ANNEX 1

Categories of direction indicators: Minimum angles required for light distribution in space of these categories of direction indicators  (1)

In all cases, the minimum vertical angles of light distribution in space of direction indicator lamps are 15° above and 15° below the horizontal except:

(a)	direction indicator lamps intended to be installed with the H plane of the lamp at a mounting height of less than 750 mm above the ground, for which they are 15° above and 5° below the horizontal;

(b)	optional direction indicator lamps intended to be installed with the H plane of the lamp at a mounting height of more than 2 100 mm above the ground, for which they are 5° above and 15° below the horizontal;

(c)	direction indicator lamps of Category 6.

Minimum horizontal visibility angles

Direction indicators for the front of the vehicle

Category 1	:	For use at a distance not less than 40 mm from the dipped-beam headlamp and/or the front fog lamp;
Category 1a	:	For use at a distance greater than 20 mm but less than 40 mm from the dipped-beam headlamp and/or the front fog lamp;
Category 1b	:	For use at a distance less than or equal to 20 mm from the dipped-beam headlamp and/or the front fog lamp.

On and above the H plane for all lamps. Under the H plane for lamps intended for M2, M3, N2 or N3 category of vehicles

Under the H plane for M1 and N1 category of vehicles

H plane: ‘horizontal plane goingthrough the reference centre of the lamp’

Categories 2a and 2b	:	Direction indicators for the rear of the vehicle
Category 2a	:	Rear direction indicator lamps with steady luminous intensity
Category 2b	:	Rear direction indicator lamps with variable luminous intensity

Under the H plane for lamps intended to be installed with this plane at a mounting height less than 750 mm above the ground.

Categories 5 and 6

:

Supplementary side direction indicators for use on a vehicle also equipped with categories 1, 1a or 1b and 2a or 2b direction indicators

---

(1)  The angles shown in these arrangements are correct for devices to be mounted on the right side of the vehicle. The arrows in these diagrams point towards the front of the vehicle.

ANNEX 2

COMMUNICATION

(Maximum format: A4 (210 × 297 mm))

Text of image

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ANNEX 3

EXAMPLES OF ARRANGEMENTS OF THE APPROVAL MARKS

a= 5 mm min.

The device bearing the approval marking shown above is a category 4 device (front-side direction indicator) approved in Italy (E3) under No 216, which may also be used in an assembly of two lamps. The horizontal arrow shows in what position this device, which cannot be mounted on either side of the vehicle indiscriminately, is to be mounted. The arrow points towards the front of the vehicle. The vertical arrow starting from a horizontal segment and directed downwards indicates a permissible mounting height of equal to or less than 750 mm from the ground for this device.

The number mentioned close to the symbol ‘4D’ indicates that the approval was granted according to the requirements of Regulation No 6 as amended by the 01 series of amendments.

The direction in which the arrows on the approval mark point, according to the category of the device, is shown below:

Figure 1

Note: The approval number and the additional symbols shall be placed close to the circle and either above or below the letter ‘E’, or to the right or left of that letter. The digits of the approval number shall be on the same side of the letter ‘E’ and face the same direction. The use of Roman numerals as approval numbers should be avoided so as to prevent any confusion with other symbols.

Figure 2

Simplified marking of grouped, combined or reciprocally incorporated lamps when two or more lamps are part of the same assembly

The vertical and horizontal lines schematise the shape of the light-signalling device. These are not part of the approval mark.

Model A

Model B

Model C

Note: The three examples of approval marks shown above (models A, B and C) represent three possible variables for the marking of a lighting device when two or more lamps are part of the same assembly of grouped, combined or reciprocally incorporated lamps.

They indicate that the device was approved in the Netherlands (E4) under number 3333 and comprises:

A rear direction indicator lamp with variable luminous intensity (category 2b) approved in accordance with the 01 series of amendments to Regulation No 6;

A red rear position (side) lamp with variable luminous intensity (R2) approved in accordance with the 01 series of amendments to Regulation No 7;

A rear fog lamp with variable luminous intensity (F2) approved in accordance with Regulation No 38 in its original version;

A reversing lamp (AR) approved in accordance with Regulation No 23 in its original version;

A stop lamp with variable luminous intensity (S2) approved in accordance with the 01 series of amendments to Regulation No 7.

Note: The three examples shown above correspond to a lighting device bearing an approval mark relating to:

A front position lamp approved in accordance with the 01 series of amendments to Regulation No 7;

A headlamp with a passing beam designed for right-hand and left-hand traffic and a driving beam with a maximum intensity comprised between 86 250 and 101 250 candelas, approved in accordance with the 02 series of amendments to Regulation No 20;

A front fog lamp approved in accordance with the 02 series of amendments to Regulation No 19;

A front direction indicator lamp of category 1a approved in accordance with the 01 series of amendments to Regulation No 6.

Figure 3

Lamp reciprocally incorporated with a headlamp

The above example corresponds to the marking of a lens intended to be used in different types of headlamps, namely:

Either	:	A headlamp with a passing beam designed for right-hand and left-hand traffic and a driving beam with a maximum intensity comprised between 86 250 and 101 250 candelas, approved in Germany (E1) in accordance with the requirements of Regulation No 8 as amended by the 04 series of amendments; which is reciprocally incorporated with a front direction indicator approved in accordance with the 01 series of amendments to Regulation No 6;
Or	:	A headlamp with a passing beam designed for right-hand and left-hand traffic and a driving beam, approved in Germany (E1) in accordance with the requirements of Regulation No 1 as amended by the 01 series of amendments, which is reciprocally incorporated with the same front direction indicator as above;
Or even	:	Either of the abovementioned headlamps approved as a single lamp.

The main body of the headlamp shall bear the only valid approval number, for instance:

Figure 4

Marking of independent lamps

The above example corresponds to the marking of a lens intended to be used in different types of lamps. The approval marks indicate that the device was approved in Spain (E9) under approval number 1432 and comprises:

A rear fog lamp (F) approved in accordance with Regulation No 38 in its original version;

A rear direction indicator lamp of category 2a approved in accordance with the 01 series of amendments to Regulation No 6;

A reversing lamp (AR) approved in accordance with Regulation No 23 in its original version;

A red rear position (side) lamp (R) approved in accordance with the 02 series of amendments to Regulation No 7;

A stop lamp with one level of illumination (S1) approved in accordance with the 02 series of amendments to Regulation No 7.

Light source modules

The light source module bearing the identification code shown above has been approved together with a lamp approved in Italy (E3) under approval number 17325.

Marking of interdependent lamps

Marking of an interdependent lamp comprising part of an interdependent lamp system providing:   A rear direction indicator lamp (category 2a) approved in accordance with the 01 series of amendments to Regulation No 6. This is also marked Y as it is an interdependent lamp forming part of an interdependent lamp system,   A rear fog lamp with variable luminous intensity (F2) approved in accordance with Regulation No 38 in its original version.

Marking of an interdependent lamp comprising part of an interdependent lamp system providing:   A rear direction indicator lamp (category 2a) approved in accordance with the 01 series of amendments to Regulation No 6. This is also marked Y as it is an interdependent lamp forming part of an interdependent lamp system,   A red rear position (side) lamp (R1) approved in accordance with the 02 series of amendments to Regulation No 7,   A stop lamp (S1) approved in accordance with Regulation No 7 in its original version.

ANNEX 4

PHOTOMETRIC MEASUREMENTS

1.   MEASUREMENT METHODS

1.1.

During photometric measurements, stray reflections shall be avoided by appropriate masking.

1.2.

In case the results of measurements should be challenged, measurements shall be carried out in such a way as to meet the following requirements: 1.2.1. The distance of measurement shall be such that the law of the inverse of the square of the distance is applicable; 1.2.2. The measuring equipment shall be such that the angular aperture of the receiver viewed from the reference centre of the light is comprised between 10′ and 1 degree; 1.2.3. The intensity requirement for a particular direction of observation shall be deemed to be satisfied if that requirement is met in a direction deviating by not more than one-quarter of a degree from the direction of observation.

1.3.

In the case where the device may be installed on the vehicle in more than one or in a field of different positions the photometric measurements shall be repeated for each position or for the extreme positions of the field of the reference axis specified by the manufacturer.

2.   TABLE OF STANDARD LIGHT DISTRIBUTION IN SPACE FOR DIRECTION INDICATOR LAMPS OF CATEGORIES 1, 1A, 1B, 2A, 2B.

For direction indicators of category 6

(outer side of the vehicle)

2.1.

The direction H = 0° and V = 0° corresponds to the reference axis. (On the vehicle, it is horizontal, parallel to the median longitudinal plane of the vehicle and oriented in the required direction of visibility.) It passes through the centre of reference. The values shown in the tables give, for the various directions of measurement, the minimum intensities as a percentage of the minimum intensities required in the table in paragraph 6.1: 2.1.1. In the direction H = 0° and V = 0° for categories 1, 1a, 1b, 2a, 2b and in the case of category 5 in the angular area in the direction A as prescribed in Annex 1; 2.1.2. In the direction H = 5° and V = 0° for category 6. 2.1.3. However, in the case where a device is intended to be installed with its H plane at a mounting height less than 750 mm above the ground, the photometric intensity is verified only up to an angle of 5° downwards.

2.2.

Within the field of light distribution of paragraph 2, schematically shown as a grid, the light pattern should be substantially uniform, i.e. in so far as the light intensity in each direction of a part of the field formed by the grid lines shall meet at least the lowest minimum value being shown on the grid lines surrounding the questioned direction as a percentage.

3.   PHOTOMETRIC MEASUREMENT OF LAMPS

The photometric performance shall be checked:

3.1.	For non-replaceable light sources (filament lamps and other): With the light sources present in the lamp, in accordance with the relevant subparagraph of paragraph 7.1 of this Regulation.

3.2.

For replaceable light source(s):   When equipped with filament lamps at 6,75 V, 13,5 V or 28,0 V, the luminous intensity values produced shall be corrected. The correction factor is the ratio between the reference luminous flux and the mean value of the luminous flux found at the voltage applied (6,75 V, 13,5 V or 28,0 V).   For LED light sources the correction factor is the ratio between the objective luminous flux and the mean value of the luminous flux found at the voltage applied (6,75 V, 13,5 V or 28,0 V).   The actual luminous fluxes of each light source used shall not deviate more than 5 % from the mean value. Alternatively and in case of filament lamps only, a standard filament lamp may be used in turn, in each of the individual positions, operated at its reference flux, the individual measurements in each position being added together.

3.3.

For any direction indicator lamp except those equipped with filament lamp(s), the luminous intensities measured after one minute and after 30 minutes of operation in flashing mode (f = 1,5 Hz, duty factor 50 %), shall comply with the minimum and maximum requirements. The luminous intensity distribution after one minute of operation can be calculated by applying at each test point the ratio of luminous intensity measured in HV after one minute and after 30 minutes of operation as above described.

ANNEX 5

MINIMUM REQUIREMENTS FOR CONFORMITY OF PRODUCTION CONTROL PROCEDURES

1.   GENERAL

1.1.

The conformity requirements shall be considered satisfied from a mechanical and geometric standpoint, if the differences do not exceed inevitable manufacturing deviations within the requirements of this Regulation.

1.2.

With respect to photometric performances, the conformity of mass-produced lamps shall not be contested if, when testing photometric performances of any lamp chosen at random according to paragraph 7 of this Regulation: 1.2.1. No measured value deviates unfavourably by more than 20 % from the values prescribed in this Regulation. 1.2.2. If, in the case of a direction indicator equipped with a replaceable light source and if results of the test described above do not meet the requirements, tests on direction indicators shall be repeated using another standard light source.

1.3.

The chromaticity coordinates shall be complied when tested under conditions of paragraph 7 of this Regulation.

2.   MINIMUM REQUIREMENTS FOR VERIFICATION OF CONFORMITY BY THE MANUFACTURER

For each type of direction indicator the holder of the approval mark shall carry out at least the following tests, at appropriate intervals. The tests shall be carried out in accordance with the provisions of this Regulation.

If any sampling shows non-conformity with regard to the type of test concerned, further samples shall be taken and tested. The manufacturer shall take steps to ensure the conformity of the production concerned.

2.1.   Nature of tests

Tests of conformity in this Regulation shall cover the photometric and colorimetric 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.

In any test of conformity carried out by the manufacturer, equivalent methods may be used with the consent of the competent authority responsible for approval tests. The manufacturer is responsible for proving that the applied methods are equivalent to those laid down in this Regulation.

2.2.3.

The application of paragraphs 2.2.1 and 2.2.2 requires regular calibration of test apparatus and its correlation with measurements made by a competent authority.

2.2.4.

In all cases the reference methods shall be those of this Regulation, particularly for the purpose of administrative verification and sampling.

2.3.   Nature of sampling

Samples of direction indicators shall be selected at random from the production of a uniform batch. A uniform batch means a set of direction indicators of the same type, defined according to the production methods of the manufacturer.

The assessment shall in general cover series production from individual factories. However, a manufacturer may group together records concerning the same type from several factories, provided these operate under the same quality system and quality management.

2.4.   Measured and recorded photometric characteristics

The sampled lamp shall be subjected to photometric measurements for the minimum values at the points listed in Annex 4, and the required chromaticity coordinates.

2.5.   Criteria governing acceptability

The manufacturer is responsible for carrying out a statistical study of the test results and for defining, in agreement with the competent authority, criteria governing the acceptability of his products in order to meet the specifications laid down for verification of conformity of products in paragraph 10.1 of this Regulation.

The criteria governing the acceptability shall be such that, with a confidence level of 95 %, the minimum probability of passing a spot check in accordance with Annex 6 (first sampling) would be 0,95.

ANNEX 6

MINIMUM REQUIREMENTS FOR SAMPLING BY AN INSPECTOR

1.   GENERAL

1.1.

The conformity requirements shall be considered satisfied from a mechanical and a geometric standpoint, in accordance with the requirements of this Regulation, if any, if the differences do not exceed inevitable manufacturing deviations.

1.2.

With respect to photometric performances, the conformity of mass-produced lamps shall not be contested if, when testing photometric performances of any lamp chosen at random according to paragraph 7 of this Regulation: 1.2.1. No measured value deviates unfavourably by more than 20 % from the values prescribed in this Regulation. 1.2.2. If, in the case of a direction indicator equipped with a replaceable light source and if results of the test described above do not meet the requirements, tests on direction indicators shall be repeated using another standard light source. 1.2.3. Direction indicators with apparent defects are disregarded.

1.3.

The chromaticity coordinates shall be complied when tested under conditions of paragraph 7 of this Regulation.

2.   FIRST SAMPLING

In the first sampling four direction indicators are selected at random. The first sample of two is marked A, the second sample of two is marked B.

2.1.   The conformity is not contested

2.1.1.

Following the sampling procedure shown in Figure 1 of this annex the conformity of mass-produced direction indicators shall not be contested if the deviation of the measured values of the direction indicators in the unfavourable directions are: 2.1.1.1. Sample A A1: One direction indicator 0  % One direction indicator not more than 20  % A2: Both direction indicators more than 0  % But not more than 20  % Go to sample B   2.1.1.2. Sample B B1: Both direction indicators 0  %

2.1.2.

Or if the conditions of paragraph 1.2.2 for sample A are fulfilled.

2.2.   The conformity is contested

2.2.1.

Following the sampling procedure shown in Figure 1 of this annex the conformity of mass-produced direction indicators shall be contested and the manufacturer requested to make his production meet the requirements (alignment) if the deviations of the measured values of the direction indicators are: 2.2.1.1. Sample A A3: One direction indicator not more than 20  % One direction indicator more than 20  % But not more than 30  % 2.2.1.2. Sample B B2: On the case of A2   One direction indicator more than 0  % But not more than 20  % One direction indicator not more than 20  % B3: On the case of A2   One direction indicator 0  % One direction indicator more than 20  % But not more than 30  %

2.2.2.

Or if the conditions of paragraph 1.2.2 for sample A are not fulfilled.

2.3.   Approval withdrawn

Conformity shall be contested and paragraph 11 applied if, following the sampling procedure in Figure 1 of this annex, the deviations of the measured values of the direction indicators are:

2.3.1.

Sample A A4: One direction indicator not more than 20  % One direction indicator more than 30  % A5: Both direction indicators more than 20  %

2.3.2.

Sample B B4: In the case of A2   One direction indicator more than 0  % But not more than 20  % One direction indicator more than 20  % B5: In the case of A2   Both direction indicators more than 20  % B6: In the case of A2   One direction indicator 0  % One direction indicator more than 30  %

2.3.3.

Or if the conditions of paragraph 1.2.2 for samples A and B are not fulfilled.

3.   REPEATED SAMPLING

In the cases of A3, B2, B3 a repeated sampling, third sample C of two direction indicators and fourth sample D of two direction indicators, selected from stock manufactured after alignment, is necessary within two months’ time after the notification.

3.1.   The conformity is not contested

3.1.1.

Following the sampling procedure shown in Figure 1 of this annex the conformity of mass-produced direction indicators shall not be contested if the deviations of the measured values of the direction indicators are: 3.1.1.1. Sample C C1: One direction indicator 0  % One direction indicator not more than 20  % C2: Both direction indicators more than 0  % But not more than 20  % Go to sample D   3.1.1.2. Sample D D1: In the case of C2   Both direction indicators 0  %

3.1.2.

Or if the conditions of paragraph 1.2.2 for sample C are fulfilled.

3.2.   The conformity is contested

3.2.1.

Following the sampling procedure shown in Figure 1 of this annex the conformity of mass-produced direction indicators shall be contested and the manufacturer requested to make his production meet the requirements (alignment) if the deviations of the measured values of the direction indicators are: 3.2.1.1. Sample D D2: In the case of C2   One direction indicator more than 0  % But not more than 20  % One direction indicator not more than 20  % 3.2.1.2. Or if the conditions of paragraph 1.2.2 for sample C are not fulfilled.

3.3.   Approval withdrawn

Conformity shall be contested and paragraph 11 applied if, following the sampling procedure in Figure 1 of this annex, the deviations of the measured values of the direction indicators are:

3.3.1.

Sample C C3: One direction indicator not more than 20  % One direction indicator more than 20  % C4: Both direction indicators more than 20  %

3.3.2.

Sample D D3: In the case of C2   One direction indicator 0 or more than 0  % One direction indicator more than 20  %

3.3.3.

Or if the conditions of paragraph 1.2.2 for samples C and D are not fulfilled.

Figure 1

Possible results on sample A

2 devices

First Sampling

4 devices selected at random split into samples A&B

2 devices

END

go over to sample B

END

Alignment

Manufacturer is ordered to bring the products in line with the requirements

2 devices

Repeated sampling

4 devices selected at random split into samples C&D

2 devices

END

go over to sample D

Possible results on sample D

Possible results on sample B

Poss. results on sample C

END

go to alignment

Approval withdrawn

Maximum deviation [per cent] in the unfavourable direction in relation to the limit values

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 (5)	H1/1 to 3
H3 (5)	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 (2)	H9/1 to 4
H9B (2)	H9/1 to 4
H10	H10/1 to 3
H11	H11/1 to 4
H11B	H11/1 to 4
H13	H13/1 to 4
H15	H15/1 to 5
H16	H16/1 to 4
H16B	H16/1 to 4
H17	H17/1 to 6
H21W (1)	H21W/1 to 2
H27W/1	H27W/1 to 3
H27W/2	H27W/1 to 3
HB3	HB3/1 to 4
HB4	HB4/1 to 4
HIR2	HIR2/1 to 3
HS1 (5)	HS1/1 to 5
HS2 (5)	HS2/1 to 3
HS5	HS5/1 to 4
HS5A (4)	HS5A/1 to 3
PSX24W (1)	P24W/1 to 3
PSX26W (1)	PSX26W1 to 3
PX24W (1)	P24W/1 to 3
S2 (5)	S1/S2/1 to 2

Group 2

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

Category	Sheet number(s)
C5W (5)	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
P21W (5)	P21W/1 to 2
P21/4W	P21/4W/1 (P21/5W/2 to 3)
P21/5W (5)	P21/5W/1 to 3
P24W	P24W/1 to 3
P27W	P27W/1 to 2
P27/7W	P27/7W/1 to 3
PR21W	PR21W/1 (P21W/2)
PR21/5W	PR21/5W/1 (P21/5W/2 to 3)
PS19W	P19W/1 to 3
PS24W	P24W/1 to 3
PSY19W	P19W/1 to 3
PSY24W	P24W/1 to 3
PW13W	P13W/1 to 3
PW16W	PC16W/1 to 3
PWR16W	PC16W/1 to 3
PWY16W	PC16W/1 to 3
PW19W	P19W/1 to 3
PWR19W	P19W/1 to 3
PWY19W	P19W/1 to 3
PW24W	P24W/1 to 3
PWR24W	P24W/1 to 3
PWY24W	P24W/1 to 3
PY21W	PY21W/1 (P21W/2)
PY21/5W	PY21/5W/1 to 3
PY24W	P24W/1 to 3
PY27/7W	PY27/7W/1 (P27/7W/2 to 3)
R5W (5)	R5W/1
R10W (5)	R10W/1
RR5W	R5W/1
RR10W	R10W/1
RY10W (5)	R10W/1
T4W (5)	T4W/1
W2.3W	W2.3W/1
W3W (5)	W3W/1
W5W (5)	W5W/1
W10W (5)	W10W/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)
WT21W	WT21W/1 to 2
WT21/7W	WT21/7W/1 to 3
WTY21W	WT21W/1 to 2
WTY21/7W	WT21/7W/1 to 3
WY5W (5)	W5W/1
WY10W (5)	W10W/1
WY16W	W16W/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)	As specified by transitional provisions in paragraph 8.3		As specified by transitional provisions in paragraph 8.4
		Supplement	Period	Supplement	Period
C5W (6), (7)	C5W/1	38	12 months	38	unlimited
C21W (7)	C21W/1 to 2	28	12 months	28	unlimited
H1 (6)	H1/1 to 3	38	12 months	38	unlimited
H3 (6)	H3/1 to 4	38	12 months	38	unlimited
H12	H12/1 to 3	40	24 months	40	unlimited
H13A	H13/1 to 4	40	24 months	40	unlimited
H14	H14/1 to 4	38	12 months	38	unlimited
HB3A	HB3/1 to 4	40	60 months	40	unlimited
HB4A	HB4/1 to 4	40	60 months	40	unlimited
HIR1 (2)	HIR1/1 to 3	40	24 months	40	unlimited
HS1 (6)	HS1/1 to 5	38	12 months	38	unlimited
HS2 (6)	HS2/1 to 3	38	12 months	38	unlimited
HS6 (3)	HS6/1 to 4	40	60 months	40	unlimited
P19W (7)	P19W/1 to 3	37	60 months	37	unlimited
P21W (6), (7)	P21W/1 to 2	38	12 months	38	unlimited
P21/5W (6), (7)	P21/5W/1 to 3	38	12 months	38	unlimited
PC16W (7)	PC16W/1 to 3	37	60 months	37	unlimited
PCR16W (7)	PC16W/1 to 3	37	12 months	37	unlimited
PCY16W (7)	PC16W/1 to 3	37	60 months	37	unlimited
PR19W (7)	P19W/1 to 3	37	12 months	37	unlimited
PR21/4W (7)	PR21/4W/1; (P21/5W/2 to 3)	40	24 months	40	unlimited
PR24W (7)	P24W/1 to 3	37	12 months	37	unlimited
PR27/7W (7)	PR27/7W/1; (P27/7W/2 to 3)	40	24 months	40	unlimited
PSR19W (7)	P19W/1 to 3	37	12 months	37	unlimited
PSR24W (7)	P24W/1 to 3	37	12 months	37	unlimited
PY19W (7)	P19W/1 to 3	37	60 months	37	unlimited
R2	R2/1 to 3	28	12 months	28	unlimited
R5W (6), (7)	R5W/1	38	12 months	38	unlimited
R10W (6), (7)	R10W/1	38	12 months	38	unlimited
RY10W (6), (7)	R10W/1	38	12 months	38	unlimited
S1	S1/S2/1 to 2	28	12 months	28	unlimited
S2 (6)	S1/S2/1 to 2	38	12 months	38	unlimited
S3	S3/1	38	12 months	38	unlimited
T1.4W (7)	T1.4W/1	40	24 months	40	unlimited
T4W (6), (7)	T4W/1	38	12 months	38	unlimited
W3W (6), (7)	W3W/1	38	12 months	38	unlimited
W5W (6), (7)	W5W/1	38	12 months	38	unlimited
W10W (6), (7)	W10W/1	38	12 months	38	unlimited
WY2.3W	WY2.3W/1	40	24 months	40	unlimited
WY5W (6)	W5W/1	40	12 months	40	unlimited
WY10W (6), (7)	W10W/1	38	12 months	38	unlimited

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

H17/1 to 6

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

PY21/5W/1 to 3

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

W10W/1

W15/5W/1 to 3

W16W/1

W21W/1 to 2

W21/5W/1 to 3

WP21W/1 to 2

WR21/5W/1

WT21W/1 to 2

WT21/7W/1 to 3

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

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

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.

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

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 (9), (13)		25,0  (12)			25,0 ± 0,15
f (9), (13)		4,5 ± 1,0	5,0 ± 0,5	5,5 ± 1,0	5,0 + 0,50/– 0,00
g (10), (11)		0,5 d ± 0,5 d			0,5 d ± 0,25 d
h1		(12)			0 ± 0,20 (8)
h2		(12)			0 ± 0,25 (8)
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.

	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, footnote 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

Text of image

CATEGORY H3 — Sheet H3/2

Text of image

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  (14)			18,0
f (16)		3,0  min.	4,0  min.		5,0 ± 0,50
k		0  (14)			0 ± 0,20
h1, h3		0  (14)			0 ± 0,15 (15)
h2, h4		0  (14)			0 ± 0,25 (15)
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.

Text of image

	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

Text of image

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  (17)		24  (17)		12  (17)
	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 (18) lm		—	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

Text of image

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

Position of filaments

Text of image

CATEGORY H4 — Sheet H4/4

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

Reference (*2)		Dimension (*3)		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		b2/29,5 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 (21)		28,5	29,0	+ 0,35 – 0,25	± 0,35	+ 0,20 – 0,00
f (19), (20), (21)		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
IR  (19), (22)		4,5	5,25	± 0,80		± 0,40
IC  (19), (20)		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
(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.

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, IR and IC;

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

CATEGORY H7 — Sheet H7/2

(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 (23)		25,0  (24)		25,0 ± 0,1
f (23)		4,1  (24)	4,9  (24)	4,1 ± 0,1
g (26)		0,5  min.		u.c.
h1 (25)		0  (24)		0 ± 0,10
h2 (25)		0  (24)		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

	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, footnote 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

Text of image

Figure 2

Maximum lamp outline (3)

CATEGORIES H8 AND H8B — Sheet H8/2

(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 (27)		25,0  (28)	25,0 ± 0,1
f (27)		3,7  (28)	3,7 ± 0,1
g		0,5  min.	u.c.
h1		0  (28)	0 ± 0,1
h2		0  (28)	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.

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, footnote 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

Text of image

Figure 2

Maximum lamp outline (3)

CATEGORIES H9 AND H9B — Sheet H9/2

(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 (29), (30)		25	(31)		± 0,10
f (29), (30)		4,8	(31)		± 0,10
g (29)		0,7	± 0,5		± 0,30
h1		0	(31)		± 0,10 (32)
h2		0	(31)		± 0,15 (32)
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	12,2	13,2	12,2
Objective values	Watts	73 max.	65 max.	73 max.	65 max.
	Luminous flux	2 100  ± 10 %	1 650  ± 10 %
Reference luminous flux at approximately			12  V	1 500
			12,2  V	1 650
			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.

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, footnote 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

Text of image

CATEGORY H10 — Sheet H10/2

Dimensions in mm (33)		Tolerance
		Filament lamps of normal production	Standard filament lamp
e (34), (35)	28,9	(36)	± 0,16
f (34), (35)	5,2	(36)	± 0,16
h1, h2	0	(36)	± 0,15 (37)
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.

	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 footnote 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

Text of image

Figure 2

Maximum lamp outline (3)

CATEGORIES H11 AND H11B — Sheet H11/2

(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 (38)		25,0  (39)		25,0 ± 0,1
f (38)		4,5	5,3  (39)	4,5 ± 0,1
g		0,5  min.		u.c.
h1		0  (39)		0 ± 0,1
h2		0  (39)		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.

	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, footnote 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

CATEGORY H12 — Sheet H12/2

Dimensions in mm (40)		Tolerance
		Filament lamps of normal production	Standard filament lamp
e (41), (42)	31,5	(43)	± 0,16
f (41), (42)	5,5	4,8 min	± 0,16
h1, h2, h3, h4	0	(43)	± 0,15 (44)
k	0	(43)	± 0,15 (45)
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.

Text of image

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

Text of image

CATEGORIES H13 AND H13A — Sheet H13/2

(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)

Text of image

CATEGORIES H13 AND H13A — Sheet H13/4

Dimensions in mm		Tolerance
		Filaments lamps of normal production		Standard filament lamp
d1 (13), (47)	1,8 max.	—		—
d2 (13), (47)	1,8 max.	—		—
e (46)	29,45	± 0,20		± 0,10
f 1 (46)	4,6	± 0,50		± 0,25
f 2 (46)	4,6	± 0,50		± 0,25
g (8), (47)	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 (10)	0	± 0,20		± 0,13
n (10)	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 (48)
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 drawings

Text of image

Figure 2

Maximum lamp outline (3)

CATEGORY H14 — Sheet H14/2

(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 (49)	26,15	(51)		± 0,1
f1 (49), (50)	5,3	(51)		± 0,1
f2 (49), (50)	5,0	(51)		± 0,1
g	0,3  min.
h1	0	(51)		± 0,1
h2	0	(51)		± 0,15
h3	0	(51)		± 0,15
h4	0	(51)		± 0,15
i	2,7			—
j	2,5	(51)		± 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 CHARACTERISTICS
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.

Text of image

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, footnote 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

Text of image

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  (52)		24  (52)		12  (52)
	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

Text of image

Position of the filaments

Text of image

CATEGORY H15 — Sheet H15/4

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

Reference (*5)		Dimension (*6)		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
IR (8), (11)		4,2	4,6	± 0,40	± 0,60	± 0,20	± 0,30
IC (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
(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 both the reference plane and plane V-V and 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.

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, IR and IC;

(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.

CATEGORIES H16 AND H16B — Sheet H16/1

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

Figure 1

Main drawing

Text of image

Figure 2

Maximum lamp outline (3)

CATEGORIES H16 AND H16B — Sheet H16/2

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

CATEGORIES H16 AND H16B — Sheet H16/3

Dimensions in mm		Filaments lamps of normal production	Standard filament lamp
		12  V	12  V
e (53)		25,0  (54)	25,0 ± 0,1
f (53)		3,2  (54)	3,2 ± 0,1
g		0,5  min.	u.c.
h1		0  (54)	0 ± 0,1
h2		0  (54)	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) H16B: PGJY19-3 in accordance with IEC Publication 60061 (sheet 7004-146-1)
ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS
Rated values	Volts	12	12
	Watts	19	19
Test voltage	Volts	13,2	13,2
Objective values	Watts	26 max.	26 max.
	Luminous flux	500 + 10 %/– 15 %
Reference luminous flux: 370 lm at approximately 12 V			370 lm
Reference luminous flux: 500 lm at approximately 13,2 V			500 lm
Reference luminous flux: 550 lm at approximately 13,5 V			550 lm

CATEGORIES H16 AND H16B — 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.

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, footnote 11, shall lie between lines Z1 and Z2 and between Z3 and Z4.

CATEGORY H17 — Sheet H17/1

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

Text of image

For the notes see sheet H17/6

CATEGORY H17 — Sheet H17/2

Dimensions in mm		Filament lamps of normal production		Standard filament lamp
		12  V		12  V
e		28,5 + 0,35/– 0,15		28,5 + 0,20/– 0,0
p		28,95		28,95
α		max. 40 °		max. 40 °
Cap PU43t-4 in accordance with IEC Publication 60061 (sheet 7004-171-1)
ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS
Rated values	Volts	12  (6)		12  (6)
	Watts	35	35	35	35
Test voltage	Volts	13,2	13,2	13,2	13,2
Objective values	Watts	37 max.	37 max.	37 max.	37 max.
	Luminous flux	900 ± 10 %	600 ± 10 %
Reference luminous flux at approximately			12,0  V	700	450
			13,2  V	900	600

For note 6 see sheet H17/6

CATEGORY H17 — Sheet H17/3

Position of the shield

Text of image

CATEGORY H17 — Sheet H17/4

Position of filaments

Text of image

CATEGORY H17 — Sheet H17/5

Table of the dimensions (in mm) referred to in the drawings on sheets H17/3 and H17/4:

Reference (*7)	Dimension (*8)	Tolerance
		Filament lamps of normal production	Standard filament lamp
a/25,0	0,3	± 0,40	± 0,20
a/26,0	0,3	± 0,35	± 0,20
b1/29,5	0,0	± 0,30	± 0,25
b1/33,0	b1/29,5 mv	± 0,30	± 0,15
b2/29,5	0,0	± 0,30	± 0,25
b2/33,0	b2/29,5 mv	± 0,30	± 0,15
c/29,5	0,5	± 0,25	± 0,15
c/31,0	c/29,5 mv	± 0,25	± 0,15
d	min. 0,1	—	—
e (11)	28,5	+ 0,35/– 0,15	+ 0,20/– 0,0
f (9), (10), (11)	1,7	± 0,30	± 0,15
g/25,0	0	± 0,50	± 0,30
g/26,0	0	± 0,40	± 0,25
h/29,5	0	± 0,40	± 0,25
h/31,0	h/29,5 mv	± 0,30	± 0,15
lR (9), (12)	4,0	± 0,40	± 0,20
lC (9), (12)	4,2	± 0,40	± 0,20
p/33,0	Depends on the shape of the shield	—	—
q/33,0	(p+q)/2	± 0,60	± 0,30

For the notes see sheet H17/6

CATEGORY H17 — Sheet H17/6

Notes:

(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 light emitted from standard filament lamps and from normal production lamps shall be white.

(4)	The bulb and supports shall not exceed the envelope as in Figure 2.

(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.

(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)	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.

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

(9)	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.

(10)	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 note 9.

(11)	e denotes the distance from the reference plane to the beginning of the passing filament as defined above.

(12)	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 0,3 mm below it, with the end turns defined under note 9.

Additional explanations to sheets H17/3 and H17/4

The dimensions below are measured in three directions:

1	For dimensions b1, a, 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 33,0 mm away from the reference plane.

Dimensions b1, b2 are measured in planes parallel to and 29,5 mm and 33,0 mm away from the reference plane.

Dimensions c and h are measured in planes parallel to and 29,5 mm and 31,0 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.

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

CATEGORIES H6W AND HY6W — Sheet H6W/1

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

Text of image

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 (55)					0,75	0,4 max
β			82,5 °	90 °	97,5 °	90° ± 5°
γ1, γ2 (56)			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
(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

Text of image

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 (57)					0,75	0,4 max
β			82,5 °	90 °	97,5 °	90° ± 5°
γ1, γ2 (58)			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
(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.

Text of image

Dimensions in mm			Filament lamps of normal production			Standard filament lamp
			min.	nom.	max.
e				20,0  (59)		20,0 ± 0,25
f		12  V			3,8	3,8 + 0/– 1
		24  V			4,5
Lateral deviation (60)					(59)	0,0 ± 0,15 (61)
β			82,5 °	90 °	97,5 °	90° ± 5°
γ1, γ2 (62)			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
(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

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Reference	a	b	h	k
Dimension	d + 1,0	d + 1,0	f + 1,2	0,50
d = actual filament diameter 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

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

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Dimensions in mm		Filament lamp of normal production	Standard filament lamp
e		31,75  (64)	31,75 ± 0,25
f (66)		4,8 max.	4,2 ± 0,20
k		0  (64)	0,0 ± 0,25
h1, h2, h3, h4 (65)		0  (64)	0,0 ± 0,25
γ1 (63)		38 ° nom.	38 ° nom.
γ2 (63)		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
Objective values	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

Reference	a	c	k	g
Dimensions	d + 1,2	d + 1,0	0,5	2,4
d= actual 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

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CATEGORIES HB3 AND HB3A — Sheet HB3/2

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CATEGORIES HB3 AND HB3A — Sheet HB3/3

Dimensions in mm (71)		Tolerances
		Filament lamps of normal production	Standard filament lamp
e (68), (70)	31,5	(69)	± 0,16
f (68), (70)	5,1	(69)	± 0,16
h1, h2	0	(69)	± 0,15 (67)
h3	0	(69)	± 0,08 (67)
γ1	45 ° min.	—	—
γ2	52 ° min.	—	—
Cap P20d in accordance with IEC Publication 60061 (sheet 7004-31-2) (72)
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.

	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, footnote 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

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CATEGORIES HB4 AND HB4A — Sheet HB4/2

CATEGORIES HB4 AND HB4A — Sheet HB4/3

Dimensions in mm (77)		Tolerances
		Filament lamps of normal production	Standard filament lamp
e (74), (76)	31,5	(75)	± 0,16
f (74), (76)	5,1	(75)	± 0,16
h1, h2	0	(75)	± 0,15 (73)
h3	0	(75)	± 0,08 (73)
g (74)	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) (78)
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.

	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 footnote 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

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CATEGORY HIR1 — Sheet HIR1/2

Dimensions in mm (83)		Tolerances
		Filament lamps of normal production	Standard filament lamp
e (80), (82)	29	(81)	± 0,16
f (80), (82)	5,1	(81)	± 0,16
g (80)	0	+ 0,7/– 0,0	+ 0,4/– 0,0
h1, h2	0	(81)	± 0,15 (79)
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
Objective values	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.

	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 footnote 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

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CATEGORY HIR2 — Sheet HIR2/2

Dimensions in mm (88)		Tolerances
		Filament lamps of normal production	Standard filament lamp
e (85), (87)	28,7	(86)	± 0,16
f (85), (87)	5,3	(86)	± 0,16
g (85)	0	+ 0,7/– 0,0	+ 0,4/– 0,0
h1, h2	0	(86)	± 0,15 (84)
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.

	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 footnote 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

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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
α		max. 40 °				max. 40 °
Cap PX43t in accordance with IEC Publication 60061 (sheet 7004-34-2)
ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS
Rated values	Volts	6  (89)		12  (89)		12  (89)
	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 (90) lm		—		—	450
Reference luminous flux at approximately					12  V	700	450
					13,2  V	825	525

CATEGORY HS1 — Sheet HS1/3

Position of shield

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Position of filaments

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CATEGORY HS1 — Sheet HS1/4

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

Reference (*11)		Dimensions (*12)		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 (*15)		28,5		+ 0,45/– 0,25		+ 0,20/– 0,00
f (*13), (*14), (*15)		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  (*13), (*16)		3,5	4,0	± 0,80		± 0,40
lC  (*13), (*14)		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
(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).

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, IR and IC;

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

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CATEGORY HS2 — Sheet HS2/2

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.
e			11,0  (91)		11,0 ± 0,15
f (92)	6  V	1,5	2,5	3,0	2,5 ± 0,15
	12  V	2,0	3,0	4,0
h1, h2			(91)		0 ± 0,15
α (2)				40 °
β (3)		75 °	90 °	105 °	90° ± 5°
γ1 (4)		15 °			15 ° min.
γ2 (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.

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

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Figure 2

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

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CATEGORY HS5 — Sheet HS5/2

Figure 3

Filament position and dimensions

CATEGORY HS5 — Sheet HS5/3

Dimensions in mm			Filament lamps of normal production		Standard filament lamp
			12  V		12  V
e		26	(93)		± 0,15
lC  (94)		4,6			± 0,3
k		0			± 0,2
h1, h3		0			± 0,15
h2, h4		0			± 0,20
lR  (94)		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.

Side elevation

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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

Reference	h	k
Dimensions	6,0	6,0

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

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Figure 2

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

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CATEGORY HS5A — Sheet HS5A/2

Figure 3

Filament position and dimensions

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CATEGORY HS5A — Sheet HS5A/3

Dimensions in mm			Filament lamps of normal production		Standard filament lamp
			12  V		12  V
e	26		—		—
lC  (95)	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  (95)	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 CHARACTERISTICS
Rated values	Voltage	V	12  (96)		12  (96)
	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

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CATEGORY HS6 — Sheet HS6/2

(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 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)

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CATEGORY HS6 — Sheet HS6/4

Dimensions in mm		Tolerance
		Filaments lamps of normal production		Standard filament lamp
d1 (13), (98)	1,4 max.	—		—
d2 (13), (98)	1,4 max.	—		—
e (97)	29,45	± 0,20		± 0,10
f1 (97)	4,4	± 0,50		± 0,25
f2 (97)	4,4	± 0,50		± 0,25
g (8), (98)	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°
θ (9)	41 °	± 4°		± 4°
Cap PX26.4t in accordance with IEC Publication 60061 (sheet 7004-128-3)
ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS (99)
Rated values	Volts	12		12
	Watts	40	35	40	35
Test voltage	Volts	13,2		13,2
Objective values	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

CATEGORIES P13W AND PW13W — Sheet P13W/1

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

Figure 1

Main drawing P13W

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CATEGORIES P13W AND PW13W — Sheet P13W/2

Dimensions in mm			Filament lamps of normal production	Standard filament lamp
e (101)	P13W		25,0  (100)	25,0 ± 0,25
	PW13W		19,25  (100)	19,25 ± 0,25
f (101)			4,3  (100)	4,3 ± 0,25
α1  (102)			30,0 ° min.	30,0 ° min.
α2  (102)			58,0 ° min.	58,0 ° min.
P13W Cap PG18.5d-1 in accordance with IEC Publication 60061 (sheet 7004-147-1) PW13W Cap WP3.3x14.5-7 in accordance with IEC Publication 60061 (sheet 7004-164-1)
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

CATEGORIES P13W AND PW13W — 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.

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	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, footnote 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, PSR19W, PW19W, PWY19W AND PWR19W — Sheet P19W/1

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

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CATEGORIES P19W, PY19W, PR19W, PS19W, PSY19W, PSR19W, PW19W, PWY19W AND PWR19W — Sheet P19W/2

Dimensions in mm (103)			Filament lamps of normal production			Standard filament lamp
			min.	nom.	max.	(107)
e (104), (105)	P19W, PS19W, PY19W, PSY19W, PR19W, PSR19W			24,0		24,0
	PW19W, PWY19W, PWR19W			18,1		18,1
f (104), (105)				4,0		4,0 ± 0,2
α (106)			58 °			58 ° min.
P19W Cap PGU20-1 in accordance with IEC Publication 60061 (sheet 7004-127-2) PY19W Cap PGU20-2 PR19W Cap PGU20-5 PS19W Cap PG20-1 PSY19W Cap PG20-2 PSR19W Cap PG20-5 PW19W Cap WP3.3x14.5-1 in accordance with IEC Publication 60061 (sheet 7004-164-1) PWY19W Cap WP3.3x14.5-2 PWR19W Cap WP3.3x14.5-5
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 PW19W	350 ± 15 %
		PY19W PSY19W PWY19W	215 ± 20 %
		PR19W PSR19W PWR19W	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, PSR19W, PW19W, PWY19W AND PWR19W — 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.

P19W, PY19W, PR19W, PS19W, PSY19W, PSR19W	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

PW19W, PWY19W and PWR19W	a1	a2	b1, b2	c1	c2
Filament lamps of normal production	2,5	2,5	0,4	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, footnote 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

Text of image

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.
e	6,12  V		31,8  (110)		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 (108)	6,12  V			(110)	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) (109)
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
(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

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

Text of image

Dimensions in mm		Filament lamps of normal production				Standard filament lamp
		min.	nom.	max.
e			31,8  (111)			31,8 ± 0,3
f				7,0		7,0 + 0/– 2
Lateral deviation					(111)	0,3 max. (112)
x, y		(111)				2,8 ± 0,5
β		75 ° (111)		90 ° (111)	105 ° (111)	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

CATEGORY P21/5W — Sheet P21/5W/1

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

Text of image

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

Reference	a	b	c	d	u	v
Dimensions	3,5	3,0	4,8		2,8

Front elevation

Reference	a	h	k
Dimensions	3,5	9,0	1,0

CATEGORIES P24W, PX24W, PY24W, PR24W, PS24W, PSX24W, PSY24W, PSR24W, PW24W, PWY24W AND PWR24W — Sheet P24W/1

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

Text of image

CATEGORIES P24W, PX24W, PY24W, PR24W, PS24W, PSX24W, PSY24W, PSR24W, PW24W, PWY24W AND PWR24W — Sheet P24W/2

Dimensions in mm (114)			Filament lamps of normal production			Standard filament lamp
			min.	nom.	max.	(118)
e (115), (116)	P24W, PY24W, PR24W, PS24W, PSY24W, PSR24W, PX24W, PSX24W			24,0		24,0
	PW24W, PWY24W, PWR24W			18,1		18,1
f (115), (116)	P24W, PY24W, PR24W, PS24W, PSY24W, PSR24W, PW24W, PWY24W, PWR24W			4,0		4,0
	PX24W, PSX24W			4,2		4,2
α (117)			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 PW24W Cap WP3.3x14.5-3 in accordance with IEC Publication 60061 (sheet 7004-164-1) PWY24W Cap WP3.3x14.5-4 PWR24W Cap WP3.3x14.5-6
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 PW24W	500 + 10/– 20 %
		PX24W PSX24W	500 + 10/– 15 %
		PY24W PSY24W PWY24W	300 + 15/– 25 %
		PR24W PSR24W PWR24W	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, PSR24W, PW24W, PWY24W AND PWR24W — 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.

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

PW24W, PWY24W, PWR24W	a1	a2	b1, b2	c1	c2
Filament lamps of normal production	2,5	2,5	0,4	5,0	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, footnote 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

Text of image

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.
e			27,9  (120)		27,9 ± 0,3
f				9,9	9,9 + 0/– 2
Lateral deviation (119)				(120)	0,0 ± 0,4
β		75 ° (120)	90 °	105 ° (120)	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.

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.

Text of image

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

Text of image

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.
e			27,9  (122)		27,9 ± 0,3
f				9,9	9,9 + 0/– 2
Lateral deviation (121)				(122)	0,0 ± 0,4
x (123)			5,1  (122)		5,1 ± 0,5
y (123)			0,0  (122)		0,0 ± 0,5
β		75 ° (122)	90 °	105 ° (122)	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.

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

Reference	a	b	c	d	u
Dimension	3,5	3,0	4,8		5,1

Front elevation

Reference	a	h	k
Dimension	3,5	11,9	1,0

CATEGORIES PC16W, PCY16W, PCR16W, PW16W, PWY16W AND PWR16W — Sheet PC16W/1

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

Text of image

CATEGORIES PC16W, PCY16W, PCR16W, PW16W, PWY16W AND PWR16W — Sheet PC16W/2

Dimensions in mm			Filament lamps of normal production			Standard filament lamp
			min.	nom.	max.	(127)
e (124), (125)	PC16W PCY16W PCR16W			18,5		18,5
	PW16W PWY16W PWR16W			17,1		17,1
f (124), (125)				4,0		4,0 ± 0,2
α (126)			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 PW16W Cap WP3.3x14.5-8 in accordance with IEC Publication 60061 (sheet 7004-164-1) PWY16W Cap WP3.3x14.5-9 PWR16W Cap WP3.3x14.5-10
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 PW16W	300 ± 15 %
		PCY16W PWY16W	180 ± 20 %
		PCR16W PWR16W	70 ± 20 %
Reference luminous flux at approximately				13,5  V		White: 300 lm
						Amber: 180 lm
						Red: 70 lm

CATEGORIES PC16W, PCY16W, PCR16W, PW16W, PWY16W AND PWR16W — 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.

PC16W, PCY16W, PCR16W	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

PW16W, PWY16W and PWR16W	a1	a2	b1, b2	c1	c2
Filament lamps of normal production	2,5	2,5	0,4	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, footnote 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

Text of image

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.	(130)
e	12  V		31,8  (129)		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 (128)	12  V			(129)	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 lm
					Red: 110 lm
(2) The light emitted from normal production lamps shall be red (see also footnote 4). (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

Text of image

Dimensions in mm		Filament lamps of normal production (135)				Standard filament lamp
		min.	nom.	max.		(136)
e			31,8  (131)			31,8 ± 0,3
f				7,0		7,0 + 0/– 2
Lateral deviation				(131)		0,3 max. (132)
x,y		(131)				2,8 ± 0,5
β		75 ° (131)	90 ° (131)	105 ° (131)		90° ± 5°
Cap BAU15d in accordance with IEC Publication 60061 (sheet 7004-19-2)
ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS
Rated values	Volts	12		24  (134)		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 flux at 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 lamp

Text of image

Dimensions in mm		Filament lamps of normal production (140)				Standard filament lamp
		min.		nom.	max.	(141)
e	12  V			31,8  (137)		31,8 ± 0,3
	24  V	30,8		31,8	32,8
f	12  V				7,0	7,0 + 0/– 2
Lateral deviation (138)	12  V				(137)	0,3 max.
	24  V				1,5
x, y	12  V			(137)		2,8 ± 0,3
x	24 V (139)	–1,0		0	1,0
y	24 V (139)	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

Text of image

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.	(145)
e			27,9  (143)		27,9 ± 0,3
f				9,9	9,9 + 0/– 2
Lateral deviation (142)				(143)	0,0 ± 0,4
x (144)			5,1  (143)		5,1 ± 0,5
y (144)			0,0  (143)		0,0 ± 0,5
β		75 ° (143)	90 °	105 ° (143)	90° ± 5°
Cap WU2.5x16q 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. (5) The light emitted from normal production lamps shall be red (see also footnote 6).

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

Text of image

Figure 2

Metal free zone (3)

Text of image

CATEGORY PSX26W — Sheet PSX26W/2

Dimensions in mm			Filament lamps of normal production	Standard filament lamp
e (147)			24,0  (146)	24,0 ± 0,25
f (147)			4,2  (146)	4,2 ± 0,25
α1  (148)			35,0 ° min.	35,0 ° min.
α2  (148)			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 12 V				345 lm
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.

	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, footnote 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

Text of image

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.	(151)
e	12  V		31,8  (150)		31,8 ± 0,3
	24  V	30,8	31,8	32,8
f	12  V			7,0	7,0 + 0/– 2
Lateral deviation (149)	12  V			(150)	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
(2) The light emitted from production lamps shall be amber (see also footnote 4). (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 PY21/5W — Sheet PY21/5W/1

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

Dimensions in mm		Filament lamps of normal production (154)			Standard filament lamp
		min.	nom.	max.	(155)
e			28,6  (152)		28,6 ± 0,3
f				7,0	7,0 + 0/– 2
Lateral deviation (153)				(152)	0,3 max.
x, y			(152)		2,8 ± 0,3
β		75 °	90 °	105 °	90° ± 5°
Cap BA15d-3 (100°/130°) in accordance with IEC Publication 60061 (sheet 7004-173-1)
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 and 6,6 max.
	Luminous flux	270		21
	± %	20		20
Reference luminous flux at approximately 13,5 V					White: 440 lm and 35 lm
					Amber: 270 lm and 21 lm

CATEGORY PY21/5W — Sheet PY21/5W/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 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 PY21/5W — Sheet PY21/5W/3

Dimensions in mm

Side elevation

Reference	a	b	c	d	u	v
Dimensions	3,5	3,0	4,8		2,8

Front elevation

Reference	a	h	k
Dimensions	3,5	9,0	1,0

CATEGORY PY27/7W — Sheet PY27/7W/1

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

Text of image

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.	(159)
e			27,9  (157)		27,9 ± 0,3
f				9,9	9,9 + 0/– 2
Lateral deviation (156)				(157)	0,0 ± 0,4
x (158)			5,1  (157)		5,1 ± 0,5
y (158)			0,0  (157)		0,0 ± 0,5
β		75 ° (157)	90 °	105 ° (157)	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. (5) The light emitted from filament lamps of normal production shall be amber (see also footnote 6).

CATEGORY R2 — Sheet R2/1

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

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ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS
		Filament lamps of normal production						Standard filament lamp
Rated values	Volts	6  (160)		12  (160)		24  (160)		12  (160)
	Watts	45	40	45	40	55	50	45	40
Test voltage	Volts	6,3		13,2		28,0		13,2
Objective values	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 (161)		—	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.

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

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CATEGORY R2 — Sheet R2/3

Filaments and shield position and dimensions (162)
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 (163) b1/33,0		0,20 b1/30,0 mv (164)	± 0,35	± 0,15
b2/30,0 (163) b2/33,0		0,20 b2/30,0 mv (164)	± 0,35	± 0,15
c/30,0 (163) c/33,0		0,50 c/30,0 mv (164)	± 0,30	± 0,15
e	6, 12 V 24 V	28,5 28,8	± 0,35	± 0,15
f	6, 12 V 24 V	1,8 2,2	± 0,40	± 0,20
g		0	± 0,50	± 0,30
h/30,0 (163) h/33,0		0 h/30,0 mv (164)	± 0,50	± 0,30
1/2(p-q)		0	± 0,60	± 0,30
IC		5,5	± 1,50	± 0,50
γ (165)		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

Dimensions in mm			Filament lamps of normal production			Standard filament lamp
			min.	nom.	max.	(168)
e			17,5	19,0	20,5	19,0 ± 0,3
Lateral deviation (167)					1,5	0,3 max.
β			60 °	90 °	120 °	90° ± 5°
Cap:	R5W:	BA15s	in accordance with IEC Publication 60061			(sheet 7004-11A-9) (166)
	RR5W:	BAW15s				(sheet 7004-11E-1)
ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS
Rated values		Volts	6  (169)	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	R5W	50 ± 20 %
		RR5W	(169)	12 ± 25 %
Reference luminous flux at approximately 13,5 V:						White: 50 lm
						Red: 12 lm
(3) The light emitted from filament lamps of normal production shall be white for category R5W and red for category RR5W (see also footnote 4).

CATEGORIES R10W, RY10W AND RR10W — Sheet R10W/1

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

Text of image

Dimensions in mm			Filament lamps of normal production			Standard filament lamp
			min.	nom.	max.	(172)
e			17,5	19,0	20,5	19,0 ± 0,3
Lateral deviation (171)					1,5	0,3 max.
β			60 °	90 °	120 °	90° ± 5°
Cap:	R10W:	BA15s	in accordance with IEC Publication 60061			(sheet 7004-11A-9) (170)
	RY10W:	BAU15s				(sheet 7004-19-2)
	RR10W:	BAW15s				(sheet 7004-11E-1)
ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS
Rated values		Volts	6  (173)	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	(173)	11 max.		11 max.
	Luminous flux	R10W	125 ± 20 %
		RY10W	75 ± 20 %
		RR10W	(173)	30 ± 25 %
Reference luminous flux at approximately 13,5 V:						White: 125 lm
						Amber: 75 lm
						Red: 30 lm
(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 footnote 4)

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

Text of image

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 (174)			–0,2		0,5	0,8	0,5 ± 0,15
b (174)			–0,15		0,2	0,55	0,2 ± 0,15
a (174)			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 (174), (175)			– 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  (176)		12  (176)		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

Text of image

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.
e (177)		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 (178)		–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.

CATEGORY T1.4W — Sheet T1.4W/1

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

Text of image

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 (179)				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
(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.

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 (180)				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	35 ± 20 %
Reference luminous flux: 35 lm at approximately 13,5 V
(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

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 (181)				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

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 (182)				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

Dimensions in mm			Filament lamps of normal production			Standard filament lamp
			min.	nom.	max.	(184)
e			11,2	12,7	14,2	12,7 ± 0,3
Lateral deviation (183)					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  (185)	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	(185)	12 ± 25 %
Reference luminous flux at approximately 13,5 V:						White: 50 lm
						Amber: 30 lm
						Red: 12 lm
(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 footnote 3).

CATEGORIES W10W AND WY10W — Sheet W10W/1

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

Dimensions in mm			Filament lamps of normal production			Standard filament lamp
			min.	nom.	max.
e			15,5	17,0	18,5	17,0 ± 0,3
Lateral deviation (186)					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		6		12	12
	Watts		10			10
Test voltage	Volts		6,75		13,5	13,5
Objective values	Watts		11 max.			11 max.
	Luminous flux	White	125 ± 20 %
		Amber	75 ± 20 %
Reference luminous flux at approximately 13,5 V:						White: 125 lm
						Amber: 75 lm

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

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.
e			25,0  (187)		25,0 ± 0,3
f				7,5	7,5 + 0/– 2
Lateral deviation (188)				(187)	0,3 max.
x (189)			2,8  (187)		2,8 ± 0,3
y (189)			0,0  (187)		0,0 ± 0,3
β		–15 ° (187)	0 °	+ 15° (187)	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

Side elevation

Reference	a	b	c	d	u
Dimensions	3,3	2,8	4,8		2,8

Front elevation

Reference	a	h	k
Dimensions	3,3	9,5	1,0

CATEGORIES W16W AND WY16W — Sheet W16W/1

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

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 (190)					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	White	310 ± 20 %
		Amber	190 ± 20 %
Reference luminous flux at approximately 13,5 V:						White: 310 lm
						Amber: 190 lm

CATEGORY W21W — Sheet W21W/1

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

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.
e			29,0  (192)		29,0 ± 0,3
f				7,5	7,5 + 0/– 2
Lateral deviation (191)				(192)	0,5 max.
β		–15 ° (192)	0 °	+ 15° (192)	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

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

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.
e			25,0  (193)		25,0 ± 0,3
f				7,5	7,5 + 0/– 2
Lateral deviation (194)				(193)	0,3 max.
x (195)			2,8  (193)		2,8 ± 0,3
y (195)			0,0  (193)		0,0 ± 0,3
β		–15 ° (193)	0 °	+ 15° (193)	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

Reference	a	b	c	d	u
Dimension	3,5	3,0	4,8		2,8

Front elevation

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

Dimensions in mm			Filament lamps of normal production			Standard filament lamp
			min.	nom.	max.
e				27,9  (197)		27,9 ± 0,3
f			5,5	6,0	7,0	6,0 ± 0,5
Lateral deviation (196)					(197)	0,0 ± 0,4
β			75 ° (197)	90 °	105 ° (197)	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.
	Luminous flux	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. (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

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.

Text of image

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.
e			25,0  (198)		25,0 ± 0,3
f				7,5	7,5 + 0/– 2
Lateral deviation (199)				(198)	0,3 max.
x (200)			2,8  (198)		2,8 ± 0,3
y (200)			0,0  (198)		0,0 ± 0,3
β		–15 ° (198)	0 °	15 ° (198)	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
(4) The light emitted from normal production lamps shall be red (see also footnote 5). (5) The light emitted from standard filament lamps shall be white or red.

CATEGORY WT21W AND WTY21W — Sheet WT21W/1

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

Text of image

Dimensions in mm			Filament lamps of normal production			Standard filament lamp (203)
			min.	nom.	max.
e		12  V		27,9  (202)		27,9 ± 0,3
		24  V	26,9	27,9	28,9
f					7,5	7,5 + 0/– 2
Lateral deviation (201)		12  V			(202)	0,0 ± 0,4
		24  V			1,5
β			75 ° (202)	90 °	105 ° (202)	90° ± 5°
Cap: WT21W: WUX2.5x16d in accordance with IEC Publication 60061 (sheet 7004-[….]-1) WTY21W: WUY2.5x16d (sheet 7004-[….]-1)
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	WT21W	460 ± 15 %
		WTY21W	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. (4) The light emitted from filament lamps of normal production shall be white for category WT21W and amber for category WTY21W (see also note 5).

CATEGORY WT21W AND WTY21W — Sheet WT21W/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

Reference	a	b	h	k
Dimension	3,5	3,0	9,5	1,0

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 WT21/7W AND WTY21/7W — Sheet WT21/7W/1

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

Text of image

Dimensions in mm		Filament lamps of normal production (6)			Standard filament lamp (7)
		min.	nom.	max.
e			27,9  (3)		27,9 ± 0,3
f				7,5	7,5 + 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: WT21/7W: WZX2.5x16q in accordance with IEC Publication 60061 (sheet 7004-[….]-1) WTY21/7W: WZY2.5x16q (sheet 7004-[….]-1)
ELECTRICAL AND PHOTOMETRIC CHARACTERISTICS
Rated values	Volts	12			12
	Watts	21		7	21	7
Test	Volts	13,5			13,5
Objevtive values	Watts	26,5 max.		8,5 max.	26,5 max.	8,5 max.
	Luminous flux	440 ± 15 %		35 ± 20 %
		280 ± 20 %		22 ± 20 %
Reference luminous flux at approximately 13,5 V:				White: 440 and 35 lm
				Amber: 280 and 22 lm

For the notes see sheet WT21/7W/2.

CATEGORY WT21/7W AND WTY21/7W — Sheet WT21/7W/2

Notes:

(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 WT21/7W/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)	If the minor filament is positioned using an asymmetric support similar to the one shown then the reference key and support structure must be located on the same side of the filament lamp.

(6)	The light emitted from filament lamps of normal production shall be white for category WT21/7W and amber for category WTY21/7W (see also note 7).

(7)	The light emitted from standard filament lamps shall be white for category WT21/7W and white or amber for category WTY21/7W.

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 WT21/7W AND WTY21/7W — Sheet WT21/7W/3

Side Elevation

Reference	a	b	c	d	u
Dimensions	3,5	3,0	4,8		5,1

Front Elevation

Reference	a	h	k
Dimensions	3,5	9,5	1,0

CATEGORY WY2.3W — Sheet WY2.3W/1

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

Text of image

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 (204)				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
(2) The light emitted from production lamps shall be amber (see also footnote 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.

Text of image

Dimensions in mm		Filament lamps of normal production			Standard filament lamp
		min.	nom.	max.
e			29,0  (206)		29,0 ± 0,3
f				7,5	7,5 + 0/– 2
Lateral deviation (205)				(206)	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
(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

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 case a category of filament lamp has more than one value of reference luminous flux specified, the value of 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.

(1)  

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

(2)  

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

(3)  

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

(4)  

(*5)	Not for use in headlamps other than Regulation No 113 class C headlamps.

(5)  

(*6)	All types except from 6 V type.

(6)  

(*7)	6 V types only.

(7)  

(*8)	Only for use in signalling lamps, cornering lamps, reversing lamps and rear registration plate lamps.

(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.

(8)  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.

(9)  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.

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

(11)  d: diameter of filament.

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

(13)  The ends of the filament are defined as the points where, when the viewing direction is as defined in footnote 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).

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

(15)  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.

(16)  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).

(17)  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.

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

(*2)   ‘…/26’ means dimension to be measured at the distance from the reference plane indicated in mm after the stroke.

(*3)   ‘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.

(19)  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.

(20)  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.

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

(22)  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.

(23)  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).

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

(25)  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.

(26)  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.

(27)  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.

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

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

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

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

(32)  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.

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

(34)  The viewing direction is direction (*4) B as shown in the figure on sheet H10/1.

(35)  The ends of the filament are defined as the points where, when the viewing direction (*4) as defined in footnote 9 above, the projection of the outside of the end turns crosses the filament axis.

(36)  To be checked by means of a ‘Box-System’, sheet H10/3 (*4).

(37)  The eccentricity is measured only in viewing directions (*4) 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.

(*4)  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.

(38)  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.

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

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

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

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

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

(44)  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.

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

(46)  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.

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

(48)  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.

(49)  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.

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

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

(52)  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.

(*5)   ‘…/26,0’ means dimension to be measured at the distance from the reference plane indicated in mm after the stroke.

(*6)   ‘31,0 mv’ means the value measured at a distance of 31,0 mm from the reference plane.

(53)  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.

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

(*7)   ‘…/25,0’means dimension to be measured at the distance from the reference plane indicated in mm after the stroke.

(*8)   ‘29,5’mv means the value measured at a distance of 29,5 mm from the reference plane.

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

(56)  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.

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

(58)  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.

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

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

(61)  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.

(62)  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.

(63)  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.

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

(65)  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.

(66)  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.

(67)  The eccentricity is measured only in viewing directions (*9) 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.

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

(69)  To be checked by means of a ‘Box-System’; sheet HB3/4 (*9).

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

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

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

(*9)  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.

(73)  The eccentricity is measured only in viewing directions (*10) 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.

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

(75)  To be checked by means of a ‘Box-System’; sheet HB4/4 (*10).

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

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

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

(*10)  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.

(79)  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.

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

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

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

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

(84)  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.

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

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

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

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

(89)  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.

(90)  Measuring luminous flux according to paragraph 3.9 of this Regulation.

(*11)   ‘…/26’ means dimension to be measured at the distance from the reference plane indicated in mm after the stroke.

(*12)   ‘29,5 mv’ means the value measured at a distance of 29,5 mm from the reference plane.

(*13)  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.

(*14)  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.

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

(*16)  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.

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

(92)  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.

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

(94)  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.

(95)  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.

(96)  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.

(97)  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.

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

d2 is the actual diameter of the driving beam filament.

(99)  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.

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

(101)  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.

(102)  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.

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

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

(105)  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.

(106)  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°.

(107)  The light emitted from standard filament lamps shall be white for categories P19W, PS19W and PW19W; white or amber for categories PY19W, PSY19W and PWY19W; white or red for categories PR19W, PSR19W and PWR19W.

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

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

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

(111)  These dimensions shall be checked by means of a ‘Box-System’  (113) 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.

(112)  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.

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

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

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

(116)  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 P24W/1, the projection of the outside of the end turns crosses the filament axis.

(117)  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°.

(118)  The light emitted from standard filament lamps shall be white for categories P24W, PX24W, PS24W, PSX24W and PW24W; white or amber for categories PY24W, PSY24W and PWY24W; white or red for categories PR24W, PSR24W and PWR24W.

(119)  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.

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

(121)  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.

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

(123)   ‘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.

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

(125)  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.

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

(127)  The light emitted from standard filament lamps shall be white for category PC16W and PW16W; white or amber for category PCY16W and PWY16W; white or red for category PCR16W and PWR16W.

(128)  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.

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

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

(131)  These dimensions shall be checked by means of a ‘Box-System’  (133) 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.

(132)  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.

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

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

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

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

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

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

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

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

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

(142)  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.

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

(144)   ‘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.

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

(146)  To be checked by means of a ‘Box-System’; sheet PSX26W/3.

(147)  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.

(148)  No part of the cap beyond the reference plane shall interfere with angle a2 as shown in Figure 1 on sheet PSX26W/1. The bulb shall be optically distortion free within the angles a1 + a2.

These requirements apply to the whole bulb circumference.

(149)  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.

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

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

(152)  These dimensions shall be checked by means of a ‘box-system’. See sheets PY21/5W/2 and PY21/5W/3. ‘x’ and ‘y’ refer to the major (high-wattage) filament, not to the reference axis.

(153)  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.

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

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

(156)  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.

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

(158)   ‘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.

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

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

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

(162)  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.

(163)  To be measured at the distance from the reference plane indicated in millimetres behind the stroke.

(164)  mv = measured value.

(165)  The angle is only for shield design and has not to be checked on finished filament lamps.

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

(167)  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.

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

(169)  Within RR5W no 6 V rated voltage type specified.

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

(171)  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.

(172)  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.

(173)  Within RR10W no 6 V rated voltage type specified.

(174)  Dimensions a, b, c and 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.

(175)  Admissible angular deviation of the shield plane position from the normal position.

(176)  Values in the left-hand column refer to the driving beam filament. Values in the right-hand column to the passing beam filament.

(177)  Distance related to the luminous centre.

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

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

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

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

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

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

(184)  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.

(185)  Within WR5W no 6 V rated voltage type specified.

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

(187)  To be checked by means of a ‘Box-System’; sheets W15/5W/2 and 3.

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

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

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

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

(192)  To be checked by means of a ‘Box-System’; see sheet W21W/2.

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

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

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

(196)  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.

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

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

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

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

(201)  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.

(202)  To be checked by means of a ‘Box-System’, sheets WT21W/2.

(203)  The light emitted from standard filament lamps shall be white for category WT21W and white or amber for category WTY21W.

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

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

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