1.

APPLICATION FOR EU TYPE-APPROVAL OF A VEHICLE TYPE

1.1.

The application for EU type-approval pursuant to Article 7(1) and (2) of Directive 2007/46/EC of a vehicle type with regard to its sound level shall be submitted by the vehicle manufacturer.

1.2.

A model for the information document is given in Appendix 1.

1.3.

A vehicle representative of the type in respect of which type-approval is sought must be submitted to the technical service responsible for the tests by the vehicle manufacturer.

1.4

At the request of the technical service, a specimen of the exhaust system and an engine of at least the same cylinder capacity and rated maximum power as that fitted to the vehicle in respect of which type-approval is sought must also be submitted.

2.

MARKINGS

2.1.

The exhaust and intake system components, excluding fixing hardware and pipes, must bear:

2.1.1.

the trade mark or name of the manufacturer of the systems and their components;

2.1.2.

the manufacturer's trade description.

2.2.

These markings must be clearly legible and indelible, even when the system is fitted to the vehicle.

3.

GRANTING OF EU TYPE-APPROVAL OF A VEHICLE TYPE

3.1.

If the relevant requirements are satisfied, EU type-approval pursuant to Article 9(3) and, if applicable 10(4) of Directive 2007/46/EC shall be granted.

3.2.

A model for the EU type-approval certificate is given in Appendix 2.

3.3.

An approval number in accordance with Annex VII to Directive 2007/46/EC shall be assigned to each vehicle type approved. The same Member State shall not assign the same number to another vehicle type.

4.

AMENDMENTS TO TYPE-APPROVALS

In the case of changes of the type approved pursuant to this Regulation, the provisions of Articles 13, 14, 15, 16 and 17(4) of Directive 2007/46/EC shall apply

5.

CONFORMITY OF PRODUCTION ARRANGEMENTS

5.1.

Measures to ensure the conformity of production arrangements shall be taken in accordance with the requirements laid down in Article 12 of Directive 2007/46/EC.

5.2.

Special provisions:

5.2.1.

The tests laid down in Annex VI of this Regulation correspond to those referred to in point 2.3.5 of Annex X to Directive 2007/46/EC

5.2.2.

The frequency of inspections referred to in point 3 of Annex X to Directive 2007/46/EC shall normally be once every two years.

5.2.2.a

The limit values set out in the table in Annex III apply with a reasonable tolerance margin during measurement. [Am. 47]

1.

METHODS OF MEASUREMENT

1.1.

The noise made by the vehicle type submitted for approval shall be measured by the two methods described in this Annex for the vehicle in motion and for the vehicle when stationary (1). In the case of a vehicle where an internal combustion engine does not operate when the vehicle is stationary, the emitted noise shall only be measured in motion.

Vehicles having a maximum permissible mass exceeding 2 800 kg shall be subjected to an additional measurement of the compressed air noise with the vehicle stationary in accordance with the specifications of Annex V, if the corresponding brake equipment is part of the vehicle.

1.2.

The two values measured in accordance with the tests set out in point 1.1 shall be entered in the test report and on a form conforming to the model laid down in Appendix 3 to Annex I.

2.

MEASURING INSTRUMENTS

2.1.

Acoustic measurements

The apparatus used for measuring the noise level must be a precision sound-level meter or equivalent measurement system meeting the requirements of class 1 instruments (inclusive of the recommended windscreen, if used). These requirements are described in ‘IEC 61672-1:2002: Precision sound level meters’, second edition, of the International Electrotechnical Commission (IEC).

Measurements shall be carried out using the ‘fast’ response of the acoustic measurement instrument and the ‘A’ weighting curve also described in ‘IEC 61672-1:2002’. When using a system that includes a periodic monitoring of the A-weighted sound pressure level, a reading should be made at a time interval not greater than 30 ms (milliseconds).

The instruments shall be maintained and calibrated in accordance with the instructions of the instrument manufacturer.

2.2.

Compliance with requirements

Compliance of the acoustic measurement instrumentation shall be verified by the existence of a valid certificate of compliance. Those certificates shall be deemed to be valid if certification of compliance with the standards was conducted within the previous 12-month period for the sound calibration device and within the previous 24-month period for the instrumentation system. All compliance testing must be conducted by a laboratory, which is authorized to perform calibrations traceable to the appropriate standards.

2.3.

Calibration of the entire Acoustic Measurement System for Measurement Session

At the beginning and at the end of every measurement session, the entire acoustic measurement system shall be checked by means of a sound calibrator that fulfils the requirements for sound calibrators of precision class 1 according to IEC 60942: 2003. Without any further adjustment the difference between the readings shall be less than or equal to 0,5 dB. If this value is exceeded, the results of the measurements obtained after the previous satisfactory check shall be discarded.

2.4.

Instrumentation for speed measurements

The engine speed shall be measured with instrumentation having an accuracy of ± 2 per cent or better at the engine speeds required for the measurements being performed.

The road speed of the vehicle shall be measured with instrumentation having an accuracy of at least ±0,5 km/h, when using continuous measurement devices.

If testing uses independent measurements of speed, this instrumentation must meet specification limits of at least ±0,2 km/h.

2.5.

Meteorological instrumentation

The meteorological instrumentation used to monitor the environmental conditions during the test shall include the following devices, which meet at least the accuracies listed below:

3.

CONDITIONS OF MEASUREMENT

3.1.

Test Site (2) and ambient conditions

The test site shall be substantially level. The surface of the test track shall be dry. The test site shall be such that when a small omni-directional noise source is placed on its surface at the central point (intersection of the microphone line PP' (3) and the centre line of the vehicle lane CC' (4)), deviations from hemispherical acoustic divergence shall not exceed ± 1 dB

This condition is deemed to be satisfied if the following requirements are met:

Measurements shall not be made under adverse weather conditions. It must be ensured that the results are not affected by gusts of wind.

The meteorological instrumentation should be positioned adjacent to the test area at a height of 1,2 m ± 0,02 m. The measurements shall be made when the ambient air temperature is between + 5 oC and + 40 oC.

The tests shall not be carried out if the wind speed, including gusts, at microphone height exceeds 5 m/s, during the noise measurement interval.

A value representative of temperature, wind speed and direction, relative humidity, and barometric pressure shall be recorded during the noise measurement interval.

Any noise peak which appears to be unrelated to the characteristics of the general noise level of the vehicle shall be ignored in taking the readings.

The background noise shall be measured for a duration of 10 seconds immediately before and after a series of vehicle tests. The measurements shall be made with the same microphones and microphone locations used during the test. The A-weighted maximum noise pressure level shall be reported.

The background noise (including any wind noise) shall be at least 10 dB below the A-weighted noise pressure level produced by the vehicle under test. If the difference between the ambient noise and the measured noise is between 10 and 15 dB(A), the appropriate correction must be subtracted from the readings on the noise-level meter in order to calculate the test results, as in the following table:

3.2.

Vehicle

3.2.1.

The vehicle tested shall be selected in a way so that that all vehicles of the same type which are put on the market fulfil the requirements of this Regulation representative of vehicles to be put on the market as specified by the manufacturer . Measurements shall be made without any trailer, except in the case of non-separable vehicles. Measurements shall be made on vehicles at the test mass mt specified according to the following table: [Am. 48]

Vehicle category

Vehicle test mass (mt)

M1

mt = mro

N1

mt = mro

N2, N3

mt = 50 kg per kW rated engine power

Extra loading to reach the test mass of the vehicle shall be placed above the driven rear axle(s). The extra loading is limited to 75 per cent of the maximum mass allowed for the rear axle. The test mass must be achieved with a tolerance of ± 5 per cent.

If the centre of gravity of the extra loading cannot be aligned with the centre of the rear axle, the test mass of the vehicle shall not exceed the sum of the front axle and the rear axle load in un-laden condition plus the extra loading.

The test mass for vehicles with more than two axles shall be the same as for a two-axle vehicle.

M2, M3

mt = mro — mass of the crew member (if applicable)

3.2.2.

Tyre rolling sound emissions are laid down in Regulation (EC) No 661/2009 on the general safety of motor vehicles. The tyres to be used for the test shall be representative for the vehicle and shall be selected by the vehicle manufacturer and recorded in Appendix 3 to Annex I of this Regulation. They shall correspond to one of the tyre sizes designated for the vehicle as original equipment. The tyre is or will be commercially available on the market at the same time as the vehicle (5). The tyres shall be inflated to the pressure recommended by the vehicle manufacturer for the test mass of the vehicle. The tyres shall have at least legal tread depth.

3.2.3.

Before the measurements are started, the engine shall be brought to its normal operating conditions.

3.2.4.

If the vehicle is fitted with more than two-wheel drive, it shall be tested in the drive which is intended for normal road use.

3.2.5.

If the vehicle is fitted with one or more fans having an automatic actuating mechanism, this system shall not be interfered with during the measurements.

3.2.6.

If the vehicle is equipped with an exhaust system containing fibrous materials, the exhaust system is to be conditioned before the test in accordance with Annex IV.

4.

METHODS OF TESTING

4.1.

Measurement of noise of vehicles in motion

4.1.1.

General test conditions

Two lines, AA' and BB', parallel to line PP' and situated respectively 10 m forward and 10 m rearward of line PP' shall be marked out on the test runway.

At least four measurements shall be made on each side of the vehicle and for each gear. Preliminary measurements may be made for adjustment purposes, but shall be disregarded.

The microphone shall be located at a distance of 7,5 m ±0,05 m from the reference line CC' of the track and 1,2 m ±0,02 m above the ground.

The reference axis for free field conditions (see IEC 61672-1:2002) shall be horizontal and directed perpendicularly towards the path of the vehicle line CC'.

4.1.2.

Specific test conditions for vehicles

4.1.2.1.

Vehicles of category M1, M2 ≤ 3 500 kg, N1

The path of the centreline of the vehicle shall follow line CC' as closely as possible throughout the entire test, from the approach to line AA' until the rear of the vehicle passes line BB'. If the vehicle is fitted with more than two-wheel drive, test it in the drive selection which is intended for normal road use.

If the vehicle is fitted with an auxiliary manual transmission or a multi-gear axle, the position used for normal urban driving shall be used. In all cases, the gear ratios for slow movements, parking or braking shall be excluded.

The test mass of the vehicle shall be be that set out in the Table in point 3.2.1

The test speed vtest is 50 km/h ± 1 km/h. The test speed must be reached, when the reference point is at line PP’.

4.1.2.1.1.

Power to mass ratio index (PMR)

PMR is defined as follows:

PMR = (Pn/mt) x 1 000 in [kW/1 000 kg]

The power to mass ratio index (PMR) is used for the calculation of acceleration.

4.1.2.1.2.

Calculation of acceleration

Acceleration calculations are applicable to M1, N1 and M2 ≤ 3 500 kg categories only.

All accelerations are calculated using different speeds of the vehicle on the test track (6). The formulae given are used for the calculation of awot i, awot i+1 and awot test. The speed either at AA' or PP' is defined as the vehicle speed when the reference point passes AA' (vAA') or PP' (vPP'). The speed at BB’ is defined when the rear of the vehicle passes BB' (vBB'). The method used for determination of the acceleration shall be indicated in the test report.

Due to the definition of the reference point for the vehicle the length of the vehicle (lveh) is considered differently in the formula below. If the reference point is in the front of the vehicle, then l = lveh, mid: l = ½ lveh and rear: l = 0.

4.1.2.1.2.1

The calculation procedure for vehicles with manual transmission, automatic transmission, adaptive transmissions and transmissions with variable gear ratios (CVTs (7)) tested with locked gear ratios is as follows:

awot test = ((vBB'/3.6)2 — (vAA'/3.6)2)/(2*(20+l))

awot test used in the determination of gear selection shall be the average of the four awot test, i during each valid measurement run.

Pre-acceleration may be used. The point of depressing the accelerator before line AA' shall be reported in the vehicle and test data (see Appendix 3 to Annex I).

4.1.2.1.2.2.

The calculation procedure for vehicles with automatic transmissions, adaptive transmissions and continuous variable transmissions (CVTs) tested with non-locked gear ratios is as follows:

awot test used in the determination of gear selection shall be the average of the four awot test, i during each valid measurement run.

Where devices or measures described in point 4.1.2.1.4.2. can be used to control transmission operation for the purpose of achieving test requirements, calculate awot test using the equation:

awot test = ((vBB'/3.6)2 — (vAA'/3.6)2)/(2*(20+l))

Pre-acceleration may be used.

Where devices or measures described in point 4.1.2.1.4.2. are not used, calculate awot test using the equation:

awot_testPP-BB = ((vBB'/3.6)2 — (vPP'/3.6)2)/(2*(10+l))

Pre-acceleration shall not be used.

The location of depressing the accelerator shall be where the reference point of the vehicle passes line AA'.

4.1.2.1.2.3

Target acceleration

The target acceleration a urban defines the typical acceleration in urban traffic and is derived from statistical investigations. It is a function depending on the PMR of a vehicle.

The target acceleration a urban is defined by:

a urban = 0,63 * log10 (PMR) -0,09

4.1.2.1.2.4.

Reference acceleration

The reference acceleration awot ref defines the required acceleration during the accelerated test on the test track. It is a function depending on the power-to-mass ratio of a vehicle. That function is different for specific vehicle categories.

The reference acceleration awot ref is defined by:

a wot ref = 1,59 * log10 (PMR) - 1,41 for PMR ≥ 25

a wot ref = a urban = 0,63 * log10 (PMR) -0,09 for PMR < 25

4.1.2.1.3.

Partial power factor kP

The partial power factor kP (see point 4.1.3.1.) is used for the weighted combination of the test results of the acceleration test and the constant speed test for vehicles of category M1 and N1.

In cases other than a single gear test, a wot ref has to be used instead of a awot test (see point 3.1.3.1.).

4.1.2.1.4.

Gear ratio selection

The selection of gear ratios for the test depends on their specific acceleration potential awot under full throttle condition, according to the reference acceleration awot ref required for the full throttle acceleration test.

Some vehicles may have different software programs or modes for the transmission (e.g. sporty, winter, adaptive). Where the vehicle has different modes leading to valid accelerations, the vehicle manufacturer shall prove to the satisfaction of the technical service, that the vehicle is tested in the mode which achieves an acceleration closest to a wot ref.

4.1.2.1.4.1.

Vehicles with manual transmissions, automatic transmissions, adaptive transmissions or CVTs tested with locked gear ratios

The following conditions for selection of gear ratios are possible:

4.1.2.1.4.2.

Vehicles with automatic transmission, adaptive transmissions and CVTs tested with non-locked gear ratios:

The gear selector position for full automatic operation shall be used.

The acceleration value awot test shall be calculated as defined in point 4.1.2.1.2.2.

The test may then include a gear change to a lower range and a higher acceleration. A gear change to a higher range and a lower acceleration is not allowed. A gear shifting to a gear ratio which is not used in urban traffic shall be avoided.

Therefore, it is permitted to establish and use electronic or mechanical devices, including alternate gear selector positions, to prevent a downshift to a gear ratio which is typically not used at the specified test condition in urban traffic.

The achieved acceleration awot test shall be greater or equal to aurban.

If possible, the manufacturer shall take measures to avoid an acceleration value awot test greater than 2,0 m/s2.

The achieved acceleration a wot test is then used for the calculation of the partial power factor kp (see point 4.1.2.1.3.) instead awot ref.

4.1.2.1.5.

Acceleration test

The manufacturer shall define the position of the reference point in front of line AA' of fully depressing the accelerator. The accelerator shall be fully depressed (as rapidly as is practicable) when the reference point of the vehicle reaches the defined point. The accelerator shall be kept in this depressed condition until the rear of the vehicle reaches line BB'. The accelerator shall then be released as rapidly as possible. The point of fully depressing the accelerator shall be reported in the vehicle and test data in accordance with Appendix 3 to Annex II. The technical service shall have the possibility of pretesting.

In the case of articulated vehicles consisting of two non-separable units regarded as a single vehicle, the semi-trailer shall be disregarded in determining when line BB' is crossed.

4.1.2.1.6.

Constant speed test

The constant speed test shall be carried out with the same gear(s) specified for the acceleration test and a constant speed of 50 km/h with a tolerance of ± 1 km/h between AA' and BB'. During the constant speed test the acceleration control shall be positioned to maintain a constant speed between AA' and BB' as specified. If the gear is locked for the acceleration test, the same gear shall be locked for the constant speed test.

The constant speed test is not required for vehicles with a PMR < 25.

4.1.2.2.

Vehicles of categories M2 > 3 500 kg, M3, N2, N3

The path of the centreline of the vehicle shall follow line CC' as closely as possible throughout the entire test, from the approach to line AA' until the rear of the vehicle passes line BB'. The test shall be conducted without a trailer or semi-trailer. If a trailer is not readily separable from the towing vehicle, the trailer shall not be taken into consideration when assessing the crossing of line BB'. If the vehicle incorporates equipment such as a concrete mixer, a compressor, etc, this equipment shall not be in operation during the test. The test mass of the vehicle shall be according to the table set out in point 3.2.1.

Target conditions of category M2 > 3 500 kg, N2

When the reference point passes line BB', the engine speed nBB’ shall be between 70 per cent and 74 per cent of speed S, at which the engine develops its rated maximum power, and the vehicle speed shall be 35 km/h ± 5 km/h. Between line AA' and line BB' a stable acceleration condition shall be ensured.

Target conditions of category M3, N3:

When the reference point passes line BB', the engine speed nBB' shall be between 85 per cent and 89 per cent of speed S, at which the engine develops its rated maximum power, and the vehicle speed shall be 35 km/h ± 5 km/h. Between line AA' and line BB' a stable acceleration condition shall be ensured.

4.1.2.2.1.

Gear ratio selection

4.1.2.2.1.1.

Vehicles with manual transmissions

Stable acceleration condition shall be ensured. The gear choice is determined by the target conditions. If the difference in speed exceeds the given tolerance, then two gears should be tested, one above and one below the target speed.

If more than one gear fulfils the target conditions, select that gear which is closest to 35 km/h. If no gear fulfils the target condition for vtest, two gears shall be tested, one above and one below vtest. The target engine speed shall be reached under any condition.

A stable acceleration condition shall be ensured. If a stable acceleration cannot be ensured in a gear, this gear has to be disregarded.

4.1.2.2.1.2.

Vehicles with automatic transmissions, adaptive transmissions and transmissions with variable gear ratio (CVTs)

The gear selector position for full automatic operation shall be used. The test may then include a gear change to a lower range and a higher acceleration. A gear change to a higher range and a lower acceleration shall not be permitted. A gear shifting to a gear ratio which is not used in urban traffic, at the specified test condition, shall be avoided. Therefore, it shall be permitted to establish and use electronic or mechanical devices to prevent a downshift to a gear ratio which is typically not used at the specified test condition in urban traffic.

If the vehicle includes a transmission design, which provides only a single gear selection (drive), which limits engine speed during the test, the vehicle shall be tested using only a target vehicle speed. If the vehicle uses an engine and transmission combination that does not fulfil the requirements set out in point 4.1.2.2.1.1., the vehicle shall be tested using only the target vehicle speed. The target vehicle speed (vBB') for the test is = 35 km/h ± 5km/h. A gear change to a higher range and a lower acceleration is allowed after the reference point of the vehicle passes line PP'. Two tests shall be performed, one with the end speed of vtest = vBB' + 5 km/h, and one with the end speed of vtest = vBB' — 5 km/h. The reported noise level is that result which is related to the test with the highest engine speed obtained during the test from AA' to BB'.

4.1.2.2.2.

Acceleration test

When the reference point of the vehicle reaches the line AA' the accelerator control shall be fully depressed (without operating the automatic downshift to a lower range than normally used in urban driving) and held fully depressed until the rear of the vehicle passes BB', but the reference point shall be at least 5 m behind BB'. The accelerator control shall then be released.

In the case of articulated vehicles consisting of two non-separable units regarded as a single vehicle, the semi-trailer shall be disregarded in determining when line BB' is crossed.

4.1.3.

Interpretation of results

The maximum A-weighted sound pressure level indicated during each passage of the vehicle between the two lines AA' and BB' shall be noted. If a noise peak obviously out of character with the general sound pressure level is observed, the measurement shall be discarded. At least four measurements for each test condition shall be made on each side of the vehicle and for each gear ratio. Left and right side may be measured simultaneously or sequentially. The first four valid consecutive measurement results, within 2 dB(A), allowing for the deletion of non valid results (see point 3.1.), shall be used for the calculation of the final result for the given side of the vehicle. The results of each side shall be averaged separately. The intermediate result is the higher value of the two averages mathematically rounded to the first decimal place.

The speed measurements at AA', BB', and PP' shall be noted and used in calculations to the first significant digit after the decimal place.

The calculated acceleration awot test shall be noted to the second digit after the decimal place.

4.1.3.1.

Vehicles of categories M1, N1 and M2 ≤ 3 500 kg

The calculated values for the acceleration test and the constant speed test are given by:

Lwot rep = Lwot (i+1) + k * (Lwot(i)- Lwot (i+1))

Lcrs rep = Lcrs(i+1) + k * (Lcrs (i) — Lcrs (i+1))

Where k = (awot ref — awot (i+1))/(awot (i) — awot (i+1))

In the case of a single gear ratio test the values are the test result of each test.

The final result is calculated by combining Lwot rep and Lcrs rep. The equation is:

Lurban = Lwot rep — kP * (Lwot rep– Lcrs rep)

The weighting factor kP gives the partial power factor for urban driving. In cases other than a single gear test kP is calculated by:

kP = 1 — (aurban/awot ref)

If only one gear was specified for the test kP is given by:

kP = 1 — (aurban/awot test)

In cases where awot test is less than aurban:

kP = 0

4.1.3.2.

Vehicles of categories M2 > 3 500 kg, M3, N2, N3

When one gear is tested the final result is equal to the intermediate result. When two gears are tested the arithmetic mean of the intermediate results shall be calculated.

4.2.

Measurement of noise emitted by stationary vehicles

4.2.1.

Sound level in the vicinity of vehicles

The measurement results shall be entered into the test report referred to in Appendix 3 to Annex I.

4.2.2.

Acoustic measurements

A precision sound level meter, or equivalent measuring system, as defined in point 2.1. shall be used for the measurements

4.2.3.

Test site — local conditions as referred to in figure 1 to Appendix 2 to Annex II

4.2.3.1.

In the vicinity of the microphone, there shall be no obstacle that could influence the acoustical field and no person shall remain between the microphone and the noise source. The meter observer shall be positioned so as not to influence the meter reading.

4.2.4.

Disturbance sound and wind interference

Readings on the measuring instruments produced by ambient noise and wind shall be at least 10 dB(A) below the sound level to be measured. A suitable windscreen may be fitted to the microphone provided that account is taken of its effect on the sensitivity of the microphone (see point 2.1.).

4.2.5.

Measuring method

4.2.5.1.

Nature and number of measurements

The maximum sound level expressed in A-weighted decibels (dB(A)) shall be measured during the operating period referred to in point 4.2.5.3.2.1.

At least three measurements shall be taken at each measuring point.

4.2.5.2.

Positioning and preparation of the vehicle

The vehicle shall be located in the centre part of the test area with the gear selector in the neutral position and the clutch engaged. If the design of the vehicle does not allow this, the vehicle shall be tested in conformity with the manufacturer's prescriptions for stationary engine testing. Before each series of measurements, the engine must be brought to its normal operating condition, as specified by the manufacturer.

If the vehicle is fitted with a fan or fans having an automatic actuating mechanism, this system shall not be interfered with during the sound level measurements.

The engine hood or compartment cover, if so fitted, shall be closed.

4.2.5.3.

Measuring of noise in proximity to the exhaust as referred to in Figure 1 to Appendix 2 to Annex II.

4.2.5.3.1.

Positions of the microphone

4.2.5.3.1.1.

The microphone shall be located at a distance of 0,5 m ±0,01 m from the reference point of the exhaust pipe defined in Figure 1, and at an angle of 45o(± 5o) to the flow axis of the pipe termination. The microphone shall be at the height of the reference point, but not less than 0,2 m from the ground surface. The reference axis of the microphone shall lie in a plane parallel to the ground surface and shall be directed toward the reference point on the exhaust outlet. If two microphone positions are possible, the location farthest laterally from the vehicle longitudinal centreline shall be used. If the flow axis of the exhaust outlet pipe is at 90o to the vehicle longitudinal centreline, the microphone shall be located at the point, which is farthest from the engine.

4.2.5.3.1.2.

For vehicles having an exhaust provided with outlets spaced more than 0,3 m apart, measurements shall be made for each outlet. The highest level shall be recorded.

4.2.5.3.1.3.

In the case of an exhaust provided with two or more outlets spaced less than 0,3 m apart and which are connected to the same silencer, only one measurement shall be made; the microphone position is related to the outlet nearest to one extreme edge of the vehicle or, when such outlet does not exist, to the outlet which is the highest above the ground.

4.2.5.3.1.4.

For vehicles with a vertical exhaust (e.g. commercial vehicles) the microphone shall be placed at the height of the exhaust outlet. Its axis shall be vertical and oriented upwards. It shall be placed at a distance of 0,5 m ±0,01 m from the exhaust pipe reference point, but never less than 0,2 m from the side of the vehicle nearest to the exhaust.

4.2.5.3.1.5.

For exhaust outlets located under the vehicle body, the microphone shall be located a minimum of 0,2 m from the nearest part of the vehicle, at a point closest to, but never less than 0,5 m from the exhaust pipe reference point, and at a height of 0,2 m above the ground, and not in line with the exhaust flow. The angularity requirement in point 4.2.5.3.1.1. may not be met in some cases.

4.2.5.3.2.

Operating conditions of the engine

4.2.5.3.2.1.

Target engine speed

The target engine speed is defined as:

If the vehicle cannot reach such engine speed, the target engine speed shall be 5 per cent below the maximum possible engine speed for that stationary test.

4.2.5.3.2.2.

Test procedure

The engine speed shall be gradually increased from idle to the target engine speed, not exceeding a tolerance band of ± 3 per cent of the target engine speed, and held constant. Then the throttle control shall be rapidly released and the engine speed shall return to idle. The noise level shall be measured during a period of operation consisting of a maintenance of constant engine speed of 1 second and throughout the entire deceleration period, the maximum sound level meter reading, mathematically rounded to the first decimal place, is taken as the test value.

4.2.5.3.2.3.

Test validation

The measurement shall be regarded as valid if the test engine speed does not deviate from the target engine speed by more than ± 3 per cent for at least 1 second.

4.2.6.

Results

At least three measurements for each test position shall be made. The maximum A-weighted sound pressure level indicated during each of the three measurements shall be recorded. The first three valid consecutive measurement results, within 2 dB(A), allowing for the deletion of non valid results (taking into account the specifications of the test site as referred to in point 3.1.), shall be used for the determination of the final result for the given measurement position. The maximum sound level, for all measurement positions, and of the three measurement results, shall constitute the final result.

Vehicle category

Description of vehicle category

Limit values

expressed in dB(A)

[decibels(A)]

Limit values for Type-approval of new vehicle types

Limit values for Type-approval of new vehicle types

Limit values for registration, sale and entry into service of new vehicles

Phase 1 valid from

[2 years after publication]

Phase 2 valid from

[5 years after publication]

Phase 3 valid from

[7 years after publication]

General

Off-road  (1)

General

Off-road  (1)

General

Off-road  (1)

M

Vehicles used for the carriage of passengers

M1

no of seats < 9

70

71  (2)

68

69  (2)

68

69  (2)

M1

no of seats < 9;

power to mass ratio > 150 kW/ton

71

71

69

69

69

69

M2

no of seats > 9; mass < 2 tons

72

72

70

70

70

70

M2

no of seats > 9; 2 tons < mass < 3.5 tons

73

74

71

72

71

72

M2

no of seats > 9; 3.5 tons < mass < 5 tons;

rated engine power < 150 kW

74

75

72

73

72

73

M2

no of seats > 9; 3.5 tons < mass < 5 tons;

rated engine power > 150 kW

76

78

74

76

74

76

M3

no of seats > 9; mass > 5 tons;

rated engine power < 150 kW

75

76

73

74

73

74

M3

no of seats > 9; mass > 5 tons;

rated engine power > 150 kW

77

79

75

77

75

77

N

Vehicles used for the carriage of goods

N1

mass < 2 tons

71

71

69

69

69

69

N1

2 tons < mass < 3.5 tons

72

73

70

71

70

71

N2

3.5 tons < mass < 12 tons;

rated engine power < 75 kW

74

75

72

73

72

73

N2

3.5 tons < mass < 12 tons;

75 < rated engine power < 150 kW

75

76

73

74

73

74

N2

3.5 tons < mass < 12 tons;

rated engine power > 150 kW

77

79

75

77

75

77

N3

mass > 12 tons;

75 < rated engine power < 150 kW

77

78

75

76

75

76

N3

mass > 12 tons;

rated engine power > 150 kW

80

82

78

80

78

80

Vehicle category

Description of vehicle category

Limit values for Type-approval of new vehicle types expressed in dB(A)

[decibels(A)]  (1)

Limit values for type-approval of both new vehicle types and for registration, sale and entry into service of new vehicles expressed in dB(A)

[decibels(A)]  (1)

Phase 1 valid from

[6 years after publication]

Phase 2 valid from

[8 years after publication]

M

Vehicles used for the carriage of passengers

M1

no of seats ≤ 9; ≤ 125 kW/ton

68

68

no of seats ≤ 9; 125kW/ton < power to mass ratio ≤ 150kW/ton

70

70

no of seats ≤ 9; power to mass ratio > 150kW/ton

73

73

M1

no of seats ≤ 4 including driver; power to mass ratio > 200 kw/ton; R point of the driver seat < 450mm from ground

74

74

M2

no of seats > 9; mass ≤ 2,5 tons

69

69

no of seats > 9; 2,5 tons < mass < 3,5 tons

72

72

no of seats > 9; 3,5 tons < mass < 5 tons;

75

75

M3

no of seats > 9; mass > 5 tons; rated engine power ≤ 180 kW

74

74

no of seats > 9; mass > 5 tons; 180 kW < rated engine power ≤ 250 kW

77

77

no of seats > 9; mass > 5 tons; rated engine power > 250 kW

78

78

N

Vehicles used for the carriage of goods

N1

mass < 2,5 tons

69

69

2.5 tons < mass < 3,5 tons

71

71

N2

3,5 tons < mass < 12 tons;

rated engine power < 150 kW

75

75

3,5 tons < mass ≤ 12 tons; rated engine power > 150 kW

76

76

N3

mass > 12 tons; rated engine power ≤ 180 kW

77

77

mass > 12 tons; 180 < rated engine power ≤ 250 kW

79

79

mass > 12 tons; rated engine power >250 kW

81

81

1.

General

Sound absorbing fibrous materials may be used in silencing systems or components thereof where any of the following conditions are fulfilled;

Where none of these conditions is fulfilled, the complete silencing system or components thereof shall be submitted to a conventional conditioning using one of three installations and procedures described below.

1.1.

Continuous road operation for 10 000 km.

1.1.1.

50 ± 20 per cent of this operation shall consist of urban driving and the remaining operation shall be long-distance runs at high speed; continuous road operation may be replaced by a corresponding test-track programme.

1.1.2.

The two speed regimes should be alternated at least twice.

1.1.3.

The complete test programme shall include a minimum of 10 breaks of at least three hours duration in order to reproduce the effects of cooling and any condensation which may occur.

1.2.

Conditioning on a test bench

1.2.1.

Using standard parts and observing the vehicle manufacturer's instructions, the exhaust system or components thereof must be fitted to the vehicle referred to in point 1.3. of Annex I or the engine referred to in point 1.4. of Annex I. In the case of the vehicle referred to in point 1.3 of Annex I, the vehicle must be mounted on a roller dynamometer. In the case of an engine referred to in point 1.4 of Annex I, the engine must be coupled to a dynamometer.

1.2.2.

The test shall be conducted in six six-hour periods with a break of at least 12 hours between each period in order to reproduce the effects of cooling and any condensation which may occur.

1.2.3.

During each six-hour period, the engine shall be run, under the following conditions in turn:

Total duration of the six sequences: three hours.

Each period shall comprise two sequenced sets of those conditions in consecutive order from (a) to (f).

1.2.4.

During the test, the silencing system or components thereof shall not be cooled by a forced draught simulating normal airflow around the vehicle. Nevertheless, at the request of the manufacturer, the silencing system or components thereof may be cooled in order not to exceed the temperature recorded at its inlet when the vehicle is running at maximum speed.

1.3.

Conditioning by pulsation

1.3.1.

The silencing system or components thereof shall be fitted to the vehicle referred to in point 1.3. of Annex I or the engine referred to in point 1.4. of Annex I. In the former case the vehicle shall be mounted on a roller dynamometer.

In the second case, the engine shall be mounted on a dynamometer. The test apparatus, a detailed diagram of which is shown in Figure 1 of the Appendix to this Annex shall be fitted at the outlet of the silencing system. Any other apparatus providing equivalent results shall be acceptable.

1.3.2.

The test apparatus shall be adjusted in a such a way that the exhaust-gas flow is alternatively interrupted and re-established by the quick-action valve for 2 500 cycles.

1.3.3.

The valve shall open when the exhaust-gas back pressure, measured at least 100 mm downstream of the intake flange, reaches a value of between 0,35 and 0,40 kPa. It shall close when this pressure does not differ by more than 10 per cent from its stabilized value with the valve open.

1.3.4.

The time-delay switch shall be set for the duration of gas exhaust resulting from the provisions laid down in point 1.3.3.

1.3.5

Engine speed shall be 75 % of the speed (S) at which the engine develops maximum power.

1.3.6.

The power indicated by the dynamometer shall be 50 % of the full-throttle power measured at 75 % of engine speed (S).

1.3.7.

Any drain holes shall be closed off during the test.

1.3.8.

The entire test shall be completed within 48 hours.

If necessary, one cooling period shall be observed after each hour.

1.

Method of measurement

The measurement is performed at microphone positions 2 and 6 according to Figure 1, with the vehicle stationary. The highest A-weighted noise level shall be registered during venting the pressure regulator and during ventilating after the use of both the service and parking brakes.

The noise during venting the pressure regulator is measured with the engine at idling speed. The ventilating noise is registered while operating the service and parking brakes; before each measurement, the air-compressor unit has to be brought up to the highest permissible operating pressure, and then the engine switched off.

2.

Evaluation of the results

For all microphone positions two measurements are taken. In order to compensate for inaccuracies of the measuring equipment, the metre reading is reduced by 1 dB(A), and the reduced value is taken as the result of measurement. The results are taken as valid if the difference between the measurements at one microphone position does not exceed 2 dB(A). The highest value measured is taken as the result. If this value exceeds the noise limit by 1 dB(A), two additional measurements are to be taken at the corresponding microphone position. In this case, three out of the four results of measurement obtained at this position have to comply with the noise limit.

3.

Limiting value

The sound level shall not exceed the limit of 72 dB(A).

1.

General

These requirements are consistent with the test to be held to check conformity of production (COP) in accordance with point 5 of Annex I.

2.

Testing procedure

The test site and measuring instruments shall be those described in Annex II.

2.1.

The vehicle(s) under test shall be subjected to the test for measurement of sound of vehicle in motion set out in point 4.1. of Annex II.

2.2.

Compressed air sound

Vehicles having maximum mass exceeding 2 800 kg and equipped with compressed air systems must be subjected to the additional test for measurement of the compressed air sound set out in point 1 of Annex V.

2.3.

Additional sound emission provisions

The vehicle manufacturer shall assess the compliance with ASEP by an appropriate evaluation or may perform the test described in Annex VIII.

3.

Sampling and evaluation of the results

One vehicle has to be chosen and subjected to the tests set out in point 2. If the test results fulfil the COP requirements of Annex X of Directive 2007/46/EC, the vehicle shall be considered to be in compliance with the COP provisions compliance with the COP provisions. The applicable COP requirements are the limit values laid down in Annex III with an additional margin of 1 dB(A). [Am. 52]

If one of the test results does not fulfil the COP requirements of Annex X of Directive 2007/46/EC, two more vehicles of the same type shall be tested pursuant to point 2 of this Annex.

If the test results for the second and the third vehicle fulfil the COP requirements of Annex X of Directive 2007/46/EC, the vehicle is considered in compliance with the COP.

If one of the test results of the second or third vehicle does not fulfil the COP requirements of Annex X of Directive 2007/46/EC, the vehicle type shall be considered not to conform to the requirements of this Regulation and the manufacturer shall take the necessary measures to re-establish the conformity

1.

Introduction

This Annex describes the specifications relating to the physical characteristics and the laying of the test track. These specifications based on a special standard (1) describe the required physical characteristics as well as the test methods for these characteristics.

2.

Required characteristics of the surface

A surface is considered to conform to this standard provided that the texture and voids content or sound absorption coefficient have been measured and found to fulfil all the requirements of points 2.1. to 2.4. and provided that the design requirements set out in point 3.2. have been met.

2.1.

Residual voids content

The residual voids content, VC, of the test track paving mixture shall not exceed 8 %. For the measurement procedure, see point 4.1.

2.2.

Sound absorption coefficient

If the surface fails to comply with the residual voids content requirement, the surface shall be acceptable only if its sound absorption coefficient, α ≤ 0,10. For the measurement procedure, see point 4.2. The requirements of point 2.1. and of this point shall be deemed to be met also if only sound absorption has been measured and found to be α ≤ 0,10.

It is to be noted that the most relevant characteristic is the sound absorption, although the residual voids content is more familiar among road constructors. However, sound absorption needs to be measured only if the surface fails to comply with the voids requirement. This is motivated because the latter is connected with relatively large uncertainties in terms of both measurements and relevance and some surfaces therefore erroneously may be rejected when based only on the voids measurement.

2.3.

Texture depth

The texture depth (TD) measured according to the volumetric method (see point 4.3. below) shall be:

TD >0,4 mm

2.4.

Homogeneity of the surface

Every practical effort shall be taken to ensure that the surface is made to be as homogeneous as possible within the test area. This includes the texture and voids content, but it should also be observed that if the rolling process results in more effective rolling at some places than others, the texture may be different and unevenness causing bumps may also occur.

2.5.

Period of testing

In order to check whether the surface continues to conform to the texture and voids content or sound absorption requirements stipulated in this standard, periodic testing of the surface shall be done at the following intervals:

when the surface is new;

if the surface meets the requirements when new, no further periodical testing is required. If it does not meet the requirement when it is new, it may do later because surfaces tend to become clogged and compacted with time.

when the surface is new;

when the noise testing starts (NB: not before four weeks after laying);

then every twelve months.

3.

Test surface design

3.1.

Area

When designing the test track layout it is important to ensure that, as a minimum requirement, the area traversed by the vehicles running through the test strip is covered with the specified test material with suitable margins for safe and practical driving. This shall require that the width of the track is at least 3 m and the length of the track extends beyond lines AA and BB by at least 10 m at either end. Figure 1 shows a plan of a suitable test site and indicates the minimum area which shall be machine laid and machine compacted with the specified test surface material. According to point 4.1.1. of Annex II, measurements have to be made on each side of the vehicle. This can be made either by measuring with two microphone locations (one on each side of the track) and driving in one direction, or measuring with a microphone only on one side of the track but driving the vehicle in two directions. If the latter method is used, then there are no surface requirements on that side of the track where there is no microphone.

3.2.

Design and preparation of the surface

3.2.1.

Basic design requirements

The test surface shall meet four design requirements.

3.2.1.1.

It shall be a dense asphaltic concrete.

3.2.1.2.

The maximum chipping size shall be 8 mm (tolerances allow from 6,3 to 10 mm).

3.2.1.3.

The thickness of the wearing course shall be > 30 mm.

3.2.1.4.

The binder shall be a straight penetration grade bitumen without modification.

3.2.2.

Design guidelines

As a guide to the surface constructor, an aggregate grading curve which will give desired characteristics is shown in Figure 2. In addition, Table 1 gives some guidelines in order to obtain the desired texture and durability. The grading curve fits the following formula:

P (% passing) = 100 . (d/dmax)1/2

where:

d = square mesh sieve size, in mm

dmax= 8 mm for the mean curve

dmax= 10 mm for the lower tolerance curve

dmax= 6,3 mm for the upper tolerance curve

In addition to the requirements set out under points 1 to 3.2.2, the following requirements of ISO 10844:2011 shall be fulfilled or a reference should be made to ISO 10844 : 1994 for a transitional period of 5 years : [Am. 54]

Table 1: Design guidelines

4.

Test method

4.1.

Measurement of the residual voids content

For the purpose of this measurement, cores have to be taken from the track in at least four different positions which are equally distributed in the test area between lines AA and BB (see Figure 1). In order to avoid inhomogeneity and unevenness in the wheel tracks, cores should not be taken in wheel tracks themselves, but close to them. Two cores (minimum) should be taken close to the wheel tracks and one core (minimum) should be taken approximately midway between the wheel tracks and each microphone location.

If there is a suspicion that the condition of homogeneity is not met (see point 2.4.), cores shall be taken from more locations within the test area.

The residual voids content shall be determined for each core, then the average value from all cores shall be calculated and compared with the requirement of point 2.1. In addition, no single core shall have a voids value which is higher than 10 %. The test surface constructor is reminded of the problem which may arise when the test area is heated by pipes or electrical wires and cores must be taken from this area. Such installations must be carefully planned with respect to future core drilling locations. It is recommended to leave a few locations of size approximately 200 x 300 mm where there are no wires/pipes or where the latter are located deep enough in order not to be damaged by cores taken from the surface layer.

4.2.

Sound absorption coefficient

The sound absorption coefficient (normal incidence) shall be measured by the impedance tube method using the procedure specified in ISO 10534-1: ‘Acoustics — Determination of sound absorption coefficient and impedance by a tube method’ (2).

Regarding test specimens, the same requirements shall be followed as regarding the residual voids content (see point 4.1.). The sound absorption shall be measured in the range between 400 Hz and 800 Hz and in the range between 800 Hz and 1 600 Hz (at least at the centre frequencies of third octave bands) and the maximum values shall be identified for both of these frequency ranges. Then these values, for all test cores, shall be averaged to constitute the final result.

4.3.

Volumetric macrotexture measurement

For the purpose of this standard, texture depth measurements shall be made on at least 10 positions evenly spaced along the wheel tracks of the test strip and the average value taken to compare with the specified minimum texture depth. See ISO 10844:1994 ISO10844:2011 for the description of the procedure. [Am. 55]

5.

Stability in time and maintenance

5.1.

Age influence

In common with any other surfaces, it is expected that the tyre/road noise level measured on the test surface may increase slightly during the first 6-12 months after construction.

The surface will achieve its required characteristics not earlier than four weeks after construction. The influence of age on the noise from trucks is generally less than that from cars.

The stability over time is determined mainly by the polishing and compaction by vehicles driving on the surface. It shall be checked according to the Period of testing referred to in point 2.5.

5.2.

Maintenance of the surface

Loose debris or dust which could significantly reduce the effective texture depth must be removed from the surface. In countries with winter climates, salt is sometimes used for de-icing. Salt may alter the surface temporarily or even permanently in such a way as to increase noise and is therefore not recommended.

5.3.

Repaving the test area

If it is necessary to repave the test track, it is usually unnecessary to repave more than the test strip (of 3 m width in Figure 1) where vehicles are driving, provided the test area outside the strip met the requirement of residual voids content or sound absorption when it was measured.

6.

Documentation of the test surface and of tests performed on it

6.1.

Documentation of the test surface

The following data shall be given in a document describing the test surface

6.1.1.

The location of the test track.

6.1.2.

Type of binder, binder hardness, type of aggregate, maximum theoretical density of the concrete (DR), thickness of the wearing course and grading curve determined from cores from the test track.

6.1.3.

Method of compaction (e.g. type of roller, roller mass, number of passes).

6.1.4.

Temperature of the mix, temperature of the ambient air and wind speed during laying of the surface.

6.1.5.

Date when the surface was laid and contractor.

6.1.6.

All or at least the latest test result, including:

6.1.6.1.

The residual voids content of each core.

6.1.6.2.

The locations in the test area from where the cores for voids measurements have been taken.

6.1.6.3.

The sound absorption coefficient of each core (if measured). Specify the results both for each core and each frequency range as well as the overall average.

6.1.6.4.

The locations in the test area from where the cores for absorption measurement have been taken.

6.1.6.5.

Texture depth, including the number of tests and standard deviation.

6.1.6.6.

The institution responsible for tests according to points 6.1.6.1. and 6.1.6.2. and the type of equipment used.

6.1.6.7.

Date of the test(s) and date when the cores were taken from the test track.

6.2.

Documentation of vehicle noise tests conducted on the surface

In the document describing the vehicle noise test(s) it shall be stated whether all the requirements of this standard were fulfilled or not. Reference shall be given to a document according to point 6.1. describing the results which verify this.

1.

General

This Annex describes a measuring method to evaluate compliance of the vehicle with the additional sound emission provisions (ASEP) set out in Article 8.

It is not mandatory to perform actual tests when applying for type-approval. The manufacturer shall sign the declaration of compliance set out in Appendix 1 to this Annex. The type-approval authority may ask for additional information about the declaration of compliance and carry out the tests described below.

The analysis of Annex VIII requires the performance of a test according to Annex II. The test specified in Annex II shall be carried out on the same test track under conditions similar to those required in the tests prescribed in this Annex.

2.

Measuring method

2.1

Measuring instruments and condition of measurements

Unless otherwise specified, the measuring instruments, the conditions of the measurements and the condition of the vehicle are equivalent to those specified in points 2 and 3 of Annex II.

If the vehicle has different modes that affect sound emission, all modes shall comply with the requirements in this Annex where the manufacturer has performed tests to prove to the approval authority compliance with those requirements, the modes used during those tests shall be reported in a test report.

2.2.

Method of testing

Unless otherwise specified, the conditions and procedures of points 4.1 to 4.1.2.1.2.2. of Annex II shall be used. For the purpose of this Annex, single test runs shall be measured and evaluated.

2.3.

Control range

Operation conditions are as follows:

Vehicle speed VAA ASEP: vAA ≥ 20 km/h

Vehicle acceleration awot ASEP: awot ≤ 5,0 4,0  m/s2 [Am. 56]

Engine speed nBB ASEP nBB ≤ 2,0 * PMR-0,222 * s or

nBB ≤ 0,9 * s, whichever is the lowest

Vehicle speed VBB ASEP:

if nBB ASEP is reached in one gear vBB ≤ 70 km/h

in all other cases vBB ≤ 80 km/h

gears k ≤ gear ratio i as determined in Annex II

If the vehicle, in the lowest valid gear, does not achieve the maximum engine speed below 70 km/h, the vehicle speed limit is 80 km/h.

2.4.

Gear ratios

The ASEP requirements apply to every gear ratio k that leads to test results within the control range as defined in point 2.3. of this Annex.

In case of vehicles with automatic transmissions, adaptive transmissions and CVTs (1) tested with non-locked gear ratios, the test may include a gear ratio change to a lower range and a higher acceleration. A gear change to a higher range and a lower acceleration is not allowed. A gear shift which leads to a condition that is not in compliance with the boundary conditions shall be avoided. In such a case, it is permitted to establish and use electronic or mechanical devices, including alternate gear selector positions.

In order for the ASEP test to be representative and repeatable (to the Type Approval Authority), the vehicles shall be tested using production gearbox calibration. [Am. 57]

2.5.

Target conditions

The sound emission shall be measured in each valid gear ratio at the four test points as specified below.

The first test point P1 is defined by using an entry speed vAA of 20 km/h. If a stable acceleration condition cannot be achieved, the speed shall be increased in steps of 5 km/h until a stable acceleration is reached.

The fourth test point P4 is defined by the maximum vehicle speed at BB' in that gear ratio within the boundary conditions according to point 2.3.

The other two test points are defined by the following formula:

Test Point Pj: vBB_j = vBB_1 + ((j — 1)/3) * (vBB_4 — vBB_1) for j = 2 and 3

Where:

vBB_1 = vehicle speed at BB' of test point P1

vBB_4 = vehicle speed at BB' of test point P4

Tolerance for vBB_j: ±3 km/h

For all test points the boundary conditions as specified in point 2.3. shall be met.

2.6.

Test of the vehicle

The path of the centreline of the vehicle shall follow line CC' as closely as possible throughout the entire test, starting from the approach to line AA' until the rear of the vehicle passes line BB'.

At line AA' the accelerator shall be fully depressed. To achieve a more stable acceleration or to avoid a down shift between line AA' and BB' pre-acceleration before line AA' may be used. The accelerator shall be kept in depressed condition until the rear of the vehicle reaches line BB'.

For every separate test run, the following parameters shall be determined and noted:

The maximum A-weighted sound pressure level of both sides of the vehicle, indicated during each passage of the vehicle between the two lines AA' and BB', shall be mathematically rounded to the first decimal place (Lwot, kj). If a sound peak obviously out of character with the general sound pressure level is observed, the measurement shall be discarded. Left and right side may be measured simultaneously or separately.

The vehicle speed readings at AA' and BB' shall be reported with the first significant digit after the decimal place. (vAA, kj; vBB, kj)

If applicable, the engine speed readings at AA' and BB' shall be reported as a full integer value (nAA, kj; nBB, kj).

The calculated acceleration shall be determined in accordance to the formula in point 4.1.2.1.2. of Annex II and reported to the second digit after the decimal place (awot, test, kj).

3.

Analysis of results

3.1.

Determination of the anchor point for each gear ratio

For measurements in gear i and lower, the anchor point consists of the maximum sound level Lwoti, the reported engine speed nwoti and vehicle speed vwoti at BB' of gear ratio i of the acceleration test in Annex II.

Lanchor, i = Lwoti, Annex II

nanchor, i = nBB, woti, Annex II

vanchor, i = vBB, woti, Annex II

For measurements in gear i+1 the anchor point consists of the maximum sound level Lwoti+1, the reported engine speed nwoti+1 and vehicle speed vwoti+1 at BB' of gear ratio i+1 of the acceleration test in Annex II.

Lanchor, i+1 = Lwoti+1,Annex II

nanchor, i+1 = nBB, woti+1,Annex II

vanchor, i+1 = vBB, woti+1,Annex II

3.2.

Slope of the regression line for each gear

The sound measurements shall be evaluated as function of engine speed according to point 3.2.1.

3.2.1.

Calculation of the slope of the regression line for each gear

The linear regression line is calculated using the anchor point and the four correlated additional measurements.

(in dB/1000 min-1)

where nj = engine speed measured at line BB’

3.2.2.

Slope of the regression line for each gear

The Slopek of a particular gear for the further calculation is the derived result of the calculation in point 3.2.1 rounded to the first decimal place, but not higher than 5 dB/1000 min-1.”

3.3.

Calculation of the linear noise level increase expected for each measurement

The sound level LASEP, kj for measurement point j and gear k shall be calculated using the engine speeds measured for each measurement point, using the slope specified in point 3.2. to the specific anchor point for each gear ratio.

For nBB_k, j ≤ nanchor, k:

LASEP_k, j = Lanchor_k + (Slopek — Y) * (nBB_k, j — nanchor, k)/1000

For nBB_k, j > nanchor, k:

LASEP_k, j = Lanchor_k + (Slopek + Y) * (nBB_k, j — nanchor, k)/1000