PART 1U.K.MODEL

INFORMATION DOCUMENT No …relating to EC type-approval of a vehicle with regard to hydrogen propulsionU.K.

The following information shall be supplied in triplicate and include a list of contents. Any drawings shall be supplied in appropriate scale and in sufficient detail on size A4 or on a folder of A4 format. Photographs, if any, shall show sufficient detail.

If the systems or components have electronic controls, information concerning their performance shall be supplied.

Appendix to information documentU.K.Statement of Service for Hydrogen Containers

PART 2U.K.MODELMaximum format: A4 (210 × 297 mm)

EC TYPE-APPROVAL CERTIFICATEU.K.

Stamp of type-approval authorityU.K.

Communication concerning:

with regard to Regulation (EC) No 79/2009, as implemented by Regulation (EU) No 406/2010.

EC type-approval number:

Reason for extension:

SECTION IU.K.

0.1.Make (trade name of manufacturer):U.K.

0.2.

Type:U.K.

0.2.1.Commercial name(s) (if available):U.K.

0.3.

Means of identification of type, if marked on the vehicle(1):U.K.

0.3.1.Location of that marking:U.K.

0.4.Category of vehicle(2):U.K.

0.5.Name and address of manufacturer:U.K.

0.8.Name(s) and address(es) of assembly plant(s):U.K.

0.9.Name and address of the manufacturer's representative (if any):U.K.

SECTION IIU.K.

1.Additional information (where applicable): see AddendumU.K.

2.Technical service responsible for carrying out the tests:U.K.

3.Date of test report:U.K.

4.Number of test report:U.K.

5.Remarks (if any): see AddendumU.K.

6.Place:U.K.

7.Date:U.K.

8.Signature:U.K.

AddendumU.K.to EC type-approval certificate No …relating to EC type-approval of a vehicle with regard to hydrogen propulsion

1.

Additional information

1.1.Vehicle equipped with hydrogen system designed to use liquid hydrogen / hydrogen system designed to use compressed (gaseous) hydrogen(3)

2.

Type-approval number of each hydrogen component or system installed on the vehicle type to comply with this Regulation

2.1.Hydrogen system(s):

2.2.Automatic shut-off valve(s):

2.3.Check valve(s) or non-return valve(s):

2.4.Container(s) and container assembly:

2.5.Fittings:

2.6.Flexible fuel line(s):

2.7.Heat exchanger(s):

2.8.Hydrogen filter(s):

2.9.Hydrogen leakage detection sensors:

2.10.Manual or automatic valve(s):

2.11.Pressure and/or temperature and/or hydrogen and/or flow sensor(s)(3):

2.12.Pressure regulator(s):

2.13.Pressure relief device:

2.14.Pressure relief valve:

2.15.Refuelling connection or receptacle:

2.16.Removable storage system connector:

3.Remarks:

PART 3U.K.Information to be provided for inspection

1.Manufacturers shall provide:U.K.

2.Manufacturers shall make the information specified in section 1 available to approval authorities and the competent authorities in the Member States responsible for the periodic inspection of vehicles in the form of manuals or by means of electronic media (e.g. CD-ROM, on-line services).U.K.

PART 1U.K.MODEL

INFORMATION DOCUMENT Norelating to EC component type-approval of a hydrogen component or systemU.K.

The following information shall be supplied in triplicate and include a list of contents. Any drawings shall be supplied in appropriate scale and in sufficient detail on size A4 or on a folder of A4 format. Photographs, if any, shall show sufficient detail.

If the systems or components have electronic controls, information concerning their performance shall be supplied.

Appendix to information documentU.K.Statement of Service for Hydrogen Containers

Specifications of containers designed to use compressed (gaseous) hydrogen

PART 2U.K.MODELMaximum format: A4 (210 × 297 mm)

EC TYPE-APPROVAL CERTIFICATEU.K.

Stamp of type-approval authorityU.K.

Communication concerning:

with regard to Regulation (EC) No 79/2009, as implemented by Regulation (EU) No 406/2010.

EC type-approval number:

Reason for extension:

SECTION IU.K.

0.1.Make (trade name of manufacturer):U.K.

0.2.Type:U.K.

0.3.

Means of identification of type, if marked on the component(5) U.K.

0.3.1.Location of that marking:U.K.

0.5.Name and address of manufacturer:U.K.

0.7.In the case of components and separate technical units, location and method of affixing of the EC approval mark:U.K.

0.8.Name(s) and address(es) of assembly plant(s):U.K.

0.9.Name and address of the manufacturer's representative (if any):U.K.

SECTION IIU.K.

1.Additional information (where applicable): see AddendumU.K.

2.Technical service responsible for carrying out the tests:U.K.

3.Date of test report:U.K.

4.Number of test report:U.K.

5.Remarks (if any): see AddendumU.K.

6.Place:U.K.

7.Date:U.K.

8.Signature:U.K.

AddendumU.K.to EC type-approval certificate No …relating to EC component type-approval of a hydrogen component or system

1.Additional information

1.1.Hydrogen system designed to use liquid hydrogen / Hydrogen system designed to use compressed (gaseous) hydrogen / Hydrogen component designed to use liquid hydrogen / Hydrogen component designed to use compressed (gaseous) hydrogen(6)

2.Specifications and test results

2.1.Containers designed to use compressed (gaseous) hydrogen

2.1.1.Container material specifications

2.1.2.Container material test results

2.1.3.Container test results

3.Restriction of use of the device (if any):

4.Remarks:

PART 3U.K. EC component type-approval mark

1.

The EC component type-approval mark shall consist of:U.K.

1.1.a rectangle surrounding the lower-case letter ‘e’ followed by the distinguishing letter(s) or number of the Member State which has granted the EC component type-approval:U.K.

1.2.In the vicinity of the rectangle the ‘base approval number’ contained in Section 4 of the type-approval number preceded by the two figures indicating the sequence number assigned to this Regulation or the latest major technical amendment to Regulation (EC) No 79/2009 or this Regulation. For this Regulation, the sequence number is 00.U.K.

2.The component type-approval mark is affixed to the component or system in such a way as to be indelible and clearly legible.U.K.

3.An example of a component type-approval mark is contained in the Addendum.U.K.

Addendum to appendix 1U.K.Example of a component type-approval mark

Legend: the above component type-approval was issued by Belgium under number 0004. The first two digits (00) indicate that the component was approved according to this Regulation.

1.INTRODUCTIONU.K.

This Annex sets out the requirements and test procedures for hydrogen components and systems designed to use liquid hydrogen and their installation on hydrogen powered vehicles.

2.GENERAL REQUIREMENTSU.K.

2.1.The materials used in a hydrogen component or system shall be compatible with hydrogen in its liquid and/or gaseous state according to section 4.11. of Part 3.U.K.

PART 1U.K.Requirements for the installation of hydrogen components and systems designed to use liquid hydrogen on hydrogen powered vehicles

1.General requirementsU.K.

1.1.All hydrogen components and systems shall be installed on the vehicle and connected in accordance with best practice.U.K.

1.2.The hydrogen system(s) shall show no leaks other than the boil-off at Maximum Allowable Working Pressure (MAWP), i.e. stay bubble-free if using leak-detecting spray.U.K.

1.3.The operating temperatures should be:U.K.

1.4.Appropriate automatic measures shall be adopted in coordination with the refuelling station to ensure that no uncontrolled hydrogen release occurs during the filling procedure.U.K.

1.5.In the event of hydrogen leakage or venting, hydrogen shall not be allowed to accumulate in enclosed or semi-enclosed spaces of the vehicle.U.K.

2.Installation of the hydrogen container on-board of a vehicleU.K.

2.1.The container can be integrated into the vehicle design to provide complementary functions. In such cases the container shall be designed to fulfil the integrated function requirements and the container requirements set out in Part 2.U.K.

2.2.When the vehicle is ready for use the lowest part of the hydrogen container shall not reduce the ground clearance of the vehicle. This shall not apply if the hydrogen container is adequately protected, at the front and the sides, and no part of the hydrogen container is located lower than this protective structure.U.K.

2.3.

The hydrogen container(s) including the safety devices affixed at it must be mounted and fixed so that the following accelerations can be absorbed without breaking of the fixation or loosening of the container(s) (demonstrated by testing or calculation). The mass used shall be representative for a fully equipped and filled container or container assembly.U.K.

Vehicle of categories M₁ and N₁:U.K.

Vehicles of categories M₂ and N₂:U.K.

Vehicles of categories M₃ and N₃:U.K.

2.4.The provisions of section 2.3 shall not apply if the vehicle is approved according to Directives 96/27/EC and 96/79/EC of the European Parliament and of the Council(7) (8).U.K.

3.Accessories fitted to the hydrogen containerU.K.

3.1. Automatic shut-off valves or non-return valves U.K.

3.1.1.Automatic shut-off valves shall be used in compliance with section 6. of Annex VI to Regulation (EC) No 79/2009, except for the boil-off management system and shall be idle closed.U.K.

3.1.2.Refuelling connections or receptacles shall be used in compliance wit section 4. of Annex VI to Regulation (EC) No 79/2009.U.K.

3.1.3.In the event that the container is displaced, the first isolating device and, if applicable, the line connecting it to the container shall be protected in such a manner that the shut-off function remains operational and the connection between the device and the container cannot be ruptured.U.K.

3.1.4.The automatic valves shall be closed idle (fail-safe).U.K.

3.1.5.When another hydrogen conversion system is switched off, irrespective of the position of the activation switch, the fuel supply to the respective hydrogen conversion system shall be switched off and remain closed until the respective hydrogen conversion system is required to operate.U.K.

3.2. Pressure relief devices U.K.

3.2.1.The pressure triggered pressure relief devices shall be fitted to the hydrogen container(s) in such a manner that they must discharge into an atmospheric outlet line that vents outside the vehicle. They shall not discharge at a heat source such as the exhaust. Additionally they shall discharge such that hydrogen cannot enter the inside of the vehicle and/or accumulate in an enclosed space. Additionally the first pressure relief device shall not discharge into a partially enclosed space. In case the secondary pressure relief device is a burst disc and is installed within the inner tank, an appropriate exhaust vent in the outer jacket is required.U.K.

3.2.2.In the case of inner tanks, the normal operating range of the inner tank pressure is between 0 MPa and the set pressure of the primary safety relief device which is lower or equal to the Maximum Allowable Working Pressure (MAWP) of the inner tank.U.K.

3.2.3.

In the case of steel inner tanks, the lower limit of the impermissible fault range corresponds to a pressure higher than 136 per cent of the Maximum Allowable Working Pressure (MAWP) of the inner tank if a safety valve is used as secondary pressure relief device. In case of steel inner tanks, the lower limit of the impermissible fault range corresponds to a pressure higher than 150 per cent of the Maximum Allowable Working Pressure (MAWP) of the inner tank if a burst disk is used as secondary pressure relief device. For other materials an equivalent level of safety is to be applied. The impermissible fault range shall be the pressure at which plastic deformation or bursting of the inner tank occurs as shown in Figure 3.2.U.K.

3.3. Gas tight housing on the hydrogen container(s) U.K.

3.3.1.All non-welded connections of hydrogen-carrying components and the hydrogen components which can leak, that are mounted within the passenger or luggage compartment or other non-ventilated compartment, shall be enclosed by a gas tight housing.U.K.

3.3.2.The gas tight housing shall be vented to the atmosphere.U.K.

3.3.3.The ventilation opening of the gas tight housing shall be at the highest point of the housing and shall not discharge at a heat source such as the exhaust. Additionally it shall discharge such that hydrogen cannot enter the inside of the vehicle and/or accumulate in an enclosed or partially enclosed space.U.K.

3.3.4.There shall be no unprotected ignition sources inside the gas tight housing.U.K.

3.3.5.Any connecting system and lead-through in the body of the vehicle for ventilation of the gas tight housing shall have at least the same cross sectional area as the tube of the pressure relief device.U.K.

3.3.6.This housing shall be for test purposes hermetically sealed and shall be gas tight at a pressure of 0,5 kPa, i.e. bubble-free for 1 minute and without any permanent deformation.U.K.

3.3.7.Any connecting system shall be secured by clamps, or other means, to the gas tight housing and the lead-through to ensure that a gas tight joint is formed.U.K.

4.Rigid and flexible fuel linesU.K.

4.1.Rigid fuel lines shall be secured such that they shall not be subjected to abrasion, critical vibration and/or other stresses.U.K.

4.2.Flexible fuel lines shall be secured such that they shall not be subjected to torsional stresses, abrasion is avoided and cannot be squeezed in normal use.U.K.

4.3.At the fixing points the fuel lines, flexible or rigid, shall be fitted in such a way that they cannot make a metal to metal contact to prevent galvanic and crevice corrosion.U.K.

4.4.Rigid and flexible fuel lines shall be routed to reasonably minimise exposure to accidental damage whether inside e.g. due to placing or movement of luggage or other loads, or outside the vehicle, e.g. due to rough ground or vehicle jacks etc.U.K.

4.5.At penetration through the vehicle body or other hydrogen components, the fuel lines shall be fitted with grommets or other protective material.U.K.

5.Fittings or gas connections between the componentsU.K.

5.1.Stainless steel tubes shall only be joined by stainless steel fittings.U.K.

5.2.The number of joints shall be limited to a minimum.U.K.

5.3.Any joints shall be made in locations where access is possible for inspection and leak testing.U.K.

5.4.In a passenger or enclosed luggage compartment, the fuel lines shall be no longer than reasonably required.U.K.

6.Refuelling connection or receptacleU.K.

6.1.The refuelling connection or receptacle shall be secured against maladjustment and shall be protected from dirt and water. It shall be safe against handing errors.U.K.

6.2.The refuelling connection or receptacle shall not be installed in the engine compartment, passenger compartment or in any other unventilated compartment.U.K.

6.3.The refuelling line shall be secured at the container as described in section 3.1.1.U.K.

6.4.The refuelling connection or receptacle shall have an isolating device according to section 3.1.2.U.K.

6.5.It shall be ensured that the propulsion system cannot be operated and the vehicle cannot move while the refuelling connection or receptacle is connected to the filling station.U.K.

7.Electrical installationU.K.

7.1.The electrical components of the hydrogen system shall be protected against overloads.U.K.

7.2.Power supply connections shall be tight against the ingress of hydrogen where hydrogen components are present or hydrogen leaks are possible.U.K.

8.Boil-off under normal conditionsU.K.

8.1.Boil-off gases shall be rendered harmless by a boil-off management system.U.K.

8.2.The boil-off management system shall be designed to accept the boil-off rate of the container(s) under normal operating conditions.U.K.

8.3.At start-up and during the operation of the vehicle, a warning system shall be activated to warn the driver in the event of the boil off management system failure.U.K.

9.Other requirementsU.K.

9.1.All pressure relief devices and vent line(s) shall be protected against vandalism so far as reasonably practicable.U.K.

9.2.The passenger compartment, the luggage compartment and all safety-critical components of the vehicle (e.g. the brake system, electrical insulation) shall be protected against adverse temperature effects due to the cryogenic fuel. Possible leakage of the cryogenic fuel shall be considered when assessing the protection that is required.U.K.

9.3.Flammable materials used in the vehicle shall be protected from liquefied air that may condense on un-insulated elements of the fuel system.U.K.

9.4.Failure of the heating circuit of the heat exchanger shall not cause leakage from the hydrogen system.U.K.

10.Safety instrumented systemsU.K.

10.1.Safety instrumented systems shall be fail-safe, redundant or self-monitoring.U.K.

10.2.If the safety-instrumented systems under section 10.1. are fail-safe or self-monitoring electronic systems, the special requirements of Annex VI to this Regulation shall be applied.U.K.

11.Requirements for the inspection of the hydrogen systemU.K.

11.1.Each hydrogen system shall be inspected at least every 48 months after the date of its entry into service, and at the time of any re-installation.U.K.

11.2.The inspection shall be performed by a technical service, in accordance with the manufacturers specifications set out in Part 3 of Annex I.U.K.

PART 2U.K.Requirements for hydrogen containers designed to use liquid hydrogen

1.INTRODUCTIONU.K.

This Part sets out the requirements and test procedures for hydrogen containers designed to use liquid hydrogen.

2.TECHNICAL REQUIREMENTSU.K.

2.1.The design validation of the container by calculation shall be done in accordance with EN 1251-2.U.K.

2.2.Mechanical stressesU.K.

The parts of the container shall withstand the following mechanical stresses:U.K.

2.2.1.Inner tankU.K.

2.2.1.1.Test pressureU.K.

The inner tank shall resist the test pressure P_test:

P_test = 1,3 (MAWP + 0,1 MPa)

with MAWP being the Maximum Allowable Working Pressure of the inner tank in MPa

2.2.1.2.Outer pressureU.K.

If an operating mode of the inner tank and its equipment under vacuum is possible, the inner tank and its equipment shall resist an outer pressure of 0,1 MPa.

2.2.2.Outer jacketU.K.

2.2.2.1.The outer jacket shall resist the Maximum Allowable Working Pressure (MAWP), which is the set pressure of its safety device.U.K.

2.2.2.2.The outer jacket shall resist an outer pressure of 0,1 MPa.U.K.

2.2.3.Outer supportsU.K.

The outer supports of the full container shall resist the accelerations referred to in section 2.3 of Part 1 without rupture, in which case the allowable stress in the support elements calculated according to linear stress model shall not exceed:

σ ≤ 0,5 Rm

2.2.4.Inner supportsU.K.

The inner supports of the full container shall resist the accelerations referred to in section 2.3 of Part 1 without rupture, in which case the allowable stress in the support elements calculated according to linear stress model shall not exceed:

σ ≤ 0,5 Rm

2.2.5.The requirements of sections 2.2.3. and 2.2.4. do not apply if it can be demonstrated that the tank may support the accelerations referred to in section 2.3 of Part 1 without any leak on the inner tank and all the different pipes upstream of the automatic safety devices, shut off valves and/or non-return valves.U.K.

2.2.6.The proof of the dimensioning of the supports of the container can be done either by calculation or by experiment.U.K.

2.3.Design temperatureU.K.

2.3.1.Inner tank and outer jacketU.K.

The design temperature of the inner tank and the outer jacket shall be 20 °C.

2.3.2.Other equipmentU.K.

For all other equipment which is not mentioned under section 2.3.1. the design temperature is the lowest respectively the highest possible operating temperature set out in section 1.3. of Part 1.

2.3.3.The thermal stresses by operating conditions like filling or withdrawal or during the cooling down processes shall be considered.U.K.

2.4.Chemical compatibilityU.K.

2.4.1.The materials of the container and its equipment shall be compatible with:U.K.

3.MATERIALSU.K.

3.1.The materials shall be composed, manufactured and further treated in a manner that:U.K.

3.2.CharacteristicsU.K.

3.2.1.Materials used at low temperatures shall follow the toughness requirements of EN 1252-1. For non-metallic materials low temperature suitability shall be validated by an experimental method, taking into account service conditions.U.K.

3.2.2.The materials used for the outer jacket shall ensure the integrity of the insulation system, and their elongation at fracture in a tensile test shall be at least 12 per cent at liquid nitrogen temperature.U.K.

3.2.3.A corrosion allowance is not required for the inner tank. A corrosion allowance is not required on other surfaces if they are adequately protected against corrosion.U.K.

3.3.Certificates and proofs of the material characteristicsU.K.

3.3.1.The filler materials shall be compatible with the parent material so as to form welds with properties equivalent to those specified for the parent material for all temperatures that the material may encounter.U.K.

3.3.2.The manufacturer shall obtain and provide chemical cast analysis and mechanical properties certificates of the material in respect of the steels or other materials used in the construction of the parts subject to pressure. In case of metallic materials the certificate must be at least type 3.1 according to EN 10204 or equivalent. In case of non-metallic materials the certificate must be of equivalent type.U.K.

3.3.3.The technical service may carry out analyses and examinations. These examinations shall be carried out either on specimens taken from the materials as supplied to the manufacturer of the container or on the finished containers.U.K.

3.3.4.The manufacturer shall make available to the technical service the results of metallurgical and mechanical tests and analyses of parent and filler materials carried out on welds.U.K.

3.3.5.Material sheets shall be marked at least with:U.K.

• sign of the manufacturer

• material identification number

• batch number

• sign of the inspecting person

3.4.Design calculationU.K.

3.4.1.Provisions regarding the inner tank:U.K.

The design of the inner tank shall be done according to the design rules of EN 1251-2.

3.4.2.Provisions regarding the outer jacket:U.K.

The design of the outer jacket shall be done according to the design rules of EN 1251-2.

3.4.3.The general tolerances of ISO 2768-1 shall apply.U.K.

4.MANUFACTURING AND MOUNTING OF THE CONTAINERU.K.

4.1.Manufacturers of welded containers shall have a welding quality system in operation, taking into account the quality requirements for welding in accordance with EN 729-2:1994 or EN 729-3:1994.U.K.

4.2.The welding process shall be approved by the technical service in accordance with EN 288-3:1992/A1:1997, EN 288-4:1992/A1:1997 and EN 288-8:1995.U.K.

4.3.Welders shall be approved by the technical service according to EN 287-1:1992/A1:1997, EN 287-2:1992/A1:1997 and for automatic welding operators in accordance with EN 1418:1997.U.K.

4.4.Manufacturing operations (e.g. forming and heat treatment, welding) shall be carried out according to EN 1251-2.U.K.

4.5.The inspections and the testing of the internal pipe work between the inner tank and the outer jacket: all welded joints of the pipe work shall be subject to 100 per cent non-destructive inspection, wherever possible by radiographic inspection, alternatively ultrasonic test, liquid penetrant testing, helium leakage test, etc.U.K.

4.6.The number of joints should be minimised. Joints shall not be permitted within the void between the inner tank and the outer jacket unless they are welded or glued.U.K.

4.7.The equipment of the container shall be mounted in a way that the system and its components function in a correct and safe way and are gas tight.U.K.

4.8.The container shall be cleaned and dried before operation according to EN 12300.U.K.

5.OTHER REQUIREMENTSU.K.

5.1.Protection of the outer jacketU.K.

The outer jacket shall be protected by means of a device preventing bursting of the outer jacket or collapsing of the inner tank.

5.2.Provisions regarding the insulationU.K.

5.2.1.Under no circumstances may ice be allowed to form on the outer wall of the container under normal operating conditions. At the area of pressure relief pipe, local ice formation is allowed on the outside of the pipe.U.K.

5.3.Level gaugeU.K.

5.3.1.A measuring gauge in the driver's compartment shall indicate the level of liquid in the container with an accuracy of +/- 10 per cent.U.K.

5.3.2.If the system comprises a float, the latter shall withstand an outside pressure greater than the Maximum Allowable Working Pressure (MAWP) of the inner tank with a minimum coefficient of safety of 2 with respect to the buckling failure criteria.U.K.

5.4.Maximum filling levelU.K.

5.4.1.A system shall be provided for preventing the container from being overfilled. This system may work in conjunction with the refuelling station. This system shall bear a permanent marking, indicating the container-type for which it has been designed and if applicable the mounting position and orientation.U.K.

5.4.2.The filling process shall not lead to any pressure relief device coming into operation irrespective of time passed during/after the filling process. The filling process shall not lead to operating conditions the BMS (boil-off management system) is not designed for and therefore cannot handle.U.K.

5.5.MarkingU.K.

5.5.1.

In addition to the EC component type-approval mark set out in Part 3 of Annex II, every container shall also bear a marking with the following data clearly legible:U.K.

5.5.1.1.The inner tank:U.K.

5.5.1.2.The outer jacket:U.K.

the identification plate shall be legible while installed.

5.5.2.The marking method shall not cause localised stress peaks in the structure of the inner tank or the outer jacket.U.K.

5.6.Inspection openingsU.K.

Inspection openings are not required in the inner or outer jacket.

6.TESTS AND INSPECTIONU.K.

6.1.Tests and inspection for the approvalU.K.

For the approval, the technical service shall perform the tests and inspections according to sections 6.3.1. to 6.3.6. on two samples of containers. The samples shall be provided in the applicable state necessary for the inspections. For the approval, samples of the container shall be subjected to the tests according to sections 6.3.7. to 6.3.9. and shall be witnessed by the technical service.

6.2.Tests and inspection during productionU.K.

The tests and inspections according to sections 6.3.1. to 6.3.6. shall be performed on each container.

6.3.Testing proceduresU.K.

6.3.1.Pressure testU.K.

6.3.1.1.The inner tank and the pipe work situated between the inner tank and the outer jacket shall withstand an inner pressure test at room temperature any suitable media, according to the following requirements.U.K.

The test pressure p_test shall be:

p_test = 1,3 (MAWP + 0,1 MPa)

with MAWP being the Maximum Allowable Working Pressure of the inner tank in MPa.

6.3.1.2.The pressure test shall be performed before the outer jacket is mounted.U.K.

6.3.1.3.The pressure in the inner tank shall be increased at a constant rate until the test pressure is reached.U.K.

6.3.1.4.The inner tank must remain under the test pressure at least for 10 minutes to establish that the pressure is not reducing.U.K.

6.3.1.5.After the test the inner tank must not show any signs of visible permanent deformation or visible leaks.U.K.

6.3.1.6.Any inner tank tested which does not pass the test because of permanent deformation shall be rejected and shall not be repaired.U.K.

6.3.1.7.Any inner tank tested which does not pass the test because of leakage may be accepted after repair and retesting.U.K.

6.3.1.8.In case of hydraulic test, upon completion of this test, the container shall be emptied and dried until the dew point inside the container is – 40 °C according to EN 12300.U.K.

6.3.1.9.A test report shall be drawn up and the inner tank shall be marked by the inspection departments if accepted.U.K.

6.3.2.Leak testingU.K.

After final assembly the hydrogen container shall be leak tested with a gas mixture containing a minimum of 10 per cent of helium

6.3.3.Verification of the dimensionsU.K.

The following dimensions shall be verified:

• for cylindrical container(s) roundness of the inner tank according to EN 1251-2:2000, 5.4

• departure from a straight line of the inner and outer jacket according to EN 1251-2, 5.4

6.3.4.Destructive and non-destructive tests of welding seamsU.K.

The tests shall be performed according to EN 1251-2.

6.3.5.Visual inspectionU.K.

The welding seams and the inner and outer surfaces of the inner and outer jackets of the container shall be inspected visually. The surfaces shall not show any critical damages or defaults.

6.3.6.MarkingU.K.

The marking shall be verified in accordance with section 5.5.

6.3.7.Burst testU.K.

The burst test shall be performed on one sample of the inner tank, not integrated in its outer jacket and not insulated.U.K.

6.3.7.1.CriteriaU.K.

6.3.7.1.1.The burst pressure shall be at least equal to the burst pressure used for the mechanical calculations. For steel tanks that is:U.K.

6.3.7.1.2.Hydrogen containers made from materials other than steel shall be demonstrated to perform as safely as containers complying with the requirements set out in points 6.3.7.1.1. and 6.3.7.1.2.U.K.

6.3.7.2.ProcedureU.K.

6.3.7.2.1.The tested tank shall be representative of the design and the manufacturing of the type to be approved.U.K.

6.3.7.2.2.The test shall be a hydraulic test.U.K.

6.3.7.2.3.The tube and piping may be modified to enable the test (purge of dead volume, introduction of the liquid, closing of non-used pipes, etc.)U.K.

6.3.7.2.4.The tank shall be filled with water. The pressure shall be increased at a constant rate not exceeding 0,5 MPa/min until burst. When the Maximum Allowable Working Pressure (MAWP) is reached there shall be a wait period of at least ten minutes at constant pressure so that the deformation of the tank shall be checked.U.K.

6.3.7.2.5.A system shall enable to look at possible deformations.U.K.

6.3.7.2.6.The pressure shall be recorded or written during the entire test.U.K.

6.3.7.3.ResultsU.K.

The test conditions and the bursting pressure shall be written in a test certificate signed by the manufacturer and the technical service.

6.3.8.Bonfire testU.K.

6.3.8.1.CriteriaU.K.

6.3.8.1.1.The tank shall not burst and the pressure inside the inner tank shall not exceed the permissible fault range of the inner tank. In case of steel inner tanks, the secondary pressure relief device shall limit the pressure inside the tank to 136 per cent of the Maximum Allowable Working Pressure (MAWP) of the inner tank, if a safety valve is used as secondary pressure relief device.U.K.

In case of steel inner tanks, the secondary pressure relief device shall limit the pressure inside the tank to 150 per cent of the Maximum Allowable Working Pressure (MAWP) of the inner tank, if a burst disk is used outside the vacuum area as secondary pressure relief device.

In case of steel inner tanks, the secondary pressure relief device shall limit the pressure inside the tank to 150 per cent of the Maximum Allowable Working Pressure plus 0,1 MPa (MAWP + 0,1 MPa) of the inner tank, if a burst disk is used inside the vacuum area as secondary pressure relief device.

For other materials, an equivalent level of safety shall be demonstrated.

The secondary pressure relief device shall not operate below 110 per cent of the set pressure of the primary pressure relief device.

6.3.8.2.ProcedureU.K.

6.3.8.2.1.The tested tank shall be representative of the design and the manufacturing of the type to be approved.U.K.

6.3.8.2.2.Its manufacturing shall be completely finished and it shall be mounted with all its equipment.U.K.

6.3.8.2.3.

The tank shall already be cooled down and the inner tank shall be at the same temperature as the liquid hydrogen. The tank shall have contained during the previous 24 hours a volume of liquid hydrogen at least equal to half of the water volume of the inner tank.U.K.

6.3.8.2.3.1.The tank shall be filled with liquid hydrogen so that the quantity of liquid hydrogen measured by the mass measurement system shall be half of the maximum allowed quantity that may be contained in the inner tank.U.K.

6.3.8.2.3.2.A fire shall burn 0,1 m underneath the tank. The length and the width of the fire shall exceed the plan dimensions of the container by 0,1 m. The temperature of the fire shall be at least 590 °C. The fire shall continue to burn for the duration of the test.U.K.

6.3.8.2.3.3.The pressure of the tank at the beginning of the test shall be between 0 MPa and 0,01 MPa at the boiling point of hydrogen in the inner tank.U.K.

6.3.8.2.3.4.Once the safety device opens, the test shall continue until the blow off of the safety device has finished. During the test the tank shall not burst and the pressure inside the inner tank shall not exceed the permissible fault range of the inner tank. In the case of steel inner tanks, the tank pressure shall not exceed 136 per cent of the Maximum Allowable Working Pressure (MAWP) of the inner tank. For other materials, an equivalent level of safety shall be applied.U.K.

6.3.8.3.ResultsU.K.

The test conditions and the maximum pressure reached within the tank during the test shall be recorded in a test certificate signed by the manufacturer and the technical service.

6.3.9.Maximum filling level testU.K.

6.3.9.1.CriteriaU.K.

During all the tests necessary for approval, the filling process shall not lead to any pressure relief device coming into operation irrespective of time passed during/after the filling process. The filling process shall not lead to operating conditions the BMS (boil-off management system) is not designed for and therefore cannot handle.

6.3.9.2.ProcedureU.K.

6.3.9.2.1.The tested tank shall be representative of the design and the manufacturing of the type to be approved.U.K.

6.3.9.2.2.Its manufacturing shall be completely finished and it shall be fitted with all its equipment and particularly the level gauge.U.K.

6.3.9.2.3.The tank shall already be cooled down and the inner tank shall be at the same temperature as the liquid hydrogen. The tank shall have contained during the previous 24 hours a volume of liquid hydrogen at least equal to half of the water volume of the inner tank.U.K.

6.3.9.2.4.The mass of hydrogen or the mass flow rate at the inlet and the outlet of the tank shall be measured with an accuracy better than 1 per cent of the maximum filling mass of the tested containerU.K.

6.3.9.2.5.The tank shall be completely filled 10 times with liquid hydrogen at equilibrium with its vapour. Between each filling at least a quarter of the liquid hydrogen of the tank shall be emptied.U.K.

6.3.9.3.ResultsU.K.

The test conditions and the ten maximum level measured by the added system shall be written in a test certificate signed by the manufacturer and the technical service.

PART 3U.K.Requirements for hydrogen components other than containers designed to use liquid hydrogen

1.INTRODUCTIONU.K.

This Part sets out the requirements and test procedures for hydrogen components other than containers designed to use liquid hydrogen.

2.GENERAL REQUIREMENTSU.K.

2.1.Materials used in hydrogen components shall be compatible with hydrogen in accordance with section 4.11.U.K.

2.2.The hydrogen system upstream of the first pressure regulator, excluding the hydrogen container, shall have a Maximum Allowable Working Pressure (MAWP) equal to the maximum pressure the component is subjected to but at least 1,5 times the set pressure of the primary safety relief device of the inner tank and a coefficient of safety not less than that of the inner tank.U.K.

2.3.Components downstream of pressure regulator(s) shall be protected against over-pressurisation and shall be designed for at least 1,5 times the outlet pressure (Maximum Allowable Working Pressure (MAWP)) of the first pressure regulator upstream.U.K.

2.4.The insulation of the components shall prevent liquefaction of the air in contact with the outer surfaces, unless a system is provided for collecting and vaporising the liquefied air. Then the materials of the components nearby shall be compatible with an atmosphere enriched with oxygen according to EN 1797.U.K.

3.TECHNICAL REQUIREMENTSU.K.

3.1.Pressure relief devicesU.K.

3.1.1.Pressure relief devices for the inner tankU.K.

3.1.1.1.The primary pressure relief device for the inner tank shall limit the pressure inside the tank to not more than 110 per cent of the Maximum Allowable Working Pressure (MAWP), even in case of a sudden vacuum loss. This device shall be a safety valve or equivalent and shall be connected directly to the gaseous part under normal operating conditions.U.K.

3.1.1.2.The secondary pressure relief device for the inner tank shall be installed to ensure that the pressure in the tank cannot under any circumstances exceed the permissible fault range of the inner tank. In the case of steel inner tanks, the secondary pressure relief device shall limit the pressure in the tank to 136 per cent of the Maximum Allowable Working Pressure (MAWP) of the inner tank, if a safety valve is used as secondary pressure relief device. In case of steel inner tanks, the secondary pressure relief device shall limit the pressure in the tank to 150 per cent of the Maximum Allowable Working Pressure (MAWP) of the inner tank, if a burst disk is used outside the vacuum area as secondary pressure relief device. In case of steel inner tanks, the secondary pressure relief device shall limit the pressure in the tank to 150 per cent of the Maximum Allowable Working Pressure plus 0,1 MPa (MAWP + 0,1 MPa) of the inner tank, if a burst disk is used inside the vacuum area as secondary pressure relief device. For other materials, an equivalent level of safety shall be demonstrated. The secondary pressure relief device shall not operate below 110 per cent of the set pressure of the primary pressure relief device.U.K.

3.1.1.3.The sizing of the safety devices shall be done in accordance with EN 13648-3.U.K.

3.1.1.4.The two devices referred to in sections 3.1.1.1. and 3.1.1.2. may be connected to the inner tank by the same fuel line.U.K.

3.1.1.5.The rating of the pressure relief devices shall be clearly marked. Tampering with the devices shall be prevented by means of a lead seal or equivalent system.U.K.

3.1.1.6.Pressure relief valves shall, after discharge, close at a pressure higher than 90 per cent of the set pressure of the pressure relief valve. They shall remain closed at all lower pressures.U.K.

3.1.1.7.Pressure relief valves shall be installed on the gaseous fraction area of the hydrogen tank.U.K.

3.1.2.Pressure relief devices for other componentsU.K.

3.1.2.1.Whenever there is a risk of cryogenic liquid or vapour becoming trapped between two items of equipment on a line, a pressure relief device or a measure ensuring an equivalent level of safety shall be provided.U.K.

3.1.2.2.Upstream of the first pressure regulator the set pressure of the safety device which prevents over-pressurisation shall not exceed the Maximum Allowable Working Pressure (MAWP) of the lines and shall not be less than 120 per cent of the Maximum Allowable Working Pressure (MAWP) of the tank, to prevent such valves opening instead of the pressure relief devices for the inner tank.U.K.

3.1.2.3.The rating of pressure relief devices downstream of the pressure regulator(s) shall not exceed the Maximum Allowable Working Pressure (MAWP) of the components downstream of the pressure regulator.U.K.

3.1.2.4.Pressure relief valves shall, after discharge, close at a pressure higher than 90 per cent of the set pressure of the pressure relief valve. They shall remain closed at all lower pressures.U.K.

3.1.3.Provisions regarding the approval of pressure relief devicesU.K.

3.1.3.1.The design, manufacturing and control of the pressure relief devices shall be in accordance with EN 13648-1 and EN 13648-2.U.K.

3.1.3.2.In case of boil off system in parallel of the primary safety device, then the safety valve shall be a category B safety device otherwise it shall be a category A safety device according to EN 13648.U.K.

3.1.3.3.Maximum Allowable Working Pressure (MAWP): 1,5 × Maximum Allowable Working Pressure (MAWP) of the inner tank or maximum pressure the component is subjected to.U.K.

3.1.3.4.Set pressureU.K.

3.1.3.4.1.Primary devices of the inner tank: according to section 3.1.1.1.U.K.

3.1.3.4.2.Secondary device of the inner tank: according to section 3.1.1.2.U.K.

3.1.3.4.3.Pressure relief devices for components other than the tank: according to section 3.1.2.U.K.

3.1.3.5.Design temperaturesU.K.

3.1.3.5.1.External temperature: according to section 1.3 of Part 1.U.K.

3.1.3.5.2.Internal temperature: – 253 °C to + 85 °C.U.K.

3.1.3.6.Applicable test procedures:U.K.

3.1.4.Lines incorporating pressure relief devicesU.K.

3.1.4.1.No isolating device shall be installed between the protected component and the pressure relief device.U.K.

3.1.4.2.The lines before and behind the pressure relief devices shall not impede their function and shall be compatible with the criteria defined in sections 3.1.1. to 3.1.3.U.K.

3.2.ValvesU.K.

3.2.1.Provisions regarding the approval of hydrogen valvesU.K.

3.2.1.1.The design, manufacturing and checking of the cryogenic hydrogen valves shall be in accordance with EN 13648-1 and EN 13648-2.U.K.

3.2.1.2.Maximum Allowable Working Pressure (MAWP): 1,5 × Maximum Allowable Working Pressure (MAWP) of the inner tank or maximum pressure the valve is subjected to.U.K.

3.2.1.3.Design temperaturesU.K.

3.2.1.3.1.External temperature: according to section 1.3 of Part 1.U.K.

3.2.1.3.2.Internal temperature:U.K.

– 253 °C to + 85 °C for valves before the heat exchanger

– 40 °C to + 85 °C for valves after the heat exchanger

3.2.1.4.Applicable test procedures:U.K.

3.3.Heat exchangersU.K.

3.3.1.Notwithstanding the provision of section 2.1. the Maximum Allowable Working Pressure (MAWP) of the heat exchanger shall be the highest Maximum Allowable Working Pressure (MAWP) of the different circuits.U.K.

3.3.2.The exhaust gases from the propulsion system shall not under any circumstances be used directly in the heat exchanger.U.K.

3.3.3.A safety system shall be provided to: prevent failure of the heat exchanger; and prevent any cryogenic liquid or gas from entering the other circuit and the system located downstream of it, if it has not been designed for this.U.K.

3.3.4.Provisions regarding the approval of hydrogen valvesU.K.

3.3.4.1.Maximum Allowable Working Pressure (MAWP): 1,5 × Maximum Allowable Working Pressure (MAWP) of the inner tank or maximum pressure the component is subjected to.U.K.

3.3.4.2.Design temperaturesU.K.

3.3.4.2.1.External temperature: according to section 1.3 of Part 1.U.K.

3.3.4.2.2.Internal temperature: – 253 °C to + 85 °C.U.K.

3.3.4.3.Applicable test proceduresU.K.

3.3.4.4.The manufacturing and mounting of the heat exchanger shall be certified according to sections 4.3. to 4.5 of Part 2.U.K.

3.4.Refuelling connections or receptaclesU.K.

3.4.1.The refuelling connections or receptacles shall be protected against contamination.U.K.

3.4.2.Provisions regarding the approval of refuelling connections or receptaclesU.K.

3.4.2.1.Maximum Allowable Working Pressure (MAWP): 1,5 × Maximum Allowable Working Pressure (MAWP) of the inner tank or maximum pressure the component is subjected to.U.K.

3.4.2.2.Design temperaturesU.K.

3.4.2.2.1.External temperature: according to section 1.3 of Part 1.U.K.

3.4.2.2.2.Internal temperature: – 253 °C to + 85 °CU.K.

3.4.2.3.Applicable test proceduresU.K.

3.5.Pressure regulatorsU.K.

3.5.1.Provisions regarding the approval of pressure regulatorsU.K.

3.5.1.1.Maximum Allowable Working Pressure (MAWP): 1,5 × Maximum Allowable Working Pressure (MAWP) of the inner tank or maximum pressure the component is subjected to.U.K.

3.5.1.2.Design temperaturesU.K.

3.5.1.2.1.External temperature: according to section 1.3 of Part 1.U.K.

3.5.1.2.2.Internal temperature: at least as given in section 1.3 of Part 1.U.K.

3.5.1.3.Applicable test proceduresU.K.

3.6.SensorsU.K.

3.6.1.Provisions regarding the approval of sensorsU.K.

3.6.1.1.Maximum Allowable Working Pressure (MAWP): 1,5 × Maximum Allowable Working Pressure (MAWP) of the inner tank or maximum pressure the component is subjected to.U.K.

3.6.1.2.Design temperaturesU.K.

3.6.1.2.1.If operated with ambient temperature: according to section 1.3 of Part 1.U.K.

3.6.1.2.2.If operated with cryogenic temperature: lowest operating temperature: – 253 °C, maximum temperature: + 85 °C or + 120 °C as given in section 1.3 of Part 1.U.K.

3.6.1.3.Applicable test proceduresU.K.

3.7.Flexible fuel linesU.K.

3.7.1.Provisions regarding the approval of flexible fuel linesU.K.

3.7.1.1.The design, manufacturing and control of the cryogenic flexible fuel lines shall be in accordance with EN 12434.U.K.

3.7.1.2.Maximum Allowable Working Pressure (MAWP): 1,5 × Maximum Allowable Working Pressure (MAWP) of the inner tank or maximum pressure the component is subjected to.U.K.

3.7.1.3.Design temperaturesU.K.

3.7.1.3.1.If operated with ambient temperature: according to section 1.3 of Part 1.U.K.

3.7.1.3.2.If operated with cryogenic temperature: lowest operating temperature: – 253 °C, maximum temperature: + 85 °C or + 120 °C as given in section 1.3 of Part 1.U.K.

3.7.1.4.Applicable test proceduresU.K.

3.8.Provisions regarding electrical components of the hydrogen systemU.K.

3.8.1.To prevent electric sparks:U.K.

3.8.2.In case of power supply bushing to establish an isolated and tight electrical connection, the electric connection shall be of a hermetic sealed type.U.K.

4.TEST PROCEDURESU.K.

4.1.General provisionsU.K.

4.1.1.Leakage tests shall be conducted with pressurised gas such as air or nitrogen containing at least 10 per cent helium.U.K.

4.1.2.Water or another fluid may be used to obtain the required pressure for pressure test.U.K.

4.1.3.All test records shall indicate the type of test medium used, if applicable.U.K.

4.1.4.The test period for leakage and pressure tests shall be not less than 3 minutes more than the response time of the sensor.U.K.

4.1.5.All tests shall be performed at ambient temperature, unless otherwise stated.U.K.

4.1.6.The different components shall be correctly dried before leak test.U.K.

4.2.Pressure testU.K.

4.2.1.A hydrogen containing component shall withstand without any visible evidence of leak or deformation a test pressure of 1,5 times its Maximum Allowable Working Pressure (MAWP) with the outlets of the high pressure part plugged. The pressure shall then be increased from 1,5 to 3 times the Maximum Allowable Working Pressure (MAWP). The component shall not show any visible evidence of rupture or cracks.U.K.

4.2.2.The pressure supply system shall be equipped with a positive shut-off valve and a pressure gauge, having a pressure range of not less than 1,5 times nor more than 2 times the test pressure and the accuracy of the gauge shall be 1 per cent of the pressure range.U.K.

4.2.3.For components requiring a leakage test, this test shall be performed prior to the pressure test.U.K.

4.3.External leakage testU.K.

4.3.1.A component shall be free from leakage through stem or body seals or other joints, and shall not show evidence of porosity in casting when tested as described in section 4.4.3. at any gas pressure between zero and its Maximum Allowable Working Pressure (MAWP).U.K.

4.3.2.

The test shall be performed on the same equipment at the following conditions:U.K.

4.3.2.1.at ambient temperature;U.K.

4.3.2.2.at the minimum operating temperature or at liquid nitrogen temperature after sufficient conditioning time at this temperature to ensure thermal stability;U.K.

4.3.2.3.at the maximum operating temperature after sufficient conditioning time at this temperature to ensure thermal stability.U.K.

4.3.3.During this test the equipment under test shall be connected to a source of gas pressure. A positive shut-off valve and a pressure gauge having a pressure range of not less than 1,5 times nor more than 2 times the test pressure shall be installed in the pressure supply piping and the accuracy of the gauge shall be 1 per cent of the pressure range. The pressure gauge shall be installed between the positive shut-off valve and the sample under test.U.K.

4.3.4.Throughout the test, the sample shall be tested for leakage, with a surface active agent without formation of bubbles or measured with a leakage rate less than 10 cm³/hour.U.K.

4.4.Endurance testU.K.

4.4.1.A hydrogen component shall be capable of conforming to the applicable leakage test requirements of sections 4.3. and 4.12., after being subjected to the number of operation cycles specified for that component in sections 3.1. to 3.7. of Part 3.U.K.

4.4.2.The appropriate tests for external leakage and seat leakage, as described in sections 4.3. and 4.12. shall be carried out immediately following the endurance test.U.K.

4.4.3.The component shall be securely connected to a pressurised source of dry air or nitrogen and subjected to the number of cycles specified for that specific component in sections 3.1. to 3.7. of Part 3. A cycle shall consist of one opening and one closing of the component within a period of not less than 10 ± 2 seconds.U.K.

4.4.4.The component shall be operated through 96 per cent of the number of specified cycles at ambient temperature and at the MAWP of the component. During the off cycle the downstream pressure of the test fixture shall be allowed to decay to 50 per cent of the MAWP of the component.U.K.

4.4.5.The component shall be operated through 2 per cent of the total cycles at the maximum material temperature (according to section 1.3 of Part 1) after sufficient conditioning time at this temperature to ensure thermal stability and at MAWP. The component shall comply with sections 4.3. and 4.12. at the appropriate maximum material temperature (according to section 1.3 of Part 1) at the completion of the high temperature cycles.U.K.

4.4.6.The component shall be operated through 2 per cent of the total cycles at the minimum material temperature (according to section 1.3 of Part 1) but not less than the temperature of liquid nitrogen after sufficient conditioning time at this temperature to ensure thermal stability and at the MAWP of the component. The component shall comply with sections 4.3. and 4.12. at the appropriate minimum material temperature (according to section 1.3 of Part 1) at the completion of the low temperature cycles.U.K.

4.5.Operational testU.K.

4.5.1.The operational test shall be carried out in accordance with EN 13648-1 or EN 13648 2. The specific requirements of the standard are applicable.U.K.

4.6.Corrosion resistance testU.K.

4.6.1.Metallic hydrogen components shall comply with the leakage tests referred to in sections 4.3. and 4.12. after being submitted to 144 hours salt spray test according to ISO 9227 with all connections closed.U.K.

4.6.2.A copper or brass hydrogen containing component shall comply with the leakage tests referred to in sections 4.3. and 4.12. and after being submitted to 24 hours immersion in ammonia according to ISO 6957 with all connections closed.U.K.

4.7.Resistance to dry-heat testU.K.

The test shall be carried out in compliance with ISO 188. The test piece shall be exposed to air at a temperature equal to the maximum operating temperature for 168 hours. The change in tensile strength shall not exceed + 25 per cent. The change in ultimate elongation shall not exceed the following values:

• maximum increase 10 per cent,

• maximum decrease 30 per cent.

4.8.Ozone ageing testU.K.

4.8.1.The test shall be in compliance with ISO 1431-1. The test piece, which shall be stressed to 20 per cent elongation, shall be exposed to air at + 40 °C with an ozone concentration of 50 parts per hundred million during 120 hours.U.K.

4.8.2.No cracking of the test piece is allowed.U.K.

4.9.Temperature cycle testU.K.

A non-metallic part containing hydrogen shall comply with the leakage tests referred to in sections 4.3. and 4.12. after having been submitted to a 96 hours temperature cycle from the minimum operating temperature up to the maximum operating temperature with a cycle time of 120 minutes, under Maximum Allowable Working Pressure (MAWP).

4.10.Pressure cycle testU.K.

4.10.1.Any flexible fuel line shall be capable of conforming to the applicable leakage test requirements referred to in section 4.3., after being subjected to 6 000 pressure cycles.U.K.

4.10.2.The pressure shall change from atmospheric pressure to the Maximum Allowable Working Pressure (MAWP) of the tank within less than five seconds, and after a time of at least five seconds, shall decrease to atmospheric pressure within less than five seconds.U.K.

4.10.3.The appropriate test for external leakage, as referred to in section 4.3. shall be carried out immediately following the endurance test.U.K.

4.11.Hydrogen compatibility testU.K.

4.11.1.The hydrogen compatibility shall be proved according to ISO 11114-4.U.K.

4.11.2.The materials of the components in contact with cryogenic temperatures shall be compatible with cryogenic temperatures according to EN 1252-1.U.K.

4.12.Seat leakage testU.K.

4.12.1.The seat leakage tests shall be carried out on samples which have previously been subjected to the external leakage test referred to in section 4.3.U.K.

4.12.2.Seat leakage tests shall be conducted with the inlet of the sample valve connected to a source of gas pressure, the valve in the closed position, and with the outlet open. A positive shut-off valve and a pressure gauge having a pressure range of not less than 1,5 times and not more than twice the test pressure shall be installed in the pressure supply piping and the accuracy of the gauge shall be 1 per cent of the pressure range. The pressure gauge shall be installed between the positive shut-off valve and the sample under test. While under the applied test pressure corresponding to the Maximum Allowable Working Pressure (MAWP), observations for leakage shall be made with the open outlet submerged in water or by a flow meter installed on the inlet side of the valve under test. The flow meter shall be capable of indicating, for the test fluid employed, the maximum leakage flow rates permitted within an accuracy of +/- 1 per cent.U.K.

4.12.3.The seat of a shut-off valve, when in the closed position, shall not leak at a rate exceeding 10 cm³/hour at any gas pressure between zero and the Maximum Allowable Working Pressure (MAWP).U.K.

4.12.4.A non-return valve, when in the closed position, shall not leak when subjected to any aerostatic pressure between 50 kPa and its Maximum Allowable Working Pressure (MAWP).U.K.

4.12.5.Non-return valves if used as a safety device or refuelling connections or receptacles shall not leak at a rate exceeding 10 cm³/hour during the test.U.K.

4.12.6.The pressure relief devices shall not leak at a rate exceeding 10 cm³/hour at any gas pressure between zero and set pressure minus 10 per cent.U.K.