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Document 32015D2119
Commission Implementing Decision (EU) 2015/2119 of 20 November 2015 establishing best available techniques (BAT) conclusions, under Directive 2010/75/EU of the European Parliament and of the Council, for the production of wood-based panels (notified under document C(2015) 8062) (Text with EEA relevance)
Commission Implementing Decision (EU) 2015/2119 of 20 November 2015 establishing best available techniques (BAT) conclusions, under Directive 2010/75/EU of the European Parliament and of the Council, for the production of wood-based panels (notified under document C(2015) 8062) (Text with EEA relevance)
Commission Implementing Decision (EU) 2015/2119 of 20 November 2015 establishing best available techniques (BAT) conclusions, under Directive 2010/75/EU of the European Parliament and of the Council, for the production of wood-based panels (notified under document C(2015) 8062) (Text with EEA relevance)
OJ L 306, 24.11.2015, p. 31–51
(BG, ES, CS, DA, DE, ET, EL, EN, FR, HR, IT, LV, LT, HU, MT, NL, PL, PT, RO, SK, SL, FI, SV)
In force
24.11.2015 |
EN |
Official Journal of the European Union |
L 306/31 |
COMMISSION IMPLEMENTING DECISION (EU) 2015/2119
of 20 November 2015
establishing best available techniques (BAT) conclusions, under Directive 2010/75/EU of the European Parliament and of the Council, for the production of wood-based panels
(notified under document C(2015) 8062)
(Text with EEA relevance)
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) |
The Commission established a forum composed of representatives of Member States, the industries concerned and non-governmental organisations promoting environmental protection by 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). |
(2) |
In accordance with Article 13(4) of Directive 2010/75/EU, the Commission obtained the opinion of that forum on the proposed content of the BAT reference document for the production of wood-based panels on 24 September 2014 and made it publicly available. |
(3) |
The BAT conclusions set out in the Annex to this Decision are the key element of that BAT reference document 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) |
BAT conclusions are the reference for setting permit conditions for installations covered by Chapter II of Directive 2010/75/EU and competent authorities should 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 BAT conclusions. |
(5) |
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 production of wood-based panels, as set out in the Annex, are adopted.
Article 2
This Decision is addressed to the Member States.
Done at Brussels, 20 November 2015.
For the Commission
Karmenu VELLA
Member of the Commission
ANNEX
BAT CONCLUSIONS FOR THE PRODUCTION OF WOOD-BASED PANELS
SCOPE | 32 |
GENERAL CONSIDERATIONS | 33 |
DEFINITIONS AND ACRONYMS | 34 |
1.1. |
GENERAL BAT CONCLUSIONS | 36 |
1.1.1. |
Environmental management system | 36 |
1.1.2. |
Good housekeeping | 37 |
1.1.3. |
Noise | 38 |
1.1.4. |
Emissions to soil and groundwater | 38 |
1.1.5. |
Energy management and energy efficiency | 39 |
1.1.6. |
Odour | 40 |
1.1.7. |
Management of waste and residues | 40 |
1.1.8. |
Monitoring | 41 |
1.2. |
EMISSIONS TO AIR | 43 |
1.2.1. |
Channelled emissions | 43 |
1.2.2. |
Diffuse emissions | 47 |
1.3. |
EMISSIONS TO WATER | 48 |
1.4. |
DESCRIPTION OF TECHNIQUES | 49 |
1.4.1. |
Emissions to air | 49 |
1.4.2. |
Emissions to water | 51 |
SCOPE
These BAT conclusions concern the activities specified in Section 6.1(c) of Annex I to Directive 2010/75/EU, namely:
— |
production in industrial installations of one or more of the following wood-based panels: oriented strand board, particleboard or fibreboard with a production capacity exceeding 600 m3 per day. |
In particular, these BAT conclusions cover the following:
— |
the manufacture of wood-based panels; |
— |
on-site combustion plants (including engines) generating hot gases for directly heated dryers; |
— |
the manufacture of impregnated paper with resins. |
These BAT conclusions do not address the following activities and processes:
— |
on-site combustion plants (including engines) not generating hot gases for directly heated dryers; |
— |
the lamination, lacquering or painting of raw board. |
Other reference documents which are relevant for the activities covered by these BAT conclusions are the following:
Reference document |
Subject |
Monitoring of Emissions to air and water from IED installations (ROM) |
Monitoring of emissions to air and water |
Large Combustion Plants (LCP) |
Combustion techniques |
Waste Incineration (WI) |
Waste incineration |
Energy Efficiency (ENE) |
Energy efficiency |
Waste Treatment (WT) |
Waste treatment |
Emissions from Storage (EFS) |
Storage and handling of materials |
Economics and Cross-Media Effects (ECM) |
Economics and cross-media effects of techniques |
Large Volume Organic Chemical industry (LVOC) |
Production of melamine, urea-formaldehyde resins and methylene diphenyl diisocyanate |
GENERAL CONSIDERATIONS
BEST AVAILABLE 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.
Unless stated otherwise, the BAT conclusions are generally applicable.
EMISSION LEVELS ASSOCIATED WITH BAT (BAT-AELs) FOR EMISSIONS TO AIR
Unless stated otherwise, the BAT-AELs for emissions to air given in these BAT conclusions refer to concentrations expressed as mass of emitted substance per volume of waste gas under standard conditions (273,15 K, 101,3 kPa) and on a dry basis, expressed in the unit mg/Nm3.
The reference oxygen levels are the following:
Emission source |
Reference oxygen levels |
Directly heated PB or directly heated OSB dryers alone or combined with the press |
18 % oxygen by volume |
All other sources |
No correction for oxygen |
The formula for calculating the emission concentration at the reference oxygen level is:
where: |
|
The BAT-AELs for emissions to air refer to the average over the sampling period, meaning the following:
Average value of three consecutive measurements of at least 30 minutes each (1)
EMISSION LEVELS ASSOCIATED WITH BAT (BAT-AELs) FOR EMISSIONS TO WATER
The BAT-AELs for emissions to water given in these BAT conclusions refer to values of concentrations (mass of emitted substances per volume of water), expressed in the unit mg/l.
These BAT-AELs refer to the average of samples obtained during one year, meaning the flow-weighted average of all 24-hour flow-proportional composite samples, taken in one year with the minimum frequency set for the relevant parameter and under normal operating conditions.
The formula for calculating the flow-weighted average of all 24-hour flow-proportional composite samples is:
where: |
|
Time-proportional sampling can be used provided that sufficient flow stability can be demonstrated.
All BAT-AELs for emissions to water apply at the point where the emission leaves the installation.
DEFINITIONS AND ACRONYMS
For the purpose of these BAT conclusions, the following definitions apply:
Term |
Definition |
COD |
Chemical oxygen demand; the amount of oxygen needed for the total oxidation of the organic matter to carbon dioxide (normally in reference to analysis with dichromate oxidation). |
Continuous measurement |
Continuous determination of a measurand using a permanently installed ‘automated measuring system’ (AMS) or ‘continuous emission monitoring system’ (CEM). |
Continuous press |
A panel press that presses a continuous mat. |
Diffuse emissions |
Non-channelled emissions that are not released via specific emission points such as stacks. |
Directly heated dryer |
A dryer where hot gases from a combustion plant, or any other source, are in direct contact with the particles, strands or fibres to be dried. The drying is achieved by convection. |
Dust |
Total particulate matter. |
Existing plant |
A plant that is not a new plant. |
Fibre |
Lignocellulosic components of wood or other plant materials derived by mechanical or thermo-mechanical pulping using a refiner. Fibres are used as the starting material for the production of fibreboard. |
Fibreboard |
As defined in EN 316 i.e. ‘panel material with a nominal thickness of 1,5 mm or greater, manufactured from lignocellulosic fibres with application of heat and/or pressure’. Fibreboards include wet process boards (hardboard, medium board, softboard) and dry-process fibreboard (MDF). |
Hardwood |
Group of wood species including aspen, beech, birch and eucalyptus. The term hardwood is used as an opposite to the term softwood. |
Indirectly heated dryer |
A dryer where the drying is exclusively achieved by radiation and conduction heat. |
Mat forming |
The process of laying out particles, strands or fibres to create the mat, which is directed to the press. |
Multi-opening press |
A panel press that presses one or more individually formed panels. |
New plant |
A plant first permitted at the site of the installation following the publication of these BAT conclusions or a complete replacement of a plant following the publication of these BAT conclusions. |
NOX |
The sum of nitrogen oxide (NO) and nitrogen dioxide (NO2), expressed as NO2. |
OSB |
Oriented strand board, as defined in EN 300 i.e. ‘multi-layered board mainly made from strands of wood together with a binder. The strands in the external layer are aligned and parallel to the board length or width. The strands in the internal layer or layers can be randomly orientated or aligned, generally at right angles to the strands in the external layers’. |
PB |
Particle board, as defined in EN 309 i.e. ‘panel material manufactured under pressure and heat from particles of wood (wood flakes, chips, shavings, saw-dust and similar) and/or other lignocellulosic material in particle form (flax shives, hemp shives, bagasse fragments and similar), with the addition of an adhesive’. |
PCDD/F |
Polychlorinated dibenzo-dioxins and -furans |
Periodic measurement |
Measurement at specified time intervals using manual or automated reference methods. |
Process water |
Waste water derived from processes and activities within the production plant, excluding surface run-off water. |
Recovered wood |
Material predominantly containing wood. Recovered wood can consist of ‘reclaimed wood’ and ‘wood residues’. ‘Reclaimed wood’ is a material predominantly containing wood derived directly from post-consumer recycled wood. |
Refining |
Transforming wood chips into fibres using a refiner. |
Roundwood |
A wood log. |
Softwood |
Wood from conifers including pine and spruce. The term softwood is used as an opposite to the term hardwood. |
Surface run-off water |
Water from precipitation run-off and drainage, collected from outdoor log yard areas, including outdoor process areas. |
TSS |
Total suspended solids (in waste water); mass concentration of all suspended solids as measured by filtration through glass fibre filters and gravimetry. |
TVOC |
Total Volatile Organic Compounds, expressed as C (in air). |
Upstream and downstream wood processing |
All active handling and manipulation, storage or transport of wood particles, chips, strands or fibres and of pressed panels. Upstream processing includes all wood processing from the point that the wood raw material leaves the storage yard. Downstream processing includes all processes after the panel leaves the press and until the raw panel or the value-added panel product is directed to storage. Upstream and downstream wood processing do not include the drying process or the pressing of panels. |
1.1. GENERAL BAT CONCLUSIONS
1.1.1. Environmental management system
BAT 1. |
In order to improve the overall environmental performance, BAT is to implement and adhere to an environmental management system (EMS) that incorporates all of the following features:
In some cases, the following features are part of the EMS:
|
The scope (e.g. level of detail) 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. Good housekeeping
BAT 2. |
In order to minimise the environmental impact of the production process, BAT is to apply good housekeeping principles using all of the techniques given below.
|
BAT 3. |
In order to reduce emissions to air, BAT is to operate the waste gas treatment systems with a high availability and at optimal capacity during normal operating conditions. |
Special procedures can be defined for other than normal operating conditions, in particular:
(i) |
during start-up and shut-down operations; |
(ii) |
during other special circumstances which could affect the proper functioning of the systems (e.g. regular and extraordinary maintenance work and cleaning operations of the combustion plant and/or of the waste gas treatment system). |
1.1.3. Noise
BAT 4. |
In order to prevent or, where that is not practicable, to reduce noise and vibrations, BAT is to use one or a combination of the techniques given below.
|
1.1.4. Emissions to soil and groundwater
BAT 5. |
In order to prevent emissions to soil and groundwater, BAT is to use the techniques given below.
|
1.1.5. Energy management and energy efficiency
BAT 6. |
In order to reduce energy consumption, BAT is to adopt an energy management plan, which includes all of the techniques given below.
|
BAT 7. |
In order to increase the energy efficiency, BAT is to optimise the operation of the combustion plant by monitoring and controlling key combustion parameters (e.g. O2, CO, NOx) and applying one or a combination of the techniques given below.
|
BAT 8. |
In order to use energy efficiently in the preparation of wet fibres for fibreboard production, BAT is to use one or a combination of the techniques given below.
|
1.1.6. Odour
BAT 9. |
In order to prevent or, where that is not practicable, to reduce odour from the installation, BAT is to set up, implement and regularly review an odour management plan, as part of the environmental management system (see BAT 1), that includes all of the following elements:
|
The applicability is restricted to cases where an odour nuisance in residential or other sensitive areas (e.g. recreational areas) can be expected and/or has been reported.
BAT 10. |
In order to prevent and reduce odour, BAT is to treat waste gas from the dryer and the press, according to BAT 17 and 19. |
1.1.7. Management of waste and residues
BAT 11. |
In order to prevent or, where that is not practicable, to reduce the quantity of waste being sent for disposal, BAT is to adopt and implement a waste management plan as part of the environmental management system (see BAT 1) that, in order of priority, ensures that waste is prevented, prepared for reuse, recycled or otherwise recovered. |
BAT 12. |
In order to reduce the quantity of solid waste being sent for disposal, BAT is to use one or a combination of the techniques given below.
|
BAT 13. |
In order to ensure the safe management and reuse of bottom ash and slag from biomass-firing, BAT is to use all of the techniques given below.
|
1.1.8. Monitoring
BAT 14. |
BAT is to monitor emissions to air and water and to monitor process flue-gases in accordance with EN standards with at least the frequency given below. If EN standards are not available, BAT is to use ISO, national or other international standards that ensure the provision of data of an equivalent scientific quality.
Monitoring of emissions to air from the dryer and for combined treated emissions from the dryer and the press
Monitoring of channelled emissions to air from upstream and downstream processing
Monitoring of combustion process flue-gas that is subsequently used for directly heated dryers (12)
Monitoring of emissions to water from wood fibre production
Monitoring of emissions to water from surface run-off water
|
BAT 15. |
In order to ensure the stability and efficiency of techniques used to prevent and reduce emissions, BAT is to monitor appropriate surrogate parameters. |
The surrogate parameters monitored may include: waste gas airflow; waste gas temperature; visual appearance of emissions; water flow and water temperature for scrubbers; voltage drop for electrostatic precipitators; fan speed and pressure drop across bag filters. The selection of surrogate parameters depends on the techniques implemented for the prevention and reduction of emissions.
BAT 16. |
BAT is to monitor key process parameters relevant for emissions to water from the production process, including waste water flow, pH and temperature. |
1.2. EMISSIONS TO AIR
1.2.1. Channelled emissions
BAT 17. |
In order to prevent or reduce emissions to air from the dryer, BAT is to achieve and manage a balanced operation of the drying process and to use one or a combination of the techniques given below.
Table 1 BAT-associated emission levels (BAT-AELs) for emissions to air from the dryer and for combined treated emissions from the dryer and the press
The associated monitoring is in BAT 14. |
BAT 18. |
In order to prevent or reduce NOX emissions to air from directly heated dryers, BAT is to use technique (a) or technique (a) in combination with technique (b).
Table 2 BAT-associated emission levels (BAT-AELs) for NOX emissions to air from a directly heated dryer
The associated monitoring is in BAT 14. |
BAT 19. |
In order to prevent or reduce emissions to air from the press, BAT is to use in-duct quenching of collected press waste gas and an appropriate combination of the techniques given below.
Table 3 BAT-associated emission levels (BAT-AELs) for emissions to air from the press
The associated monitoring is in BAT 14. |
BAT 20. |
In order to reduce dust emissions to air from upstream and downstream wood processing, conveying of wood materials and mat forming, BAT is to use either a bag filter or a cyclofilter. |
Due to safety concerns, a bag filter or a cyclofilter may not be applicable when recovered wood is used as a raw material. In that case a wet abatement technique (e.g. scrubber) may be used.
Table 4
BAT-associated emission levels (BAT-AELs) for channelled dust emissions to air from upstream and downstream wood processing, conveying of wood materials and mat forming
Parameter |
Unit |
BAT-AELs (average over the sampling period) |
Dust |
mg/Nm3 |
< 3–5 (21) |
The associated monitoring is in BAT 14.
BAT 21. |
In order to reduce emissions of volatile organic compounds to air from the drying ovens for the impregnation of paper, BAT is to use one or a combination of the techniques given below.
Table 5 BAT-associated emission levels (BAT-AELs) for TVOC and formaldehyde emissions to air from a drying oven for the impregnation of paper
The associated monitoring is in BAT 14. |
1.2.2. Diffuse emissions
BAT 22. |
In order to prevent or, where that is not practicable, to reduce diffuse emissions to air from the press, BAT is to optimise the efficiency of the off-gas collection and to channel the off-gases for treatment (see BAT 19). |
Effective collection and treatment of waste gases (see BAT 19) both at the press exit and along the press line for continuous presses. For existing multi-opening presses the applicability of enclosing the press may be restricted due to safety reasons.
BAT 23. |
In order to reduce diffuse dust emissions to air from the transport, handling, and storage of wood materials, BAT is to set up and implement a dust management plan, as part of the environmental management system (see BAT 1) and to apply one or a combination of the techniques given below.
|
1.3. EMISSIONS TO WATER
BAT 24. |
In order to reduce the pollution load of the collected waste water, BAT is to use both of the techniques given below.
|
BAT 25. |
In order to reduce emissions to water from surface run-off water, BAT is to use a combination of the techniques given below.
Table 6 BAT-associated emission levels (BAT-AELs) for TSS for the direct discharge of surface run-off water to a receiving water body
The associated monitoring is in BAT 14. |
BAT 26. |
In order to prevent or reduce the generation of process waste water from wood fibre production, BAT is to maximise process water recycling. |
Recycle process water from chip washing, cooking and/or refining in closed or open loops by treating it at the refiner plant level by mechanical removal of solids, in the most appropriate manner, or by evaporation.
BAT 27. |
In order to reduce emissions to water from wood fibre production, BAT is to use a combination of the techniques given below.
Table 7 BAT-associated emission levels (BAT-AELs) for the direct discharge to a receiving water body of process waste water from wood fibre production
The associated monitoring is in BAT 14. |
BAT 28. |
In order to prevent or reduce the generation of waste water from wet air abatement systems that will need treatment prior to discharge, BAT is to use one or a combination of the techniques given below.
|
1.4. DESCRIPTION OF TECHNIQUES
1.4.1. Emissions to air
Technique |
Description |
Biofilter |
A biofilter degrades organic compounds by biological oxidation. A waste gas stream is passed through a supporting bed of inert material (e.g. plastics or ceramics) on which organic compounds are oxidised by naturally occurring microorganisms. The biofilter is sensitive to dust, high temperatures or high variation in the waste gas inlet temperature. |
Bioscrubber |
A bioscrubber is a biofilter combined with a wet scrubber that preconditions the waste gas by removing dust and lowering the inlet temperature. Water is recycled continuously, entering the top of the packed bed column, from where it trickles down. Water collects in a settlement tank where additional degradation takes place. Adjustment of pH and the addition of nutrients can optimise degradation. |
Cyclone |
A cyclone uses inertia to remove dust from waste gas streams by imparting centrifugal forces, usually within a conical chamber. Cyclones are used as a pretreatment before further dust abatement or abatement of organic compounds. Cyclones can be applied alone or as multicyclones. |
Cyclofilter |
A cyclofilter uses a combination of cyclone technology (to separate coarser dust) and bag filters (to capture finer dust). |
Electrostatic precipitator (ESP) |
Electrostatic precipitators operate such that particles are charged and separated under the influence of an electrical field. The ESP is capable of operating over a wide range of conditions. |
Wet electrostatic precipitator (WESP) |
The wet electrostatic precipitator consists of a wet scrubber stage, which scrubs and condenses the waste gas, and an electrostatic precipitator operating in wet mode in which the collected material is removed from the plates of the collectors by flushing with water. A mechanism is usually installed to remove water droplets before discharge of the waste gas (e.g. a demister). Collected dust is separated from the water phase. |
Bag filter |
Bag filters consist of porous woven or felted fabric through which gases pass to remove particles. The use of a bag filter requires the selection of a fabric appropriate for the characteristics of the flue-gas and the maximum operating temperature. |
Catalytic thermal oxidiser (CTO) |
Catalytic thermal oxidisers destroy organic compounds catalytically over a metal surface and thermally in a combustion chamber where a flame from combustion of a fuel, normally natural gas, and the VOCs present in the waste gas, heat the waste gas stream. The incineration temperature is between 400 °C and 700 °C. Heat can be recovered from the treated waste gas before release. |
Regenerative thermal oxidiser (RTO) |
Thermal oxidisers destroy organic compounds thermally in a combustion chamber where a flame from the combustion of a fuel, normally natural gas, and the VOCs present in the waste gas, heat the waste gas stream. The incineration temperature is between 800 °C and 1 100 °C. Regenerative thermal oxidisers have two or more ceramic packed bed chambers where the combustion heat from one incineration cycle in the first chamber is used to preheat the packed bed in the second chamber. Heat can be recovered from the treated waste gas before release. |
UTWS dryer and combustion with heat exchanger and thermal treatment of discharged dryer waste gas |
UTWS is a German acronym: ‘Umluft’ (recirculation of dryer waste gas), ‘Teilstromverbrennung’ (post-combustion of partial directed dryer waste gas stream), ‘Wärmerückgewinnung’ (heat recovery of dryer waste gas), ‘Staubabsheidung’ (dust treatment of air emission discharge from the combustion plant). UTWS is a combination of a rotary dryer with a heat exchanger and a combustion plant with recirculation of dryer waste gas. The recirculated dryer waste gas is a hot vapour stream that enables a vapour drying process. The dryer waste gas is reheated in a heat exchanger heated by the combustion flue-gases and is fed back to the dryer. Part of the dryer waste gas stream is continuously fed to the combustion chamber for post-combustion. Pollutants emitted from the wood drying are destroyed over the heat exchanger and by the post-combustion. The flue gases discharged from the combustion plant are treated by a bag filter or electrostatic precipitator. |
Wet scrubber |
Wet scrubbers capture and remove dust by inertial impaction, direct interception and absorption in the water phase. Wet scrubbers can have various designs and operating principles, e.g. spray scrubber, impingement plate scrubber or Venturi scrubber, and can be used as a dust pretreatment or a stand-alone technique. Some removal of organic compounds may be achieved and can be further enhanced by using chemicals in the scrubbing water (achieving chemical oxidation or another conversion). The resulting liquid has to be treated by separating the collected dust by sedimentation or filtration. |
1.4.2. Emissions to water
Technique |
Description |
Biological treatment |
The biological oxidation of dissolved organic substances using the metabolism of microorganisms, or the breakdown of organic content in waste water by the action of microorganisms in the absence of air. The biological action is usually followed by the removal of suspended solids, e.g. by sedimentation. |
Coagulation and flocculation |
Coagulation and flocculation are used to separate suspended solids from waste water and are often carried out in successive steps. Coagulation is carried out by adding coagulants with charges opposite to those of the suspended solids. Flocculation is carried out by adding polymers, so that collisions of microfloc particles cause them to bond to produce larger flocs. |
Flotation |
The separation of large flocs or floating particles from the effluent by bringing them to the surface of the suspension. |
Dissolved air flotation |
Flotation techniques relying on the use of dissolved air to achieve separation of coagulated and flocculated material.. |
Filtration |
The separation of solids from a waste water carrier by passing them through a porous medium. It includes different types of techniques, e.g. sand filtration, microfiltration and ultrafiltration. |
Oil-water separation |
The separation and extraction of insoluble hydrocarbons, relying on the principle of the difference in gravity between the phases (liquid-liquid or solid-liquid). The higher density phase settles and the lower density phase floats to the surface. |
Retention basins |
Large surface area lagoons for the passive gravitational settlement of solids. |
Sedimentation |
The separation of suspended particles and material by gravitational settling. |
(1) A more suitable measurement period may be employed for any parameter where, due to sampling or analytical limitations, a 30-minute measurement is inappropriate.
(2) EN 14961-1:2010 can be used for the classification of solid biofuels.
(3) Methane monitored according to EN ISO 25140 or EN ISO 25139 is subtracted from the result when using natural gas, LPG, etc. as a fuel.
(4) Not relevant when using mainly wood-derived fuels, natural gas, LPG, etc. as a fuel.
(5) Including As, Cd, Co, Cr, Cu, Hg, Mn, Ni, Pb, Sb, Tl and V.
(6) Relevant if contaminated recovered wood is used as fuel.
(7) Relevant if SNCR is applied.
(8) In the absence of an EN standard, the preferred approach is isokinetic sampling in an impinging solution with a heated probe and filter box and without probe washing, e.g. based on the US EPA M316 method.
(9) Methane monitored according to EN ISO 25140 or EN ISO 25139 is subtracted from the result when using natural gas, LPG, etc. as a fuel.
(10) In the absence of an EN standard, the preferred approach is isokinetic sampling in an impinging solution with a heated probe and filter box and without probe washing, e.g. based on the US EPA M316 method.
(11) Sampling from bag filters and cyclofilters can be replaced by continuous monitoring of the pressure drop across the filter as an indicative surrogate parameter.
(12) The measurement point is before the mixing of the flue-gas with other airstreams and only if technically feasible.
(13) There is a tendency to replace COD with TOC for economic and environmental reasons. A correlation between the two parameters should be established on a site-specific basis.
(14) Including As, Cr, Cu, Ni, Pb and Zn.
(15) Flow-proportional sampling can be replaced by another standard sampling procedure if the flow is insufficient for representative sampling.
(16) Descriptions of the techniques are given in Section 1.4.1.
(17) This BAT-AEL does not apply when using pine as the predominant raw material.
(18) Emissions below 30 mg/Nm3 can be achieved using UTWS dryer.
(19) When using almost exclusively recovered wood, the upper end of the range may be up to 15 mg/Nm3.
(20) Descriptions of the techniques are given in Section 1.4.1.
(21) When a bag filter or a cyclofilter is not applicable, the upper end of the range can be up to 10 mg/Nm3.
(22) Description of the technique is given in Section 1.4.1.
(23) An outer piece of wood, with or without the bark removed, from the first cuts in a sawing process to render the log into lumber (timber).
(24) Descriptions of the techniques are given in Section 1.4.2.
(25) Descriptions of the techniques are given in Section 1.4.2.
(26) Descriptions of the techniques are given in Section 1.4.2.