer processes and weighing) |
|
— |
BOF-related processes like the preheating of vessels, slopping during oxygen blowing, hot metal and scrap charging, tapping of liquid steel and slag from BOF and |
|
— |
secondary metallurgy and continuous casting, |
is to minimise dust emissions by means of process integrated techniques, such as general techniques to prevent or control diffuse or fugitive emissions, and by using appropriate enclosures and hoods with efficient extraction and a subsequent off-gas cleaning by means of a bag filter or an ESP.
The overall average dust collection efficiency associated with BAT is > 90 %
The BAT-associated emission level for dust, as a daily mean value, for all dedusted off-gases is < 1 – 15 mg/Nm3 in the case of bag filters and < 20 mg/Nm3 in the case of electrostatic precipitators.
If the emissions from hot metal pretreatment and the secondary metallurgy are treated separately, the BAT-associated emission level for dust, as a daily mean value, is < 1 – 10 mg/Nm3 for bag filters and < 20 mg/Nm3 for electrostatic precipitators.
Description
General techniques to prevent diffuse and fugitive emissions from the relevant BOF process secondary sources include:
|
— |
independent capture and use of dedusting devices for each subprocess in the BOF shop |
|
— |
correct management of the desulphurisation installation to prevent air emissions |
|
— |
total enclosure of the desulphurisation installation |
|
— |
maintaining the lid on when the hot metal ladle is not in use and the cleaning of hot metal ladles and removal of skulls on a regular basis or alternatively apply a roof extraction system |
|
— |
maintaining the hot metal ladle in front of the converter for approximately two minutes after putting the hot metal into the converter if a roof extraction system is not applied |
|
— |
computer control and optimisation of the steelmaking process, e.g. so that slopping (i.e. when the slag foams to such an extent that it flows out of the vessel) is prevented or reduced |
|
— |
reduction of slopping during tapping by limiting elements that cause slopping and the use of anti-slopping agents |
|
— |
closure of doors from the room around the converter during oxygen blowing |
|
— |
continuous camera observation of the roof for visible emission |
|
— |
the use of a roof extraction system. |
Applicability
In existing plants, the design of the plant may restrict the possibilities for proper evacuation.
79. BAT for on-site slag processing is to reduce dust emissions by using one or a combination of the following techniques:
|
I. |
efficient extraction of the slag crusher and screening devices with subsequent off-gas cleaning, if relevant |
|
II. |
transport of untreated slag by shovel loaders |
|
III. |
extraction or wetting of conveyor transfer points for broken material |
|
IV. |
wetting of slag storage heaps |
|
V. |
use of water fogs when broken slag is loaded. |
The BAT-associated emission level for dust in the case of using BAT I is < 10 – 20 mg/Nm3, determined as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour).
Water and waste water
80. BAT is to prevent or reduce water use and waste water emissions from primary dedusting of basic oxygen furnace (BOF) gas by using one of the following techniques as set out in BAT 75 and BAT 76:
|
— |
dry dedusting of basic oxygen furnace (BOF) gas; |
|
— |
minimising scrubbing water and reusing it as much as possible(e.g. for slag granulation) in case wet dedusting is applied. |
81. BAT is to minimise the waste water discharge from continuous casting by using the following techniques in combination:
|
I. |
the removal of solids by flocculation, sedimentation and/or filtration |
|
II. |
the removal of oil in skimming tanks or any other effective device |
|
III. |
the recirculation of cooling water and water from vacuum generation as much as possible. |
The BAT-associated emission levels, based on a qualified random sample or a 24-hour composite sample, for waste water from continuous casting machines are:
|
— |
suspended solids |
< 20 mg/l |
|
— |
iron |
< 5 mg/l |
|
— |
zinc |
< 2 mg/l |
|
— |
nickel |
< 0,5 mg/l |
|
— |
total chromium |
< 0,5 mg/l |
|
— |
total hydrocarbons |
< 5 mg/l. |
Production residues
82. BAT is to prevent waste generation by using one or a combination of the following techniques (see BAT 8):
|
I. |
appropriate collection and storage to facilitate a specific treatment |
|
II. |
on-site recycling of dust from basic oxygen furnace (BOF) gas treatment, dust from secondary dedusting and mill scale from continuous casting back to the steelmaking processes with due regard for the effect of emissions from the plant where they are recycled |
|
III. |
on-site recycling of BOF slag and BOF slag fines in various applications |
|
IV. |
slag treatment where market conditions allow for the external use of slag (e.g. as an aggregate in materials or for construction) |
|
V. |
use of filter dusts and sludge for external recovery of iron and non-ferrous metals such as zinc in the non-ferrous metals industry |
|
VI. |
use of a settling tank for sludge with the subsequent recycling of the coarse fraction in the sinter/blast furnace or cement industry when grain size distribution allows for a reasonable separation. |
Applicability of BAT V
Dust hot briquetting and recycling with recovery of high zinc concentrated pellets for external reuse is applicable when a dry electrostatic precipitation is used to clean the BOF gas. Recovery of zinc by briquetting is not applicable in wet dedusting systems because of unstable sedimentation in the settling tanks caused by the formation of hydrogen (from a reaction of metallic zinc and water). Due to these safety reasons, the zinc content in the sludge should be limited to 8 – 10 %.
BAT is to manage in a controlled manner basic oxygen furnace process residues which can neither be avoided nor recycled.
Energy
83. BAT is to collect, clean and buffer BOF gas for subsequent use as a fuel.
Applicability
In some cases, it may not be economically feasible or, with regard to appropriate energy management, not feasible to recover the BOF gas by suppressed combustion. In these cases, the BOF gas may be combusted with the generation of steam. The kind of combustion (full or suppressed combustion) depends on local energy management.
84. BAT is to reduce energy consumption by using ladle-lid systems.
Applicability
The lids can be very heavy as they are made out of refractory bricks and therefore the capacity of the cranes and the design of the whole building may constrain the applicability in existing plants. There are different technical designs for implementing the system into the particular conditions of a steel plant.
85. BAT is to optimise the process and reduce energy consumption by using a direct tapping process after blowing.
Description
Direct tapping normally requires expensive facilities like sub-lance or DROP IN sensor-systems to tap without waiting for a chemical analysis of the samples taken (direct tapping). Alternatively, a new technique has been developed to achieve direct tapping without such facilities. This technique requires a lot of experience and developmental work. In practice, the carbon is directly blown down to 0,04 % and simultaneously the bath temperature decreases to a reasonably low target. Before tapping, both the temperature and oxygen activity are measured for further actions.
Applicability
A suitable hot metal analyser and slag stopping facilities are required and the availability of a ladle furnace facilitates implementation of the technique.
86. BAT is to reduce energy consumption by using continuous near net shape strip casting, if the quality and the product mix of the produced steel grades justify it.
Description
Near net shape strip casting means the continuous casting of steel to strips with thicknesses of less than 15 mm. The casting process is combined with the direct hot rolling, cooling and coiling of the strips without an intermediate reheating furnace used for conventional casting techniques, e.g. continuous casting of slabs or thin slabs. Therefore, strip casting represents a technique for producing flat steel strips of different widths and thicknesses of less than 2 mm.
Applicability
The applicability depends on the produced steel grades (e.g. heavy plates cannot be produced with this process) and on the product portfolio (product mix) of the individual steel plant. In existing plants, the applicability may be constrained by the layout and the available space as e.g. retrofitting with a strip caster requires approximately 100 m in length.
1.7. BAT Conclusions For Electric Arc Furnace Steelmaking And Casting
Unless otherwise stated, the BAT conclusions presented in this section can be applied to all electric arc furnace steelmaking and casting.
Air emissions
87. BAT for the electric arc furnace (EAF) process is to prevent mercury emissions by avoiding, as much as possible, raw materials and auxiliaries which contain mercury (see BAT 6 and 7).
88. BAT for the electric arc furnace (EAF) primary and secondary dedusting (including scrap preheating, charging, melting, tapping, ladle furnace and secondary metallurgy) is to achieve an efficient extraction of all emission sources by using one of the techniques listed below and to use subsequent dedusting by means of a bag filter:
|
I. |
a combination of direct off-gas extraction (4th or 2nd hole) and hood systems |
|
II. |
direct gas extraction and doghouse systems |
|
III. |
direct gas extraction and total building evacuation (low-capacity electric arc furnaces (EAF) may not require direct gas extraction to achieve the same extraction efficiency). |
The overall average collection efficiency associated with BAT is > 98 %.
The BAT-associated emission level for dust is < 5 mg/Nm3, determined as a daily mean value.
The BAT-associated emission level for mercury is < 0,05 mg/Nm3, determined as the average over the sampling period (discontinuous measurement, spot samples for at least four hours).
89. BAT for the electric arc furnace (EAF) primary and secondary dedusting (including scrap preheating, charging, melting, tapping, ladle furnace and secondary metallurgy) is to prevent and reduce polychlorinated dibenzodioxins/furans (PCDD/F) and polychlorinated biphenyls (PCB) emissions by avoiding, as much as possible, raw materials which contain PCDD/F and PCB or their precursors (see BAT 6 and 7) and using one or a combination of the following techniques, in conjunction with an appropriate dust removal system:
|
I. |
appropriate post-combustion |
|
II. |
appropriate rapid quenching |
|
III. |
injection of adequate adsorption agents into the duct before dedusting. |
The BAT-associated emission level for polychlorinated dibenzodioxins/furans (PCDD/F) is < 0,1 ng I-TEQ/Nm3, based on a 6 – 8 hour random sample during steady-state conditions. In some cases, the BAT-associated emission level can be achieved with primary measures only.
Applicability of BAT I
In existing plants, circumstances like available space, given off-gas duct system, etc. need to be taken into consideration for assessing the applicability.
90. BAT for on-site slag processing is to reduce dust emissions by using one or a combination of the following techniques:
|
I. |
efficient extraction of the slag crusher and screening devices with subsequent off-gas cleaning, if relevant |
|
II. |
transport of untreated slag by shovel loaders |
|
III. |
extraction or wetting of conveyor transfer points for broken material |
|
IV. |
wetting of slag storage heaps |
|
V. |
use of water fogs when broken slag is loaded. |
In the case of using BAT I, the BAT-associated emission level for dust is < 10 – 20 mg/Nm3, determined as the average over the sampling period (discontinuous measurement, spot samples for at least half an hour).
Water and waste water
91. BAT is to minimise the water consumption from the electric arc furnace (EAF) process by the use of closed loop water cooling systems for the cooling of furnace devices as much as possible unless once-through cooling systems are used.
92. BAT is to minimise the waste water discharge from continuous casting by using the following techniques in combination:
|
I. |
the removal of solids by flocculation, sedimentation and/or filtration |
|
II. |
the removal of oil in skimming tanks or in any other effective device |
|
III. |
the recirculation of cooling water and water from vacuum generation as much as possible. |
The BAT-associated emission levels, for waste water from continuous casting machines, based on a qualified random sample or a 24-hour composite sample, are:
|
— |
suspended solids |
< 20 mg/l |
|
— |
iron |
< 5 mg/l |
|
— |
zinc |
< 2 mg/l |
|
— |
nickel |
< 0,5 mg/l |
|
— |
total chromium |
< 0,5 mg/l |
|
— |
total hydrocarbons |
< 5 mg/l |
Production residues
93. BAT is to prevent waste generation by using one or a combination of the following techniques:
|
I. |
appropriate collection and storage to facilitate a specific treatment |
|
II. |
recovery and on-site recycling of refractory materials from the different processes and use internally, i.e. for the substitution of dolomite, magnesite and lime |
|
III. |
use of filter dusts for the external recovery of non-ferrous metals such as zinc in the non-ferrous metals industry, if necessary, after the enrichment of filter dusts by recirculation to the electric arc furnace (EAF) |
|
IV. |
separation of scale from continuous casting in the water treatment process and recovery with subsequent recycling, e.g. in the sinter/blast furnace or cement industry |
|
V. |
external use of refractory materials and slag from the electric arc furnace (EAF) process as a secondary raw material where market conditions allow for it. |
BAT is to manage in a controlled manner EAF process residues which can neither be avoided nor recycled.
Applicability
The external use or recycling of production residues as mentioned under BAT III – V depend on the cooperation and agreement of a third party which may not be within the control of the operator, and therefore may not be within the scope of the permit.
Energy
94. BAT is to reduce energy consumption by using continuous near net shape strip casting, if the quality and the product mix of the produced steel grades justify it.
Description
Near net shape strip casting means the continuous casting of steel to strips with thicknesses of less than 15 mm. The casting process is combined with the direct hot rolling, cooling and coiling of the strips without an intermediate reheating furnace used for conventional casting techniques, e.g. continuous casting of slabs or thin slabs. Therefore, strip casting represents a technique for producing flat steel strips of different widths and thicknesses of less than 2 mm.
Applicability
The applicability depends on the produced steel grades (e.g. heavy plates cannot be produced with this process) and on the product portfolio (product mix) of the individual steel plant. In existing plants, the applicability may be constrained by the layout and the available space as e.g. retrofitting with a strip caster requires approximately 100 m in length.
Noise
95. BAT is to reduce noise emissions from electric arc furnace (EAF) installations and processes generating high sound energies by using a combination of the following constructional and operational techniques depending on and according to local conditions (in addition to using the techniques listed in BAT 18):
|
I. |
construct the electric arc furnace (EAF) building in such a way as to absorb noise from mechanical shocks resulting from the operation of the furnace |
|
II. |
construct and install cranes destined to transport the charging baskets to prevent mechanical shocks |
|
III. |
special use of acoustical insulation of the inside walls and roofs to prevent the airborne noise of the electric arc furnace (EAF) building |
|
IV. |
separation of the furnace and the outside wall to reduce the structure-borne noise from the electric arc furnace (EAF) building |
|
V. |
housing of processes generating high sound energies (i.e. electric arc furnace (EAF) and decarburisation units) within the main building. |
(1) In some cases, TOC is measured instead of COD (in order to avoid HgCl2 used in the analysis for COD). The correlation between COD and TOC should be elaborated for each sinter plant case by case. The COD/TOC ratio may vary approximately between two and four.
(2) In some cases, TOC is measured instead of COD (in order to avoid HgCl2 used in the analysis for COD). The correlation between COD and TOC should be elaborated for each pelletisation plant case by case. The COD/TOC ratio may vary approximately between two and four.
(3) The lower end of the range has been defined based on the performance of one specific plant achieved under real operating conditions by the BAT obtaining the best environmental performance.
(4) This level is based on the use of the non-isokinetic Mohrhauer method (former VDI 2303)
(5) This level is based on the use of an isokinetic sampling method according to VDI 2066
(6) In some cases, TOC is measured instead of COD (in order to avoid HgCl2 used in the analysis for COD). The correlation between COD and TOC should be elaborated for each coke oven plant case by case. The COD/TOC ratio may vary approximately between two and four.
(7) This level is based on the use of the DIN 38405 D 27 or any other national or international standard that ensures the provision of data of an equivalent scientific quality.
(8) This level is based on the use of the DIN 38405 D 13-2 or any other national or international standard that ensures the provision of data of an equivalent scientific quality.
(9) This level is based on the use of the DIN 38405 D 13-2 or any other national or international standard that ensures the provision of data of an equivalent scientific quality.