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Document 42010X1113(01)

Regulation No 37 of the Economic Commission for Europe of the United Nations (UN/ECE) — Uniform provisions concerning the approval of filament lamps for use in approved lamp units on power-driven vehicles and of their trailers

OJ L 297, 13.11.2010, p. 1–182 (BG, ES, CS, DA, DE, ET, EL, EN, FR, IT, LV, LT, HU, MT, NL, PL, PT, RO, SK, SL, FI, SV)

Legal status of the document In force

ELI: http://data.europa.eu/eli/reg/2010/37(2)/oj

13.11.2010   

EN

Official Journal of the European Union

L 297/1

Only the original UN/ECE texts have legal effect under international public law. The status and date of entry into force of this Regulation should be checked in the latest version of the UN/ECE status document TRANS/WP.29/343, available at:

http://www.unece.org/trans/main/wp29/wp29wgs/wp29gen/wp29fdocstts.html

Regulation No 37 of the Economic Commission for Europe of the United Nations (UN/ECE) — Uniform provisions concerning the approval of filament lamps for use in approved lamp units on power-driven vehicles and of their trailers

Incorporating all valid text up to:

Supplement 34 to the 03 series of amendments — Date of entry into force: 19 August 2010.

CONTENTS

REGULATION

1.

 Scope

2.

 Administrative provisions

2.1.

 Definitions

2.2.

 Application for approval

2.3.

 Inscriptions

2.4.

 Approval

3.

 Technical requirements

3.1.

 Definitions

3.2.

 General specifications

3.3.

 Manufacture

3.4.

 Tests

3.5.

 Filament position and dimensions

3.6.

 Colour

3.7.

 UV radiation

3.8.

 Observation concerning selective-yellow colour

3.9.

 Check on optical quality

3.10.

 Standard filament lamps

4.

 Conformity of production

5.

 Penalties for non-conformity of production

6.

 Production definitely discontinued

7.

 Names and addresses of technical services responsible for conducting approval tests, and of administrative departments

8.

 Transitional provisions

ANNEXES

Annex 1 —

 Sheets for filament lamps

Annex 2 —

 Communication concerning the approval or extension or refusal or withdrawal of approval or production definitely discontinued of a type of filament lamp pursuant to Regulation No 37

Annex 3 —

 Example of the arrangement of the approval mark

Annex 4 —

 Luminous centre and shapes of filament lamps

Annex 5 —

 Checking the colour of filament lamps

Annex 6 —

 Minimum requirements for quality procedures by the manufacturer

Annex 7 —

 Sampling and compliance levels for manufacturer test records

Annex 8 —

 Minimum requirements for spot checks by the administrative authority

Annex 9 —

 Compliance approved by spot check

Annex 10 —

 Translation of the terms used in the drawings in Annex 1

1.   SCOPE

This Regulation applies to filament lamps shown in Annex 1 and intended for use in approved lamp units of power-driven vehicles and of their trailers.

2.   ADMINISTRATIVE PROVISIONS

2.1.   Definitions

2.1.1.   Definition of ‘category’

The term ‘category’ is used in this Regulation to describe different basic design of standardised filament lamps. Each category has a specific designation, as for example: ‘H4’, ‘P21W’, ‘T4W’, ‘PY21W’ or ‘RR10W’.

2.1.2.   Definition of ‘type’

Filament lamps of different ‘types’  (1) are filament lamps within the same category which differ in such essential respects as:

2.1.2.1.

trade name or mark (Filament lamps bearing the same trade name or mark but produced by different manufacturers are considered as being of different types. Filament lamps produced by the same manufacturer differing only by the trade name or mark may be considered to be of the same type);

2.1.2.2.

bulb design and/or cap design, in so far as these differences affect the optical results;

2.1.2.3.

rated voltage;

2.1.2.4.

halogen.

2.2.   Application for approval

2.2.1.

 Application for approval shall be submitted by the owner of the trade name or mark, or by his duly accredited representative.

2.2.2.

 Every application for approval shall be accompanied (see also paragraph 2.4.2) by:

2.2.2.1.

drawings in triplicate, sufficiently detailed to permit identification of the type;

2.2.2.2.

a brief technical description;

2.2.2.3.

five samples of each colour which has been applied for.

2.2.3.

 In the case of a type of filament lamp differing only by the trade name or mark from a type that has already been approved it shall be sufficient to submit:

2.2.3.1.

a declaration by the manufacturer that the type submitted is identical (except in the trade name or mark) with and has been produced by the same manufacturer as, the type already approved, the latter being identified by its approval code;

2.2.3.2.

two samples bearing the new trade name or mark.

2.2.4.

 The competent authority shall verify the existence of satisfactory arrangements for ensuring effective control of the conformity of production before type approval is granted.

2.3.   Inscriptions

2.3.1.

 Filament lamps submitted for approval shall bear on the cap or bulb (2):

2.3.1.1.

the trade name or mark of the applicant;

2.3.1.2.

the rated voltage. However, for filament lamps for which only a 12 V type is standardised and the maximum allowed bulb diameter of which does not exceed 7,5 mm, the rated voltage need not be marked;

2.3.1.3.

the international designation of the relevant category. The wattage character ‘W’ of this designation need not be marked when the maximum allowed bulb diameter of the filament lamp type does not exceed 7,5 mm;

2.3.1.4.

the rated wattage (in the sequence, high wattage/low wattage filament for dual-filament lamps); this need not be indicated separately if it is part of the international designation of the relevant filament lamp category;

2.3.1.5.

a space of sufficient size to accommodate the approval mark.

2.3.2.

 The space mentioned in paragraph 2.3.1.5 above shall be indicated in the drawings accompanying the application for approval.

2.3.3.

 Halogen filament lamps meeting the requirements of paragraph 3.7 below shall be marked with a ‘U’.

2.3.4.

 Inscriptions other than those covered by paragraphs 2.3.1 and 2.4.3 may be affixed, on the condition that they do not adversely affect the luminous characteristics.

2.4.   Approval

2.4.1.

 If all samples of a type of filament lamp which are submitted in pursuance of paragraphs 2.2.2.3 or 2.2.3.2 above meet the requirements of this Regulation, approval shall be granted.

2.4.2.

 An approval code shall be assigned to each type approved. Its first character (at present 2, corresponding to the 02 series of amendments which entered into force on 27 October 1983 and to the 03 series of amendments (not requiring changes in the approval number), which entered into force on 1 June 1984) shall indicate the series of amendments incorporating the most recent major technical amendments made to the Regulation at the time of issue of the approval. This will be followed by an identification code comprising not more than two characters. Only the Arabic numerals and capital letters listed in footnote 3 (3) shall be used. The same Contracting Party may not assign the same code to another type of filament lamp. Notice of approval or of extension or refusal or withdrawal of approval or production definitely discontinued of a type of filament lamp pursuant to this Regulation shall be communicated to the Parties of the Agreement which apply this Regulation by means of a form conforming to the model in Annex 2 to this Regulation and of a drawing, supplied by the applicant for approval in a format not exceeding A4 (210 x 297 mm) and on a scale of at least 2:1. If the applicant so desires, the same approval code may be assigned to the filament lamp emitting white light and to the filament lamp emitting selective-yellow light (see paragraph 2.1.2.3).

2.4.3.

 To every filament lamp conforming to a type approved under this Regulation there shall be affixed in the space referred to in paragraph 2.3.1.5, in addition to the inscriptions required under paragraph 2.3.1, an international approval mark consisting of:

2.4.3.1.

a truncated circle surrounding the letter ‘E’ followed by the distinguishing number of the country which has granted approval (4);

2.4.3.2.

the approval code, placed close to the truncated circle.

2.4.4.

 If the applicant has obtained the same approval code for several trade names or marks, one or more of them will suffice to meet the requirements of paragraph 2.3.1.1.

2.4.5.

 The marks and inscriptions specified in paragraphs 2.3.1 and 2.4.3 shall be clearly legible and be indelible.

2.4.6.

 Annex 3 to this Regulation gives an example of arrangement of the approval mark.

3.   TECHNICAL REQUIREMENTS

3.1.   Definitions

3.1.1.   ‘Rated voltage’: voltage (in volts) marked on the filament lamp.

3.1.2.   ‘Rated wattage’: wattage (in watts) marked on the filament lamp which may be incorporated into the international designation of the relevant category.

3.1.3.   ‘Test voltage’: voltage, at the filament lamp terminals for which the electrical and photometric characteristics of the filament lamp are intended and are to be tested.

3.1.4.   ‘Objective values’: values to be achieved, within the specified tolerances, when the filament lamp is supplied with current at its test voltage.

3.1.5.   ‘Standard (étalon) filament lamp’: a filament lamp emitting white or amber or red light with reduced dimensional tolerances, used for the photometric testing of lighting and light-signalling devices. Standard filament lamps are specified in only one voltage rating for each category.

3.1.6.   ‘Reference luminous flux’: specified luminous flux of a standard filament lamp to which the optical characteristics of a lighting device shall be referred.

3.1.7.   ‘Measuring luminous flux’: specified value of the luminous flux for testing a filament lamp in a standard headlamp as specified in paragraph 3.9.

3.1.8.   ‘Reference axis’: an axis defined with reference to the cap and to which certain dimensions of the filament lamp are referred.

3.1.9.   ‘Reference plane’: a plane defined with reference to the cap and to which certain dimensions of the filament lamp are referred.

3.2.   General specifications

3.2.1.

 Each sample submitted shall conform to the relevant specifications of this Regulation.

3.2.2.

 Filament lamps shall be so designed as to be and to remain in good working order when in normal use. They shall moreover exhibit no fault in design or manufacture.

3.3.   Manufacture

3.3.1.

 Filament lamp bulbs shall exhibit no scores or spots which might impair their efficiency and their optical performance.

3.3.2.

 Filament lamps shall be equipped with standard caps complying with the cap data sheets of IEC Publication 60061, third edition, as specified on the individual data sheets of Annex 1.

3.3.3.

 The cap shall be strong and firmly secured to the bulb.

3.3.4.

 To ascertain whether filament lamps conform to the requirements of paragraphs 3.3.1 to 3.3.3 above, a visual inspection, a dimension check and, where necessary, a trial fitting shall be carried out.

3.4.   Tests

3.4.1.

 Filament lamps shall first be aged at their test voltage for approximately one hour. For dual-filament lamps, each filament shall be aged separately.

3.4.2.

 In the case of a filament lamp having a coated bulb, after the ageing period corresponding to paragraph 3.4.1, the surface of the bulb shall be lightly wiped with a cotton cloth soaked in a mixture of 70 vol. per cent of n-heptane and 30 vol. per cent of toluol. After about five minutes, the surface shall be inspected visually. It shall not show any apparent changes.

3.4.3.

 The position and dimensions of the filament shall be measured with the filament lamps being supplied with current at from 90 per cent to 100 per cent of the test voltage.

3.4.4.

 Unless otherwise specified, electrical and photometric measurements shall be carried out at the test voltage.

3.4.5.

 Electrical measurements shall be carried out with instruments of at least class 0.2.

3.4.6.

 The luminous flux (in lumen) specified on the filament lamp data sheets of Annex 1 is valid for filament lamps emitting white light unless a special colour is stated there.

In the case where the selective-yellow colour is allowed, the luminous flux of the filament lamp with the selective-yellow outer bulb shall be at least 85 per cent of the specified luminous flux of the relevant filament lamp emitting white light.

3.5.   Filament position and dimensions

3.5.1.

 The geometric shapes of the filament shall in principle be as specified on the filament lamp data sheets of Annex 1.

3.5.2.

 For line filaments the correct position and shape shall be checked as specified in the relevant data sheets.

3.5.3.

 If the filament is shown on the filament lamp data sheet in at least one view as a point, the position of the luminous centre shall be determined in conformity with Annex 4.

3.5.4.

 The length of a line filament shall be determined by its ends, defined — unless otherwise specified on the relevant data sheet — as the apices of the first and the last filament turn as seen in projection perpendicular to the reference axis of the filament lamp. Such an apex shall comply with the requirement that the angle formed by the legs shall not exceed 90°. In the case of coiled-coil filaments the apices of the secondary turns shall be taken into account.

3.5.4.1.

 For axial filaments the extreme position of the apices considered shall be determined by rotating the filament lamp about its reference axis. The length shall then be measured in a direction parallel to the reference axis.

3.5.4.2.

 For transverse filaments the filament axis shall be placed perpendicular to the direction of projection. The length shall be measured in a direction perpendicular to the reference axis.

3.6.   Colour

3.6.1.

 The colour of the light emitted by the filament lamp shall be white unless otherwise specified on the relevant data sheet.

3.6.2.

 The definitions of the colour of the light emitted, given in Regulation No 48 and its series of amendments in force at the time of application for type approval, shall apply to this Regulation.

3.6.3.

 The colour of the light emitted shall be measured by the method specified in Annex 5. Each measured value shall lie within the required tolerance area (5). Moreover, in the case of filament lamps emitting white light, the measured values shall not deviate more than 0,020 units in the x and/or y direction from a point of choice on the Planckian locus (IEC Publication 15.2 Colorimetry, 1986). Filament lamps for use in light signalling devices shall meet the requirements as specified in paragraph 2.4.2 of IEC Publication 60809, Amendment [5] to Edition 2.

3.7.   UV radiation

The UV radiation of a halogen lamp shall be such that:

Formula

Formula

where:

Ee (λ)

(W/nm)

is the spectral distribution of the radiant flux;

V (λ)

(1)

is the spectral luminous efficiency;

km = 683

(lm/W)

is the photometric radiation equivalent;

λ

(nm)

is the wave length.

This value shall be calculated using intervals of five nanometres.

3.8.   Observation concerning selective-yellow colour

An approval of a filament lamp type under this Regulation may be granted, pursuant to paragraph 3.6 above, for a filament lamp emitting white light as well as selective-yellow light; Article 3 of the Agreement to which this Regulation is annexed shall not prevent the Contracting Parties from prohibiting, on vehicles registered by them, filament lamps emitting either white or selective-yellow light.

3.9.   Check on optical quality

(Applies only to filament lamps of categories R2, H4 and HS1)

3.9.1.

 This check on optical quality shall be carried out at a voltage such that the measuring luminous flux is obtained; the specifications of paragraph 3.4.6 are to be observed accordingly.

3.9.2.

 For 12-Volt filament lamps emitting white light:

The sample which most nearly conforms to the requirements laid down for the standard filament lamp shall be tested in a standard headlamp as specified in paragraph 3.9.5 and it shall be verified whether the assembly comprising the aforesaid headlamp and the filament lamp being tested meets the light-distribution requirements laid down for the passing-beam in the relevant Regulation.

3.9.3.

 For 6-Volt and 24-Volt filament lamps emitting white light:

The sample which most nearly conforms to the nominal dimension values shall be tested in a standard headlamp as specified in paragraph 3.9.5 and it shall be verified whether the assembly comprising the aforesaid headlamp and the filament lamp being tested meets the light-distribution requirements laid down for the passing-beam in the relevant Regulation. Deviations not exceeding 10 per cent of the minimum values will be acceptable.

3.9.4.

 Filament lamps emitting selective-yellow light shall be tested in the same manner as described in paragraphs 3.9.2 and 3.9.3 in a standard headlamp as specified in paragraph 3.9.5 to ensure that the illumination complies with at least 85 per cent for 12-Volt filament lamps, and at least 77 per cent for 6-Volt and 24-Volt filament lamps, with the minimum values of the light-distribution requirements laid down for the passing-beam in the relevant Regulation. The maximum illumination limits remain unchanged.

In the case of a filament lamp having a selective-yellow bulb, this test shall be left out if the approval is also given to the same type of filament lamp emitting white light.

3.9.5.

 A headlamp shall be deemed to be a standard headlamp if:

3.9.5.1.

it satisfies the pertinent conditions of approval;

3.9.5.2.

it has an effective diameter of not less than 160 mm;

3.9.5.3.

with a standard filament lamp it produces at the various points and in the various zones specified for the headlamp type concerned, illumination equal to:

3.9.5.3.1.

not more than 90 per cent of the maximum limits;

3.9.5.3.2.

not less than 120 per cent of the minimum limits prescribed for the headlamp type concerned.

3.10.   Standard filament lamps

Additional requirements for standard (étalon) filament lamps are given on the relevant data sheets of Annex 1.

Bulbs of standard (étalon) filament lamps emitting white light shall not alter the CIE trichromatic coordinates of a luminous source having a colour temperature of 2 856 K by more than 0,010 units in the x and/or y direction.

For standard (étalon) filament lamps emitting amber or red light, changes of the bulb temperature shall not affect the luminous flux which might impair photometric measurements of signalling devices.

4.   CONFORMITY OF PRODUCTION

4.1.

 Filament lamps approved to this Regulation shall be so manufactured as to conform to the type approved by meeting the inscriptions and technical requirements set forth in paragraph 3 above and Annexes 1, 3 and 4 to this Regulation.

4.2.

 In order to verify that the requirements of paragraph 4.1 are met, suitable controls of the production shall be carried out.

4.3.

 The holder of the approval shall in particular:

4.3.1.

ensure existence of procedures for the effective control of the quality of products;

4.3.2.

have access to the control equipment necessary for checking the conformity to each approved type;

4.3.3.

ensure that data of test results are recorded and that related documents shall remain available for a period to be determined in accordance with the administrative service;

4.3.4.

analyse the results of each type of test, applying criteria of Annex 7, in order to verify and ensure the stability of the product characteristics making allowance for variation of an industrial production;

4.3.5.

ensure that for each type of filament lamp, at least the tests prescribed in Annex 6 to this Regulation are carried out;

4.3.6.

ensure that any collecting of samples giving evidence of non-conformity with the type of test considered shall give rise to another sampling and another test. All the necessary steps shall be taken to re-establish the conformity of the corresponding production.

4.4.

 The competent authority which has granted type-approval may at any time verify the conformity control methods applicable to each production unit.

4.4.1.

 In every inspection, the test books and production survey records shall be presented to the visiting inspector.

4.4.2.

 The inspector may take samples at random which will be tested in the manufacturer’s laboratory. The minimum number of samples may be determined according to the results of the manufacturer’s own verification.

4.4.3.

 When the quality level appears unsatisfactory or when it seems necessary to verify the validity of the tests carried out in application of paragraph 4.4.2 above, the inspector shall select samples, to be sent to the technical service which has conducted the type approval tests.

4.4.4.

 The competent authority may carry out any tests prescribed in this Regulation. Where the competent authority decides to carry out spot checks, criteria of Annexes 8 and 9 to this Regulation shall be applied.

4.4.5.

 The normal frequency of inspection authorised by the competent authority shall be one every two years. In the case where negative results are recorded during one of these visits, the competent authority shall ensure that all necessary steps are taken to re-establish the conformity of production as rapidly as possible.

5.   PENALTIES FOR NON-CONFORMITY OF PRODUCTION

5.1.

 The approval granted in respect of a filament lamp pursuant to this Regulation may be withdrawn if the requirements are not met or if a filament lamp bearing the approval mark does not conform to the type approved.

5.2.

 If a Contracting Party to the Agreement applying this Regulation withdraws an approval it has previously granted, it shall forthwith so notify the other Contracting Parties applying this Regulation, by means of a communication form conforming to the model in Annex 2 to this Regulation.

6.   PRODUCTION DEFINITELY DISCONTINUED

If the holder of the approval completely ceases to manufacture a type of filament lamp approved in accordance with this Regulation, he shall so inform the authority which has granted the approval. Upon receiving the relevant communication, that authority shall inform thereof the other Parties to the 1958 Agreement applying this Regulation by means of a communication form conforming to the model in Annex 2 to this Regulation.

7.   NAMES AND ADDRESSES OF THE TECHNICAL SERVICES RESPONSIBLE FOR CONDUCTING APPROVAL TESTS, AND OF ADMINISTRATIVE DEPARTMENTS

The Parties to the 1958 Agreement which apply this Regulation shall communicate to the United Nations secretariat the names and addresses of the technical services responsible for conducting approval tests and of the administrative departments which grant approval and to which forms certifying approval or extension or refusal or withdrawal of approval, or production definitely discontinued issued in other countries, are to be sent.

8.   TRANSITIONAL PROVISIONS

8.1.

 Approvals granted under the preceding series of amendments shall remain valid, except that for conformity of production, current production filament lamps shall comply with the requirements of the latest series of amendments starting 12 months from the date of application of this amendment (6).

8.2.

 The correspondence between the former designations and the new ones is indicated in the following table:

Old designations

New designations in the 03 series of amendments

P25-1

P21W

P25-2

P21/5W

R19/5

R5W

R19/10

R10W

C11

C5W

C15

C21W

T8/4

T4W

W10/5

W5W

W10/3

W3W

8.3.

 As from 12 months after the entry into force of the Supplement 28 to the 03 series of amendments to Regulation No 37, no filament lamps of the categories R2, S1 and C21W shall be used in lamps for type approval purposes.

8.4.

 However, Contracting Parties applying this Regulation may continue to grant approvals for lamps where filament lamps of categories R2, S1 and C21W are used, provided that these lamps are intended as replacement parts for installation on vehicles in use.

(1)  A selective-yellow bulb or an additional selective-yellow outer bulb, solely intended to change the colour but not the other characteristics of a filament lamp emitting white light, does not constitute a change of type of the filament lamp.

(2)  In the latter case, the luminous characteristics shall not be adversely affected.

(3)  0 1 2 3 4 5 6 7 8 9

A B C D E F G H J K L M N P R S T U V W X Y Z.

(4)  1 for Germany, 2 for France, 3 for Italy, 4 for the Netherlands, 5 for Sweden, 6 for Belgium, 7 for Hungary, 8 for the Czech Republic, 9 for Spain, 10 for Serbia, 11 for the United Kingdom, 12 for Austria, 13 for Luxembourg, 14 for Switzerland, 15 (vacant), 16 for Norway, 17 for Finland, 18 for Denmark, 19 for Romania, 20 for Poland, 21 for Portugal, 22 for the Russian Federation, 23 for Greece, 24 for Ireland, 25 for Croatia, 26 for Slovenia, 27 for Slovakia, 28 for Belarus, 29 for Estonia, 30 (vacant), 31 for Bosnia and Herzegovina, 32 for Latvia, 33 (vacant), 34 for Bulgaria, 35 (vacant), 36 for Lithuania, 37 for Turkey, 38 (vacant), 39 for Azerbaijan, 40 for The former Yugoslav Republic of Macedonia, 41 (vacant), 42 for the European Community (Approvals are granted by its Member States using their respective ECE symbol), 43 for Japan, 44 (vacant), 45 for Australia, 46 for Ukraine, 47 for South Africa, 48 for New Zealand, 49 for Cyprus, 50 for Malta, 51 for the Republic of Korea, 52 for Malaysia, 53 for Thailand, 54 and 55 (vacant), 56 for Montenegro, 57 (vacant) and 58 for Tunisia. Subsequent numbers shall be assigned to other countries in the chronological order in which they ratify or accede to the Agreement concerning the adoption of uniform technical prescriptions for wheeled vehicles, equipment and parts which can be fitted and/or be used on wheeled vehicles and the conditions for reciprocal recognition of approvals granted on the basis of these prescriptions, and the numbers thus assigned shall be communicated by the Secretary-General of the United Nations to the Contracting Parties to the Agreement.

(5)  For Conformity of Production purposes of amber and red colour only, at least 80 per cent of the measuring results shall lie within the required tolerance area.

(6)  The amended text of this paragraph was introduced by Supplement 14 to the 03 series of amendments. This supplement entered into force on 3 September 1997 and it also introduced in the text of the Regulation new paragraphs 2.3.3 and 3.7 and in Annex 1 new sheets HIR1 and PY27/7W.

ANNEX 1

SHEETS  (*1) FOR FILAMENT LAMPS

List of categories of filament lamps, grouped and their sheet numbers:

Group 1

Without general restrictions:

Category

Sheet number(s)

H1

H1/1 to 3

H3

H3/1 to 4

H4

H4/1 to 5

H7

H7/1 to 4

H8

H8/1 to 4

H8B

H8/1 to 4

H9 (*3)

H9/1 to 4

H9B (*3)

H9/1 to 4

H10

H10/1 to 3

H11

H11/1 to 4

H11B

H11/1 to 4

H12

H12/1 to 3

H13

H13/1 to 4

H13A

H13/1 to 4

H14

H14/1 to 4

H15

H15/1 to 5

H16

H16/1 to 4

H21W (*2)

H21W/1 to 2

H27W/1

H27W/1 to 3

H27W/2

H27W/1 to 3

HB3

HB3/1 to 4

HB3A

HB3/1 to 4

HB4

HB4/1 to 4

HB4A

HB4/1 to 4

HIR1 (*3)

HIR1/1 to 3

HIR2

HIR2/1 to 3

HS1

HS1/1 to 5

HS2

HS2/1 to 3

HS5

HS5/1 to 4

HS5A (*5)

HS5A/1 to 3

HS6 (*4)

HS6/1 to 4

PSX24W (*2)

P24W/1 to 3

PSX26W (*2)

PSX26W1 to 3

PX24W (*2)

P24W/1 to 3

S2

S1/S2/1 to 2

S3

S3/1

Group 2

Only for use in signalling lamps, cornering lamps, reversing lamps and rear registration plate lamps:

Category

Sheet number(s)

C5W

C5W/1

H6W

H6W/1

H10W/1

H10W/1 to 2

HY6W

H6W/1

HY10W

H10W/1 to 2

HY21W

H21W/1 to 2

P13W

P13W/1 to 3

P19W

P19W/1 to 3

P21W

P21W/1 to 2

P21/4W

P21/4W/1 (P21/5W/2 to 3)

P21/5W

P21/5W/1 to 3

P24W

P24W/1 to 3

P27W

P27W/1 to 2

P27/7W

P27/7W/1 to 3

PC16W

PC16W/1 to 3

PCR16W

PC16W/1 to 3

PCY16W

PC16W/1 to 3

PR19W

P19W/1 to 3

PR21W

PR21W/1 (P21W/2)

PR21/4W

PR21/4W/1 (P21/5W/2 to 3)

PR21/5W

PR21/5W/1 (P21/5W/2 to 3)

PR24W

P24W/1 to 3

PR27/7W

PR27/7W/1 (P27/7W/2 to 3)

PS19W

P19W/1 to 3

PS24W

P24W/1 to 3

PSR19W

P19W/1 to 3

PSR24W

P24W/1 to 3

PSY19W

P19W/1 to 3

PSY24W

P24W/1 to 3

PY19W

P19W/1 to 3

PY21W

PY21W/1 (P21W/2)

PY24W

P24W/1 to 3

PY27/7W

PY27/7W/1 (P27/7W/2 to 3)

R5W

R5W/1

R10W

R10W/1

RR5W

R5W/1

RR10W

R10W/1

RY10W

R10W/1

T1.4W

T1.4W/1

T4W

T4W/1

W2.3W

W2.3W/1

W3W

W3W/1

W5W

W5W/1

W15/5W

W15/5W/1 to 3

W16W

W16W/1

W21W

W21W/1 to 2

W21/5W

W21/5W/1 to 3

WP21W

WP21W/1 to 2

WPY21W

WP21W/1 to 2

WR5W

W5W/1

WR21/5W

WR21/5W/1 (W21/5W/2 to 3)

WY2.3W

WY2.3W/1

WY5W

W5W/1

WY21W

WY21W/1 to 2

Group 3

For replacement purposes only (see transitional provisions of paragraphs 8.3 and 8.4):

Category

Sheet number(s)

C21W

C21W/1 to 2

R2

R2/1 to 3

S1

S1/S2/1 to 2

List of sheets for filament lamps and their sequence in this Annex:

Sheet number(s)

 

C5W/1

 

C21W/1 to 2

 

H1/1 to 3

 

H3/1 to 4

 

H4/1 to 5

 

H7/1 to 4

 

H8/1 to 4

 

H9/1 to 4

 

H10/1 to 3

 

H11/1 to 4

 

H12/1 to 3

 

H13/1 to 4

 

H14/1 to 4

 

H15/1 to 5

 

H16/1 to 4

 

H6W/1

 

H10W/1 to 2

 

H21W/1 to 2

 

H27W/1 to 3

 

HB3/1 to 4

 

HB4/1 to 4

 

HIR1/1 to 3

 

HIR2/1 to 3

 

HS1/1 to 5

 

HS2/1 to 3

 

HS5/1 to 4

 

HS5A/1 to 3

 

HS6/1 to 4

 

P13W/1 to 3

 

P19W/1 to 3

 

P21W/1 to 2

 

P21/4W/1

 

P21/5W/1 to 3

 

P24W/1 to 3

 

P27W/1 to 2

 

P27/7W/1 to 3

 

PC16W/1 to 3

 

PR21W/1

 

PR21/4W/1

 

PR21/5W/1

 

PR27/7W/1

 

PSX26W/1 to 3

 

PY21W/1

 

PY27/7W/1

 

R2/1 to 3

 

R5W/1

 

R10W/1

 

S1/S2/1 to 2

 

S3/1

 

T1.4W/1

 

T4W/1

 

W2.3W/1

 

W3W/1

 

W5W/1

 

W15/5W/1 to 3

 

W16W/1

 

W21W/1 to 2

 

W21/5W/1 to 3

 

WP21W/1 to 2

 

WR21/5W/1

 

WY2.3W/1

 

WY21W/1 to 2

CATEGORY C5W — Sheet C5W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 1

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

b (1)

34,0

35,0

36,0

35,0 ± 0,5

f (2)  (3)

7,5  (4)

 

15  (5)

9 ± 1,5

Cap SV8,5 in accordance with IEC Publication 60061 (sheet 7004-81-4)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6

12

24

12

Watts

5

5

Test voltage

Volts

6,75

13,5

28,0

13,5

Objective values

Watts

5,5 max.

7,7 max.

5,5 max.

Luminous flux

45 ± 20 %

 

Reference luminous flux: 45 lm at approximately 13,5 V

CATEGORY C21W — Sheet C21W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

FILAMENT LAMP FOR REVERSING LAMP ONLY

Image 2

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

b (6)

40,0

41,0

42,0

41,0 ± 0,5

f (7)

7,5

 

10,5

8 ± 1,0

Cap SV8,5 in accordance with IEC Publication 60061 (sheet 7004-81-4)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

21

21

Test voltage

Volts

13,5

13,5

Objective values

Watts

26,5 max.

26,5 max.

Luminous flux

460 ± 15 %

 

Reference luminous flux: 460 lm at approximately 13,5 V

CATEGORY C21W — Sheet C21W/2

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and to the centre of the filament lamp's length, whether a filament lamp complies with the requirements.

Image 3

12 V

a

h

k

filament lamps of normal production

4,0 + d

14,5

2,0

standard filament lamp

2,0 + d

14,5

0,5

d= nominal filament diameter as stated by the manufacturer.

Test procedure and requirements

1.

 The filament lamp is placed in a holder (socket) capable of being so rotated through 360° about the reference axis that the front elevation is seen on the screen on to which the image of the filament is projected. The reference plane on the screen shall coincide with the centre of the filament lamp. The central axis sought on the screen shall coincide with the centre of the filament lamp length.

2.

 Front elevation

2.1.

The projection of the filament shall lie entirely within the rectangle when the filament lamp is rotated through 360°.

2.2.

The centre of the filament shall not be offset by more than distance ‘k’ from the central axis sought.

CATEGORY H1 — Sheet H1/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 4
1 1 2 3 4

CATEGORY H1 — Sheet H1/2

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

6 V

12 V

24 V

12 V

e (6)  (10)

25,0  (9)

25,0 ± 0,15

f (6)  (10)

4,5 ± 1,0

5,0 ± 0,5

5,5 ± 1,0

5,0 + 0,50 / – 0,00

g (7)  (8)

0,5 d ± 0,5 d

0,5 d ± 0,25 d

h1

 (9)

0 ± 0,20 (5)

h2

 (9)

0 ± 0,25 (5)

ε

45° ± 12°

45° ± 3°

Cap P14,5s in accordance with IEC Publication 60061 (sheet 7004-46-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6

12

24

12

Watts

55

70

55

Test Voltage

Volts

6,3

13,2

28,0

13,2

Objective values

Watts

63 max.

68 max.

84 max.

68 max.

Luminous flux ± %

1 350

1 550

1 900

 

15

 

Reference luminous flux at approximately

12 V

1 150

13,2 V

1 550

CATEGORY H1 — Sheet H1/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 5

 

a1

a2

b1

b2

c1

c2

6 V

1,4 d

1,9 d

0,25

6

3,5

12 V

6

4,5

24 V

7

4,5

d= diameter of filament.

The filament position is checked solely in directions A and B as shown on sheet H1/1.

The filament shall lie entirely within the limits shown.

The beginning of the filament as defined on sheet H1/2, note 10, shall lie between lines Z1 and Z2.

CATEGORY H3 — Sheet H3/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 6
1 2 3

CATEGORY H3 — Sheet H3/2

Image 7
4 5

CATEGORY H3 — Sheet H3/3

Dimensions in mm

Filaments lamps of normal production

Standard filament lamp

6 V

12 V

24 V

12 V

e

18,0  (6)

18,0

f (8)

3,0 min.

4,0 min.

5,0 ± 0,50

k

0  (6)

0 ± 0,20

h1, h3

0  (6)

0 ± 0,15 (7)

h2, h4

0  (6)

0 ± 0,25 (7)

Cap PK22s in accordance with IEC Publication 60061 (sheet 7004-47-4)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6

12

24

12

Watts

55

70

55

Test voltage

Volts

6,3

13,2

28,0

13,2

Objective values

Watts

63 max.

68 max.

84 max.

68 max.

Luminous flux ± %

1 050

1 450

1 750

 

15

 

Reference luminous flux at approximately

12 V

1 100

13,2 V

1 450

CATEGORY H3 — Sheet H3/4

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament complies with the requirements.

Image 8

 

a

c

k

g

6 V

1,8 d

1,6 d

1,0

2,0

12 V

2,8

24 V

2,9

d= diameter of filament

The filament shall lie entirely within the limits shown.

The centre of the filament shall lie within the limits of dimension k.

CATEGORY H4 — Sheet H4/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawing

Image 9

Figure 2

Figure 3

Maximum lamp outlines (4)

Image 10

(1)

 The reference plane is the plane formed by the seating points of the three lugs of the cap ring.

(2)

 The reference axis is perpendicular to the reference plane and passes through the centre of the circle of diameter ‘M’.

(3)

 The colour of the light emitted shall be white or selective-yellow.

(4)

 The bulb and supports shall not exceed the envelope as in Figure 2. However, where a selective-yellow outer bulb is used the bulb and supports shall not exceed the envelope as in Figure 3.

(5)

 The obscuration shall extend at least as far as the cylindrical part of the bulb. It shall also overlap the internal shield when the latter is viewed in a direction perpendicular to the reference axis.

CATEGORY H4 — Sheet H4/2

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

12 V

24 V

12 V

e

28,5 + 0,35 / – 0,25

29,0 ± 0,35

28,5 + 0,20 / – 0,00

p

28,95

29,25

28,95

α

max. 40 °

max.40 °

Cap P43t in accordance with IEC Publication 60061 (sheet 7004-39-6)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12  (6)

24  (6)

12  (6)

Watts

60

55

75

70

60

55

Test voltage

Volts

13,2

28,0

13,2

Objective values

Watts

75 max.

68 max.

85 max.

80 max.

75 max.

68 max.

Luminous flux ± %

1 650

1 000

1 900

1 200

 

15

 

Measuring flux (lm) (7)

750

800

 

Reference luminous flux at approximately

12 V

1 250

750

13,2 V

1 650

1 000

CATEGORY H4 — Sheet H4/3

Position of shield

Image 11

The drawing is not mandatory with respect to the design of the shield.

Position of filaments

Image 12

CATEGORY H4 — Sheet H4/4

Table of the dimensions (in mm) referred to in the drawings on sheet H4/3

Reference (*6)

Dimension (*7)

Tolerance

Filaments lamps of normal production

Standard filament lamp

12 V

24 V

12 V

24 V

12 V

24 V

12 V

a/26

0,8

± 0,35

± 0,20

a/23,5

0,8

± 0,60

± 0,20

b1/29,5

30,0

0

± 0,30

± 0,35

± 0,20

b1/33

b1/29,5 mv

b1/30,0 mv

± 0,30

± 0,35

± 0,15

b2/29,5

30,0

0

± 0,30

± 0,35

± 0,20

b2/33

b1/29,5 mv

b2/30,0 mv

± 0,30

± 0,35

± 0,15

c/29,5

30,0

0,6

0,75

± 0,35

± 0,20

c/33

c/29,5 mv

c/30,0 mv

± 0,35

± 0,15

d

min. 0,1

e (13)

28,5

29,0

+ 0,35

– 0,25

± 0,35

+ 0,20

– 0,00

f (11)  (12)  (13)

1,7

2,0

+ 0,50

– 0,30

± 0,40

+ 0,30

– 0,10

g/26

0

± 0,50

± 0,30

g/23,5

0

± 0,70

± 0,30

h/29,5

30,0

0

± 0,50

± 0,30

h/33

h/29,5 mv

h/30,0 mv

± 0,35

± 0,20

lR (11)  (14)

4,5

5,25

± 0,80

± 0,40

lC (11)  (12)

5,5

5,25

± 0,50

± 0,80

± 0,35

p/33

Depends on the shape of the shield

q/33

(p + q) / 2

± 0,60

± 0,30

CATEGORY H4 — Sheet H4/5

Additional explanations to sheet H4/3

The dimensions below are measured in three directions:

(1)

for dimensions a, b1, c, d, e, f, lR and lC;

(2)

for dimensions g, h, p and q;

(3)

for dimension b2.

Dimensions p and q are measured in planes parallel to and 33 mm away from the reference plane.

Dimensions b1, b2, c and h are measured in planes parallel to and 29,5 mm (30,0 mm for 24 V filament lamps) and 33 mm away from the reference plane.

Dimensions a and g are measured in planes parallel to and 26,0 mm and 23,5 mm away from the reference plane.

Note: For the method of measurement, see Appendix E of IEC Publication 60809.

CATEGORY H7 — Sheet H7/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp

Figure 1

Main drawing

Image 13

Figure 2

Maximum lamp outline (5)

Image 14

Figure 3

Definition of reference axis (2)

Image 15

(1)

 The reference plane is defined by the points on the surfaces of the holder on which the three supporting bosses of the cap ring will rest.

(2)

 The reference axis is perpendicular to the reference plane and crosses the intersection of the two perpendiculars as indicated in Figure 3.

(3)

 The colour of the light emitted shall be white or selective-yellow.

(4)

 Notes concerning the filament diameter.

(a)

No actual diameter restrictions apply but the objective for future developments is to have d max. = 1,3 mm for 12 V and d max. = 1,7 for 24V filament lamps.

(b)

For the same manufacturer, the design diameter of standard (étalon) filament lamp and filament lamp of normal production shall be the same.

(5)

 Glass bulb and supports shall not exceed the envelope as indicated in Figure 2. The envelope is concentric to the reference axis.

CATEGORY H7 — Sheet H7/2

Figure 4

Distortion free area (6) and black top (7)

Image 16

Figure 5

Metal free zone (8)

Image 17

Figure 6

Permissible offset of filament axis (9)

(for standard filament lamps only)

Image 18

Figure 7

Bulb eccentricity

Image 19

(6)

 Glass bulb shall be optically distortion free within the angles γ1 and γ2. This requirement applies to the whole bulb circumference within the angles γ1 and γ2.

(7)

 The obscuration shall extend at least to the cylindrical part of the bulb on the whole bulb top circumference. It shall moreover extend at least to a plane parallel to the reference plane where 3 crosses the outer bulb surface (view B as indicated on sheet H7/1).

(8)

 The internal design of the lamp shall be such that stray light images and reflections are only located above the filament itself seen from the horizontal direction. (View A as indicated in Figure 1 on sheet H7/1).

No metal parts other than filament turns shall be located in the shaded area as seen in Figure 5.

CATEGORY H7 — Sheet H7/3

Dimensions in mm

Filaments lamps of normal production

Standard filament lamp

12 V

24 V

12 V

e (9)

25,0  (10)

25,0 ± 0,1

f (9)

4,1  (10)

4,9  (10)

4,1 ± 0,1

g (12)

0,5 min.

under consideration

h1 (11)

0  (10)

0 ± 0,10

h2 (11)

0  (10)

0 ± 0,15

γ1

40 ° min.

40 ° min.

γ2

50 ° min.

50 ° min.

γ3

30 ° min.

30 ° min.

Cap PX26d in accordance with IEC Publication 60061 (sheet 7004-5-6)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

24

12

Watts

55

70

55

Test voltage

Volts

13,2

28,0

13,2

Objective values

Watts

58 max.

75 max.

58 max.

Luminous flux

1 500  ± 10 %

1 750  ± 10 %

 

Reference luminous flux at approximately

12 V

1 100

13,2 V

1 500

CATEGORY H7 — Sheet H7/4

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

(Dimensions in mm)

Image 20

 

a1

a2

b1

b2

c1

c2

12 V

d + 0,30

d + 0,50

0,2

4,6

4,0

24 V

d + 0,60

d + 1,00

0,25

5,9

4,4

d= diameter of filament

The filament position is checked solely in directions A and B as shown on sheet H7/1, Figure 1.

The filament shall lie entirely within the limits shown.

The ends of the filament as defined on sheet H7/3, note 9, shall lie between lines Z1 and Z2 and between Z3 and Z4.

CATEGORIES H8 AND H8B — Sheet H8/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawings

Image 21

Figure 2

Maximum lamp outline (3)

Image 22

(1)

 The reference plane is the plane formed by the underside of the bevelled lead-in flange of the cap.

(2)

 The reference axis is perpendicular to the reference plane and passing through the centre of the 19 mm cap diameter.

(3)

 Glass bulb and supports shall not exceed the envelope as indicated in Figure 2. The envelope is concentric to the reference axis.

(4)

 The colour of the light emitted shall be white or selective-yellow.

(5)

 Notes concerning the filament diameter.

(a)

No actual diameter restrictions apply but the objective for future developments is to have d max. = 1,2 mm.

(b)

For the same manufacturer, the design diameter of standard (étalon) filament lamp and filament lamp of normal production shall be the same.

CATEGORIES H8 AND H8B — Sheet H8/2

Figure 3

Distortion free area (6) and black top (7)

Image 23

Figure 4

Metal free zone (8)

Image 24

Figure 5

Permissible offset of filament axis (9)

(for standard filament lamps only)

Image 25

Figure 6

Bulb eccentricity (10)

Image 26

(6)

 Glass bulb shall be optically distortion free within the angles γ1 and γ2. This requirement applies to the whole bulb circumference within the angles γ1 and γ2.

(7)

 The obscuration shall extend at least to the cylindrical part of the bulb on the whole bulb top circumference. It shall moreover extend at least to a plane parallel to the reference plane where γ3 crosses the outer bulb surface (view B as indicated on sheet H8/1).

(8)

 The internal design of the lamp shall be such that stray light images and reflections are only located above the filament itself seen from the horizontal direction. (View A as indicated in Figure 1 on sheet H8/1). No metal parts other than filament turns shall be located in the shaded area as seen in Figure 4.

(9)

 The offset of the filament with respect to the reference axis is measured only in viewing directions A and B as shown in Figure 1 in sheet H8/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(10)

 Offset of filament in relation to bulb axis measured in two planes parallel to the reference plane where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

CATEGORIES H8 AND H8B — Sheet H8/3

Dimensions in mm

Filaments lamps of normal production

Standard filament lamp

12 V

12 V

e (11)

25,0  (12)

25,0 ± 0,1

f (11)

3,7  (12)

3,7 ± 0,1

g

0,5 min.

under consideration

h1

0  (12)

0 ± 0,1

h2

0  (12)

0 ± 0,15

γ1

50 ° min.

50 ° min.

γ2

40 ° min.

40 ° min.

γ3

30 ° min.

30 ° min.

Cap:

H8:

PGJ19-1

in accordance with IEC Publication 60061 (sheet 7004-110-2)

H8B:

PGJY19-1

in accordance with IEC Publication 60061 (sheet 7004-146-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

35

35

Test voltage

Volts

13,2

13,2

Objective values

Watts

43 max.

43 max.

Luminous flux

800 ± 15 %

 

Reference luminous flux at approximately

12 V

600

13,2 V

800

CATEGORIES H8 AND H8B — Sheet H8/4

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament complies with the requirements.

Image 27

a1

a2

b1

b2

c1

c2

d + 0,50

d + 0,70

0,25

4,6

3,5

d= diameter of filament

The filament position is checked solely in directions A and B as shown on sheet H8/1, Figure 1.

The filament shall lie entirely within the limits shown.

The ends of the filament as defined on sheet H8/3, note 11, shall lie between lines Z1 and Z2 and between Z3 and Z4.

CATEGORIES H9 AND H9B — Sheet H9/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawings

Image 28

Figure 2

Maximum lamp outline (3)

Image 29

(1)

 The reference plane is the plane formed by the underside of the bevelled lead-in flange of the cap.

(2)

 The reference axis is perpendicular to the reference plane and passing through the centre of the 19 mm cap diameter.

(3)

 Glass bulb and supports shall not exceed the envelope as indicated in Figure 2. The envelope is concentric to the reference axis.

(4)

 Notes concerning the filament diameter.

(a)

No actual diameter restrictions apply but the objective for future developments is to have d max. = 1,4 mm.

(b)

For the same manufacturer, the design diameter of standard (étalon) filament lamp and filament lamp of normal production shall be the same.

CATEGORIES H9 AND H9B — Sheet H9/2

Figure 3

Distortion free area (5)

Image 30

Figure 4

Metal free zone (6)

Image 31

Figure 5

Permissible offset of filament axis (7)

(for standard filament lamps only)

Image 32

Figure 6

Bulb eccentricity (8)

Image 33

(5)

 Glass bulb shall be optically distortion free within the angles γ1 and γ2. This requirement applies to the whole bulb circumference within the angles γ1 and γ2.

(6)

 The internal design of the lamp shall be such that stray light images and reflections are only located above the filament itself seen from the horizontal direction. (View A as indicated in Figure 1, sheet H9/1). No metal parts other than filament turns shall be located in the shaded area as seen in Figure 4.

(7)

 The offset of the filament with respect to the reference axis is measured only in viewing directions A and B as shown in Figure 1 on sheet H9/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(8)

 Offset of filament in relation to bulb axis measured in two planes parallel to the reference plane where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

CATEGORIES H9 AND H9B — Sheet H9/3

Dimensions in mm

Tolerances

Filaments lamps of normal production

Standard filament lamp

12 V

12 V

e (9)  (10)

25

 (11)

± 0,10

f (9)  (10)

4,8

 (11)

± 0,10

g (9)

0,7

± 0,5

± 0,30

h1

0

 (11)

± 0,10 (12)

h2

0

 (11)

± 0,15 (12)

γ1

50 ° min.

γ2

40 ° min.

Cap:

H9:

PGJ19-5

in accordance with IEC Publication 60061 (sheet 7004-110-2)

H9B:

PGJY19-5

in accordance with IEC Publication 60061 (sheet 7004-146-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

65

65

Test voltage

Volts

13,2

13,2

Objective values

Watts

73 max.

73 max.

Luminous flux

2 100 ± 10 %

 

Reference luminous flux at approximately

12 V

1 500

13,2 V

2 100

CATEGORIES H9 AND H9B — Sheet H9/4

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament complies with the requirements.

Image 34

a1

a2

b1

b2

c1

c2

d + 0,4

d + 0,7

0,25

5,7

4,6

d= diameter of filament

The filament position is checked solely in directions A and B as shown on sheet H9/1, Figure 1.

The filament shall lie entirely within the limits shown.

The ends of the filament as defined on sheet H9/3, note 10, shall lie between lines Z1 and Z2 and between Z3 and Z4.

CATEGORY H10 — Sheet H10/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 35
1 2 3 4 5 6 7

CATEGORY H10 — Sheet H10/2

Dimensions in mm (8)

Tolerance

Filament lamps of normal production

Standard filament lamp

e (9)  (10)

28,9

 (11)

± 0,16

f (12) (13)

5,2

 (11)

± 0,16

h1, h2

0

 (11)

± 0,15 (12)

γ1

50° min.

γ2

52° min.

γ3

45 °

± 5°

± 5°

Cap PY20d in accordance with IEC Publication 60061 (sheet 7004-31-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

42

42

Test voltage

Volts

13,2

13,2

Objective values

Watts

50 max.

50 max.

Luminous flux

850 ± 15 %

 

Reference luminous flux at approximately

12 V

600

13,2 V

850

CATEGORY H10 — Sheet H10/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 36

 

a1

a2

b1

b2

c1

c2

12 V

1,4 d

1,8 d

0,25

6,1

4,9

d= diameter of filament.

The filament position is checked solely in directions A and B as shown on sheet H10/1.

The filament shall lie entirely within the limits shown.

The ends of the filament as defined on sheet H10/2 note 10 shall lie between lines Z1 and Z2 and between lines Z3 and Z4.

CATEGORIES H11 AND H11B — Sheet H11/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawings

Image 37

Figure 2

Maximum lamp outline (3)

Image 38

(1)

 The reference plane is the plane formed by the underside of the bevelled lead-in flange of the cap.

(2)

 The reference axis is perpendicular to the reference plane and passing through the centre of the 19 mm cap diameter.

(3)

 Glass bulb and supports shall not exceed the envelope as indicated in Figure 2. The envelope is concentric to the reference axis.

(4)

 The colour of the light emitted shall be white or selective-yellow.

(5)

 Notes concerning the filament diameter:

(a)

No actual diameter restrictions apply but the objective for future developments is to have d max. = 1,4 mm.

(b)

For the same manufacturer, the design diameter of standard (étalon) filament lamp and filament lamp of normal production shall be the same.

CATEGORIES H11 AND H11B — Sheet H11/2

Figure 3

Distortion free area (6) and black top (7)

Image 39

Figure 4

Metal free zone (8)

Image 40

Figure 5

Permissible offset of filament axis (9)

(for standard filament lamps only)

Image 41

Figure 6

Bulb eccentricity (10)

Image 42

(6)

 Glass bulb shall be optically distortion free within the angles γ1 and γ2. This requirement applies to the whole bulb circumference within the angles γ1 and γ2.

(7)

 The obscuration shall extend at least to the cylindrical part of the bulb on the whole bulb top circumference. It shall, moreover, extend at least to a plane parallel to the reference plane where γ3 crosses the outer bulb surface (view B as indicated on sheet H11/1).

(8)

 The internal design of the lamp shall be such that stray light images and reflections are only located above the filament itself seen from the horizontal direction (view A as indicated in Figure 1 on sheet H11/1). No metal parts other than filament turns shall be located in the shaded area as seen in Figure 4.

(9)

 The offset of the filament with respect to the reference axis is measured only in viewing directions A and B as shown in Figure 1 on sheet H11/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(10)

 Eccentricity of bulb axis with respect to filament axis measured in two planes parallel to the reference plane where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

CATEGORIES H11 AND H11B — Sheet H11/3

Dimensions in mm

Filaments lamps of normal production

Standard filament lamp

12 V

24 V

12 V

e (11)

25,0  (12)

25,0 ± 0,1

f (13)

4,5

5,3 (14)

4,5 ± 0,1

g

0,5 min.

under consideration

h1

0 (15)

0 ± 0,1

h2

0 (16)

0 ± 0,15

γ1

50° min.

50° min.

γ2

40° min.

40° min.

γ3

30° min.

30° min.

Cap:

H11:

PGJ19-2

in accordance with IEC Publication 60061 (sheet 7004-110-2)

H11B:

PGJY19-2

in accordance with IEC Publication 60061 (sheet 7004-146-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

24

12

Watts

55

70

55

Test voltage

Volts

13,2

28,0

13,2

Objective values

Watts

62 max.

80 max.

62 max.

Luminous flux

1 350  ± 10 %

1 600  ± 10 %

 

Reference luminous flux at approximately

12 V

1 000

13,2 V

1 350

CATEGORIES H11 AND H11B — Sheet H11/4

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament complies with the requirements.

Image 43

 

a1

a2

b1

b2

c1

c2

12 V

d + 0,3

d + 0,5

0,2

5,0

4,0

24 V

d + 0,6

d + 1,0

0,25

6,3

4,6

d= diameter of filament

The filament position is checked solely in directions A and B as shown on sheet H11/1, Figure 1.

The filament shall lie entirely within the limits shown.

The ends of the filament as defined on sheet H11/3, note 11, shall lie between lines Z1 and Z2 and between Z3 and Z4.

CATEGORY H12 — Sheet H12/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 44
1 2 3 4 5 6 7

CATEGORY H12 — Sheet H12/2

Dimensions in mm (8)

Tolerance

Filament lamps of normal production

Standard filament lamp

e (9)  (10)

31,5

 (11)

± 0,16

f (9)  (10)

5,5

4,8 min

± 0,16

h1, h2, h3, h4

0

 (11)

± 0,15 (12)

k

0

 (11)

± 0,15 (13)

γ1

50° min.

γ2

52° min.

γ3

45 °

± 5°

± 5°

Cap PZ20d in accordance with IEC Publication 60061 (sheet 7004-31-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

53

53

Test voltage

Volts

13,2

13,2

Objective values

Watts

61 max.

61 max.

Luminous flux

1 050  ± 15 %

 

Reference luminous flux at approximately

12 V

775

13,2 V

1 050

CATEGORY H12 — Sheet H12/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 45

a1

a2

b1

b2

c

1,6 d

1,3 d

0,30

0,30

2,8

d= diameter of filament

For the directions of view A, B and C, see sheet H12/1.

The filament shall lie entirely within the limits shown.

The centre the filament shall lie between the limits of dimensions b1 and b2.

CATEGORIES H13 AND H13A — Sheet H13/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawing

Image 46
1 2 3 4 5

CATEGORIES H13 AND H13A — Sheet H13/2

Figure 2

Definition of reference axis (2)

Image 47

Figure 4

Bulb offset (8)

Image 48

Figure 3

Undistorted area (6) and opaque coating (7)

Image 49

Figure 5

Light blocking toward cap (9)

Image 50

(6)

 Glass bulb shall be optically distortion-free axially and cylindrically within the angles β and δ. This requirement applies to the whole bulb circumference within the angles β and δ and does not need to be verified in the area covered by the opaque coating.

(7)

 The opaque coating shall extend at least to the cylindrical part of the bulb on the whole bulb top circumference. It shall moreover extend at least to a plane parallel to the reference plane where γ crosses the outer bulb surface (view B as indicated on sheet H13/1).

(8)

 Offset of passing-beam filament in relation to the bulb axis is measured in two planes parallel to the reference plane where the projection of the outside end turns nearest to and farthest from the reference plane crosses the passing-beam filament axis.

(9)

 Light shall be blocked over the cap end of the bulb extending to angle θ. This requirement applies in all directions around the reference axis.

CATEGORIES H13 AND H13A — Sheet H13/3

Figure 6

Position and dimensions of filaments (10) (11) (12) (13) (14)

Image 51
10 11 12 13 14 15

CATEGORIES H13 AND H13A — Sheet H13/4

Dimensions in mm

Tolerance

Filaments lamps of normal production

Standard filament lamp

d1 (13) (17)

1,8 max.

d2 (13) (17)

1,8 max.

e (16)

29,45

± 0,20

± 0,10

f1 (16)

4,6

± 0,50

± 0,25

f2 (16)

4,6

± 0,50

± 0,25

g (8) (17)

0,5 d1

± 0,40

± 0,20

h (8)

0

± 0,30

± 0,15

j (10)

2,5

± 0,20

± 0,10

k (10)

2,0

± 0,20

± 0,10

m (11)

0

± 0,20

± 0,13

n (11)

0

± 0,20

± 0,13

p (10)

0

± 0,08

± 0,08

β

42° min.

δ

52° min.

γ

43 °

+ 0° / – 5°

+ 0° / – 5°

θ (9)

41 °

± 4°

± 4°

Cap:

H13:

P26.4t

in accordance with IEC Publication 60061 (sheet 7004-128-3)

H13A:

PJ26.4t

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS (18)

Rated values

Volts

12

12

Watts

55

60

55

60

Test voltage

Volts

13,2

13,2

Objective values

Watts

68 max.

75 max.

68 max.

75 max.

Luminous flux

1 100  ± 15 %

1 700  ± 15 %

 

Reference luminous flux at approximately

12 V

800

1 200

13,2 V

1 100

1 700

CATEGORY H14 — Sheet H14/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawing

Image 52

Figure 2

Maximum lamp outline (3)

Image 53

(1)

 The reference plane is defined by the points on the surface of the holder on which the three lugs of the cap ring will rest.

(2)

 The reference axis is perpendicular to the reference plane and passing through the centre of the cap ring diameter ‘M’

(3)

 Glass bulb and supports shall not exceed the envelope as indicated in Figure 2. The envelope is concentric to the reference axis.

CATEGORY H14 — Sheet H14/2

Figure 3

Distortion free area (4) and black top (5)

Image 54

Figure 4

Bulb eccentricity

Image 55

Figure 5

Offset of filament axis (7)

(for standard filament lamps only)

Image 56

(4)

 Glass bulb shall be optically distortion free within the angles γ1 and γ2. This requirement applies to the whole bulb circumference within the angles γ1 and γ2 and does not need to be verified in the area covered by the obscuration.

(5)

 The obscuration shall extend at least to the cylindrical part of the bulb on the whole bulb top circumference. It shall, moreover, extend at least to a plane parallel to the reference plane where γ3 crosses the outer bulb surface (view B as indicated on sheet H14/1).

(6)

 Eccentricity of bulb with respect to passing-beam filament axis is measured in two planes parallel to the reference plane where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the passing-beam filament axis.

(7)

 The offset of the filaments with respect to the reference axis is measured only in viewing direction A, B and C as shown in Figure 1 on sheet H14/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filaments axis.

CATEGORY H14 — Sheet H14/3

Dimensions in mm

Filament lamp of normal production

Standard filament lamps

e (8)

26,15

 (10)

± 0,1

f1 (8)  (9)

5,3

 (10)

± 0,1

f2 (8)  (9)

5,0

 (10)

± 0,1

g

0,3 min.

 

 

h1

0

 (10)

± 0,1

h2

0

 (10)

± 0,15

h3

0

 (10)

± 0,15

h4

0

 (10)

± 0,15

i

2,7

 

j

2,5

 (10)

± 0,1

γ1

55° min.

γ2

52° min.

γ3

43 °

0 / – 5°

0 / – 5°

Cap P38t in accordance with IEC Publication 60061 (sheet 7004-133-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTCS

Rated values

Volts

12

12

Watts

55

60

55

60

Test voltage

Volts

13,2

13,2

Objective values

Watts

68 max.

75 max.

68 max.

75 max.

Luminous flux

1 150  ± 15 %

1 750  ± 15 %

 

 

Reference luminous flux at approximately

12 V

860

1 300

13,2 V

1 150

1 750

CATEGORY H14 — Sheet H14/4

Screen projection requirements

This test is used to determine, by checking whether the filaments are correctly positioned relative to the reference axis and the reference plane, whether a filament lamp complies with the requirements.

Image 57

a1

a2

b1

b2

c1

c2

c3

i

k

d1 + 0,5

1,6 * d2

0,2

5,8

5,1

5,75

2,7

0,15

d1 is diameter of the passing beam filament and d2 that of the driving beam filament.

Notes concerning the filaments diameter:

(a)

No actual diameter restrictions apply but the objective for future developments is to have d1 max. = 1,6 mm and d2 max. = 1,6 mm.

(b)

For the same manufacture, the design diameter of standard filament lamps and filament lamps of normal production shall be the same.

The positions of the filaments are checked solely in directions A, B and C as shown in Figure 1 on sheet H14/1.

The passing-beam filament shall lie entirely in the rectangle A and the driving beam filament entirely in rectangle B.

The ends of the passing-beam filament as defined on sheet H14/3, note 8 shall lie between lines Z1 and Z2 and between lines Z3 and Z4.

CATEGORY H15 — Sheet H15/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawing

Figure 3

Maximum lamp outlines (3)

Image 58

Figure 2

Definition of reference axis (2)

Image 59

Figure 4

Distortion free area (4)

Image 60

(1)

 The reference plane is defined by the points at which the holder touches the three lugs of the cap ring from the plug side. It is intended for use as an internal reference plane.

The auxiliary reference plane is defined by the points on the surface of the holder on which the three supporting bosses of the cap ring will rest. It is intended for use as an external reference plane.

The Cap is designed for use of the (internal) reference plane, but for certain applications the (external) auxiliary reference plane may be used instead.

(2)

 The reference axis is perpendicular to the reference plane and crosses the intersection of the two perpendiculars as indicated in figure 2 on sheet H15/1.

(3)

 Glass bulb and supports shall not exceed the envelope as indicated in figure 3. The envelope is concentric to the reference axis.

(4)

 Glass bulb shall be optically distortion free within the angles γ1 and γ2 as indicated in figure 4. This requirement applies to the whole bulb circumference within the angles γ1 and γ2.

CATEGORY H15 — Sheet H15/2

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

 

12 V

24 V

12 V

e

30,0 + 0,35 / – 0,25

30,0 + 0,35 / – 0,25

30,0 + 0,20 / – 0,15

γ1

50° min

50° min

50° min

γ2

50° min

50° min

50° min

r

For details see cap sheet

Cap PGJ23t-1 in accordance with IEC Publication 60061 (sheet 7004-155-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12  (5)

24  (5)

12  (5)

 

Watts

15

55

20

60

15

55

Test voltage

Volts

13,2

28,0

13,2

13,2

Objective values

Watts

19 max.

64 max.

24 max.

73 max.

19 max.

64 max.

 

Luminous flux

260

1 350

300

1 500

 

 

 

± 10 %

 

 

Reference luminous flux at approximately 12 V

 

1 000

Reference luminous flux at approximately 13,2 V

 

1 350

Reference luminous flux at approximately 13,5 V

290

 

CATEGORY H15 — Sheet H15/3

Position of the shield

Image 61

Position of the filaments

Image 62

CATEGORY H15 — Sheet H15/4

Table of the dimensions (in mm) referred to in the drawings on sheet H15/3

Reference (*9)

Dimension (*10)

Tolerance

Filament lamps of normal production

Standard filament lamp

12 V

24 V

12 V

24 V

12 V

24 V

12 V

24 V

a/24,0

a/24,5

1,8

± 0,35

± 0,20

a/26,0

1,8

± 0,35

± 0,20

b1/31,0

0

± 0,30

± 0,15

b1/33,5

b1/34,0

b1/31,0 mv

± 0,30

± 0,15

b2/31,0

0

± 0,30

± 0,15

b2/33,5

b2/34,0

b2/31,0 mv

± 0,30

± 0,15

c1/31,0

0

± 0,30

± 0,50

± 0,15

± 0,25

c1/33,5

c1/34,0

c1/31,0 mv

± 0,30

± 0,50

± 0,15

± 0,25

c2/33,5

c2/34,0

1,1

± 0,30

± 0,50

± 0,15

± 0,25

d

min. 0,1

f (8)  (9)  (10)

2,7

± 0,30

± 0,40

+ 0,20

– 0,10

+ 0,25

– 0,15

g/24,0

g/24,5

0

± 0,50

± 0,70

± 0,25

± 0,35

g/26,0

0

± 0,50

± 0,70

± 0,25

± 0,35

h/31,0

0

± 0,50

± 0,60

± 0,25

± 0,30

h/33,5

h/34,0

h/31,0 mv

± 0,30

± 0,40

± 0,15

± 0,20

lR  (8)  (11)

4,2

4,6

± 0,40

± 0,60

± 0,20

± 0,30

lC  (8)  (9)

4,4

5,4

± 0,40

± 0,60

± 0,20

± 0,30

p/33,5

p/34,0

Depends on the shape of the shield

q/33,5

q/34,0

p/33,5

p/34,0

± 1,20

± 0,60

CATEGORY H15 — Sheet H15/5

Additional explanations to sheet H15/3

The dimensions below are measured in four directions:

(1)

for dimensions a, c1, c2, d, e, f, lR and lC;

(2)

for dimensions g, h, p and q;

(3)

for dimension b1;

(4)

for dimension b2.

Dimensions b1, b2, c1 and h are measured in planes parallel to the reference plane at distances of 31,0 mm and 33,5 mm (34,0 mm for 24 V types).

Dimensions c2, p and q are measured in a plane parallel to the reference plane at a distance of 33,5 mm (34,0 mm for 24 V types).

Dimensions a and g are measured in planes parallel to the reference plane at distances of 24,0 mm (24,5 mm for 24 V types) and 26,0 mm.

CATEGORY H16 — Sheet H16/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

CATEGORY H16

Figure 1

Main drawing

Image 63

Figure 2

Maximum lamp outline (3)

Image 64

(1)

 The reference plane is the plane formed by the underside of the bevelled lead-in flange of the cap.

(2)

 The reference axis is perpendicular to the reference plane and passing through the centre of the 19 mm cap diameter.

(3)

 Glass bulb and supports shall not exceed the envelope as indicated in Figure 2. The envelope is concentric to the reference axis.

(4)

 The light emitted shall be white or selective yellow.

(5)

 Notes concerning the filament diameter:

No actual diameter restrictions apply but the objective for future developments is to have d max. = 0,9 mm.

For the same manufacturer, the design diameter of standard (étalon) filament lamp and filament lamp of normal production shall be the same.

CATEGORY H16 — Sheet H16/2

Figure 3

Distortion free area (6) and black top (7)

Image 65

Figure 4

Metal free zone (8)

Image 66

Figure 5

Permissible offset of filament axis (9)

(for standard filament lamps only)

Image 67

Figure 6

Bulb eccentricity (10)

Image 68

(6)

 Glass bulb shall be optically distortion free within the angles γ1 and γ2. This requirement applies to the whole bulb circumference within the angles γ1 and γ2.

(7)

 The obscuration shall extend at least to angle γ3 and shall extend at least to the cylindrical part of the bulb on the whole bulb top circumference.

(8)

 The internal design of the lamp shall be such that stray light images and reflections are only located above the filament itself seen from the horizontal direction. (View A as indicated in Figure 1 on sheet H16/1). No metal parts other than filament turns shall be located in the shaded area as seen in Figure 4.

(9)

 The offset of the filament with respect to the reference axis is measured only in viewing directions A and B as shown in Figure 1 in sheet H16/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(10)

 Offset of filament in relation to bulb axis measured in two planes parallel to the reference plane where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

CATEGORY H16 — Sheet H16/3

Dimensions in mm

Filaments lamps of normal production

Standard filament lamp

12 V

12 V

e (11)

25,0  (12)

25,0 ± 0,1

f (11)

3,2  (12)

3,2 ± 0,1

g

0,5 min.

under consideration

h1

0  (12)

0 ± 0,1

h2

0  (12)

0 ± 0,15

γ1

50° min.

50° min.

γ2

40° min.

40° min.

γ3

30° min.

30° min.

Cap: H16: PGJ19-3 in accordance with IEC Publication 60061 (sheet 7004-110-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

19

19

Test voltage

Volts

13,2

13,2

Objective values

Watts

22 max.

22 max.

Luminous flux

500 + 10 % / – 15 %

 

Reference luminous flux: 500 lm at approximately 13,2 V

Reference luminous flux: 550 lm at approximately 13,5 V

CATEGORY H16 — Sheet H16/4

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament complies with the requirements.

Image 69

a1

a2

b1

b2

c1

c2

d + 0,50

d + 0,70

0,25

3,6

2,6

d= diameter of filament

The filament position is checked solely in directions A and B as shown on sheet H16/1, Figure 1.

The filament shall lie entirely within the limits shown.

The ends of the filament as defined on sheet H16/3, note 11, shall lie between lines Z1 and Z2 and between Z3 and Z4.

CATEGORIES H6W AND HY6W — Sheet H6W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 70

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

14,25

15,0

15,75

15,0 ± 0,25

Lateral deviation (1)

 

 

0,75

0,4 max

β

82,5 °

90 °

97,5 °

90° ± 5°

γ1, γ2 (2)

30 °

 

 

30° min.

Cap:

H6W:

BAX9s

in accordance with IEC Publication 60061 (sheet 7004-8-1)

HY6W:

BAZ9s

in accordance with IEC Publication 60061 (sheet 7004-150-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

6

6

Test voltage

Volts

13,5

13,5

Objective values

Watts

7,35 max.

7,35 max.

Luminous flux

H6W

125 ± 12 %

 

HY6W

75 ± 17 %

 

Reference luminous flux at approximately 13,5 V

White: 125 lm

Amber: 75 lm

(1)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(2)

 In the area between the outer legs of the angles 1 and 2, the bulb shall have no optically distorting areas and the curvature of the bulb shall have a radius not less than 50 per cent of the actual bulb diameter.

(3)

 Over the entire length of the cap there shall be no projections or soldering exceeding the permissible maximum diameter of the cap.

(4)

 The light emitted from filament lamps of normal production shall be white for category H6W and amber for category HY6W.

(5)

 The light emitted from standard filament lamps shall be white for category H6W and amber or white for category HY6W.

CATEGORIES H10W/1 AND HY10W — Sheet H10W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 71

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

14,25

15,0

15,75

15,0 ± 0,25

Lateral deviation (1)

 

 

0,75

0,4 max

β

82,5 °

90 °

97,5 °

90° ± 5°

γ1, γ2 (2)

30 °

 

 

30 ° min.

Cap

H10W/1:

BAU9s

in accordance with IEC Publication 60061 (sheet 7004-150A-1)

HY10W:

BAUZ9s

in accordance with IEC Publication 60061 (sheet 7004-150B-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

10

10

Test voltage

Volts

13,5

13,5

Objective values

Watts

12 max.

12 max.

Luminous flux

H10W/1

200 ± 12 %

 

HY10W

120 ± 17 %

 

Reference luminous flux at approximately 13,5 V

White: 200 lm

Amber: 120 lm

(1)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(2)

 In the area between the outer legs of the angles γ1 and γ2, the bulb shall have no optically distorting areas and the curvature of the bulb shall have a radius not less than 50 per cent of the actual bulb diameter.

(3)

 Over the entire length of the cap there shall be no projections or soldering exceeding the permissible maximum diameter of the cap.

(4)

 The light emitted from filament lamps of normal production shall be white for category H10W/1 and amber for category HY10W.

(5)

 The light emitted from standard filament lamps shall be white for category H10W/1 and amber or white for category HY10W.

CATEGORIES H21W AND HY21W — Sheet H21W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 72

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

20,0  (1)

 

20,0 ± 0,25

f

12 V

 

 

3,8

3,8 + 0/ – 1

24 V

 

 

4,5

 

Lateral deviation (2)

 

 

(3)

0,0 ± 0,15 (4)

β

82,5 °

90 °

97,5 °

90° ± 5°

γ1, γ2 (5)

45 °

 

 

45° min.

Cap:

H21W:

BAY9s

in accordance with IEC Publication 60061 (sheet 7004-9-1)

HY21W:

BAW9s

in accordance with IEC Publication 60061 (sheet 7004-149-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

24

12

Watts

21

21

21

Test voltage

Volts

13,5

28,0

13,5

Objective values

Watts

26,25 max.

29,4 max.

26,25 max.

Luminous flux

H21W

600 ± 12 %

600 ± 15 %

 

HY21W

300 ± 17 %

300 ± 20 %

 

Reference luminous flux at approximately

12 V

White: 415 lm

13,2 V

White: 560 lm

13,5 V

White: 600 lm

Amber: 300 lm

(1)

 To be checked by means of a ‘Box system’, sheet H21W/2.

(2)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(3)

 The lateral deviation with respect to the plane perpendicular to axis X-X is measured in the position described in paragraph 1 of the test procedure specified on sheet H21W/2.

(4)

 In the area between the outer legs of the angles γ1 and γ2, the bulb shall have no optical distorting areas and the curvature of the bulb shall have a radius not less than 50 per cent of the actual bulb diameter.

(5)

 The light emitted from filament lamps of normal production shall be white for category H21W and amber for category HY21W.

(6)

 The light emitted from standard filament lamps shall be white for category H21W and amber or white for category HY21W.

CATEGORIES H21W AND HY21W — Sheet H21W/2

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane and has an axis perpendicular, within ± 7,5°, to the plane through the centre line of the reference pin and the reference axis, whether a filament lamp complies with the requirements

Image 73

Reference

a

b

h

k

Dimension

d + 1,0

d + 1,0

f + 1,2

0,50

d

=

diameter of filament

f

=

actual filament length

Test procedures and requirements

1.   The filament lamp is placed in a holder capable of being rotated about its axis and having either a calibrated scale or fixed stops corresponding to the angular displacement tolerance limits. The holder is then so rotated that an end view of the filament is seen on the screen on to which the image of the filament is projected. The end view of the filament shall be obtained within the angular displacements tolerance limits.

2.   Side elevation

The filament lamp placed with the cap down, the reference axis vertical and the filament seen end-on, the projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘b’, having its centre at the theoretical position of the centre of the filament.

3.   Front elevation

The filament lamp placed with the cap down and the reference axis vertical, the filament lamp being viewed in a direction at right angles to the filament axis:

3.1.

the projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘h’, having its centre at the theoretical position of the centre of the filament;

3.2.

the centre of the filament shall not be offset by more than distance ‘k’ from the reference axis.

CATEGORIES H27W/1 AND H27W/2 — Sheet H27W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

CATEGORY H27W/1

Image 74

CATEGORY H27W/2

Image 75

(1)

 The reference plane is defined by the plane formed by the underside of the bevelled lead-in flange of the cap.

(2)

 The reference axis is perpendicular to the reference plane and passes through the centre of the 13,10 mm cap diameter.

(3)

 Glass bulb and supports shall not exceed the size of a theoretical cylinder centred on the reference axis.

(4)

 The obscuration shall extend over the whole bulb top including the bulb cylindrical portion up to the intersection with γ1.

CATEGORIES H27W/1 AND H27W/2 — Sheet H27W/2

Image 76

Dimensions in mm

Filament lamp of normal production

Standard filament lamp

e

31,75  (6)

31,75 ± 0,25

f (8)

4,8 max.

4,2 ± 0,20

k

0  (6)

0,0 ± 0,25

h1, h2, h3, h4 (7)

0  (6)

0,0 ± 0,25

γ1 (5)

38° nom.

38° nom.

γ2 (5)

44° nom.

44° nom.

Cap:

H27W/1:

PG13

in accordance with IEC Publication 60061 (sheet 7004-107-4)

H27W/2:

PGJ13

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

27

27

Test voltage

Volts

13,5

13,5

Objectivevalues

Watts

31 max.

31 max.

Luminous flux

477 ± 15 %

 

Reference luminous flux at approximately

12 V

350 lm

13,2 V

450 lm

13,5 V

477 lm

CATEGORIES H27W/1 AND H27W/2 — Sheet H27W/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

(Dimensions in mm)

Image 77

Reference

a

c

k

g

Dimensions

d + 1,2

d + 1,0

0,5

2,4

d= diameter of filament

The filament shall lie entirely within the limits shown.

The centre of the filament shall lie within the limits of dimension k.

CATEGORIES HB3 AND HB3A — Sheet HB3/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 78
1 2 3 4 5

CATEGORIES HB3 AND HB3A — Sheet HB3/2

Distortion free area (7)

Image 79

Filament position and dimensions

Image 80

(6)

 The colour of the light emitted shall be white or selective-yellow.

(7)

 Glass bulb periphery shall be optically distortion-free axially within the angles γ1 and γ2. This requirement applies to the whole bulb circumference within the angles γ1 and γ2.

CATEGORIES HB3 AND HB3A — Sheet HB3/3

Dimensions in mm (12)

Tolerances

Filament lamps of normal production

Standard filament lamp

e (9)  (11)

31,5

 (10)

± 0,16

f (9)  (11)

5,1

 (10)

± 0,16

h1, h2

0

 (10)

± 0,15 (8)

h3

0

 (10)

± 0,08 (8)

1

45° min.

2

52° min.

Cap P20d in accordance with IEC Publication 60061 (sheet 7004-31-2) (13)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

60

60

Test voltage

Volts

13,2

13,2

Objective values

Watts

73 max.

73 max.

Luminous flux

1 860 ± 12 %

 

Reference luminous flux at approximately

12 V

1 300

13,2 V

1 860

CATEGORIES HB3 AND HB3A — Sheet HB3/4

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 81

 

p

q

r

s

t

u

v

12 V

1,3 d

1,6 d

3,0

2,9

0,9

0,4

0,7

d= diameter of filament

The filament position is checked solely in directions A and B as shown on sheet HB3/1.

The filament shall lie entirely within the limits shown.

The beginning of the filament as defined on sheet HB3/3, note 11, shall lie in volume ‘B’ and the end of the filament in volume ‘C’.

Volume ‘A’ does not involve any filament centre requirement.

CATEGORIES HB4 AND HB4A — Sheet HB4/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 82
1 2 3 4 5

CATEGORIES HB4 AND HB4A — Sheet HB4/2

Distortion free area (7) and black top (8)

Image 83

Bulb eccentricity

Image 84

Filament position and dimensions

Image 85

(6)

 The colour of the light emitted shall be white or selective-yellow.

(7)

 Glass bulb periphery shall be optically distortion-free axially and cylindrically within the angles γ1 and γ2. This requirement applies to the whole bulb circumference within the angles γ1 and γ2 and does not need to be verified in the area covered by the obscuration.

(8)

 The obscuration shall extend to at least angle γ3 and shall be at least as far as the undistorted part of the bulb defined by angle γ1.

CATEGORIES HB4 AND HB4A — Sheet HB4/3

Dimensions in mm (13)

Tolerances

Filament lamps of normal production

Standard filament lamp

e (10)  (12)

31,5

 (11)

± 0,16

f (10)  (12)

5,1

 (11)

± 0,16

h1, h2

0

 (11)

± 0,15 (9)

h3

0

 (11)

± 0,08 (9)

g (10)

0,75

± 0,5

± 0,3

γ1

50° min.

γ2

52° min.

γ3

45 °

± 5°

± 5°

Cap P22d in accordance with IEC Publication 60061 (sheet 7004-32-2) (14)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

51

51

Test voltage

Volts

13,2

13,2

Objective values

Watts

62 max.

62 max.

Luminous flux

1 095 ± 15 %

 

Reference luminous flux at approximately

12 V

825

13,2 V

1 095

CATEGORIES HB4 AND HB4A — Sheet HB4/4

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 86

 

p

q

r

s

t

u

v

12 V

1,3 d

1,6 d

3,0

2,9

0,9

0,4

0,7

d= diameter of filament

The filament position is checked solely in directions A and B as shown on sheet HB4/1.

The filament shall lie entirely within the limits shown.

The beginning of the filament as defined on sheet HB4/3 note 12 shall lie in volume ‘B’ and the end of the filament in volume ‘C’.

Volume ‘A’ does not involve any filament centre requirement.

CATEGORY HIR1 — Sheet HIR1/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 87
1 2 3 4 5 6

CATEGORY HIR1 — Sheet HIR1/2

Dimensions in mm (11)

Tolerances

Filament lamps of normal production

Standard filament lamp

e (8)  (10)

29

 (9)

± 0,16

f (8)  (10)

5,1

 (9)

± 0,16

g (8)

0

+ 0,7 / – 0,0

+ 0,4 / – 0,0

h1, h2

0

 (9)

± 0,15 (7)

d

1,6 max.

 

 

γ1

50° min.

γ2

50° min.

Cap PX20d in accordance with IEC Publication 60061 (sheet 7004-31-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

65

65

Test voltage

Volts

13,2

13,2

Objectivevalues

Watts

73 max.

73 max.

Luminous flux

2 500 ± 15 %

 

Reference luminous flux at approximately

12 V

1 840

13,2 V

2 500

CATEGORY HIR1 — Sheet HIR1/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 88

 

a1

a2

b1

b2

c1

c2

12 V

d + 0,4

d + 0,8

0,35

6,1

5,2

d= diameter of filament

The filament position is checked solely in directions A and B as shown on sheet HIR1/1.

The ends of the filament as defined on sheet HIR1/2 note 10 shall lie between lines Z1 and Z2 and between lines Z3 and Z4.

CATEGORY HIR2 — Sheet HIR2/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 89
1 2 3 4 5 6

CATEGORY HIR2 — Sheet HIR2/2

Dimensions in mm (11)

Tolerances

Filament lamps of normal production

Standard filament lamp

e (8)  (10)

28,7

 (9)

± 0,16

f (8)  (10)

5,3

 (9)

± 0,16

g (8)

0

+ 0,7 / – 0,0

+ 0,4 / – 0,0

h1, h2

0

 (9)

± 0,15 (7)

d

1,6 max.

γ1

50° min.

γ2

50° min.

Cap PX22d in accordance with IEC Publication 60061 (sheet 7004-32-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

55

55

Test voltage

Volts

13,2

13,2

Objective values

Watts

63 max.

63 max.

Luminous flux

1 875 ± 15 %

 

Reference luminous flux at approximately

12 V

1 355

13,2 V

1 875

CATEGORY HIR2 — Sheet HIR2/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 90

 

a1

a2

b1

b2

c1

c2

12 V

d + 0,4

d + 0,8

0,35

6,6

5,7

d= diameter of filament

The filament position is checked solely in directions A and B as shown on sheet HIR2/1.

The ends of the filament as defined on sheet HIR2/2 note 10 shall lie between lines Z1 and Z2 and between lines Z3 and Z4.

CATEGORY HS1 — Sheet HS1/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawing

Image 91

Maximum lamp outlines (4)

Figure 2

Figure 3

Image 92

(1)

 The reference plane is the plane formed by the seating points of the three lugs of the cap ring.

(2)

 The reference axis is perpendicular to the reference plane and passes through the centre of the circle of diameter ‘M’.

(3)

 The colour of the light emitted shall be white or selective-yellow.

(4)

 The bulb and supports shall not exceed the envelope as in Figure 2. However, where a selective-yellow outer bulb is used the bulb and supports shall not exceed the envelope as in Figure 3.

(5)

 The obscuration shall extend at least as far as the cylindrical part of the bulb. It shall also overlap the internal shield when the latter is viewed in a direction perpendicular to the reference axis.

CATEGORY HS1 — Sheet HS1/2

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

6 V

12 V

12 V

e

28,5 + 0,45 / – 0,25

28,5 + 0,20 / – 0,00

p

28,95

28,95

a

max. 40°

max. 40°

Cap PX43t in accordance with IEC Publication 60061 (sheet 7004-34-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6  (6)

12  (6)

12  (6)

Watts

35

35

35

35

35

35

Test voltage

Volts

6,3

13,2

13,2

Objective values

Watts ± %

35

35

35

35

35

35

5

5

Luminous flux ± %

700

440

825

525

 

15

 

Measuring flux (7) lm

 

450

 

Reference luminous flux at approximately

12 V

700

450

13,2 V

825

525

CATEGORY HS1 — Sheet HS1/3

Position of shield

Image 93

Position of filaments

Image 94

CATEGORY HS1 — Sheet HS1/4

Table of the dimensions (in mm) referred to in the drawings on sheet HS1/3

Reference (*13)

Dimensions (*14)

Tolerance

Filaments lamps of normal production

Standard filament lamp

6 V

12 V

6 V

12 V

6 V

12 V

12 V

a/26

0,8

± 0,35

± 0,20

a/25

0,8

± 0,55

± 0,20

b1/29,5

0

± 0,35

± 0,20

b1/33

b1/29,5 mv

± 0,35

± 0,15

b2/29,5

0

± 0,35

± 0,20

b2/33

b2/29,5 mv

± 0,35

± 0,15

c/29,5

0,6

± 0,35

± 0,20

c/31

c/29,5 mv

± 0,30

± 0,15

d

min. 0,1 / max. 1,5

e (13)

28,5

+ 0,45 / – 0,25

+ 0,20 / – 0,00

f (11)  (12)  (13)

1,7

+ 0,50 / – 0,30

+ 0,30 / – 0,10

g/26

0

± 0,50

± 0,30

g/25

0

± 0,70

± 0,30

h/29,5

0

± 0,50

± 0,30

h/31

h/29,5 mv

± 0,30

± 0,20

lR  (11)  (14)

3,5

4,0

± 0,80

± 0,40

lC  (11)  (12)

3,3

4,5

± 0,80

± 0,35

p/33

Depends on the shape of the shield

q/33

(p + q) / 2

± 0,60

± 0,30

CATEGORY HS1 — Sheet HS1/5

Additional explanations to sheet HS1/3

The dimensions below are measured in three directions:

(1)

for dimensions a, b1, c, d, e, f, lR and lC;

(2)

for dimensions g, h, p and q;

(3)

for dimension b2.

Dimensions p and q are measured in planes parallel to and 33 mm away from the reference plane.

Dimensions b1 and b2 are measured in planes parallel to and 29,5 mm and 33 mm away from the reference plane.

Dimensions a and g are measured in planes parallel to and 25,0 mm and 26,0 mm away from the reference plane.

Dimensions c and h are measured in planes parallel to and 29,5 mm and 31 mm away from the reference plane.

Note: For the method of measurement, see Appendix E of IEC Publication 60809.

CATEGORY HS2 — Sheet HS2/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 95
1 2 3 4

CATEGORY HS2 — Sheet HS2/2

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

11,0 (5)

 

11,0 ± 0,15

f (6)

6 V

1,5

2,5

3,0

2,5 ± 0,15

12 V

2,0

3,0

4,0

 

h1, h2

 

(5)

 

0 ± 0,15

α (2)

 

 

40 °

 

β (3)

75 °

90 °

105 °

90° ± 5°

γ (4)

15 °

 

 

15° min.

γ (4)

40 °

 

 

40° min.

Cap PX13,5s in accordance with IEC Publication 60061 (sheet 7004-35-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6

12

6

Watts

15

15

Test voltage

Volts

6,75

13,5

6,75

Objective values

Watts

15 ± 6 %

15 ± 6 %

Luminous flux

320 ± 15 %

 

Reference luminous flux: 320 lm at approximately 6,75 V

CATEGORY HS2 — Sheet HS2/3

Screen projection requirements

This test is used to determine, by checking whether the filament lamp complies with the requirements by checking whether the filament lamp is correctly positioned relative to the reference axis and reference plane.

Image 96

Reference

a1

a2

b1

b2

c1 (6 V)

c1 (12 V)

c2

Dimension

d + 1,0

d + 1,4

0,25

0,25

4,0

4,5

1,75

d= actual filament diameter

The filament shall lie entirely within the limits shown.

The beginning of the filament shall lie between the lines Z1 and Z2.

CATEGORY HS5 — Sheet HS5/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

FILAMENT LAMP FOR MOTORCYCLES

Figure 1

Main drawing

Image 97

Figure 2

Distortion free area (4) and black top (5)

Image 98

(1)

 The reference plane is defined by the three ramp inside surface.

(2)

 The reference axis is perpendicular to the reference plane and passing through the centre of the 23 mm cap diameter.

(3)

 Glass bulb and supports shall not exceed the envelope as indicated in Figure 1. The envelope is concentric to the reference axis.

(4)

 Glass bulb shall be optically distortion free within the angles 1 and 2. This requirement applies to the whole bulb circumference within the angles 1 and 2.

(5)

 The obscuration shall extend at least to angle 3 and shall extend at least to the cylindrical part of the bulb on the whole top circumference.

CATEGORY HS5 — Sheet HS5/2

Figure 3

Filament position and dimensions

View B of driving-beam filament

Image 99

View A of passing-beam filament

Image 100

Top view of driving-beam filament

Image 101

Top view of passing-beam filament

Image 102

CATEGORY HS5 — Sheet HS5/3

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

12 V

12 V

e

26

 (6)

± 0,15

lC  (7)

4,6

± 0,3

k

0

± 0,2

h1, h3

0

± 0,15

h2, h4

0

± 0,20

lR  (7)

4,6

± 0,3

j

0

± 0,2

g1, g3

0

± 0,30

g2, g4

2,5

± 0,40

γ1

50° min.

γ2

23° min.

γ3

50° min.

Cap P23t in accordance with IEC Publication 60061 (sheet 7004-138-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTCS

Rated values

Voltage

V

12

12

Wattage

W

35

30

35

30

Test voltage

V

13,2

13,2

Objective Values

Wattage

W

40 max.

37 max.

40 max.

37 max.

Luminous flux

lm

620

515

 

 

± %

15

15

 

 

Reference luminous at approximately

12 V

460

380

13,2 V

620

515

CATEGORY HS5 — Sheet HS5/4

Screen projection requirement

This test is used to determine whether a filament lamp complies with the requirements by checking whether:

(a)

the passing-beam filament is correctly positioned relative to the reference axis and the reference plane; and whether

(b)

the driving-beam filament is correctly positioned relative to the passing-beam filament.

(Dimensions in millimeters)

Side elevation

Image 103

Reference

a

b

c

d

v

Dimensions

d1 + 0,6

d1 + 0,8

d2 + 1,2

d2 + 1,6

2,5

d1

=

Diameter of the passing-beam filament

d2

=

Diameter of the driving-beam filament

Front elevation

Image 104

Reference

h

k

Dimensions

6,0

0,5

The filaments shall lie entirely within the limits shown.

The centre of the filament shall lie within the limits of dimension k.

CATEGORY HS5A — Sheet HS5A/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

FILAMENT LAMP FOR MOTORCYCLES

Figure 1

Main drawing

Image 105

Figure 2

Distortion free area (4) and black top (5)

Image 106

(1)

 The reference plane is defined by three ramps inside surface.

(2)

 The reference axis is perpendicular to the reference plane and passing through the centre of the 23 mm cap diameter.

(3)

 Glass bulb and supports shall not exceed the envelope as indicated in figure 1. The envelope is concentric to the reference axis.

(4)

 Glass bulb shall be optically distortion free within the angles γ1 and γ2. This requirement applies to the whole bulb circumference within the angles γ1 and γ2.

(5)

 The obscuration shall extend at least to angle γ3 and shall extend at least to the cylindrical part of the bulb on the whole top circumference.

CATEGORY HS5A — Sheet HS5A/2

Figure 3

Filament position and dimensions

Image 107

CATEGORY HS5A — Sheet HS5A/3

Dimensions in mm

Filament lamps of normal Production

Standard filament lamp

12 V

12 V

e

26

lC  (6)

4,6

± 0,5

± 0,3

k

0

± 0,4

± 0,2

h1, h3

0

± 0,3

± 0,15

h2, h4

0

± 0,4

± 0,2

lR  (6)

4,6

± 0,5

± 0,3

j

0

± 0,6

± 0,3

g1, g3

0

± 0,6

± 0,3

g2, g4

2,5

± 0,4

± 0,2

γ1

50° min.

γ2

23° min.

γ3

50° min.

Cap PX23t in accordance with IEC Publication 60061 (sheet 7004-138A-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTCS

Rated values

Voltage

V

12  (7)

12  (7)

Wattage

W

45

40

45

40

Test voltage

V

13,2

13,2

Objective Values

Wattage

W

50 max.

45 max.

50 max.

45 max.

Luminous flux

lm

750

640

 

 

± %

15

15

 

 

Reference luminous at approximately

12 V

550 lm

470 lm

13,2 V

750 lm

640 lm

CATEGORY HS6 — Sheet HS6/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawings

Image 108
1 2 3 4 5

CATEGORY HS6 — Sheet HS6/2

Figure 2

Definition of reference axis (9)

Image 109

Figure 4

Bulb offset (8)

Image 110

Figure 3

Undistorted area (6) and opaque coating (7)

Image 111

Figure 5

Light blocking toward cap (9)

Image 112

(6)

 Glass bulb shall be optically distortion-free axially and cylindrically within the angles β and δ. This requirement applies to the whole bulb circumference within the angles and and does not need to be verified in the area covered by the opaque coating.

(7)

 The opaque coating shall extend at least to the cylindrical part of the bulb on the whole bulb top circumference. It shall moreover extend at least to a plane parallel to the reference plane where crosses the outer bulb surface as shown in Figure 3 (view in direction B as indicated on sheet HS6/1).

(8)

 Offset of passing-beam filament in relation to the bulb axis is measured in two planes parallel to the reference plane where the projection of the outside end turns nearest to and farthest from the reference plane crosses the passing-beam filament axis.

(9)

 Light shall be blocked over the cap end of the bulb extending to angle θ. This requirement applies in all directions around the reference axis.

CATEGORY HS6 — Sheet HS6/3

Figure 6

Position and dimensions of filaments (10) (11) (12) (13) (14)

Image 113
10 11 12 13 14 15

CATEGORY HS6 — Sheet HS6/4

Dimensions in mm

Tolerance

Filaments lamps of normal production

Standard filament lamp

d1 (13) (16)

1,4 max.

d2 (13) (17)

1,4 max.

e (16)

29,45

± 0,20

± 0,10

f1 (16)

4,4

± 0,50

± 0,25

f2 (16)

4,4

± 0,50

± 0,25

g (8) (17)

0,5 d1

± 0,50

± 0,30

h (8)

0

± 0,40

± 0,20

j (10)

2,5

± 0,30

± 0,20

k (10)

2,0

± 0,20

± 0,10

m (11)

0

± 0,24

± 0,20

n (11)

0

± 0,24

± 0,20

p (10)

0

± 0,30

± 0,20

β

42° min.

δ

52° min.

γ

43 °

+ 0° / – 5°

+ 0° / – 5°

(9)

41 °

± 4°

± 4°

Cap

:

PX26,4t in accordance with IEC Publication 60061 (sheet 7004-128-3)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS (17)

Ratedvalues

Volts

12

12

Watts

40

35

40

35

Test voltage

Volts

13,2

13,2

Objectivevalues

Watts

45 max.

40 max.

45 max.

40 max.

Luminous flux

900 ± 15 %

600 ± 15 %

 

Reference luminous flux at approximately

12 V

630 / 420

13,2 V

900 / 600

CATEGORY P13W — Sheet P13W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawing

Image 114

Figure 2

Metal free zone (3)

Image 115

(1)

 The reference plane is defined by the meeting points of the cap-holder fit.

(2)

 No actual filament diameter restrictions apply but the objective is d max. = 1,0 mm.

(3)

 No opaque parts other than filament turns shall be located in the shaded area indicated in Figure 2. This applies to the rotational body within the angles α1 + α2.

CATEGORY P13W — Sheet P13W/2

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

e (5)

25,0  (4)

25,0 ± 0,25

f (5)

4,3  (4)

4,3 ± 0,25

α1  (6)

30,0° min.

30,0° min.

α2  (6)

58,0° min.

58,0° min.

Cap PG18.5d-1 in accordance with IEC Publication 60061 (sheet 7004-147-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Voltage

V

12

12

Wattage

W

13

13

Test voltage

V

13,5

13,5

Objective values

Wattage

W

19 max.

19 max.

Luminous flux

lm

250

 

±

+ 15 % / – 20 %

 

Reference luminous flux at approximately 13,5 V

250 lm

CATEGORY P13W — Sheet P13W/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 116

 

p

q

u1, u2

r, s

t, v

Filament lamps of normal production

1,7

1,9

0,3

2,6

0,9

Standard filament lamps

1,5

1,7

0,25

2,45

0,6

The filament position is checked in two mutually perpendicular planes, one of them being the plane through the lead-in wires.

The ends of the filament as defined on sheet P13W/2, note 4, shall lie between Z1 and Z2 and between the lines Z3 and Z4.

The filament shall lie entirely within the limits shown.

CATEGORIES P19W, PY19W, PR19W, PS19W, PSY19W AND PSR19W — Sheet P19W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 117
1 2 3

CATEGORIES P19W, PY19W, PR19W, PS19W, PSY19W AND PSR19W — Sheet P19W/2

Dimensions in mm (4)

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

α (8)

e (5)  (6)

 

24,0

 

24,0

f (5)  (6)

 

4,0

 

4,0 ± 0,2

α (7)

58 °

 

 

58° min.

P19W Cap PGU20-1

PY19W Cap PGU20-2

PR19W Cap PGU20-5

PS19W Cap PG20-1

PSY19W Cap PG20-2

PSR19W Cap PG20-5

in accordance with IEC Publication 60061

(sheet 7004-127-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

19

19

Test voltage

Volts

13,5

13,5

Objective values

Watts

20 max.

20 max.

Luminous flux

P19W

PS19W

350 ± 15 %

 

PY19W

PSY19W

215 ± 20 %

 

PR19W

PSR19W

80 ± 20 %

 

Reference luminous flux at approximately 13,5 V

White: 350 lm

Amber: 215 lm

Red: 80 lm

 

CATEGORIES P19W, PY19W, PR19W, PS19W, PSY19W AND PSR19W — Sheet P19W/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 118

 

a1

a2

b1, b2

c1

c2

Filament lamps of normal production

2,9

3,9

0,5

5,2

3,8

Standard filament lamps

1,5

1,7

0,25

4,7

3,8

The filament position is checked in two mutually perpendicular planes, one of them being the plane through the lead-in wires.

The ends of the filament as defined on sheet P19W/2, note 6, shall lie between Z1 and Z2 and between the lines Z3 and Z4.

The filament shall lie entirely within the limits shown.

CATEGORY P21W — Sheet P21W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 119

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

6,12 V

 

31,8  (3)

 

31,8 ± 0,3

24 V

30,8

31,8

32,8

 

f

12 V

5,5

6,0

7,0

6,0 ± 0,5

6 V

 

 

7,0

 

Lateral deviation (1)

6,12 V

 

 

(3)

0,3 max.

24 V

 

 

1,5

 

β

75 °

90 °

105 °

90° ± 5°

Cap BA15s in accordance with IEC Publication 60061 (sheet 7004-11A-9) (2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6

12

24

12

Watts

21

21

Test voltage

Volts

6,75

13,5

28,0

13,5

Objective values

Watts

27,6 max.

26,5 max.

29,7 max.

26,5 max.

Luminous flux

460 ± 15 %

 

Reference luminous flux: 460 lm at approximately 13,5 V

(1)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis of the pins.

(2)

 Filament lamps with cap BA15d may be used for special purposes; they have the same dimensions.

(3)

 To be checked by means of a ‘Box-System’; sheet P21W/2.

(4)

 In this view the filament of the 24 V type may be straight or V-shaped. This shall be indicated in the application of approval. If it is straight, the screen projection requirements, sheet P21W/2, apply. If it is V-shaped, the filament ends shall be at the same distance within ± 3 mm from the reference plane.

CATEGORY P21W — Sheet P21W/2

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane and has an axis perpendicular, within ± 15°, to the plane through the centre line of the pins (P21W) or of the reference pin (PY21W and PR21W) and the reference axis, whether a filament lamp complies with the requirements.

Side elevation

Front elevation

Image 120


Reference

a

b

h

k

Dimension

3,5

3,0

9,0

1,0

Test procedures and requirements

1.   The filament lamp is placed in a holder capable of being rotated about its axis and having either a calibrated scale or fixed stops corresponding to the angular displacement tolerance limits. The holder is then so rotated that an end view of the filament is seen on the screen on to which the image of the filament is projected. The end view of the filament shall be obtained within the angular displacements tolerance limits.

2.   Side elevation

The filament lamp placed with the cap down, the reference axis vertical and the filament seen end-on, the projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘b’, having its centre at the theoretical position of the centre of the filament.

3.   Front elevation

The filament lamp placed with the cap down and the reference axis vertical, the filament lamp being viewed in a direction at right angles to the filament axis:

3.1.

The projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘h’, having its centre at the theoretical position of the centre of the filament.

3.2.

The centre of the filament shall not be offset by more than distance ‘k’ from the reference axis.

CATEGORY P21/4W — Sheet P21/4W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 121

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

31,8  (1)

 

31,8 ± 0,3

f

 

 

7,0

7,0 + 0 / – 2

Lateral deviation

 

 

(1)

0,3 max. (2)

x, y

(1)

2,8 ± 0,5

β

75 ° (1)

90 ° (1)

105 ° (1)

90° ± 5°

Cap BAZ15d in accordance with IEC Publication 60061 (sheet 7004-11C-3)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

24

12

Watts

21

4

21

4

21 / 4

Test voltage

Volts

13,5

28,0

13,5

Objective values

Watts

26,5 max.

5,5 max.

29,7 max.

8,8 max.

26,5 / 5,5 max.

Luminous flux ± %

440

15

440

20

 

15

20

15

20

 

Reference luminous flux: 440 lm and 15 lm at approximately 13,5 V

(1)

 These dimensions shall be checked by means of a ‘Box-System’ 3 based on the dimensions and tolerances shown above. ‘x’ and ‘y’ refer to the major (high-wattage) filament, not to the reference axis. Means of increasing the positioning accuracy of the filament and of the cap-holder assembly are under consideration.

(2)

 Maximum lateral deviation of the major filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis of the reference pin.

(3)

 The ‘Box-System’ is the same as for filament lamp P21/5W.

CATEGORY P21/5W — Sheet P21/5W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 122

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

6,12 V

 

31,8  (1)

 

31,8 ± 0,3

24 V

30,8

31,8

32,8

 

f

6,12 V

 

 

7,0

7,0 + 0 / – 2

Lateral deviation (2)

6,12 V

 

 

(1)

0,3 max.

24 V

 

 

1,5

 

x, y

6,12 V

 

(1)

 

2,8 ± 0,3

x

24 V (3)

–1,0

0

1,0

 

y

24 V (3)

1,8

2,8

3,8

 

β

 

75 °

90 °

105 °

90° ± 5°

Cap BAY15d in accordance with IEC Publication 60061 (sheet 7004-11B-7)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6

12

24

12

Watts

21

5

21

5

21

5

21 / 5

Test voltage

Volts

6,75

13,5

28,0

13,5

Objective values

Watts

27,6 max.

6,6 max.

26,5 max.

6,6 max.

29,7 max.

11,0 max.

26,5 and 6,6 max.

Luminous flux ± %

440

35

440

35

440

40

 

15

20

15

20

15

20

 

Reference luminous flux: 440 and 35 lm at approximately 13,5 V

For the notes see sheet P21/5W/2.

CATEGORY P21/5W — Sheet P21/5W/2

Notes:

(1)

 These dimensions shall be checked by means of a ‘box-system’. See sheets P21/5W/2 and P21/5W/3. ‘x’ and ‘y’ refer to the major (high-wattage) filament, not to the reference axis.

(2)

 Maximum lateral deviation of the major (high wattage) filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis of the reference pin.

(3)

 In this view the filaments of the 24 V type may be straight or V-shaped. This shall be indicated in the application of approval. If the filaments are straight, the screen projection requirements apply. If they are V-shaped, the ends of each filament shall be at the same distance within ± 3 mm from the reference plane.

Screen projection requirements

This test is used to determine, by checking whether:

(a)

the major (high wattage) filament is correctly positioned relative to the reference axis and reference plane and has an axis perpendicular, within ± 15°, to the plane through the centres of the pins and the reference axis; and whether

(b)

the minor (low wattage) filament is correctly positioned relative to the major (high wattage) filament, whether a filament lamp complies with the requirements.

Test procedure and requirements

1.   The filament lamp is placed in a holder capable of being rotated about its axis and having either a calibrated scale or fixed stops corresponding to the angular displacement tolerance limits. (i.e. 15°). The holder is then so rotated that an end view of the major filament is seen on the screen on which the image of the filament is projected. The end view of that filament shall be obtained within the angular displacement tolerance limits.

2.   Side elevation

The filament lamp placed with the cap down, the reference axis vertical, the reference pin to the right and the major filament seen end-on:

2.1.

the projection of the major filament shall lie entirely within a rectangle of height ‘a’ and width ‘b’, having its centre at the theoretical position of the centre of the filament;

2.2.

the projection of the minor filament shall lie entirely:

2.2.1.

within a rectangle of width ‘c’ and height ‘d’ having its centre at a distance ‘v’ to the right of and at a distance ‘u’ above the theoretical position of the centre of the major filament;

2.2.2.

above a straight line tangential to the upper edge of the projection of the major filament and rising from left to right at an angle of 25°.

2.2.3.

to the right of the projection of the major filament.

3.   Front elevation

The filament lamp being placed with the cap down and the reference axis vertical, the filament lamp being viewed in a direction at right angles to axis of the major filament:

3.1.

the projection of the major filament shall lie entirely within a rectangle of height ‘a’ and width ‘h’, centred on the theoretical position of the centre of the filament;

3.2.

the centre of the major filament shall not be offset by more than distance ‘k’ from the reference axis.

3.3.

the centre of the minor filament axis shall not be offset from the reference axis by more than ± 2 mm (± 0,4 mm for standard filament lamps).

CATEGORY P21/5W — Sheet P21/5W/3

(Dimensions in mm)

Side elevation

Image 123

Reference

a

b

c

d

u

v

Dimension

3,5

3,0

4,8

2,8

Front elevation

Image 124

Reference

a

h

k

Dimension

3,5

9,0

1,0

CATEGORIES P24W, PX24W, PY24W, PR24W, PS24W, PSX24W, PSY24W and PSR24W — Sheet P24W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 125
1 2 3

CATEGORIES P24W, PX24W, PY24W, PR24W, PS24W, PSX24W, PSY24W and PSR24W — Sheet P24W/2

Dimensions in mm (4)

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 (8)

e (5)  (6)

 

24,0

 

24,0

f (5)  (6)

P24W, PY24W, PR24W, PS24W, PSY24W, PSR24W

 

4,0

 

4,0

PX24W, PSX24W

 

4,2

 

4,2

α (7)

58,0 °

 

 

58,0° min.

P24W

Cap PGU20-3

in accordance with IEC Publication 60061 (sheet 7004-127-2)

PX24W

Cap PGU20-7

PY24W

Cap PGU20-4

PR24W

Cap PGU20-6

PS24W

Cap PG20-3

PSX24W

Cap PG20-7

PSY24W

Cap PG20-4

PSR24W

Cap PG20-6

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

24

24

Test voltage

Volts

13,5

13,5

Objective values

Watts

25 max.

25 max.

Luminous flux

P24W PS24W

500 + 10 / – 20 %

 

PX24W PSX24W

500 + 10 / – 15 %

 

PY24W PSY24W

300 + 15 / – 25 %

 

PR24W PSR24W

115 + 15 / – 25 %

 

Reference luminous flux at approximately

12 V

White: 345 lm

13,2 V

White: 465 lm

13,5 V

White: 500 lm

Amber: 300 lm

Red: 115 lm

CATEGORIES P24W, PX24W, PY24W, PR24W, PS24W, PSX24W, PSY24W and PSR24W — Sheet P24W/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 126

P24W, PY24W, PR24W, PS24W, PSY24W, PSR24W

a1

a2

b1, b2

c1

c2

Filament lamps of normal production

2,9

3,9

0,5

5,2

3,8

Standard filament lamps

1,5

1,7

0,25

4,7

3,8


PX24W, PSX24W

a1

a2

b1, b2

c1

c2

Filament lamps of normal production

1,9

1,9

0,35

5,0

4,0

Standard filament lamps

1,5

1,5

0,25

4,7

4,0

The filament position is checked in two mutually perpendicular planes, one of them being the plane through the lead-in wires.

The ends of the filament as defined on sheet P24W/2, note 6, shall lie between Z1 and Z2 and between the lines Z3 and Z4.

The filament shall lie entirely within the limits shown.

CATEGORY P27W — Sheet P27W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 127

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

27,9  (3)

 

27,9 ± 0,3

f

 

 

9,9

9,9 + 0 / – 2

Lateral deviation (2)

 

 

(3)

0,0 ± 0,4

β

75 ° (3)

90 °

105 ° (3)

90° ± 5°

Cap W2.5x16d in accordance with IEC Publication 60061 (sheet 7004-104-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

27

27

Test voltage

Volts

13,5

13,5

Objective values

Watts

32,1 max.

32,1 max.

Luminous flux

475 ± 15 %

 

Reference luminous flux: 475 lm at approximately 13,5 V

(1)

 The reference axis is defined with respect to the reference keys and is perpendicular to the reference plane.

(2)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis through the reference keys.

(3)

 To be checked by means of a ‘Box System’, sheet P27W/2.

CATEGORY P27W — Sheet P27W/2

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane and has an axis perpendicular, within ± 15°, to the plane through the centres of the keys and the reference axis, whether a filament lamp complies with the requirements.

Image 128

Reference

a

b

h

k

Dimension

3,5

3,0

11,9

1,0

Test procedures and requirements

1.   The filament lamp is placed in a holder capable of being rotated about its axis and having either a calibrated scale or fixed stops corresponding to the angular displacement tolerance limits. The holder is then so rotated that an end view of the filament is seen on the screen on to which the image of the filament is projected. The end view of the filament shall be obtained within the angular displacements tolerance limits.

2.   Side elevation

The filament lamp placed with the cap down, the reference axis vertical and the filament seen end-on, the projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘b’, having its centre at the theoretical position of the centre of the filament.

3.   Front elevation

The filament lamp placed with the cap down and the reference axis vertical, the filament lamp being viewed in a direction at right angles to the filament axis:

3.1.

The projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘h’, having its centre at the theoretical position of the centre of the filament.

3.2.

The centre of the filament shall not be offset by more than distance ‘k’ from the reference axis.

CATEGORY P27/7W — Sheet P27/7W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 129

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

27,9  (3)

 

27,9 ± 0,3

f

 

 

9,9

9,9 + 0 / – 2

Lateral deviation (2)

 

 

(3)

0,0 ± 0,4

x (4)

 

5,1  (3)

 

5,1 ± 0,5

y (4)

 

0,0  (3)

 

0,0 ± 0,5

β

75 ° (3)

90 °

105 ° (3)

90° ± 5°

Cap W2,5x16q in accordance with IEC Publication 60061 (sheet 7004-104-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

27

7

27

7

Test voltage

Volts

13,5

13,5

Objective values

Watts

32,1 max.

8,5 max.

32,1 max.

8,5 max.

Luminous flux

475 ± 15 %

36 ± 15 %

 

Reference luminous flux: 475 and 36 lm at approximately 13,5 V

(1)

 The reference axis is defined with respect to the reference keys and is perpendicular to the reference plane.

(2)

 Maximum lateral deviation of the major (high wattage) filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis through the reference keys.

(3)

 To be checked by means of a ‘Box-System’, sheets P27/7W/2 and 3.

(4)

 ‘x’ and ‘y’ denote the offset of the axis of the minor (low wattage) filament with respect to the axis of the major (high wattage) filament.

CATEGORY P27/7W — Sheet P27/7W/2

Screen projection requirements

This test is used to determine, by checking whether:

(a)

the major (high wattage) filament is correctly positioned relative to the reference axis and reference plane and has an axis perpendicular, within ± 15°, to the plane through the centres of the keys and the reference axis; and whether:

(b)

the minor (low wattage) filament is correctly positioned relative to the major (high wattage) filament, whether a filament lamp complies with the requirements.

Test procedure and requirements

1.   The filament lamp is placed in a holder capable of being rotated about its axis and having either a calibrated scale or fixed stops corresponding to the angular displacement tolerance limits. The holder is then so rotated that an end view of the major filament is seen on the screen on which the image of the filament is projected. The end view of that filament shall be obtained within the angular displacement tolerance limits.

2.   Side elevation

The filament lamp placed with the cap down, the reference axis vertical, the reference key to the right and the major filament seen end-on:

2.1.

the projection of the major filament shall lie entirely within a rectangle of height ‘a’ and width ‘b’, having its centre at the theoretical position of the centre of the filament;

2.2.

the projection of the minor filament shall lie entirely within a rectangle of width ‘c’ and height ‘d’ having its centre at a distance ‘u’ above the theoretical position of the centre of the major filament.

3.   Front elevation

The filament lamp being placed with the cap down and the reference axis vertical, the filament lamp being viewed in a direction at right angles to axis of the major filament:

3.1.

the projection of the major filament shall lie entirely within a rectangle of height ‘a’ and width ‘h’, centred on the theoretical position of the centre of the filament;

3.2.

the centre of the major filament shall not be offset by more than distance ‘k’ from the reference axis;

3.3.

the centre of the minor filament axis shall not be offset from the reference axis by more than ± 2 mm (± 0,4 mm for standard filament lamps).

CATEGORY P27/7W — Sheet P27/7W/3

Side elevation

Image 130

Reference

a

b

c

d

u

Dimensions

3,5

3,0

4,8

5,1

Front elevation

Image 131

Reference

a

h

k

Dimensions

3,5

11,9

1,0

CATEGORIES PC16W, PCY16W AND PCR16W — Sheet PC16W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 132
1 2 3

CATEGORIES PC16W, PCY16W AND PCR16W — Sheet PC16W/2

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 (7)

e (4)  (5)

 

18,5

 

18,5

f (4)  (5)

 

4,0

 

4,0 ± 0,2

α (6)

54 °

 

 

54° min.

PC16W

Cap PU20d-1

in accordance with IEC Publication 60061 (sheet 7004-157-1)

PCY16W

Cap PU20d-2

PCR16W

Cap PU20d-7

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

16

16

Test voltage

Volts

13,5

13,5

Objective values

Watts

17 max.

17 max.

Luminous flux

PC16W

300 ± 15 %

 

PCY16W

180 ± 20 %

 

PCR16W

70 ± 20 %

 

Reference luminous flux at approximately

13,5 V

White: 300 lm

Amber: 180 lm

Red: 70 lm

CATEGORIES PC16W, PCY16W AND PCR16W — Sheet PC16W/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 133

 

a1

a2

b1, b2

c1

c2

Filament lamps of normal production

2,9

3,9

0,5

5,2

3,8

Standard filament lamps

1,5

1,7

0,25

4,7

3,8

The filament position is checked in two mutually perpendicular planes, one of them being the plane through the lead-in wires.

The ends of the filament as defined on sheet PC16W/2, note 5, shall lie between Z1 and Z2 and between the lines Z3 and Z4.

The filament shall lie entirely within the limits shown.

CATEGORY PR21W — Sheet PR21W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 134

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

(4)

e

12 V

 

31,8  (3)

 

31,8 ± 0,3

24 V

30,8

31,8

32,8

 

f

12 V

5,5

6,0

7,0

6,0 ± 0,5

Lateral deviation (1)

12 V

 

 

(3)

0,3 max

24 V

 

 

1,5

 

β

75 °

90 °

105 °

90° ± 5°

Cap BAW15s in accordance with IEC Publication 60061 (sheet 7004-11E-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

24

12

Watts

21

21

Test voltage

Volts

13,5

28,0

 

Objective values

Watts

26,5 max.

29,7 max.

26,5 max.

Luminous flux

110 ± 20 %

 

Reference luminous flux at approximately 13,5 V

White: 460

lmRed: 110 lm

 

(1)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis of the reference pin.

(2)

 The light emitted from normal production lamps shall be red (see also note 4).

(3)

 To be checked by means of a ‘Box-System’, sheet P21W/2.

(4)

 The light emitted from standard filament lamps shall be white or red.

(5)

 In this view the filament of the 24 V type may be straight or V-shaped. This shall be indicated in the application of approval. If it is straight, the screen projection requirements, sheet P21W/2, apply. If it is V-shaped, the filament ends shall be at the same distance within ± 3 mm from the reference plane.

CATEGORY PR21/4W — Sheet PR21/4W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 135

Dimensions in mm

Filament lamps of normal production (12)

Standard filament lamp

min.

nom.

max.

 (13)

e

 

31,8  (8)

 

31,8 ± 0,3

f

 

 

7,0

7,0 + 0 / – 2

Lateral deviation

 

 

 (8)

0,3 max. (9)

x, y

 (8)

2,8 ± 0,5

β

75 ° (8)

90 ° (8)

105 ° (8)

90° ± 5°

Cap BAU15d in accordance with IEC Publication 60061(sheet 7004-19-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

24  (11)

12

Watts

21

4

21

4

21 / 4

Test voltage

Volts

13,5

28,0

13,5

Objective values

Watts

26,5 max.

5,5 max.

29,7 max.

8,8 max.

26,5 / 5,5 max.

Luminous flux ± %

105

4

105

5

 

20

25

20

25

 

Reference luminous fluxat approximately 13,5 V

White: 440 lm and 15 lm

Red: 105 lm and 4 lm

CATEGORY PR21/5W — Sheet PR21/5W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament.

Image 136

Dimensions in mm

Filament lamps of normal production (17)

Standard filament lamp

min.

nom.

max.

 (18)

e

12 V

 

31,8  (14)

 

31,8 ± 0,3

24 V

30,8

31,8

32,8

 

f

12 V

 

 

7,0

7,0 + 0 / – 2

Lateral deviation (15)

12 V

 

 

 (14)

0,3 max.

24 V

 

 

1,5

 

x, y

12 V

 

 (14)

 

2,8 ± 0,3

x

24 V (16)

–1,0

0

1,0

 

y

24 V (16)

1,8

2,8

3,8

 

β

 

75 °

90 °

105 °

90° ± 5°

Cap BAW15d in accordance with IEC Publication 60061 (sheet 7004-11E-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

24

12

Watts

21

5

21

5

21 / 5

Test voltage

Volts

13,5

28,0

13,5

Objective values

Watts

26,5 max.

6,6 max.

29,7 max.

11,0 max.

26,5 and 6,6 max.

Luminous flux ± %

105

8

105

10

 

 

20

25

20

25

 

Reference luminous flux at approximately 13,5 V

White: 440 lm and 35 lm

Red: 105 lm and 8 lm

CATEGORY PR27/7W — Sheet PR27/7W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 137

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

(6)

e

 

27,9  (3)

 

27,9 ± 0,3

f

 

 

9,9

9,9 + 0 / – 2

Lateral deviation (2)

 

 

(3)

0,0 ± 0,4

x (4)

 

5,1  (3)

 

5,1 ± 0,5

y (4)

 

0,0  (3)

 

0,0 ± 0,5

β

75 ° (3)

90 °

105 ° (3)

90° ± 5°

Cap WU2,5x16 in accordance with IEC Publication 60061 (sheet 7004-104D-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

27

7

27

7

Test voltage

Volts

13,5

13,5

Objective values

Watts

32,1 max.

8,5 max.

32,1 max.

8,5 max.

Luminous flux

110 ± 20 %

9 ± 20 %

 

Reference luminous flux at approximately 13,5 V

White: 475 and 36 lm

Red: 110 and 9 lm

(1)

 The reference axis is defined with respect to the reference keys and is perpendicular to the reference plane.

(2)

 Maximum lateral deviation of the major (high wattage) filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis through the reference keys.

(3)

 To be checked by means of a ‘Box-System’, sheets P27/7W/2 and 3.

(4)

 ‘x’ and ‘y’ denote the offset of the axis of the minor (low wattage) filament with respect to the axis of the major (high wattage) filament.

(5)

 The light emitted from normal production lamps shall be red (see also note 6).

(6)

 The light emitted from standard filament lamps shall be white or red.

CATEGORY PSX26W — Sheet PSX26W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Figure 1

Main drawing (1)

Image 138

Figure 2

Metal free zone (3)

Image 139

(1)

 The reference plane is defined by the meeting points of the cap-holder fit.

(2)

 No actual filament diameter restrictions apply but the objective is d max. = 1,1 mm.

(3)

 No opaque parts other than filament turns shall be located in the shaded area indicated in Figure 2. This applies to the rotational body within the angles α1 + α2.

CATEGORY PSX26W — Sheet PSX26W/2

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

e (5)

24,0  (4)

24,0 ± 0,25

f (5)

4,2  (4)

4,2 ± 0,25

α1 (6)

35,0° min.

35,0° min.

α2 (6)

58,0° min.

58,0° min.

Cap PG18.5d-3

in accordance with IEC Publication 60061 (sheet 7004-147-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Voltage

V

12

12

Wattage

W

26

26

Test voltage

V

13,5

13,5

Objective values

Wattage

W

26 max.

26 max.

Luminous flux

lm

500

 

±

+ 10 % / – 10 %

 

Reference luminous flux at approximately 13,2 V

465 lm

Reference luminous flux at approximately 13,5 V

500 lm

CATEGORY PSX26W — Sheet PSX26W/3

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane, whether a filament lamp complies with the requirements.

Image 140

 

a1

a2

b1, b2

c1

c2

Filament lamps of normal production

1,7

1,7

0,30

5,0

4,0

Standard filament lamps

1,5

1,5

0,25

4,7

4,0

The filament position is checked in two mutually perpendicular planes, one of them being the plane through the lead-in wires.

The ends of the filament as defined on sheet PSX26W/2, note 4, shall lie between Z1 and Z2 and between the lines Z3 and Z4.

The filament shall lie entirely within the limits shown.

CATEGORY PY21W — Sheet PY21W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 141

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

(4)

e

12 V

 

31,8  (3)

 

31,8 ± 0,3

24 V

30,8

31,8

32,8

 

f

12 V

 

 

7,0

7,0 + 0 / – 2

Lateral deviation (1)

12 V

 

 

(2)

0,3 max.

24 V

 

 

1,5

 

β

75 °

90 °

105 °

90° ± 5°

Cap BAU15s in accordance with IEC Publication 60061 (sheet 7004-19-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

24

12

Watts

21

21

Test voltage

Volts

13,5

28,0

13,5

Objective values

Watts

26,5 max.

29,7 max.

26,5 max.

Luminous flux

280 ± 20 %

 

Reference luminous flux at approximately 13,5 V

White: 460 lm

 

Amber: 280 lm

(1)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis of the reference pin.

(2)

 The light emitted from production lamps shall be amber (see also note 4).

(3)

 To be checked by means of a ‘Box-System’; sheet P21W/2.

(4)

 The light emitted from standard filament lamps shall be amber or white.

(5)

 In this view the filament of the 24 V type may be straight or V-shaped. This shall be indicated in the application of approval. If it is straight, the screen projection requirements, sheet P21W/2, apply. If it is V-shaped, the filament ends shall be at the same distance within ± 3 mm from the reference plane.

CATEGORY PY27/7W — Sheet PY27/7W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 142

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

(6)

e

 

27,9  (3)

 

27,9 ± 0,3

f

 

 

9,9

9,9 + 0 / – 2

Lateral deviation (2)

 

 

(3)

0,0 ± 0,4

x (4)

 

5,1  (3)

 

5,1 ± 0,5

y (4)

 

0,0  (3)

 

0,0 ± 0,5

β

75 ° (3)

90 °

105 ° (3)

90° ± 5°

Cap WX2,5x16q in accordance with IEC Publication 60061 (sheet 7004-104A-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

27

7

27

7

Test voltage

Volts

13,5

13,5

Objective values

Watts

32,1 max.

8,5 max.

32,1 max.

8,5 max.

Luminous flux

280 ± 15 %

21 ± 15 %

 

Reference luminous flux at approximately 13,5 V

White: 475 and 36 lm

Amber: 280 and 21 lm

 

(1)

 The reference axis is defined with respect to the reference keys and is perpendicular to the reference plane.

(2)

 Maximum lateral deviation of the major (high wattage) filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis through the reference keys.

(3)

 To be checked by means of a ‘Box-System’, sheets P27/7W/2 and 3.

(4)

 ‘x’ and ‘y’ denote the offset of the axis of the minor (low wattage) filament with respect to the axis of the major (high wattage) filament.

(5)

 The light emitted from filament lamps of normal production shall be amber (see also note 6).

(6)

 The light emitted from standard filament lamps shall be amber or white.

CATEGORY R2 — Sheet R2/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 143

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

 

Filament lamps of normal production

Standard filament lamp

Rated values

Volts

6  (4)

12  (4)

24  (4)

12  (4)

Watts

45

40

45

40

55

50

45

40

Test voltage

Volts

6,3

13,2

28,0

13,2

Objectivevalues

Watts

53 max.

47 max.

57 max.

51 max.

76 max.

69 max.

52

+ 0 %

– 10 %

46

± 5 %

Luminous flux

720 min.

570

± 15 %

860 min.

675

± 15 %

1 000 min.

860

± 15 %

 

Measuring flux (5)

450

450

450

 

Reference luminous flux at approximately 12 V

700

450

(1)

 The reference axis is perpendicular to the reference plane and passes through the centre of the 45 mm cap diameter.

(2)

 The colour of the light emitted shall be white or selective-yellow.

(3)

 No part of the cap shall, by reflection of light emitted by the passing-beam filament, throw any stray rising ray when the filament lamp is in the normal operating position on the vehicle.

(4)

 The values indicated on the left and on the right refer to the driving-beam filament and the passing-beam filament respectively.

(5)

 Measuring luminous flux for measurements according to paragraph 3.9 of this Regulation.

CATEGORY R2 — Sheet R2/2

Position and dimensions (in mm) of shield and filaments

The drawings are not mandatory with respect to the design of the shield and filaments.

Image 144

CATEGORY R2 — Sheet R2/3

FILAMENTS AND SHIELD POSITION AND DIMENSIONS (19)

Dimensions in mm

Tolerance

Filament lamps of normal production

Standard filament lamp

6 V 12 V 24 V

12 V

a

0,60

± 0,35

± 0,15

b1 / 30,0 (20)

b1 / 33,0

0,20

b1 / 30,0 mv (21)

± 0,35

± 0,15

b2 / 30,0 (20)

b2 / 33,0

0,20

b2 / 30,0 mv (21)

± 0,35

± 0,15

c / 30,0 (20)

c / 33,0

0,50

c / 30,0 mv (21)

± 0,30

± 0,15

e

6 V, 12 V

24 V

28,5

28,8

± 0,35

± 0,15

f

6 V, 12 V

24 V

1,8

2,2

± 0,40

± 0,20

g

0

± 0,50

± 0,30

h / 30,0 (20)

h 33,0

0

h / 30,0 mv (21)

± 0,50

± 0,30

1 / 2 (p – q)

0

± 0,60

± 0,30

lc

5,5

± 1,50

± 0,50

γ (22)

15° nom.

 

 

Cap P45t-41 in accordance with IEC Publication 60061 (sheet 7004-95-5)

CATEGORY R5W and RR5W — Sheet R5W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 145

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

(4)

e

17,5

19,0

20,5

19,0 ± 0,3

Lateral deviation (2)

 

 

1,5

0,3 max.

β

60 °

90 °

120 °

90° ± 5°

Cap:

R5W:

BA15s

in accordance with IEC Publication 60061

(sheet 7004-11A-9) (1)

RR5W:

BAW15s

(sheet 7004-11E-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6  (5)

12

24

12

Watts

5

5

Test voltage

Volts

6,75

13,5

28,0

13,5

Objective values

Watts

5,5 max.

7,7 max.

5,5 max.

Luminous

R5W

50 ± 20 %

 

flux

RR5W

(5)

12 ± 25 %

 

Reference luminous flux at approximately 13,5 V

White: 50 lm

Red: 2 lm

(1)

 Filament lamps with cap BA15d may be used for special purposes; they have the same dimensions.

(2)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis of the reference pin.

(3)

 The light emitted from standard filament lamps shall be white for category R5W; white or red for category RR5W.

(4)

 The light emitted from filament lamps of normal production shall be white for category R5W and red for category RR5W (see also note 4).

(5)

 Within RR5W no 6 V rated voltage type specified.

CATEGORIES R10W, RY10W AND RR10W — Sheet R10W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 146

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

(4)

e

17,5

19,0

20,5

19,0 ± 0,3

Lateral deviation (2)

 

 

1,5

0,3 max.

β

60 °

90 °

120 °

90° ± 5°

Cap:

R10W:

BA15s

in accordance with IEC Publication 60061

(sheet 7004-11A-9) (1)

RY10W:

BAU15s

(sheet 7004-19-2)

RR10W:

BAW15s

(sheet 7004-11E-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6  (3)

12

24

12

Watts

10

10

Test voltage

Volts

6,75

13,5

28

13,5

Objective values

Watts

R10W RY10W

11 max.

14 max.

11 max.

RR10W

(5)

11 max.

11 max.

Luminous flux

R10W

125 ± 20 %

 

RY10W

75 ± 20 %

 

RR10W

(5)

30 ± 25 %

 

Reference luminous flux at approximately 13,5 V

White: 125 lm

Amber: 75 lm

Red: 30 lm

(1)

 Filament lamps R10W with cap BA15d may be used for special purposes; they have the same dimensions.

(2)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis of the reference pin.

(3)

 The light emitted from filament lamps of normal production shall be white for category R10W, amber for category RY10W and red for category RR10W (see also note 4)

(4)

 The light emitted from standard filament lamps shall be white for category R10W; white or amber for category RY10W; white or red for category RR10W.

(5)

 Within RR10W no 6 V rated voltage type specified.

CATEGORIES S1 AND S2 — Sheet S1/S2/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

FILAMENT LAMPS FOR MOTORCYCLES

Image 147
1 2 3 4

CATEGORIES S1 AND S2 — Sheet S1/S2/2

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

32,35

32,70

33,05

32,7 ± 0,15

f

1,4

1,8

2,2

1,8 ± 0,2

l

4,0

5,5

7,0

5,5 ± 0,5

c (5)

–0,2

0,5

0,8

0,5 ± 0,15

b (5)

–0,15

0,2

0,55

0,2 ± 0,15

a (5)

0,25

0,6

0,95

0,6 ± 0,15

h

–0,5

0

0,5

0 ± 0,2

g

–0,5

0

0,5

0 ± 0,2

β (5)  (6)

– 2°30′

0 °

+ 2°30′

0° ± 1°

Cap BA20d in accordance with IEC Publication 60061 (sheet 7004-12-7)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

S1

6 (7)

12  (7)

6

S2

12

Watts

S1

25

25

25

25

25

25

S2

35

35

35

35

35

35

Test voltage

Volts

S1

6,75

13,5

6,75

S2

6,3

13,5

13,5

Objective values

Watts

S1

25 ± 5 %

25 ± 5 %

25 ± 5 %

25 ± 5 %

25 ± 5 %

25 ± 5 %

S2

35 ± 5 %

35 ± 5 %

35 ± 5 %

35 ± 5 %

35 ± 5 %

35 ± 5 %

Luminous flux

S1

435 ± 20 %

315 ± 20 %

435 ± 20 %

315 ± 20 %

 

S2

650 ± 20 %

465 ± 20 %

650 ± 20 %

465 ± 20 %

 

Reference luminous flux

S1

at approximately

6 V

398

284

S2

at approximately

12 V

568

426

13,2 V

634

457

13,5 V

650

465

CATEGORY S3 — Sheet S3/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

FILAMENT LAMP FOR MOPEDS

Image 148

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e (2)

19,0

19,5

20,0

19,5 ± 0,25

f

6 V

 

 

3,0

2,5 ± 0,5

12 V

 

 

4,0

 

h1, h2 (3)

–0,5

0

0,5

0 ± 0,3

Cap P26s in accordance with IEC Publication 60061 (sheet 7004-36-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6

12

6

Watts

15

15

Test voltage

Volts

6,75

13,5

6,75

Objective values

Watts

15 ± 6 %

15 ± 6 %

Luminous flux

240 ± 15 %

 

Reference luminous flux: 240 lm at approximately 6,75 V

(1)

 The colour of the light emitted shall be white or selective-yellow.

(2)

 Distance related to the luminous centre.

(3)

 Lateral deviation of filament axis with respect to the reference axis. It is sufficient to check this deviation in two mutually perpendicular planes.

CATEGORY T1.4W — Sheet T1.4W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 149

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

7,6

8,3

9,0

8,3 ± 0,35

Lateral deviation (1)

 

 

0,7

0,35 max

β

55 °

70 °

85 °

70° ± 5°

Cap P11.5d in accordance with IEC Publication 60061 (sheet 7004-79-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

1,4

1,4

Test voltage

Volts

13,5

13,5

Objective values

Watts

1,54 max.

1,54 max.

Luminous flux

8 ± 15 %

 

Reference luminous flux: 8 lm at approximately 13,5 V

(1)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(2)

 The reference axis is perpendicular to the reference plane and passes through the centre of the circle of diameter ‘M’.

CATEGORY T4W — Sheet T4W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 150

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

13,5

15,0

16,5

15,0 ± 0,3

Lateral deviation (1)

 

 

1,5

0,5 max

β

 

90 °

 

90° ± 5°

Cap BA9s in accordance with IEC Publication 60061 (sheet 7004-14-9)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6

12

24

12

Watts

4

4

Test voltage

Volts

6,75

13,5

28,0

13,5

Objective values

Watts

4,4 max.

5,5 max.

4,4 max.

Luminous flux

3 ± 20 %

 

Reference luminous flux: 35 lm at approximately 13,5 V

(1)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis of pins.

(2)

 Over the entire length of the cap there shall be no projections or soldering extending beyond the permissible maximum diameter of the cap.

CATEGORY W2.3W — Sheet W2.3W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 151

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

10,3

10,8

11,3

10,8 ± 0,3

Lateral deviation (23)

 

 

1,0

0,5 max

β

–15 °

0 °

+15 °

0° ± 5°

Cap W2x4.6d in accordance with IEC Publication 60061 (sheet 7004-94-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

2,3

2,3

Test voltage

Volts

13,5

13,5

Objective values

Watts

2,5 max.

2,5 max.

Luminous flux

18,6 ± 20 %

 

Reference luminous flux: 18,6 lm at approximately 13,5 V

CATEGORY W3W — Sheet W3W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 152

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

11,2

12,7

14,2

12,7 ± 0,3

Lateral deviation (24)

 

 

1,5

0,5 max

β

–15 °

0 °

+15 °

0° ± 5°

Cap W2.1x9.5d in accordance with IEC Publication 60061 (sheet 7004-91-3)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6

12

24

12

Watts

3

3

Test voltage

Volts

6,75

13,5

28,0

13,5

Objective values

Watts

3,45 max.

4,6 max.

3,45 max.

Luminous flux

22 ± 30 %

 

Reference luminous flux: 22 lm at approximately 13,5 V

CATEGORY W5W, WY5W and WR5W — Sheet W5W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 153

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

(3)

e

11,2

12,7

14,2

12,7 ± 0,3

Lateral deviation (1)

 

 

1,5

0,5 max.

β

–15 °

0 °

+15 °

0° ± 5°

Cap W2.1x9.5d in accordance with IEC Publication 60061 (sheet 7004-91-3)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

6  (4)

12

24

12

Watts

5

5

Test voltage

Volts

6,75

13,5

28,0

13,5

Objective values

Watts

5,5 max.

7,7 max.

5,5 max.

Luminous flux

W5W

50 ± 20 %

 

WY5W

30 ± 20 %

 

WR5W

(4)

12 ± 25 %

 

Reference luminous flux at approximately 13,5 V

White: 50 lm

Amber: 30 lm

Red: 12 lm

(1)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(2)

 The light emitted from filament lamps of normal production shall be white for category W5W, amber for category WY5W and red for category WR5W (see also note 3).

(3)

 The light emitted from standard filament lamps shall be white for category W5W; white or amber for category WY5W; white or red for category WR5W.

(4)

 Within WR5W no 6 V rated voltage type specified.

CATEGORY W15/5W — Sheet W15/5W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

FILAMENT LAMP FOR MOTORCYCLES

Image 154

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

25,0  (25)

 

25,0 ± 0,3

f

 

 

7,5

7,5 + 0 / – 2

Lateral deviation (26)

 

 

 (25)

0,3 max.

x (27)

 

2,8  (25)

 

2,8 ± 0,3

y (27)

 

0,0  (25)

 

0,0 ± 0,3

β

–15 ° (25)

0 °

+15 ° (25)

0° ± 5°

Cap WZ3x16q in accordance with IEC Publication 60061 (sheet 7004-151-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

15

5

15

5

Test voltage

Volts

13,5

13,5

Objective values

Watts

19,1 max.

6,6 max.

19,1 max.

6,6 max.

Luminous flux

280 ± 15 %

35 ± 20 %

 

Reference luminous flux: 280 lm and 35 lm at approximately 13,5 V

CATEGORY W15/5W — Sheet W15/5W/2

Screen projection requirements

This test is used to determine, by checking whether:

(a)

the major filament is correctly positioned relative to the reference axis and reference plane and has an axis perpendicular, within ± 15°, to the plane through the axis X-X and the reference axis; and whether:

(b)

the minor filament is correctly positioned relative to the major filament, whether a filament lamp complies with the requirements.

Test procedure and requirements

1.   The filament lamp is placed in a holder capable of being rotated about its axis and having either a calibrated scale or fixed stops corresponding to the angular displacement tolerance limits. The holder is then so rotated that an end view of the major filament is seen on the screen on which the image of the filament is projected. The end view of that filament shall be obtained within the angular displacement tolerance limits. (± 15°).

2.   Side elevation

The filament lamp placed with the cap down, the reference axis vertical and the major filament seen end-on:

2.1.

the projection of the major filament shall lie entirely within a rectangle of height ‘a’ and width ‘b’, having its centre at the theoretical position of the centre of the filament;

2.2.

the projection of the minor filament shall lie entirely within a rectangle of width ‘c’ and height ‘d’ having its centre at a distance ‘u’ above the theoretical position of the centre of the major filament.

3.   Front elevation

The filament lamp being placed with the cap down and the reference axis vertical, the filament lamp being viewed in a direction at right angles to axis of the major filament:

3.1.

the projection of the major filament shall lie entirely within a rectangle of height ‘a’ and width ‘h’, centred on the theoretical position of the centre of the filament;

3.2.

the centre of the major filament shall not be offset by more than distance ‘k’ from the reference axis;

3.3.

the centre of the minor filament axis shall not be offset from the reference axis by more than ± 2 mm (± 0,4 mm for standard filament lamps).

CATEGORY W15/5W — Sheet W15/5W/3

(Dimensions in millimetres)

Side elevation

Image 155

Reference

a

b

c

d

u

Dimensions

3,3

2,8

4,8

2,8

Front elevation

Image 156

Reference

a

h

k

Dimensions

3,3

9,5

1,0

CATEGORY W16W — Sheet W16W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 157

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

18,3

20,6

22,9

20,6 ± 0,3

Lateral deviation (28)

 

 

1,0

0,5 max.

β

–15 °

0 °

+15 °

0° ± 5°

Cap W2.1x9.5d in accordance with IEC Publication 60061 (sheet 7004-91-3)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

16

16

Test voltage

Volts

13,5

13,5

Objective values

Watts

21,35 max.

21,35 max.

Luminous flux

310 ± 20 %

 

Reference luminous flux: 310 lm at approximately 13,5 V

CATEGORY W21W — Sheet W21W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 158

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

29,0  (30)

 

29,0 ± 0,3

f

 

 

7,5

7,5 + 0 / – 2

Lateral deviation (29)

 

 

 (30)

0,5 max.

β

–15 ° (30)

0 °

+15 ° (30)

0° ± 5°

Cap W3x16d in accordance with IEC Publication 60061 (sheet 7004-105-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

21

21

Test voltage

Volts

13,5

13,5

Objective values

Watts

26,5 max.

26,5 max.

Luminous flux

460 ± 15 %

 

Reference luminous flux: 460 lm at approximately 13,5 V

CATEGORY W21W — Sheet W21W/2

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane and has an axis perpendicular, within ± 15°, to the plane through the axis X-X and the reference axis, whether a filament lamp complies with the requirements.

Side elevation

Front elevation

Image 159


Reference

a

b

h

k

Dimension

3,5

3,0

9,5

1,0

Test procedures and requirements

1.   The filament lamp is placed in a holder capable of being rotated about its axis and having either a calibrated scale or fixed stops corresponding to the angular displacement tolerance limits, i.e. ± 15°. The holder is then so rotated that an end view of the filament is seen on the screen on to which the image of the filament is projected. The end view of the filament shall be obtained within the angular displacements tolerance limits (± 15°).

2.   Side elevation

The filament lamp placed with the cap down, the reference axis vertical and the filament seen end-on, the projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘b’, having its centre at the theoretical position of the centre of the filament.

3.   Front elevation

The filament lamp placed with the cap down and the reference axis vertical, the filament lamp being viewed in a direction at right angles to the filament axis:

3.1.

the projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘h’, having its centre at the theoretical position of the centre of the filament;

3.2.

the centre of the filament shall not be offset by more than distance ‘k’ from the reference axis.

CATEGORY W21/5W — Sheet W21/5W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 160

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

25,0  (31)

 

25,0 ± 0,3

f

 

 

7,5

7,5 + 0 / – 2

Lateral deviation (32)

 

 

 (31)

0,3 max.

x (33)

 

2,8  (31)

 

2,8 ± 0,3

y (33)

 

0,0  (31)

 

0,0 ± 0,3

β

–15 ° (31)

0 °

+15 ° (31)

0° ± 5°

Cap W3x16q in accordance with IEC Publication 60061 (sheet 7004-106-3)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

21

5

21

5

Test voltage

Volts

13,5

13,5

Objective values

Watts

26,5 max.

6,6 max.

26,5 max.

6,6 max.

Luminous flux

440 ± 15 %

35 ± 20 %

 

Reference luminous flux: 440 and 35 lm at approximately 13,5 V

CATEGORY W21/5W — Sheet W21/5W/2

Screen projection requirements

This test is used to determine, by checking whether:

(a)

the major filament is correctly positioned relative to the reference axis and reference plane and has an axis perpendicular, within ± 15°, to the plane through the axis X-X and the reference axis; and whether:

(b)

the minor filament is correctly positioned relative to the major filament, whether a filament lamp complies with the requirements.

Test procedure and requirements

1.   The filament lamp is placed in a holder capable of being rotated about its axis and having either a calibrated scale or fixed stops corresponding to the angular displacement tolerance limits. The holder is then so rotated that an end view of the major filament is seen on the screen on which the image of the filament is projected. The end view of that filament shall be obtained within the angular displacement tolerance limits (± 15°).

2.   Side elevation

The filament lamp placed with the cap down, the reference axis vertical and the major filament seen end-on:

2.1.

the projection of the major filament shall lie entirely within a rectangle of height ‘a’ and width ‘b’, having its centre at the theoretical position of the centre of the filament;

2.2.

the projection of the minor filament shall lie entirely within a rectangle of width ‘c’ and height ‘d’ having its centre at a distance ‘u’ above the theoretical position of the centre of the major filament.

3.   Front elevation

The filament lamp being placed with the cap down and the reference axis vertical, the filament lamp being viewed in a direction at right angles to axis of the major filament:

3.1.

the projection of the major filament shall lie entirely within a rectangle of height ‘a’ and width ‘h’, centred on the theoretical position of the centre of the filament;

3.2.

the centre of the major filament shall not be offset by more than distance ‘k’ from the reference axis;

3.3.

the centre of the minor filament axis shall not be offset from the reference axis by more than ± 2 mm (± 0,4 mm for standard filament lamps).

CATEGORY W21/5W — Sheet W21/5W/3

Side elevation

Image 161

Reference

a

b

c

d

u

Dimension

3,5

3,0

4,8

2,8

Front elevation

Image 162

Reference

a

h

k

Dimension

3,5

9,5

1,0

CATEGORIES WP21W AND WPY21W — Sheet WP21W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 163

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

27,9  (3)

 

27,9 ± 0,3

f

5,5

6,0

7,0

6,0 ± 0,5

Lateral deviation (2)

 

 

(3)

0,0 ± 0,4

β

75 ° (3)

90 °

105 ° (3)

90° ± 5°

Cap:

WP21W:

WY2.5x16d

in accordance with IEC Publication 60061

(sheet 7004-104B-1)

WPY21W:

WZ2.5x16d

(sheet 7004-104C-1)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

21

21

Test voltage

Volts

13,5

13,5

Objective values

Watts

26,5 max.

26,5 max.

Luminousflux

WP21W

460 ± 15 %

 

WPY21W

280 ± 20 %

 

Reference luminous flux at approximately 13,5 V

White: 460 lm

 

Amber: 280 lm

(1)

 The reference axis is defined with respect to the reference keys and is perpendicular to the reference plane.

(2)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis through the reference keys.

(3)

 To be checked by means of a ‘Box-System’; sheet WP21W/2.

(4)

 The light emitted from filament lamps of normal production shall be white for category WP21W and amber for category WPY21W (see also footnote 5).

(5)

 The light emitted from standard filament lamps shall be white for category WP21W and white or amber for category WPY21W.

CATEGORIES WP21W AND WPY21W — Sheet WP21W/2

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane and has an axis perpendicular, within ± 15°, to the plane through the centre line of the keys and the reference axis, whether a filament lamp complies with the requirements.

Side elevation

Front elevation

Image 164


Reference

a

b

h

k

Dimension

3,5

3,0

9,0

1,0

Test procedures and requirements

1.   The filament lamp is placed in a holder capable of being rotated about its axis and having either a calibrated scale or fixed stops corresponding to the angular displacement tolerance limits. The holder is then so rotated that an end view of the filament is seen on the screen on to which the image of the filament is projected. The end view of the filament shall be obtained within the angular displacements tolerance limits.

2.   Side elevation

The filament lamp placed with the cap down, the reference axis vertical and the filament seen end-on, the projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘b’, having its centre at the theoretical position of the centre of the filament.

3.   Front elevation

The filament lamp placed with the cap down and the reference axis vertical, the filament lamp being viewed in a direction at right angles to the filament axis:

3.1.

The projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘h’, having its centre at the theoretical position of the centre of the filament.

3.2.

The centre of the filament shall not be offset by more than distance ‘k’ from the reference axis.

CATEGORY WR21/5W — Sheet WR21/5W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 165

a

=

major (high wattage) filament

b

=

minor (low wattage) filament

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

25,0  (1)

 

25,0 ± 0,3

f

 

 

7,5

7,5 + 0 / – 2

Lateral deviation (2)

 

 

(1)

0,3 max.

x (3)

 

2,8  (1)

 

2,8 ± 0,3

y (3)

 

0,0  (1)

 

0,0 ± 0,3

β

–15 ° (1)

0 °

+15 ° (1)

0° ± 5°

Cap WY3x16q in accordance with IEC Publication 60061 (sheet 7004-106-3)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

21

5

21

5

Test voltage

Volts

13,5

13,5

Objective values

Watts

26,5 max.

6,6 max.

26,5 max.

6,6 max.

Luminous flux

105 ± 20 %

8 ± 25 %

 

Reference luminous flux at approximately 13,5 V

White: 440 lm and 35 lm

Red: 105 lm and 8 lm

(1)

 To be checked by means of a ‘Box-System’; sheets W21/5W/2 and 3.

(2)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(3)

 ‘x’ and ‘y’ denote the offset of the axis of the minor filament with respect to the axis of the major filament.

(4)

 The light emitted from normal production lamps shall be red (see also note 5).

(5)

 The light emitted from standard filament lamps shall be white or red.

CATEGORY WY2.3W — Sheet WY2.3W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 166

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

10,3

10,8

11,3

10,8 ± 0,3

Lateral deviation (1)

 

 

1,0

0,5 max

β

–15 °

0 °

+15 °

0° ± 5°

Cap W2x4.6d in accordance with IEC Publication 60061 (sheet 7004-94-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

2,3

2,3

Test voltage

Volts

13,5

13,5

Objective values

Watts

2,5 max.

2,5 max.

Luminous flux

11,2 ± 20 %

 

Reference luminous flux at approximately 13,5 V

White: 18,6 lm

 

Amber: 11,2 lm

(1)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(2)

 The light emitted from production lamps shall be amber (see also note 3).

(3)

 The light emitted from standard filament lamps shall be amber or white.

CATEGORY WY21W — Sheet WY21W/1

The drawings are intended only to illustrate the essential dimensions (in mm) of the filament lamp.

Image 167

Dimensions in mm

Filament lamps of normal production

Standard filament lamp

min.

nom.

max.

 

e

 

29,0  (2)

 

29,0 ± 0,3

f

 

 

7,5

7,5 + 0 / – 2

Lateral deviation (1)

 

 

(2)

0,5 max.

β

–15 °

0 °

+15 °

0° ± 5°

Cap WX3x16d in accordance with IEC Publication 60061 (sheet 7004-105-2)

ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS

Rated values

Volts

12

12

Watts

21

21

Test voltage

Volts

13,5

13,5

Objective values

Watts

26,5 max.

26,5 max.

Luminous flux

280 ± 20 %

 

Reference luminous flux at approximately 13,5 V

White: 460 lm

 

Amber: 280 lm

(1)

 Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(2)

 The light emitted from filament lamps of normal production shall be amber (see also note 4).

(3)

 To be checked by means of a ‘Box-System’; sheet WY21W/2.

(4)

 The light emitted from standard filament lamps shall be amber or white.

CATEGORY WY21W — Sheet WY21W/2

Screen projection requirements

This test is used to determine, by checking whether the filament is correctly positioned relative to the reference axis and reference plane and has an axis perpendicular, within ± 15°, to the plane through the axis X-X and the reference axis, whether a filament lamp complies with the requirements.

Side elevation

Front elevation

Image 168


Reference

a

b

h

k

Dimension

3,5

3,0

9,5

1,0

Test procedures and requirements

1.   The filament lamp is placed in a holder capable of being rotated about its axis and having either a calibrated scale or fixed stops corresponding to the angular displacement tolerance limits, i.e. ± 15°. The holder is then so rotated that an end view of the filament is seen on the screen on to which the image of the filament is projected. The end view of the filament shall be obtained within the angular displacements tolerance limits (± 15°).

2.   Side elevation

The filament lamp placed with the cap down, the reference axis vertical and the filament seen end-on, the projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘b’, having its centre at the theoretical position of the centre of the filament.

3.   Front elevation

The filament lamp placed with the cap down and the reference axis vertical, the filament lamp being viewed in a direction at right angles to the filament axis:

3.1.

The projection of the filament shall lie entirely within a rectangle of height ‘a’ and width ‘h’, having its centre at the theoretical position of the centre of the filament.

3.2.

The centre of the filament shall not be offset by more than distance ‘k’ from the reference axis.

(*1)  Tables, electrical and photometric characteristics:

 

Voltage is expressed in V;

 

Wattage is expressed in W;

 

Luminous flux is expressed in lm.

 

In a case that for a category of filament lamp more than one value of reference luminous flux is specified, the value at approximately 12 V for approval of a lighting device and 13,5 V for approval of a light-signalling device shall be applied unless otherwise specified by the regulation used for the approval of the device.

(*2)  Not for use in passing beam headlamps.

(*3)  Not for use in front fog lamps marked ‘B’ as defined in Regulation No 19.

(*4)  Not for use in Regulation No 112 headlamps.

(*5)  Not for use in headlamps other than Regulation 113 class C headlamps.

(1)  This dimension corresponds to a distance between two apertures of 3,5 mm diameter each bearing against one of the caps.

(2)  The filament shall be housed in a cylinder 19 mm long co-axial with the filament lamp and placed symmetrically about the filament lamp centre.

The diameter of the cylinder is for 6 V and 12 V filament lamps: d + 4 mm (for standard filament lamps: d + 2 mm) and for 24 V filament lamps: d + 5 mm, ‘d’ being the nominal diameter of the filament as stated by the manufacturer.

(3)  The deviation of the filament centre from the centre of the filament lamp shall not be more than ± 2,0 mm (for standard filament lamps: ± 0,5 mm) measured in the direction of the reference axis.

(4)  4,5 mm for 6 V filament lamps.

(5)  16,5 mm for 24 V filament lamps.

(6)  This dimension corresponds to a distance between two apertures of 3,5 mm diameter.

(7)  The position of the filament is checked by means of a ‘Box-System’; sheet C21W/2.

(5)  The eccentricity is measured only in the horizontal and vertical directions of the filament lamp as shown in the figure. The points to be measured are those where the projections of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(6)  The viewing direction is the perpendicular to the reference axis contained in the plane defined by the reference axis and the centre of the second pin of the cap.

(7)  Offset of filament in relation to bulb axis measured at 27,5 mm from the reference plane.

(8)  d: diameter of filament.

(9)  To be checked by means of a ‘Box System’, sheet H1/3.

(10)  The ends of the filament are defined as the points where, when the viewing direction is as defined in note 6 above, the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the reference axis.(special instructions for coiled-coil filaments are under consideration).

(6)  To be checked by means of a ‘Box-System’; sheet H3/4.

(7)  For standard filament lamps the points to be measured are those where the projection of the outside of the end turns crosses the filament axis.

(8)  The positions of the first and the last turn of the filament are defined by the intersections of the outside of the first and of the last light emitting turn, respectively, with the plane parallel to and 18 mm distant from the reference plane. (Additional instructions for coiled-coil filament are under consideration).

(6)  The value indicated in the left hand column relate to the driving-beam filament. Those indicated in the right-hand column relate to the passing beam filament.

(7)  Measuring luminous flux for measuring according to paragraph 3.9 of this Regulation.

(*6)   ‘…/26’ means dimension to be measured at the distance from the reference plane indicated in mm after the stroke.

(*7)   ‘29,5 mv’ or ‘30,0 mv’ means the value measured at a distance of 29,5 or 30,0 mm from the reference plane.

(8)  Plane V-V is the plane perpendicular to the reference plane and passing through the reference axis and through the intersection of the circle of diameter ‘M’ with the axis of the reference lug.

(9)  Plane H-H is the plane perpendicular to both the reference plane and plane V-V and passing through the reference axis.

(10)  30,0 mm for the 24-Volt type.

(11)  The end turns of the filament are defined as being the first luminous turn and the last luminous turn that are at substantially the correct helix angle. For coiled-coil filaments, the turns are defined by the envelope of the primary coil.

(12)  For the passing-beam filament, the points to be measured are the intersections, seen in direction 1, of the lateral edge of the shield with the outside of the end turns defined under footnote 11.

(13)   ‘e’ denotes the distance from the reference plane to the beginning of the passing beam filament as defined above.

(14)  For the driving-beam filament the points to be measured are the intersections, seen in direction 1, of a plane, parallel to plane H-H and situated at a distance of 0,8 mm below it, with the end turns defined under footnote 11.

(9)  The ends of the filament are defined as the points where, when the viewing direction is direction A as shown in Figure 1 on sheet H7/1, the projection of the outside of the end turns crosses the filament axis. (Special instructions for coiled-coil filaments are under consideration).

(10)  To be checked by means of a ‘Box System’, sheet H7/4.

(11)  The offset of the filament with respect to the reference axis is measured only in viewing directions A and B as shown in Figure 1 in sheet H7/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(12)  Offset of filament in relation to bulb axis measured in two planes parallel to the reference plane where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(11)  The ends of the filament are defined as the points where, when the viewing direction is direction A as shown in Figure 1 on sheet H8/1, the projection of the outside of the end turns crosses the filament axis.

(12)  To be checked by means of a ‘Box System’; sheet H8/4.

(9)  The viewing direction is direction A as shown in Figure 1 on sheet H9/1.

(10)  The ends of the filament are defined as the points where, when the viewing direction is as defined in note 9 above, the projection of the outside of the end turns crosses the filament axis.

(11)  To be checked by means of a ‘Box System’; sheet H9/4.

(12)  The eccentricity is measured only in viewing directions A and B as shown in Figure 1 on sheet H9/1. The points to be measured are those where the projection of the outside of the end turns nearest or furthest from the reference plane crosses the filament axis.

(8)  Dimensions shall be checked with O-ring removed.

(9)  The viewing direction is direction (*8)/B as shown in the figure on sheet H10/1.

(10)  The ends of the filament are defined as the points where, when the viewing direction (*8) as defined in note 9 above, the projection of the outside of the end turns crosses the filament axis.

(11)  To be checked by means of a ‘Box-System’, sheet H10/3 (*8).

(12)  The eccentricity is measured only in viewing directions (*8) A and B as shown in the figure on sheet H10/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(*8)  Manufacturers may choose another set of perpendicular viewing directions. The viewing directions specified by the manufacturer are to be used by the testing laboratory when checking filament dimensions and position.

(11)  The ends of the filament are defined as the points where, when the viewing direction is View A as shown in Figure 1 on sheet H11/1, the projection of the outside of the end turns crosses the filament axis.

(12)  To be checked by means of a ‘Box System’; sheet H11/4.

(8)  Dimensions shall be checked with O-ring removed.

(9)  The viewing direction is direction A as shown in the figure on sheet H12/1.

(10)  The ends of the filament are defined as the points where, when the viewing direction as defined in note 9 above, the projection of the outside of the end turns crosses the filament axis.

(11)  To be checked by means of a ‘Box-System’; sheet H12/3.

(12)  Dimensions h1 and h2 are measured in viewing direction A, dimension h3 in direction C and dimension h4 in direction B as shown in the figure on sheet H12/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(13)  Dimension k is measured only in viewing direction A.

(16)  The ends of the filament are defined as the points where, when the viewing direction is direction A as shown on sheet H13/1, the projection of the outside of the end turns crosses the filament axis.

(17)  d1 is the actual diameter of the passing-beam filament. d2 is the actual diameter of the driving-beam filament.

(18)  The values indicated in the left-hand columns relate to the passing-beam filament and those indicated in the right-hand columns to the driving-beam filament.

(8)  The ends of the filaments are defined as the points where, when the viewing direction is direction A as shown in Figure 1 on sheet H14/1, the projection of the outside of the end turns crosses the filaments axis.

(9)   ‘f1’ represents the length of the passing-beam filament and ‘f2’ represents the length of the driving-beam filament.

(10)  To be checked by means of a ‘Box system’; sheet H14/4.

(5)  The values indicated in the left-hand columns relate to the low wattage filament. Those indicated in the right-hand columns relate to the high wattage filament.

(*9)   ‘…/26,0’ means dimension to be measured at the distance from the reference plane indicated in mm after the stroke.

(*10)   ‘31,0 mv’ means the value measured at a distance of 31,0 mm from the reference plane.

(6)  Plane V-V is the plane perpendicular to the reference plane and passing through the reference axis and through the axis of the reference lug.

(7)  Plane H-H is the plane perpendicular to the reference plane and plane V-V passing through the reference axis.

(8)  The end turns of the filament are defined as being the first luminous turn and the last luminous turn that are at substantially the correct helix angle.

(9)  For the high wattage filament, the points to be measured are the intersections, seen in direction 1, of the lateral edge of the shield with the outside of the end turns defined under footnote 8.

(10)   ‘e’ denotes the distance from the reference plane to the beginning of the driving beam filament as defined above.

(11)  For the low wattage filament the points to be measured are the intersections, seen in direction 1, of a plane, parallel to plane H-H and situated at a distance of 1,8 mm above it, with the end turns defined under footnote 8.

(12)  34,0 for the 24 V type.

(13)  24,5 for the 24 V type.

(11)  The ends of the filament are defined as the points where, when the viewing direction is direction A as shown in Figure 1 on sheet H16/1, the projection of the outside of the end turns crosses the filament axis.

(12)  To be checked by means of a ‘Box System’; sheet H16/4.

(5)  Glass bulb shall be optically distortion free within the angles γ1 and γ2. This requirement applies to the whole bulb circumference within the angles γ1 and γ2.

(6)  To be checked by means of a ‘Box System’, sheet H27W/3.

(7)  For standard filament lamps, the points to be measured are those where the projection of the outside of the end turns crosses the filament axis.

(8)  The ends of the filament are defined by the intersections of the outside of the first and of the last light emitting turn, respectively, with the plane parallel to and 31,75 mm from the reference plane.

(8)  The eccentricity is measured only in viewing directions (*11) A and B as shown in the figure on sheet HB3/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(9)  The viewing direction is direction (*11) B as shown in the figure on sheet HB3/1.

(10)  To be checked by means of a ‘Box-System’; sheet HB3/4 (*11).

(11)  The ends of the filament are defined as the points where, when the viewing direction (*11) as defined in note (9) above, the projection of the outside of the end turns crosses the filament axis.

(12)  Dimensions shall be checked with O-ring removed.

(13)  Filament lamp HB3 shall be equipped with the right-angle cap and filament lamp HB3A with the straight cap.

(*11)  Manufacturers may choose another set of perpendicular viewing directions. The viewing directions specified by the manufacturer are to be used by the testing laboratory when checking filament dimensions and position.

(9)  The eccentricity is measured only in viewing directions (*12) A and B as shown in the figure on sheet HB4/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(10)  The viewing direction is direction (*12) B as shown in the figure on sheet HB4/1.

(11)  To be checked by means of a ‘Box-System’; sheet HB4/4 (*12).

(12)  The ends of the filament are defined as the points where, when the viewing direction (*12) as defined in note 10 above, the projection of the outside of the end turns crosses the filament axis.

(13)  Dimensions shall be checked with O-ring removed.

(14)  Filament lamp HB4 shall be equipped with the right-angle cap and filament lamp HB4A with the straight cap.

(*12)  Manufacturers may choose another set of perpendicular viewing directions. The viewing directions specified by the manufacturer are to be used by the testing laboratory when checking filament dimensions and position.

(7)  The eccentricity is measured only in viewing directions A and B as shown in the figure on sheet HIR1/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(8)  The viewing direction is direction B as shown in the figure on sheet HIR1/1.

(9)  To be checked by means of a ‘Box-System’; sheet HIR1/3.

(10)  The ends of the filament are defined as the points where, when the viewing direction as defined in note 8 above, the projection of the outside of the end turns crosses the filament axis.

(11)  Dimensions shall be checked with O-ring mounted.

(7)  The eccentricity is measured only in viewing directions A and B as shown in the figure on sheet HIR2/1. The points to be measured are those where the projection of the outside of the end turns nearest to or furthest from the reference plane crosses the filament axis.

(8)  The viewing direction is direction B as shown in the figure on sheet HIR2/1.

(9)  To be checked by means of a ‘Box-System’; sheet HIR2/3.

(10)  The ends of the filament are defined as the points where, when the viewing direction as defined in note 8 above, the projection of the outside of the end turns crosses the filament axis.

(11)  Dimensions shall be checked with O-ring removed.

(6)  The values indicated in the left hand column relate to the driving-beam. Those indicated in the right-hand column relate to the passing beam.

(7)  Measuring luminous flux for measuring according to paragraph 3.9 of this Regulation.

(*13)   ‘…/26’ means dimension to be measured at the distance from the reference plane indicated in mm after the stroke.

(*14)   ‘29,5 mv’ means the value measured at a distance of 29,5 mm from the reference plane.

(8)  Plane V-V is the plane perpendicular to the reference plane and passing through the reference axis and through the intersection of the circle of diameter ‘M’ with the axis of the reference lug.

(9)  Plane H-H is the plane perpendicular to both the reference plane and plane V-V and passing through the reference axis.

(10)  (Blank).

(11)  The end turns of the filament are defined as being the first luminous turn and the last luminous turn that are at substantially the correct helix angle. For coiled-coil filaments, the turns are defined by the envelope of the primary coil.

(12)  For the passing-beam filament, the points to be measured are the intersections, seen in direction 1, of the lateral edge of the shield with the outside of the end turns defined under footnote 11.

(13)   ‘e’ denotes the distance from the reference plane to the beginning of the passing beam filament as defined above.

(14)  For the driving-beam filament the points to be measured are the intersections, seen in direction 1, of a plane, parallel to plane H-H and situated at a distance of 0,8 mm below it, with the end turns defined under footnote 11.

(*15)  To be checked by means of the ‘box system’, sheet HS2/3.

(6)  In order to avoid rapid filament failure, the supply voltage shall not exceed 8,5 V for 6 V filament lamps and 15 V for 12 V types.

(6)  To be checked by means of a ‘Box-System’. Sheet HS5/4.

(7)  The positions of the first and the last turn of the filament are defined by the intersections of the outside of the first and the outside of the last light-emitting turn, respectively, with the plane parallel to and 26 mm distant from the reference plane.

(6)  The positions of the first and the last turn of the filament are defined by the intersections of the outside of the first and the outside of the last light-emitting turn, respectively, with the plane parallel to and 26 mm distant from the reference plane.

(7)  The values indicated in the left-hand columns relate to the driving-beam filament and those indicated in the right-hand columns to the passing-beam filament.

(16)  The ends of the filament are defined as the points where, when the viewing direction is direction A as shown on sheet HS6/1, the projection of the outside of the end turns crosses the filament axis.

(17)  d1 is the actual diameter of the passing-beam filament.

d2 is the actual diameter of the driving-beam filament.

(18)  The values indicated in the left-hand columns relate to the driving-beam filament and those in the right-hand columns to the passing-beam filament.

(4)  To be checked by means of a ‘Box-System’; sheet P13W/3.

(5)  The ends of the filament are defined as the points where, when the viewing direction is perpendicular to the plane through the filament lead-in wires, the projection of the outside of the end turns crosses the filament axis.

(6)  No part of the cap beyond the reference plane shall interfere with angle α2 as shown in Figure 1 on sheet P13W/1. The bulb shall be optically distortion free within the angles α1+ α2. These requirements apply to the whole bulb circumference.

(4)  For categories PS19W, PSY19W and PSR19W, dimensions may be checked with O-ring removed to assure the correct mounting during testing.

(5)  The filament position is checked by means of a ‘Box-System’; sheet P19W/3.

(6)  The ends of the filament are defined as the points where, when the viewing direction is perpendicular to the plane through the filament lead-in wires as showed in the drawing on sheet P19W/1, the projection of the outside of the end turns crosses the filament axis.

(7)  No part of the cap beyond the reference plane shall interfere with angle α. The bulb shall be optically distortion free within the angle 2α + 180°.

(8)  The light emitted from standard filament lamps shall be white for categories P19W and PS19W; white or amber for categories PY19W and PSY19W; white or red for categories PR19W and PSR19W.

(4)  For categories PS24W, PSX24W, PSY24W and PSR24W, dimensions may be checked with O-ring removed to assure the correct mounting during testing.

(5)  The filament position is checked by means of a ‘box-system’; sheet P24W/3.

(6)  The ends of the filament are defined as the points where, when the viewing direction is perpendicular to the plane through the filament lead-in wires as shown in the drawing on sheet P24W/1, the projection of the outside of the end turns crosses the filament axis.

(7)  No part of the cap beyond the reference plane shall interfere with angle α. The bulb shall be optically distortion free within the angle 2α + 180°.

(8)  The light emitted from standard filament lamps shall be white for categories P24W, PX24W, PS24W and PSX24W; white or amber for categories PY24W and PSY24W; white or red for categories PR24W and PSR24W.

(4)  The filament position is checked by means of a ‘Box-System’; sheet PC16W/3.

(5)  The ends of the filament are defined as the points where, when the viewing direction is perpendicular to the plane through the filament lead-in wires as showed in the drawing on sheet PC16W/1, the projection of the outside of the end turns crosses the filament axis.

(6)  No part of the cap beyond the reference plane shall interfere with angle α. The bulb shall be optically distortion free within the angle 2α + 180°.

(7)  The light emitted from standard filament lamps shall be white for category PC16W; white or amber for category PCY16W; white or red for category PCR16W.

(8)  These dimensions shall be checked by means of a ‘Box-System’  (10) based on the dimensions and tolerances shown above. ‘x’ and ‘y’ refer to the major (high-wattage) filament, not to the reference axis. Means of increasing the positioning accuracy of the filament and of the cap-holder assembly are under consideration.

(9)  Maximum lateral deviation of the major filament centre from two mutually perpendicular planes both containing the reference axis and one containing the axis of the reference pin.

(10)  The ‘Box-System’ is the same as for filament lamp P21/5W.

(11)  The 24-Volt filament lamp is not recommended for future embodiments.

(12)  The light emitted from normal production lamps shall be red (see also note 6).

(13)  The light emitted from standard filament lamps shall be white or red.

(14)  See footnote 1 on sheet P21/5W/2.

(15)  See footnote 2 on sheet P21/5W/2.

(16)  See footnote 3 on sheet P21/5W/2.

(17)  The light emitted from normal production lamps shall be red (see also note 5).

(18)  The light emitted from standard filament lamps shall be white or red.

(4)  To be checked by means of a ‘Box-System’; sheet PSX26W/3.

(5)  The ends of the filament are defined as the points where, when the viewing direction is perpendicular to the plane through the filament lead-in wires, the projection of the outside of the end turns crosses the filament axis.

(6)  No part of the cap beyond the reference plane shall interfere with angle α2 as shown in Figure 1 on sheet PSX26W/1. The bulb shall be optically distortion free within the angles α1 + α2. These requirements apply to the whole bulb circumference.

(19)  The position and dimensions of the shield and filaments shall be checked by means of the method of measurement as described in IEC Publication 60809.

(20)  To be measured at the distance from the reference plane indicated in millimetres behind the stroke.

(21)  mv = measured value.

(22)  The angle γ is only for shield design and has not to be checked on finished filament lamps.

(5)  Dimensions a, b, c and β refer to a plane parallel to the reference plane and cutting the two edges of the shield at a distance of e + 1,5 mm.

(6)  Admissible angular deviation of the shield plane position from the normal position.

(7)  Values in the left-hand column refer to the driving-beam filament. Values in the right-hand column to the passing-beam filament.

(23)  Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(24)  Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(25)  To be checked by means of a ‘Box-System’; sheets W15/5W/2 and 3.

(26)  Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(27)   ‘x’ and ‘y’ denote the offset of the axis of the minor filament with respect to the axis of the major filament.

(28)  Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(29)  Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(30)  To be checked by means of a ‘Box-System’; see sheet W21W/2.

(31)  To be checked by means of a ‘Box-System’; sheets W21/5W/2 and 3.

(32)  Maximum lateral deviation of filament centre from two mutually perpendicular planes both containing the reference axis and one containing axis X-X.

(33)   ‘x’ and ‘y’ denote the offset of the axis of the minor filament with respect to the axis of the major filament.

ANNEX 2

COMMUNICATION

(maximum format: A4 (210 × 297 mm))

Image 169

Text of image

Image 170

Text of image

ANNEX 3

EXAMPLE OF THE ARRANGEMENT OF THE APPROVAL MARK

(see paragraph 2.4.3)

Image 171

The above approval mark affixed to a filament lamp indicates that the lamp has been approved in the United Kingdom (E11) under the approval code A1.

The first character of the approval code indicates that the approval was granted in accordance with the requirements of Regulation No 37 as amended by the 02 and 03 (*1) series of amendments.

(*1)  Not requiring changes in the approval number.

ANNEX 4

LUMINOUS CENTRE AND SHAPES OF LAMP FILAMENTS

Save as possibly otherwise stated on the filament lamp data sheets, this standard is applicable to the determination of the luminous centre of different filament shapes.

The position of the luminous centre depends upon the filament shape.

No

Filament shapes

Observations

1

Image 172

With b > 1,5 h, the deviation of the filament axis with respect to a plane normal to the reference axis shall not exceed 15°.

2

Image 173

Only applicable to filaments which can be inscribed in a rectangle of b > 3h.

3

Image 174

Applicable to filaments which can be inscribed in a rectangle of b ≤ 3h, whereby, however, k < 2h.

The side lines of the circumscribed rectangles in Nos 2 and 3 are parallel and perpendicular, respectively, to the reference axis.

The luminous centre is the intersection of the dash-dot lines.

The drawings are intended only to demonstrate the essential dimensions.

ANNEX 5

CHECKING THE COLOUR OF FILAMENT LAMPS

1.   General

1.1.

 Measurements shall be made on finished lamps. Filament lamps with secondary (outer) bulb acting as colour filter shall be handled as filament lamp with primary bulb.

1.2.

 Tests shall be made at an ambient temperature of 23 °C ± 5 °C.

1.3.

 Tests shall be made at test voltage as specified in the relevant lamp data sheet.

1.4.

 Filament lamps shall be measured preferably in the normal operating position. In case of dual filament lamps the high wattage (major or driving-beam) filament shall be operated only.

1.5.

 Before starting a test, the stabilisation of the temperature of the filament lamp shall be obtained by operating at test voltage for 10 minutes.

2.   Colour

2.1.

 Colour tests shall be made with a measuring system that determines CIE trichromatic co-ordinates of the received light with an accuracy of ± 0,002.

2.2.

 The trichromatic coordinates shall be measured with a colorimetric receiver integrating over a right circular cone subtending an angle of minimum 5° and maximum 15°, at the centre of the filament.

2.3.

 Measuring directions (see the figure below).

2.3.1.

Initially, the receiver shall be positioned perpendicular to the lamp axis and to the filament axis (or plane in case of a curved filament). After measurement the receiver shall be moved around the filament lamp in bi-directional steps of about 30° until the area specified in paragraphs 2.3.2 or 2.3.3 is covered. In each position a measurement shall be made. However, no measurement shall be made when:

(a)

the centreline of the receiver coincides with the filament axis; or

(b)

the line of sight between the receiver and the filament is blocked by opaque (non-transmitting) parts of the light source, such as lead wires or a second filament, if any.

2.3.2.

For filament lamps used in headlamps, measurements shall be made in directions around the filament lamp with the centreline of the receiver aperture located within an angle ± 30°, from the plane perpendicular to the lamp axis with the origin in the centre of the filament. In case of filament lamps with two filaments, the centre of the driving-beam filament shall be taken.

2.3.3.

For filament lamps used in light signalling devices, measurements shall be made in directions around the filament lamp with exception of:

(a)

the area claimed or covered by the cap of the filament lamp; and

(b)

the immediate transition area along the cap.

In case of filament lamps with two filaments, the centre of the major filament shall be taken.

Figure illustrating the positions of colorimetric receiver

Image 175

ANNEX 6

MINIMUM REQUIREMENTS FOR QUALITY CONTROL PROCEDURES BY THE MANUFACTURER

1.   General

The conformity requirements shall be considered satisfied from a photometric, geometrical, visual and electrical standpoint if the specified tolerances for production filament lamps in the relevant data sheet of Annex 1 and the relevant data sheet for the caps are met.

2.   Minimum requirements for verification of conformity by the manufacturer

For each type of filament lamp the manufacturer or the holder of the approval mark shall carry out tests, in accordance with the provisions of this Regulation, at appropriate intervals.

2.1.   Nature of tests

Tests of conformity of these specifications shall cover their photometric, geometrical and optical characteristics.

2.2.   Methods used in tests

2.2.1.

 Tests shall generally be carried out in accordance with the methods set out in this Regulation.

2.2.2.

 The application of paragraph 2.2.1 requires regular calibration of test apparatus and its correlation with measurements made by a competent authority.

2.3.   Nature of sampling

Samples of filament lamps shall be selected at random from the production of a uniform batch. A uniform batch means a set of filament lamps of the same type, defined according to the production methods of the manufacturer.

2.4.   Inspected and recorded characteristics

The filament lamps shall be inspected and test results recorded following the grouping of characteristics as listed in Annex 7, Table 1.

2.5.   Criteria governing acceptability

The manufacturer or the holder of approval is responsible for carrying out a statistical study of the test results in order to meet the specifications laid down for verification of conformity of production in paragraph 4.1 of this Regulation.

Compliance shall be assured if the level of acceptable non-compliance per grouping of characteristics given in Table 1 of Annex 7 is not exceeded. This means that the number of filament lamps not complying with the requirement for any grouping of characteristics of any filament lamp type does not exceed the qualifying limits in the relevant Tables 2, 3 or 4 of Annex 7.

Note: Each individual filament lamp requirement shall be considered as a characteristic.

ANNEX 7

SAMPLING AND COMPLIANCE LEVELS FOR MANUFACTURER TEST RECORDS

Table 1

Characteristics

Grouping of characteristics

Grouping (*1) of test records between lamp types

Minimum 12 monthly sample per grouping (*1)

Acceptable level of non-compliance per grouping of characteristics (%)

Marking, legibility and durability

All types with the same external dimensions

315

1

Bulb quality

All types with the same bulb

315

1

Colour of the bulb

All types (emitting red and amber light) of the same category and colour technology

20

External lamp dimensions (excluding cap/base)

All types of the same category

200

1

Dimensions of caps and bases

All types of the same category

200

6,5

Dimensions related to internal elements (*2)

All lamps of one type

200

6,5

Initial readings, watts and lumens (*2)

All lamps of one type

200

1

Colour endurance test

All lamps (emitting red, amber and white light) of one colour coating technology

20  (*3)

1

Qualifying limits for acceptance based on different numbers of test results for each grouping of characteristics are listed in Table 2 as maximum number of non-compliance. The limits are based on an acceptable level of 1 per cent of non-compliance, assuming an acceptance probability of at least 0,95.

Table 2 (*4)

Number of test results of each characteristics

Qualifying limits for acceptance

20

0

21 - 50

1

51 - 80

2

81 - 125

3

126 - 200

5

201 - 260

6

261 - 315

7

316 - 370

8

371 - 435

9

436 - 500

10

501 - 570

11

571 - 645

12

646 - 720

13

721 - 800

14

801 - 860

15

861 - 920

16

921 - 990

17

991 - 1 060

18

1 061 - 1 125

19

1 126 - 1 190

20

1 191 - 1 249

21

Qualifying limits for acceptance based on different numbers of test results for each grouping of characteristics are listed in Table 3 given as maximum number of non-compliance. The limits are based on an acceptable level of 6,5 per cent of non-compliance, assuming an acceptance probability of at least 0,95.

Table 3

Number of lamps in records

Qualifying limit

- 200

21

201 - 213

22

214 - 227

23

228 - 240

24

241 - 254

25

255 - 268

26

269 - 281

27

282 - 295

28

296 - 308

29

309 - 322

30

323 - 336

31

337 - 349

32

350 - 363

33

364 - 376

34

377 - 390

35

391 - 404

36

405 - 417

37

418 - 431

38

432 - 444

39

445 - 458

40

459 - 472

41

473 - 485

42

486 - 499

43

500 - 512

44

513 - 526

45

527 - 540

46

541 - 553

47

554 - 567

48

568 - 580

49

581 - 594

50

595 - 608

51

609 - 621

52

622 - 635

53

636 - 648

54

649 - 662

55

663 - 676

56

677 - 689

57

690 - 703

58

704 - 716

59

717 - 730

60

731 - 744

61

745 - 757

62

758 - 771

63

772 - 784

64

785 - 798

65

799 - 812

66

813 - 825

67

826 - 839

68

840 - 852

69

853 - 866

70

867 - 880

71

881 - 893

72

894 - 907

73

908 - 920

74

921 - 934

75

935 - 948

76

949 - 961

77

962 - 975

78

976 - 988

79

989 - 1 002

80

1 003 - 1 016

81

1 017 - 1 029

82

1 030 - 1 043

83

1 044 - 1 056

84

1 057 - 1 070

85

1 071 - 1 084

86

1 085 - 1 097

87

1 098 - 1 111

88

1 112 - 1 124

89

1 125 - 1 138

90

1 139 - 1 152

91

1 153 - 1 165

92

1 166 - 1 179

93

1 180 - 1 192

94

1 193 - 1 206

95

1 207 - 1 220

96

1 221 - 1 233

97

1 234 - 1 249

98

Qualifying limits for acceptance based on different numbers of test results for each grouping of characteristics are listed in Table 4 given as a percentage of the results, assuming an acceptance probability of at least 0,95.

Table 4

Number of test results of each characteristic

Qualifying limits shown as a percentage of results.

Acceptable level of 1 % of non-compliance

Qualifying limits shown as a percentage of results.

Acceptable level of 6,5 % of non-compliance

1 250

1,68

7,91

2 000

1,52

7,61

4 000

1,37

7,29

6 000

1,30

7,15

8 000

1,26

7,06

10 000

1,23

7,00

20 000

1,16

6,85

40 000

1,12

6,75

80 000

1,09

6,68

100 000

1,08

6,65

1 000 000

1,02

6,55

(*1)  The assessment shall in general cover series production filament lamps from individual factories. A manufacturer may group together records concerning the same type from several factories, provided these operate under the same quality system and quality management.

(*2)  In case a filament lamp has more than one inner element (filament, shield) the grouping of characteristics (dimensions, watts, lumens) applies to each element separately.

(*3)  Representative distribution over categories of lamps using the same colour coating technology and finishing, and that comprises lamps of the smallest and the largest diameter of the outer bulb, each at the highest rated wattage.

(*4)  In accordance with ISO 2859-1:1999 ‘Sampling procedures for inspection by attributes — Part 1: Sampling schemes indexed by acceptance quality limit (AQL) for lot-by-lot inspection’ including Technical Corrigendum 1:2001.

ANNEX 8

MINIMUM REQUIREMENTS FOR SPOT CHECKS BY THE ADMINISTRATIVE AUTHORITY

1.   General

The conformity requirements shall be considered satisfied from a photometric, geometrical, visual and electrical standpoint if the specified tolerances for production filament lamps in the relevant data sheet of Annex 1 and the relevant data sheet for the caps are met.

2.   The conformity of mass-produced filament lamps shall not be contested if the results are in agreement with Annex 9 to this Regulation.

3.   Conformity shall be contested and the manufacturer requested to make the production meet the requirements if the results are not in agreement with Annex 9 to this Regulation.

4.   If paragraph 3 of this Annex is applied, a further sample of 250 filament lamps, selected at random from a recent production run, shall be taken within two months.

ANNEX 9

COMPLIANCE APPROVED BY SPOT CHECK

Compliance approved or disapproved shall be decided according to the values in Table 1. For each grouping of characteristics filament lamps shall be either accepted or rejected according to the values in Table 1 (1).

Table 1

 

1  % (*1)

6,5  % (*1)

 

Accept

Reject

Accept

Reject

First sample size: 125

2

5

11

16

If the number of non-conforming units is greater than 2 (11) and less than 5 (16) take a second sample size of 125 and assess the 250

6

7

26

27

(1)  The proposed scheme is designed to assess the compliance of filament lamps to an acceptance level of non-compliance of 1 per cent and 6,5 per cent respectively and is based on the Double Sampling Plan for Normal Inspection in IEC Publication 60410: Sampling Plans and Procedures for Inspection by Attributes.

(*1)  The filament lamps shall be inspected and test results recorded following the grouping of characteristics as listed in Annex 7, Table 1.

ANNEX 10

TRANSLATIONS OF THE TERMS USED IN THE DRAWINGS IN ANNEX 1

English

 

a = major (high wattage) filament

 

Auxiliary reference plane

 

Axis of bulb

 

Axis of driving-beam filament

 

Axis of high wattage filament

 

Axis of low wattage filament

 

Axis of passing-beam filament

 

Axis of the bulb

 

b = minor (low wattage) filament

 

Bulb axis

 

Category

 

Central axis sought

 

Definition of Z – Z line

 

Definition: Ring centre and reference axis

 

Distortion free area and black top

 

Driving

 

Driving-beam

 

Driving-beam filament

 

Driving-beam filament axis

 

Earth

 

Enlarged centre of View A

 

Enlarged centre of View B

 

Filament axis

 

Filament centre

 

Filament centres

 

Filament position

 

Filament position and dimensions

 

First filament turn

 

For driving-beam filament

 

For passing-beam filament

 

Ground

 

High wattage

 

High-wattage filament

 

Low wattage

 

Low-wattage filament

 

Lug width 3 mm

 

max

 

Maximum lamp outlines

 

Metal free zone

 

Nominal position of lampholder studs

 

Obscuration angle limits of cap

 

Offset of filament

 

Passing

 

Passing beam filament axis

 

Passing-beam

 

Passing-beam filament

 

Permissible offset of filament axis

 

Plane C

 

Position and dimensions of filaments

 

Position of the filaments

 

Position of the shield

 

Reference axis

 

Reference boss

 

Reference diameter

 

Reference key

 

Reference lug

 

Reference mark

 

Reference notch

 

Reference pin

 

Reference plane

 

Ring centre

 

Second pin

 

Section A-B

 

Section D-E

 

Shield

 

Top view

 

Top view of driving-beam and passing-beam filament

 

View A

 

View A passing-beam filament

 

View A: measuring H2

 

View B

 

View B driving-beam filament

 

View B: measuring k, h1, h3, f

 

View C

 

View C: measuring h4

 

View from A / View from 1

 

View from B / View from 2

 

View from C / View from 3

 

Views A and C

 

Views B and C

 

x mm to reference plane

 

x to reference plane

 
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