RU2730129C1 - Method for cryogenic-strength test of hydrogen tank - Google Patents

Abstract

FIELD: aerospace engineering.

SUBSTANCE: invention relates to cryogenic-fuel tanks of rocket and space equipment and, first of all, to hydrogen tanks. According to the proposed method, the tank is tested in a cryostat, at the same time before the tests the tank volume is connected to the internal volume of the cryostat, after which the air is replaced with nitrogen. Cooling tank and inner vessel of cryostat from 300 K to 90÷85 K are carried out with liquid nitrogen, then replacing nitrogen with hydrogen and cooling with hydrogen liquid tank and inner vessel of cryostat from 90÷85 K to 20÷22 K. After that, the tank is filled with liquid hydrogen and the tank volume is disconnected from the internal volume of the cryostat, and then pressure in the tank is increased to the design value and in case of tank integrity liquid hydrogen is removed from the tank. Thereafter, the volume of the tank is reconnected with the inner volume of the cryostat and the cryostat tank and internal vessel are heated from 20÷22 K to 70÷80 K with gaseous hydrogen, and then to 300 K – with gaseous nitrogen. After that nitrogen is changed to air, and at destruction of tank structure in process of increasing pressure of liquid hydrogen volume of tank is connected to internal volume of cryostat and liquid hydrogen is removed from both volumes, but first of all from volume with higher weight of liquid hydrogen, and then tank and inner vessel of cryostat are heated from 20÷22 K to 70÷80 K with gaseous hydrogen, and then to 280÷290 K – with nitrogen. After that nitrogen is replaced with air.

EFFECT: simplified cryogenic-strength test of hydrogen tank, increased safety and reliability of tests.

1 cl, 1 dwg

Description

The invention relates to cryogenic fuel tanks for rocket and space technology, and primarily to hydrogen tanks.

The known method of cryogenic-strength testing of a hydrogen tank, in which chilling and strength tests are carried out using liquid nitrogen (see the magazine "Flight" 2015 No. 7, pp. 18-24).

Despite the simplicity, relative safety and low cost, the method has the following disadvantages:

- the hydrogen tank is undercooled by more than 55 K;

- the need to create a special system for weighting the hydrogen tank when filling its volume with liquid nitrogen;

- creation of a special tray for receiving liquid nitrogen in the event of a tank rupture.

A known method of cryogenic-strength testing of a hydrogen tank using liquid hydrogen (see the journal "Cosmonautics and Rocket Engineering" 2012 No. 2 (67) pp. 62-69).

In this method, the strength tests of a hydrogen tank are carried out using the same cryogenic liquid for which it is designed, which allows one to reliably simulate the operating temperatures and the effect of the height of the liquid hydrogen column on the tank design. However, despite the noted advantage of the method, it has significant disadvantages:

- the loss of large volumes of liquid hydrogen during the destruction of the tank, which requires the creation of complex and expensive fire and explosion safety systems in the event of emergency situations during testing.

The closest to the proposed method is a cryogenic-strength test, including replacing air in the tank with nitrogen, cooling the tank from 300 K to 80 K with liquid nitrogen, filling and draining liquid nitrogen from the tank, replacing the nitrogen medium with helium, cooling the tank from 80 K to 20K - 22 K with the help of a helium refrigerator, increasing the helium pressure in the tank to the calculated one at a cryostatting temperature of 20K - 22 K, heating the tank to 300 K and compressing helium from the tank into the storage, replacing helium with air. (See "Bulletin of the Bauman Moscow State Technical University. Mechanical Engineering Series No. 3 2012).

Despite the fact that this method allows you to reduce the cooling time, the power of the helium refrigerator and does not require the consumption of liquid hydrogen, the method has a number of significant disadvantages, the main of which are:

- the need for a large supply of gaseous helium, so, for example, in a hydrogen tank V = 100 m ³ at a temperature of 20 K and a design pressure of 5 kgf / cm ^{2 there} will be about 7500 nm ^{3 of} helium and in the event of a tank breakdown will lead to the loss of a rather expensive helium, and moreover, it will be necessary to develop and create special safety systems due to the replacement of hydraulic tests for strength with pneumatic ones;

- cooling and cryostatting of the tank at a level of 20 K requires the creation of a helium refrigerator based on highly efficient screw compressor units and highly efficient turbo expanders, systems for purifying helium from oil, low-temperature impurities, regeneration of adsorbers and vacuum pumping, creation of a multifunctional monitoring and control system, as well as, as shown experience in operating such refrigerators at the Kurchatov IAE, IVTANE, training and education of highly qualified personnel for operation.

The problem being solved is to increase the technological safety and reliability of testing while reducing their cost.

The specified technical result is achieved by the fact that in the method of cryogenic-strength testing of a hydrogen tank, including replacing air in the tank with nitrogen, cooling the tank from 300 K to 80 K with liquid nitrogen, filling and draining liquid nitrogen from the tank, replacing the nitrogen medium with helium, cooling tank from 80 K to 20 K ÷ 22 K using a helium refrigerator, increasing the helium pressure in the tank to the calculated one at a cryostatting temperature of 20 K ÷ 22 K, heating the tank to 300 K and compressing helium from the tank into the storage, replacing helium with air, testing the tank is carried out in a cryostat, while before the start of the tests the volume of the tank is connected to the inner volume of the cryostat, after which the air is replaced with nitrogen, the tank and the inner vessel of the cryostat are cooled down with liquid nitrogen from 300 K to 90 K ÷ 85 K, then nitrogen is replaced with hydrogen and the tank and the inner vessel of the cryostat are cooled down with liquid hydrogen from 90 K ÷ 85 K to 20 K ÷ 22 K after which the tank is filled with liquid hydrogen and the volume of ba is disconnected from the internal volume of the cryostat, and then increase the pressure in the tank to the calculated value and, if the tank is intact, remove liquid hydrogen from the tank, then reconnect the tank volume with the internal volume of the cryostat and heat the tank and the internal vessel of the cryostat from 20 K ÷ 22 K up to 70 K ÷ 80 K with gaseous hydrogen, and then up to 300 K with gaseous nitrogen, after which the nitrogen is changed to air, and if the tank structure is destroyed during the pressure increase of liquid hydrogen, the volume of the tank is connected to the inner volume of the cryostat and liquid hydrogen is removed from both volumes, but first of all from the volume with a larger mass of liquid hydrogen, and then the tank and the inner vessel of the cryostat are heated from 20 K ÷ 22 K to 70 K ÷ 80 K with hydrogen gas, and then up to 280 K ÷ 290 K with nitrogen, after which they are replaced nitrogen to air.

The analysis of the prior art made it possible to establish that the applicant has not found an analogue characterized by aggregate features identical to all essential features of the claimed invention, therefore, it meets the criterion of novelty.

The attached drawing shows a schematic pneumohydraulic diagram of a bench cryogenic system operating according to this method.

The bench cryogenic system includes a cryostat 1 with a screen-vacuum insulation and a removable cover 2, a nitrogen tank 3 with a volume of (8 ÷ 10) m ³ and a working pressure P _p = 1.0 MPa with a pressure regulator 4, a pressurizing evaporator 5, a valve 6 for dispensing liquid nitrogen and a gas discharge valve 7 to the atmosphere, a hydrogen tank 8 with a volume of (8 ÷ 10) m ³ and a working pressure P _p = 1.0 MPa, equipped with a pressure regulator 9, a boost evaporator 10, a valve 11 for dispensing liquid hydrogen and a gas discharge valve 12 to the atmosphere , an armature shield 13, complete with shut-off and control valves 14-36, safety valves 37, 38, a liquid hydrogen gasifier 39, a liquid nitrogen gasifier 40, a hydrogen or nitrogen gas heater 41, an ejector 42, a vacuum pump 43 and an inside-panel piping.

Inside the cryostat 1, a hydrogen tank 44 and a system of collectors made in the form of squirrel wheels are mounted, namely:

- nitrogen collector 45 with nozzles 46 for spraying liquid nitrogen onto the surface of the hydrogen tank 43 during its cooling from 300 K to 85 K ÷ 90 K;

nitrogen collector 47 with nozzles 48, designed to heat the tank from 80 K to 300 K;

- hydrogen manifold 49 with nozzles 50 for spraying liquid hydrogen in the process of cooling down the hydrogen tank 44 from 85 K ÷ 90 K to 22 K ÷ 25 K;

- hydrogen manifold 51 with nozzles 52, designed to heat the hydrogen tank 44 from 20 K to 70 K ÷ 80 K.

Each of the named collectors is connected to the corresponding valve of the armature shield 13, for example, the nitrogen collector 45 - to the valve 25.

In addition, the cryostat 1 is equipped with a pipeline 53 for draining liquid hydrogen and a pipeline 54 for removing gaseous nitrogen or hydrogen from the cryostat 1.

During the tests, the hydrogen tank 44 itself contains:

- pipeline 55 for filling and draining liquid hydrogen;

- nitrogen ejector 56 for cooling tank 44 from 300 K to 85 K ÷ 90 K;

- nitrogen ejector 57 for warming up the tank 44 from 70 K ÷ 80 K to 280 K ÷ 290 K.

All of the above devices are also connected through removable sections to the corresponding valves of the armature shield 13, and a control tank 59 with a volume of (1.5 ÷ 2.0) m ³ is made on the removable pipeline 58 for the removal of gaseous nitrogen or hydrogen.

The filling of the nitrogen tank 3 with liquid nitrogen is carried out from the liquid nitrogen storage through the pipeline 60, and the filling of the hydrogen tank 8 and the cryogenic tank 44 is carried out from the storage of liquid hydrogen through the pipeline 61, in parallel to which the pump 64 is connected by means of valves 62 and 63.

(Storages of liquid hydrogen and liquid nitrogen are not shown in the drawing).

The bench cryogenic system also includes a system for monitoring technological parameters (not shown in the drawing), from where the operator receives information from pressure sensors 65 ÷ 70, level sensors 71 ÷ 75 and temperature sensors 76 and 77.

The functional purpose of the above positions of the stop-control valves and parameter control sensors is disclosed in the description of the operation of the bench cryogenic system.

The method of cryogenic-strength testing of a hydrogen tank is carried out as follows.

Prior to testing, the bench cryogenic system should be brought into the following initial position:

- the hydrogen tank 44 is installed in the cryostat 2 and is connected through removable sections to the reinforcement shield 13;

- valves 30 and 36 are open in the armature panel 13, the rest of the valves are closed;

- nitrogen tank 3 is filled with liquid nitrogen and a pressure of 1.0 MPa is maintained in it by means of a pressure regulator 4 by supplying gaseous nitrogen from a pressurizing evaporator 5, while the level in tank 3 is controlled by sensor 75, and pressure - by sensor 70.

The tank 3 is filled with liquid nitrogen from the storage through pipeline 60, valve 27, valve 6 and open gas discharge valve 7. After filling, valve 6 and valve 27 are closed;

- the hydrogen tank 8 is filled with liquid hydrogen and in it with the help of the pressure regulator 9 due to the supply of gaseous hydrogen from the pressurizing evaporator 10 a pressure of 1.0 MPa is maintained. The level in the tank 8 is controlled by the sensor 74, the pressure - by the sensor 69. The tank 8 is filled with liquid hydrogen from the storage through the pipeline 61 through the open valves 63, 14, 11 and the open valve 12 of the gas discharge into the candle (not shown in the drawing). After filling the container 8, valves 11, 12, 14 and 63 are closed;

- the monitoring and control system was brought into readiness.

Before starting the operation of replacing the air medium with nitrogen, the open position of the valve 36 connecting the volume of the cryogenic tank 44 and the internal volume of the cryostat 1 through pipelines 54 and 58 is checked and fixed. The air medium is replaced with nitrogen by evacuating the total volume followed by filling with gaseous nitrogen. The vacuuming operation is carried out in two stages. At the first stage, the total volume is evacuated using an ejector 42, and at the second, using a vacuum pump 43.

To perform the first stage, the valve 30 is closed, valves 33, 32 and 6 are opened and liquid nitrogen is supplied from the nitrogen container 3 to the gasifier 40, after which gaseous nitrogen with a temperature of 270 K ÷ 280 K and a pressure of 1.0 MPa enters the ejector nozzle 42, after which, by opening the valve 31, the total volume is connected to the ejector 42, where, due to the ejection, air is pumped out from the total volume with the removal of the air-nitrogen mixture after the ejector 42 into the candle.

Upon reaching the value of the vacuum controlled by sensors 65 and 66, about 100-50 mm Hg. Art. go to the second stage of evacuation. For this, valves 31, 32 and 33 are closed, the vacuum pump 43 is turned on, and then, by gradually opening valve 29, the total volume is connected to pumping. Upon reaching a vacuum value of the order of 1⋅10 ^-1 ÷ 5⋅10 ^-2 mm Hg. Art., controlled by the sensor 67, close the valve 29, turn off the vacuum pump 43 and fill the total volume with gaseous nitrogen to a pressure of (0.1 ÷ 0.12) MPa. Filling is carried out by supplying gaseous nitrogen through a nitrogen manifold 47 with nozzles 48, for which the valve 32 is opened and after the gasifier 40 by smoothly opening the valve 26 the total volume is filled up to a pressure of (0.1 ÷ 0.12) MPa, monitored by sensors 65 and 66. After filling with nitrogen, valves 26 and 32 are closed, valve 30 is opened and the next stage of cooling hydrogen tank 44 from 300 K to 85 K ÷ 90 K with the help of liquid nitrogen is started. In this case, to accelerate the chilling process, the hydrogen tank 44 is cooled both from the outside and from the inside. For this, valves 25 and 23 are opened and liquid nitrogen is supplied from the nitrogen tank 3 at a pressure of 1.0 MPa to the nitrogen collector 45, where nitrogen is sprayed through the nozzles 46 over the entire outer surface, and to intensify the cooling process inside the volume of the hydrogen tank 44, liquid nitrogen is supplied into the ejector 56 also under a pressure of 1.0 MPa, which allows, due to the ejection, to significantly increase the rate of circulation of gaseous nitrogen inside the volume of the hydrogen tank 44 and, as a consequence, to increase the heat transfer coefficient to the inner surface. The resulting gaseous nitrogen from the tank 44 is removed through the pipeline 58 through the valve 36, after which it is connected to the flow of nitrogen gas returned from the cryostat through the pipeline 54, after which the total nitrogen flow through the valve 30 and the check valve 34 is discharged into the candle.

In the process of cooling down, the nitrogen temperature is monitored using sensors 76 and 77. When the temperature of the effluent streams reaches about 85 K ÷ 90 K, the cooling process with nitrogen is considered complete, valves 23, 25 and 30 are closed and the next step is to replace the nitrogen medium with a hydrogen medium, which is carried out in the same way as replacing air with nitrogen. The only difference is that when the total volume is pumped out by the vacuum pump 43, the heater 41 is switched on to increase the temperature of the pumped out nitrogen in front of the vacuum pump 43. When a vacuum in the total volume is about 1⋅10 ^-1 ÷ 1⋅10 ^-2 mm Hg. Art. the valve 29 is closed and the vacuum pump 43 is turned off. Next, the volume of the tank 44 and the internal volume of the cryostat 1 are filled with hydrogen, which is supplied from the hydrogen container 8 through the pipeline 55 to the bottom of the hydrogen tank 44. For this, the valve 11 is opened, and then, using the control valve 18, liquid hydrogen into the tank 44, which, falling to the bottom of the tank 44, evaporates and fills the volume of the tank 44 and the internal volume of the cryostat 1 through line 58, valve 36 and line 54. The pressure increase is constantly monitored by sensors 65 and 66. When a pressure of the order of (0 , 12 ÷ 0.15) MPa, the valve 30 is opened and the hydrogen gas generated during the cooling down of the structure of the hydrogen tank 44 is discharged into the candle through the check valve 34.

To accelerate the process of cooling the tank down to hydrogen temperatures, liquid hydrogen is additionally supplied to the hydrogen collector 49 with nozzles 50 by means of valve 17, which is opened, and liquid hydrogen under a pressure of 1.0 MPa from nozzles 50 is sprayed over the entire surface of the tank 44, and the resulting gaseous hydrogen is removed from the internal volume of the cryostat 1 through the pipeline 54, is connected to the flow of gaseous hydrogen coming from the tank 44, and then the total flow is discharged through the valve 30 and the check valve 34 into the candle. In the process of cooling down the hydrogen tank 44, the temperatures of the streams of gaseous hydrogen are constantly monitored by sensors 75 and 76. When a temperature value of about 22 K - 25 K is reached, the process of cooling down the hydrogen tank is considered complete, after which they proceed to filling the hydrogen tank with liquid hydrogen from the storage (not shown in the drawing ). To do this, open the valve 63, open the valve 19 and fill the tank 44 with liquid hydrogen through the open valve 19, controlling the level in the tank 44 with the sensor 71 and the control tank 59 with the sensor 73. To cool down the pump 64 and prepare it for operation, open the valve 62. As soon as the level in the control tank according to the readings of the sensor 73 will be 85-90%, the filling process of the hydrogen tank 44 is stopped by closing the valve 19. In the process of filling the hydrogen tank 44, the outer surface of the tank is periodically sprayed with liquid hydrogen supplied from the hydrogen tank 8 by valve 17 to the hydrogen collector 49 through the nozzles 50, which ensures a stable thermostatting regime of the tank 44 at the level of 20 K - 22 K both in the process of filling the tank 44 with liquid hydrogen and during the main stage of testing - this is the strength test of the tank 44.

To carry out this stage, the tank 44 is disconnected from the internal volume of the cryostat 1 by closing the valve 36, and then the valve 28 is opened and liquid hydrogen is supplied to the gasifier 39, and with the control valve 21, the pressure is raised and maintained in the control tank 59, and therefore in the hydrogen tank 44 equal to the calculated value, while controlling the pressure by sensors 66 and 68, and withstand a given time. If the strength test of the tank passes without destruction, then proceed to the next stage - pumping liquid hydrogen from the tank 44 to the storage using the pump 64. To do this, close the valve 21, open the valve 19, open the valve 63 and start the pump 64 in operation. As a result, liquid hydrogen from tank 44 through conduit 55, valve 19, will be pumped by pump 64 through valve 62 through conduit 61 into the liquid hydrogen storage. During pumping, the valve 21 maintains a pressure in the hydrogen tank 44 due to the pressurization of gaseous hydrogen generated in the gasifier 39, which ensures a stable non-cavitation mode of operation of the pump 64. The pressure is controlled by the sensor 68.

When the minimum level of liquid hydrogen is reached in the hydrogen tank 44, the pump 64 is stopped, valve 19 is closed, valve 36 is opened and the volumes of the tank 44 and the internal volume of the cryostat 1 are again connected, after which the process of warming up the tank 44 and cryostat 1 from 20 K ÷ 22 K up to 300 K. The heating operation is performed in two stages. At the first stage, the process of warming up from 20 K ÷ 22 K to 70 K - 80 K is carried out with gaseous hydrogen, which is obtained in the gasifier 39 and through the valve 16 under a pressure of 1.0 MPa is directed to the collector 51, where warm hydrogen is directed to the surface through the nozzles 52 hydrogen tank 44 and the inner case of the cryostat 1. At the same time, warm hydrogen enters the inner volume of the tank 44 through the control valve 20, where it is throttled, reducing the pressure from 1.0 MPa to (0.11-0.12) MPa. As a result of heat exchange, the temperature of the tank 44 and the inner housing of the cryostat 1 will begin to increase, and when the temperature of gaseous hydrogen reaches the order of 70 K ÷ 80 K removed from the inner volume of the cryostat 1 and tank 44 through pipelines 58 and 54 and then through valve 30 and check valve 34 into candle. Temperature control is carried out using sensors 76, 77. At this point, the first stage of warming up is completed, valves 11, 28, 16 and 20 are closed and thus the supply of hydrogen to the tank 44 and cryostat 1 is stopped, and then the second stage of warming up the tank 44 and cryostat 1 up to 280 K ÷ 290 K using nitrogen gas. The warming operation is carried out as follows. Valve 6 is opened on nitrogen tank 3, valve 32 for supplying liquid nitrogen to gasifier 40, and gaseous nitrogen with a temperature of 290 K ÷ 300 K and a pressure of 1.0 MPa is first fed through valve 26 into manifold 47, where nitrogen from nozzles 48 enters the surface tank 44 and the surface of the inner vessel of the cryostat 1, and then open the valve 23 and also supply at a pressure of 1.0 MPa to the ejector 56, with which, by increasing the multiplicity of the circulation flow inside the tank 44, the intensity of heat transfer from nitrogen to the inner surface of the tank 44 increases. In the process of warming up, both streams of gaseous nitrogen are discharged to the candle through valve 30 and check valve 34, while the temperature of the streams is controlled by sensors 76 and 77. When the temperatures leaving the tank 44 and cryostat 1 of the streams of the order of 280 K ÷ 290 K are reached, the heating process is considered complete ...

After warming up the tank 44 and the cryostat 1, replace the nitrogen with air. To carry out this operation, valves 23 and 26 are closed, stopping the supply of gaseous nitrogen to tank 44 and cryostat 1, valve 30 is closed, valve 33 is opened and gaseous nitrogen is supplied with a pressure of 1.0 MPa and a temperature of 290 K ÷ 300 K to the ejector 42 and then open valve 31. When the pressure in the total volume is about 100-50 mm Hg. Art. close valve 31 and through valve 22 let air into tank 44 and cryostat 1. After filling with air through valve 35, take a sample for the oxygen content, if the oxygen content in the sample is more than 19%, then close valve 6 on nitrogen tank 3 and valves 32 and 33 At this, the cryogenic-strength tests of the hydrogen tank 44 are considered completed, the tank 44 is dismantled from the cryostat 1. Before dismantling the tank 44, remove the cover 2 of the cryostat 1, disconnect the removable sections from the tank 44, remove the ejectors 56, 57 and the filling line 55 from the tank 44, and drainage of liquid hydrogen, after which the tank 44 is lifted from the cryostat 1 and transferred to the next operation according to the technological route.

In the event that, in the process of increasing the pressure to the calculated value in the tank 44 filled with liquid hydrogen, its destruction occurs, then, depending on the place of depressurization of the tank 44, part of the liquid hydrogen will fill a part of the internal volume of the cryostat 1, in which due to the periodic supply of liquid hydrogen from tank 8 with the help of valve 17 into collector 49 under a pressure of 1.0 MPa and spraying liquid hydrogen through nozzles 50 onto the surface of tank 44 and cryostat 1, the temperature inside the cryostat 1 is maintained at 20 K ÷ 22 K. Therefore, when the structure of tank 44 is destroyed during its During hydraulic tests, liquid hydrogen supplied from the storage to fill the tank volume is stored and returned to the storage using the pump 64 with a loss of 0.5% to 1.5%. Liquid hydrogen is pumped as follows. The valves 21, 30 are closed, the valve 36 is opened, the valve 63 is closed, the valve 62 is opened and the pump 61 is prepared for operation. The pressure in the tank 44 and the internal volume of the cryostat 1 is created and maintained by the control valve 21, which is controlled by the sensors 65, 66, 68. by supplying gaseous hydrogen, providing a cavitation-free operation of the pump 61. Pumping out of liquid hydrogen begins to be performed from the volume in which there is a larger amount of liquid hydrogen, which is determined by the level sensors 71 and 72. If there is more liquid hydrogen in the tank 44 than in cryostat 1, then valve 19 is opened, pump 66 is turned on and liquid hydrogen is pumped out of tank 44 into storage. When the minimum level of liquid hydrogen in the tank is reached, liquid hydrogen is pumped out of the cryostat 1, for which valve 15 is opened and valve 19 is closed. When the minimum level of liquid hydrogen in the inner volume of the cryostat 1 is reached, pump 64 is turned off, valves 62, 15 and 21 are closed, after which the operations to warm up the tank 44 and cryostat 1 from 20 K to 300 K and dismantle the tank 44 from the cryostat 1 are carried out identically to the operations for tank 44, which has passed the cryogenic strength test without destruction. In case of erroneous actions of the operator or the occurrence of emergency situations, safety valves 37 and 38 are installed to protect the tank and cryostat.

The proposed method of cryogenic-strength testing of a hydrogen tank, as can be seen from the description, significantly simplifies the test technology, increases their safety and reliability, and in addition, as shown by the estimated calculations, reduces capital and operating costs by 10-15 times, especially in the case if a bench cryogenic system is created at launch cryogenic filling complexes of rocket and space technology or at factories for the production of large-tonnage liquid hydrogen.

Claims (1)

A method of cryogenic-strength testing of a hydrogen tank, including replacing air in the tank with nitrogen, cooling the tank from 300 K to 80 K with liquid nitrogen, filling and draining liquid nitrogen from the tank, replacing the nitrogen medium with helium, cooling the tank from 80 K to 20 K h 22 K with the help of a helium refrigerator, increasing the helium pressure in the tank to the calculated one at a cryostatting temperature of 20 K ÷ 22 K, heating the tank to 300 K and compressing helium from the tank into the storage, replacing helium with air, characterized in that the tank is tested in a cryostat , at the same time, before the start of the tests, the volume of the tank is connected to the inner volume of the cryostat, after which the air is replaced with nitrogen, the tank and the inner vessel of the cryostat are cooled down with liquid nitrogen from 300 K to 90 K ÷ 85 K, then the nitrogen is replaced with hydrogen and cooled down with liquid hydrogen the tank and the inner vessel of the cryostat from 90 K ÷ 85 K to 20 K ÷ 22 K, after which the tank is filled with liquid hydrogen and the volume of the tank is disconnected from the inner volume of the cryostat a, and then the pressure in the tank is increased to the calculated value and in the case of the integrity of the tank, liquid hydrogen is removed from the tank, after which the volume of the tank is again connected to the internal volume of the cryostat and the tank and the inner vessel of the cryostat are warmed up from 20 K ÷ 22 K to 70 K ÷ 80 K with gaseous hydrogen, and then up to 300 K with gaseous nitrogen, after which the nitrogen is changed to air, and when the tank structure is destroyed during the pressure increase of liquid hydrogen, the tank volume is connected to the inner volume of the cryostat and liquid hydrogen is removed from both volumes, but in the first a turn from a volume with a larger mass of liquid hydrogen, and then the tank and the inner vessel of the cryostat are heated from 20 K ÷ 22 K to 70 K ÷ 80 K with gaseous hydrogen, and then up to 280 K ÷ 290 K with nitrogen, after which the nitrogen is replaced by air ...

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