CN216524275U - Mass method liquid hydrogen flow standard device driven by liquid hydrogen pump - Google Patents

Abstract

The utility model discloses a mass method liquid hydrogen flow standard device driven by a liquid hydrogen pump. And outlets of the two sets of high-pressure driving air sources are connected with a heat-insulating pre-cooling tank, and outlets of the heat-insulating pre-cooling tank are respectively connected with the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B. The liquid outlet of the standard liquid hydrogen storage A tank is connected with the inlet of a low-temperature liquid hydrogen pump set, the outlet of the low-temperature liquid hydrogen pump set is connected with the inlet of a gas pipe of a supercooling tank, the outlet of the gas pipe of the supercooling tank is connected with the inlet of a detected flowmeter, the outlet of the detected flowmeter is connected with the liquid inlet of the standard liquid hydrogen storage B tank, and the standard liquid hydrogen storage B tank is arranged on a high-precision weighing unit. The liquid outlet of the hydrogen storage tank is connected with the liquid filling ports of the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B through a manifold respectively. The standard flow generated by the utility model realizes stepless regulation by matching the low-temperature liquid hydrogen pump set with the proportion regulating valve, can directly trace to the standard weights of corresponding metering grades, has very small liquid hydrogen loss, can repeatedly use the liquid hydrogen stored in the hydrogen storage tank, and has high safety.

Description

Mass method liquid hydrogen flow standard device driven by liquid hydrogen pump

Technical Field

The utility model belongs to the technical field of hydrogen energy metering, and relates to a mass method liquid hydrogen flow standard device driven by a liquid hydrogen pump.

Background

The hydrogen energy is one of the cleanest energy sources, has the advantages of various sources, zero emission at terminals, wide application and the like, and has great effects on ensuring the national energy safety, promoting the energy industry upgrading and the like. Hydrogen energy is expected to be a great prospect in the process of achieving the goals of carbon peaking and carbon neutralization. Meanwhile, the hydrogen energy can also be used as a bridge for bearing renewable and unstable wind energy and solar energy, so that the energy conservation and the efficiency improvement of the whole society are contributed, and the hydrogen energy can bring a cleaner and better living environment for people.

High-pressure hydrogen and low-temperature liquid hydrogen are two states of hydrogen in the hydrogen energy industry chain, wherein the high-pressure hydrogen is the mainstream hydrogen storage and hydrogenation mode at present, but with the maturity of high-pressure hydrogen storage materials such as a carbon fiber fully-wound composite material gas cylinder with a metal liner, a hydrogen storage container capable of bearing 70MPa is gradually pushed to the market. On the other hand, compared with high-pressure hydrogen, the liquid hydrogen has higher volume energy density and has obvious advantages in the aspects of large-scale development of storage and transportation of the hydrogen energy industry. Therefore, with the rise of hydrogen-powered automobiles, the demand for hydrogen gas is increasing, and the status of liquid hydrogen is further increasing.

The hydrogen energy industrial chain comprises a plurality of links such as upstream hydrogen preparation, midstream hydrogen storage and transportation, downstream hydrogen adding stations, hydrogen energy fuel cell application and the like. The hydrogen energy metering technology is involved in the processes of preparation, storage, transportation, hydrogenation and use of hydrogen energy products. However, there is currently less interest in performance testing and flow measurement of hydrogen products, and mature methods, standards, and infrastructure for hydrogen energy equipment performance testing and testing are lacking. Up to now, the flow meter can be used for directly measuring the yield of the cryogenic liquid hydrogen at home and abroad. However, with the national layout and rapid development of the hydrogen energy industry, accurate flow measurement is required in hydrogen storage and transportation and various trade handover links. Therefore, the improvement of the hydrogen flow metering system and the large-scale hydrogen flow metering industry has important significance.

At present, the low-temperature liquid flow standard device including liquid hydrogen mainly comprises a standard meter method and a mass method, and the metering characteristics of the standard meter method are usually obtained by verifying and calibrating the standard meter method through the mass method. Therefore, from the perspective of tracing the liquid hydrogen flow, a mass method liquid hydrogen flow standard device is established to realize the verification and calibration of the liquid hydrogen flow, thereby supporting the healthy and rapid development of the hydrogen energy industry chain.

Disclosure of Invention

Aiming at the problem of the liquid hydrogen standard flow which is urgently generated in the real-time verification and calibration of the liquid hydrogen flowmeter, the utility model provides a liquid hydrogen pump-driven mass method liquid hydrogen standard flow generation device.

In order to realize the aim and realize the continuous generation and the control of the standard flow of the liquid hydrogen, the utility model adopts the following technical scheme:

the device comprises a high-pressure driving gas source, a heat-insulation pre-cooling groove, a standard hydrogen storage tank, a supply hydrogen storage tank, a low-temperature liquid hydrogen pump set, a supercooling box, a vacuum supercooling box, a detected flowmeter, a special discharge pipeline, a high-precision weighing unit and a matched pipeline;

the high-pressure driving gas source, the heat-insulation pre-cooling groove and the standard hydrogen storage tank are respectively provided with two, the outlet of each high-pressure driving gas source is connected with one heat-insulation pre-cooling groove, and the outlet end of the gas pipe of each heat-insulation pre-cooling groove is connected with the standard hydrogen storage tank through a pipeline; the standard hydrogen storage tank comprises a standard liquid hydrogen storage tank A and a standard liquid hydrogen storage tank B;

the liquid outlet of the standard liquid hydrogen storage tank A is connected with the inlet of a low-temperature liquid hydrogen pump set, the outlet of the low-temperature liquid hydrogen pump set is connected with the inlet of a gas pipe of a supercooling tank, the outlet of the gas pipe of the supercooling tank is connected with the inlet of a detected flowmeter, and the outlet of the detected flowmeter is connected with the liquid inlet of the standard liquid hydrogen storage tank B;

the liquid outlet of the standard liquid hydrogen storage B tank is connected with the liquid inlet of the standard liquid hydrogen storage A tank and the liquid inlet of the hydrogen storage tank through a liquid return pipeline;

the standard liquid hydrogen storage tank A and an exhaust valve for supplying the hydrogen storage tank are connected with the special exhaust pipeline through a manifold, and the exhaust valve of the standard liquid hydrogen storage tank B is connected with the special exhaust pipeline through a hose;

the liquid outlet of the hydrogen storage tank is respectively connected with the liquid feeding ports of the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B through a manifold;

the standard liquid hydrogen storage B tank is arranged on the high-precision weighing unit;

and a helium gas diffuser and a liquid hydrogen diffuser are arranged in the standard hydrogen storage tank.

Further, the detected flowmeter is arranged in the vacuum cooling box.

Furthermore, the high-pressure driving gas source adopts a low-temperature high-pressure helium source, is composed of a high-pressure gas cylinder and a compressor, and is used for purging and precooling the whole liquid hydrogen flow standard device.

Furthermore, liquid nitrogen or liquid helium is filled in the supercooling box, and the test pipeline in the supercooling box is cooled forcibly.

Furthermore, the clutch mechanism of the standard liquid hydrogen storage B tank adopts a double-layer vacuum heat insulation quick plugging mode, and is used for reducing heat leakage of a system and avoiding influence on a quality measurement result of the standard liquid hydrogen storage B tank.

Furthermore, the hydrogen supply storage tank realizes timely supplement of liquid hydrogen in the standard hydrogen storage tank through the matching of a self-pressurization device and a liquid level meter and a pressure gauge.

Furthermore, a proportional control valve is arranged on a pipeline of the low-temperature liquid hydrogen pump set and used for obtaining verification flow points with different sizes and realizing stepless regulation.

Compared with the prior art, the utility model has the following beneficial effects:

1. the standard flow range generated by the utility model can be accurately adjusted by matching the low-temperature liquid hydrogen pump set with the proportion adjusting valve, flowmeter parameters with different flows can be tested, the adjusting margin of the proportion adjusting valve is wider, and stepless adjustment can be realized within the flow range of the low-temperature liquid hydrogen pump set;

2. the utility model can provide the liquid hydrogen actual flow standard flow required by the verification and calibration of the liquid hydrogen flowmeter, can directly trace to the standard weights of corresponding metering grades, and completes the tracing of the quality;

3. in the process of generating the standard flow, the liquid hydrogen loss is very small, and the liquid hydrogen stored in the standard hydrogen storage tank can be reused;

4. the standard liquid hydrogen storage tank B is separated from the pipeline system in a quick-connection-opening and quick-connection-disconnection mode, so that the standard liquid hydrogen storage tank B can be quickly separated from the weighing unit, static weighing is realized, and the measuring accuracy of the system is improved;

5. the clutch mode of the standard hydrogen storage tank can be matched with a corresponding actuator for remote control, so that the safety and compatibility of the system are improved;

6. the heat insulation vacuum, the temperature and the pressure of the standard liquid hydrogen storage tank and the pipeline system are monitored in real time, and the overall safety of the system is higher.

Drawings

FIG. 1 is a schematic diagram of a liquid hydrogen flow rate standard device driven by a liquid hydrogen pump;

FIG. 2 is a schematic diagram of a pre-cooling system piping arrangement;

FIG. 3 is a schematic diagram of a standard liquid hydrogen A-tank arrangement with multiple pipe connections;

FIG. 4 is a schematic diagram of a standard liquid hydrogen B storage tank and a high-precision weighing unit device;

FIG. 5 is a schematic view of a cryogenic liquid hydrogen pump package;

FIG. 6 is a schematic view of a subcooling tank device;

FIG. 7 is a schematic view of a vacuum coldbox apparatus;

fig. 8 is a schematic view of a supply hydrogen storage tank device having a multi-line interface.

In the figure: 1. a first source of low temperature high pressure helium; 2. a second low temperature high pressure helium source; 3. a first precision pressure reducing valve; 4. a second precision pressure reducing valve; 5. a first insulated pre-cooling tank; 6. a second adiabatic pre-cooling bath; 7. a standard liquid hydrogen storage tank A; 8. a standard liquid hydrogen storage B tank; 9. a supply hydrogen storage tank; 10-1, a first thermometer; 11-1, a first pressure gauge; 12-1, a first safety valve; 12-2, a second safety valve; 13. a proportional regulating valve; 14-1, a first stop valve; 14-2, a second stop valve; 14-3, a third stop valve; 14-4, a fourth stop valve; 15. a low temperature liquid hydrogen pump; 16. an supercooling box; 17. a vacuum cooling box; 18. detecting the flow meter; 19. a liquid return pipeline; 20. specially arranging pipelines; 21-1, a first vacuum pump; 21-2, a second vacuum pump; 21-3, a third vacuum pump; 22. a high-precision weighing unit; 23-1, a first exhaust valve; 23-2, a second exhaust valve; 701. a first liquid level meter; 702. a first helium gas diffuser; 703. a first liquid hydrogen diffuser; 704. a first vacuum jacket; 501. a pre-cooling tank pipeline; 502. a pre-cooling tank body; 10-2, a second thermometer; 11-2, a second pressure gauge; 701. a first liquid level meter; 705. a third thermometer; 706. a third pressure gauge; 707. a fourth thermometer; 708. a fourth pressure gauge; 709. a first inlet valve; 710. a first outlet valve; 711. a first fill port valve; 801. a second level gauge; 802. a second helium gas diffuser; 803. a second liquid hydrogen diffuser; 804. a second vacuum jacket; 805. a fifth thermometer; 806. a fifth pressure gauge; 807. a sixth thermometer; 808. a sixth pressure gauge; 809. a second inlet valve; 810. a second outlet valve; 811. a second fill port valve; 1601. a seventh thermometer; 1602. a seventh pressure gauge; 1603. a third liquid level meter; 1701. an eighth thermometer; 1702. an eighth pressure gauge; 901. a third liquid level meter; 902. a third liquid hydrogen diffuser; 903. a third vacuum jacket; 904. a ninth thermometer; 905. a ninth pressure gauge; 906. a tenth thermometer; 907. a tenth pressure gauge; 908. a pressure increasing valve; 909. a third inlet valve; 910. a third outlet valve.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the technical solution of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is obvious that the description is only a part of the embodiments of the present invention, and not all embodiments. Based on the embodiments of the utility model, all other embodiments obtained by a person skilled in the art without creative efforts shall fall within the protection scope of the utility model.

The utility model relates to a mass method liquid hydrogen flow standard device driven by a liquid hydrogen pump, which comprises two low-temperature high-pressure helium sources, two heat-insulating pre-cooling grooves, a standard liquid hydrogen storage tank A, a standard liquid hydrogen storage tank B, a liquid hydrogen supply storage tank, a low-temperature liquid hydrogen pump set, a thermometer, a pressure gauge, a safety valve, a stop valve, an exhaust valve, a booster valve, a precise pressure reducing valve, a helium gas diffuser, a liquid level meter, a liquid hydrogen diffuser, a vacuum sleeve, an over-cooling tank, a vacuum cooling tank, a detected flowmeter, a vacuum pump, a quick connector, a liquid return pipeline, a special discharge pipeline, a high-precision weighing unit and a matched pipeline system.

The utility model is further illustrated by the following examples in conjunction with the accompanying drawings:

examples

The following components are connected in the manner shown in fig. 1, and the implementation of the device of the utility model is well within the skill of the art. The device comprises a first low-temperature high-pressure helium source 1, a second low-temperature high-pressure helium source 2, a first precision pressure reducing valve 3, a second precision pressure reducing valve 4, a first heat insulation pre-cooling groove 5, a second heat insulation pre-cooling groove 6, a standard liquid hydrogen storage A tank 7, a standard liquid hydrogen storage B tank 8, a supply hydrogen storage tank 9, a first thermometer 10-1, a first pressure gauge 11-1, a first liquid level meter 701, a first helium gas diffuser 702, a first liquid hydrogen diffuser 703, a first vacuum sleeve 704, a first safety valve 12-1, a proportion adjusting valve 13, a first stop valve 14-1, a low-temperature liquid hydrogen pump 15, an overcooling tank 16, a vacuum cooling tank 17, a detected flow meter 18, a liquid return pipeline 19, a special exhaust pipeline 20, a first vacuum pump 21-1, a high-precision weighing unit 22 and a first exhaust valve 23-1.

Referring to fig. 1, in the operation of the liquid hydrogen flow calibration device of the present invention, liquid hydrogen in the calibration system varies according to the required calibration flow range, and the low-temperature liquid hydrogen pump set composed of a plurality of low-temperature liquid hydrogen pumps 15 is matched with the driving mode of the proportional regulating valve 13 to provide a stable flow for the flow meter 18 to be tested in the system. By utilizing the proportion regulating valve 13, the flow of the liquid can be conveniently regulated, the regulating margin of the proportion regulating valve 13 is wider, and stepless regulation can be realized within the flow range of the low-temperature liquid hydrogen pump set.

The device comprises a first low-temperature high-pressure helium source 1 and a second low-temperature high-pressure helium source 2 which are provided with precooling systems and contain inert helium gas, impurities in a standard liquid hydrogen storage tank A7, a standard liquid hydrogen storage tank B8 and pipelines are purged, the whole liquid hydrogen flow standard device is precooled to the temperature of low-temperature liquid hydrogen, and finally helium and the impurities in the pipelines are discharged through a special discharge pipeline 20. The first precision pressure reducing valve 3 and the second precision pressure reducing valve 4 control helium gas driving through pressure reduction at inlet and outlet. The first and second adiabatic pre-cooling cells 5 and 6 cool the incoming helium gas pipeline to liquid hydrogen temperature. And a first thermometer 10-1 and a first pressure gauge 11-1 are arranged on an outlet pipeline of the first insulating pre-cooling groove 5 and are used for recording the experiment temperature and pressure in real time so as to carry out safety monitoring. The first safety valve 12-1 is used for ensuring the system safety in emergency situations such as heat insulation failure and the like and avoiding the pressure in the pipeline and the standard liquid hydrogen storage B tank 8 from exceeding the limit. After the purging and pre-cooling are finished, helium and impurities in the pipeline flow into the special exhaust pipeline 20 through the first exhaust valve 23-1. The first shut-off valve 14-1 is used to control the flow state of the shut-off flow. The system is provided with a supply hydrogen storage tank 9 with a self-pressurization device, and liquid hydrogen filling of a standard liquid hydrogen storage A tank 7 and a standard liquid hydrogen storage B tank 8 is realized by the self-pressurization device.

After the device is precooled integrally and liquid hydrogen is filled completely, before the flow standard device detects the flow of the flow meter, the valves for connecting the hydrogen storage tank 9 with the standard liquid hydrogen storage A tank 7 and the standard liquid hydrogen storage B tank 8 are closed, the liquid inlet and outlet valves of the standard liquid hydrogen storage A tank 7 and the liquid inlet and outlet valves of the hydrogen storage liquid hydrogen storage B tank 8 are opened, the liquid hydrogen pump 15 is started and matched with the proportion regulating valve 13, and liquid hydrogen in the standard liquid hydrogen storage A tank 7 is driven to flow out of the tank body through the first liquid hydrogen diffuser 703, flows to the standard liquid hydrogen storage B tank 8 and flows back to the standard liquid hydrogen storage A tank 7 through the liquid return pipeline 19. The first liquid hydrogen diffuser 703 is used to reduce the uniform distribution speed, and avoid the flow instability and potential safety hazard caused by the excessive pressure and liquid level fluctuation in the tank due to the flow in and out of the tank. The supercooling tank 16 ensures that the liquid hydrogen flowing into the detected flowmeter 18 is in a pure liquid phase through the supercooling degree, and ensures that the test liquid hydrogen is not gasified due to heat leakage of the system.

The first liquid level meter 701 is arranged in the standard liquid hydrogen storage A tank 7, so that the flow liquid level in the standard liquid hydrogen storage A tank 7 can be measured in real time when liquid hydrogen flows, and the volume standard flow for providing reference for experiments can be provided.

A vacuum sleeve is arranged on the inner periphery of the tank body of the standard liquid hydrogen storage B tank 8, and the heat insulation layer between the inner tank bodies is continuously vacuumized through an external first vacuum pump 21-1. After the experiment is finished, the system is reset, and the pressure of the second precise pressure reducing valve 4 is reduced through the inlet and the outlet to control helium to drive liquid hydrogen in the standard liquid hydrogen storage B tank 8 to flow back to the standard liquid hydrogen storage A tank 7 through the liquid return pipeline 19. A high-precision weighing unit 22 is arranged below the standard liquid hydrogen B storage tank 8, so that static mass weighing of the standard liquid hydrogen B storage tank 8 can be realized.

When the reading of the to-be-detected flow meter 18 tends to be stable, the liquid outlet valve of the standard liquid hydrogen storage B tank 8 is closed, liquid hydrogen in the standard liquid hydrogen storage A tank 7 is stably and continuously added to the standard liquid hydrogen storage B tank 8 on the high-precision weighing unit 22, and therefore a standard liquid hydrogen accumulated flow is generated.

And taking the time point of cutting off the valve at the liquid outlet of the standard liquid hydrogen B storage tank 8 as the starting point of starting timing, and closing the time point of the liquid inlet of the standard liquid hydrogen B storage tank 8 as the stopping point of ending timing. The standard liquid hydrogen cumulative flow Q_ΒMass difference Deltam before and after liquid is added from liquid hydrogen storage tank B_ΒAnd the filling time Deltat, i.e.

Then the standard liquid hydrogen flow Q is measured_ΒAnd the value displayed by the detected flowmeter is analyzed and compared, so that the aim of field verification of the detected flowmeter is fulfilled.

Fig. 2 is a schematic diagram of a pre-cooling system. The pipeline of the pre-cooling system consists of a low-temperature high-pressure helium source, a heat-insulating pre-cooling tank and pipelines thereof. And the second pressure gauge 11-2 is connected with an outlet of the first low-temperature high-pressure helium source 1 and is used for monitoring the change of the pressure value of the first low-temperature high-pressure helium source 1 in real time. The first precision pressure reducing valve 3 is connected to a pipeline of the precooling system, and the pressure of the first low-temperature high-pressure helium source 1 is changed by manually adjusting the first precision pressure reducing valve 3, so that the output quantity of helium is controlled. The low-temperature high-pressure helium gas flowing out of the first low-temperature high-pressure helium gas source 1 flows into a pipeline in the heat-insulating precooling tank 5 after passing through the first precision pressure reducing valve 3, so that the low-temperature high-pressure helium gas is precooled to the temperature of low-temperature liquid hydrogen, and then purging and precooling are carried out in the tank and the pipeline. The pre-cooling system can be formed by a single cryogenic refrigerator or a heat-insulating pre-cooling tank constructed by cryogenic fluids such as liquid nitrogen and liquid hydrogen, and the heat-insulating pre-cooling tank 5 constructed by the cryogenic fluids is selected in the embodiment. 501 is a pre-cooling tank pipeline used for transporting carriers. 502 is a pre-cooling tank body used to hold the carrier during pre-cooling. The second thermometer 10-2 is used to monitor the temperature of the adiabatic pre-cooling tank 5 in real time, and the temperature in the adiabatic pre-cooling tank 5 can be adjusted according to the value displayed by the second thermometer 10-2. The low-temperature high-pressure helium source device with the precooling system plays a role in releasing high-pressure helium to purge and precool the whole device.

Fig. 3 is a schematic diagram of a standard liquid hydrogen storage a tank 7 with multiple pipe joints. The standard liquid hydrogen storage A tank 7 is internally provided with a fourth thermometer 707 and a fourth pressure gauge 708 for recording the temperature and the pressure of the liquid hydrogen in the tank in real time, thereby playing a role of safety monitoring. A third temperature gauge 705 and a third pressure gauge 706 are used to monitor the real-time temperature and pressure values in the first vacuum jacket 704. The second safety valve 12-2 is arranged on the standard liquid hydrogen storage A tank 7, so that the system safety under emergency conditions such as heat insulation failure and the like is ensured, and the pressure in the pipeline and the standard liquid hydrogen storage A tank 7 is prevented from exceeding the limit. The second exhaust valve 23-2 is used for discharging gas impurities in the standard liquid hydrogen storage A tank 7 and in the pipeline. The second vacuum pump 21-2 is connected with the standard liquid hydrogen storage A tank 7 through a second stop valve 14-2, and the second stop valve 14-2 plays a role in controlling the second vacuum pump 21-2 to pump air in the vacuum layer 704 of the standard liquid hydrogen storage A tank 7 at any time. The first inlet valve 709 and the first outlet valve 710 respectively control the input and output of the liquid hydrogen of the standard liquid hydrogen storage a tank. During precooling, the low-temperature high-pressure helium enters the standard liquid hydrogen storage A tank 7 through the helium diffuser 702, and the temperature in the storage tank and the temperature in the pipeline are precooled. The first helium gas diffuser 702 and the first liquid hydrogen diffuser 703 of the standard liquid hydrogen storage tank a 7 avoid flow instability and safety hazards caused by excessive pressure and liquid level fluctuation in the tank due to flow into and out of the storage tank. The first liquid level meter 701 may display the liquid hydrogen level value of the current standard liquid hydrogen storage a-tank 7 to provide a reference volumetric standard flow rate. The filling of the liquid hydrogen in the standard liquid hydrogen storage a tank 7 is achieved by opening the first filling port valve 711. This liquid hydrogen storage tank output device with multi-line interface has fine memory function to liquid hydrogen, and external liquid feeding demand in the time of can satisfying the experiment is one of the most important links of complete set of device.

Fig. 4 is a schematic diagram of a standard liquid hydrogen B tank and a high-precision weighing unit device, and the device comprises a standard liquid hydrogen B tank 8 and a high-precision weighing unit 22. The high-precision weighing unit 22 is a high-precision unit electronic scale capable of real-time timing weighing, and is placed below the standard liquid hydrogen storage B tank 8 and used for measuring the weight of the standard liquid hydrogen storage B tank 8 in real time. After the experiment is finished, the liquid inlet and outlet pipeline connected with the standard liquid hydrogen storage B tank 8 in a double-layer vacuum heat insulation quick plugging mode is disconnected, so that the standard liquid hydrogen storage B tank 8 is separated from the whole device system to complete self unit weighing, and the accuracy of system measurement is improved.

The second liquid level meter 801 is arranged in the standard liquid hydrogen B storage tank 8, and can measure the flow liquid level in the standard liquid hydrogen B storage tank 8 in real time when liquid hydrogen flows so as to provide a volume standard flow for an experiment to refer. The second helium diffuser 802 and the second liquid hydrogen diffuser 803 of the standard liquid hydrogen storage tank B8 are used for reducing the uniform distribution speed, and avoiding flow instability and potential safety hazard caused by excessive pressure and liquid level fluctuation in the tank due to flow in and out of the storage tank. A sixth thermometer 807 and a sixth pressure gauge 808 are arranged in the 8 standard liquid hydrogen storage B tank body and are used for recording the temperature and the pressure of the liquid hydrogen in the tank body in real time, so that the safety monitoring effect is achieved. The fifth temperature gauge 805 and the fifth pressure gauge 806 are used to monitor the real-time temperature and pressure values in the vacuum jacket. The first exhaust valve 23-1 has a function of discharging gas impurities in the standard liquid hydrogen storage B tank 8 and in the pipeline. The second liquid inlet valve 809 and the second liquid outlet valve 810 of the standard liquid hydrogen storage B tank 8 respectively control the inflow and outflow of liquid hydrogen in the tank. The second vacuum pump 21-1 is connected with the standard liquid hydrogen storage B tank 8 through a third stop valve 14-3, and the third stop valve 14-3 plays a role in controlling the second vacuum pump 21-1 to pump air in the standard liquid hydrogen storage B tank 8 at any time.

Fig. 5 is a schematic diagram of a cryogenic liquid hydrogen pump set. The low-temperature liquid hydrogen pump 15 can expand the flow test range. The adjusting margin of the proportional adjusting valve 13 is wide, and stepless adjustment can be realized within the flow range of the low-temperature liquid hydrogen pump 15. The first stop valve 14-1 is arranged at the inlet and the outlet of each low-temperature liquid hydrogen pump 15, so that the safety of the system is improved.

Fig. 6 is a schematic view of a subcooling tank device. Liquid helium or liquid nitrogen is filled in the supercooling tank 16, and the hydrogen of the test liquid is prevented from being gasified through supercooling degree. The supercooling box 16 is provided with a seventh thermometer 1601 and a seventh pressure gauge 1602, and is used for recording the temperature value and the pressure value of the liquid hydrogen in the box body in real time, so that the safety monitoring effect is achieved. A third level gauge 1603 is used to record the level of liquid helium or liquid nitrogen as the supercooling tank is filled.

Fig. 7 is a schematic view of the vacuum cold box device. The flow meter 18 to be tested is placed in the vacuum cooling box 17. The upstream and downstream test sections of the tested flowmeter 18 are provided with an eighth thermometer 1701 and an eighth pressure gauge 1702, which are used for recording the temperature value and the pressure value of the test section in real time and playing a role in safety monitoring.

Fig. 8 is a schematic view of a supply hydrogen storage tank device having a multi-line interface. The pressure increasing valve 908 is opened to increase the pressure in the supply hydrogen storage tank 9, thereby filling the standard liquid hydrogen storage A, B tank. The fourth level gauge 901 is provided in the hydrogen storage tank 9, and the liquid hydrogen level in the hydrogen storage tank 9 can be measured in real time. The third hydrohydrogen diffuser 902 of the supply hydrogen tank 9 is used to reduce the distribution velocity and avoid the flow instability and safety hazard caused by the excessive pressure and liquid level fluctuation in the tank due to the flow in and out of the tank. The supply hydrogen storage tank 9 is equipped with a tenth thermometer 906 in the tank body, and a tenth pressure gauge 907 is used for recording the temperature and the pressure value of the liquid hydrogen in the tank body in real time, thereby playing a role in safety monitoring. A ninth thermometer 904 and a ninth pressure gauge 905 are used to monitor the real-time temperature and pressure values in the vacuum jacket. The third exhaust valve 23-3 has a function of discharging gas impurities supplied into the hydrogen storage tank 9 and the pipeline. A third liquid inlet valve 909 and a third liquid outlet valve 910 which are provided to the hydrogen storage tank 9 control the inflow and outflow of liquid hydrogen in the tank, respectively. The third vacuum pump 21-3 is connected to the supply hydrogen storage tank 9 through a fourth cut-off valve 14-4, and the fourth cut-off valve 14-4 plays a role of controlling the third vacuum pump 21-3 to pump air supplied to the third vacuum jacket 903 in the hydrogen storage tank 9 at any time.

The working process is as follows:

1. before the liquid hydrogen flow standard device is calibrated, a precooling process of the whole device is carried out to prevent the liquid hydrogen from being gasified due to the influence of temperature in the flowing process to cause the measurement error of the weighing unit. And in the precooling working stage, the low-temperature high-pressure helium source is switched on, the pipeline is precooled and cooled through the adiabatic precooling tank, the helium temperature is cooled to the liquid hydrogen temperature, then the cooled helium flows into the thermometer and the pressure gauge on the pipeline, then flows into the tank body of the standard liquid hydrogen storage tank A through the helium diffuser, and then continuously flows through the low-temperature liquid hydrogen pump set, the supercooling tank, the detected flowmeter, the standard liquid hydrogen storage tank B and the liquid return pipeline after flowing out.

2. And when the temperature of the whole system device is cooled to the temperature value of the low-temperature liquid hydrogen, opening exhaust valves of the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B, discharging helium gas and gas impurities in the tanks into special exhaust pipelines, and precooling and purging are finished.

3. And filling liquid hydrogen into the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B. In the liquid hydrogen filling stage, a liquid outlet valve of the hydrogen storage tank and liquid filling port valves of the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B are opened, a pressure increasing valve of the hydrogen storage tank is opened, liquid hydrogen is driven to flow to the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B by increasing the pressure supplied to the hydrogen storage tank, and the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B are filled by matching with a pressure gauge, a liquid level meter and the like.

4. After the whole precooling and liquid hydrogen filling of the device are finished and before the flow of the flowmeter is verified by the flow standard device, the valves for connecting the hydrogen storage tank with the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B are closed, and the liquid inlet and outlet valves of the standard liquid hydrogen storage tank A and the liquid inlet and outlet valves of the standard liquid hydrogen storage tank B are opened.

5. And starting the liquid hydrogen pump to drive the liquid hydrogen in the standard liquid hydrogen storage tank A to flow through the liquid hydrogen pump, the supercooling tank, the detected flowmeter and the standard liquid hydrogen storage tank B.

6. When the flow of the flowmeter begins to be calibrated, the liquid outlet valve of the short-circuit pipeline of the standard liquid hydrogen storage B tank is closed, and the liquid inlet valve of the hydrogen supply storage tank is opened, so that the liquid hydrogen in the liquid return pipeline flows into the hydrogen supply storage tank.

7. Liquid hydrogen in the standard liquid hydrogen storage tank A flows through the detected meter and is stably added to the standard liquid hydrogen storage tank B on the weighing unit, so that a standard accumulated flow of liquid hydrogen is generated. Closing a liquid inlet valve of the quasi-liquid hydrogen storage tank B; the standard liquid hydrogen storage tank B is quickly separated from the liquid hydrogen inlet pipeline, the liquid adding pipeline and the vacuum suction pipeline through double-layer vacuum heat insulation quick connectors, and static weighing is achieved. The clutch mode of the standard liquid hydrogen storage tank can be matched with a corresponding actuator for remote control, and the safety and compatibility of the system are improved.

Taking the time point of closing a liquid outlet valve of a standard liquid hydrogen storage B tank as the starting point t of device timing₀At this time, the precision is highThe weight of the standard liquid hydrogen storage B tank measured by the weighing unit is m₀(ii) a The time point of closing the liquid inlet valve of the standard liquid hydrogen storage B tank is taken as the cut-off point t of timing₁At this time, the mass of the standard liquid hydrogen storage B tank is m₁. The standard liquid hydrogen flow rate Q_ΒMass difference Deltam before and after liquid adding by weighing B unit_ΒAnd filling time Δ t, i.e.:

8. and after the verification is finished, the system executes resetting. In the resetting stage, liquid inlet and outlet valves of the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B are respectively opened, a low-temperature high-pressure helium gas source connected with the standard liquid hydrogen storage tank B is opened, liquid hydrogen in the standard liquid hydrogen storage tank B is driven to return to the standard liquid hydrogen storage tank A through a liquid return pipeline, and the system reaches the initial state again.

The adiabatic vacuum, the temperature and the pressure of the liquid hydrogen storage tank and the pipeline system are monitored in real time, and the overall safety of the system is higher.

The liquid hydrogen flow standard device system can ensure the stable state of the liquid hydrogen in the flow process and avoid gasification. The establishment of the liquid hydrogen flow standard device can realize the real-flow verification and calibration of the liquid hydrogen. The system can provide the liquid hydrogen real flow standard accumulated flow required by the verification and calibration of the liquid hydrogen flowmeter, and can directly trace to the standard weights of corresponding metering grades to finish the tracing of the quality.

In conclusion, the mass method liquid hydrogen flow standard device driven by the liquid hydrogen pump has a wide range of measuring flow meters, and the stepless regulation of the liquid hydrogen flow can be realized by matching the low-temperature liquid hydrogen pump set with the proportion regulating valve. The separation device adopts a double-layer vacuum heat insulation quick-plugging port, and can realize static weighing of the standard liquid hydrogen storage tank B. The device is provided with a thermometer and a pressure gauge for real-time monitoring, and is provided with safety valves for ensuring the system safety under emergency situations such as heat insulation failure and the like, so that the pressure in the pipeline and the hydrogen storage tank is prevented from exceeding, and the safety of the system is high.

While the utility model has been described in connection with specific embodiments thereof, it will be understood that these should not be construed as limiting the scope of the utility model, which is defined in the following claims, and any variations which fall within the scope of the claims are intended to be embraced thereby.

Claims (7)

1. Liquid hydrogen pump driven mass method liquid hydrogen flow standard device, including high pressure drive air supply, adiabatic precooling groove, standard hydrogen storage tank, supply with hydrogen storage tank, low temperature liquid hydrogen pump package, super-cooling box, vacuum cold box, examined flowmeter, special row pipeline, high accuracy weighing unit and supporting pipeline, its characterized in that:

the high-pressure driving gas source, the heat-insulation pre-cooling groove and the standard hydrogen storage tank are respectively provided with two, the outlet of each high-pressure driving gas source is connected with one heat-insulation pre-cooling groove, and the outlet end of the gas pipe of each heat-insulation pre-cooling groove is connected with the standard hydrogen storage tank through a pipeline; the standard hydrogen storage tank comprises a standard liquid hydrogen storage A tank and a standard liquid hydrogen storage B tank;

the liquid outlet of the standard liquid hydrogen storage tank A is connected with the inlet of a low-temperature liquid hydrogen pump set, the outlet of the low-temperature liquid hydrogen pump set is connected with the inlet of a gas pipe of a supercooling tank, the outlet of the gas pipe of the supercooling tank is connected with the inlet of a detected flowmeter, and the outlet of the detected flowmeter is connected with the liquid inlet of the standard liquid hydrogen storage tank B;

the liquid outlet of the standard liquid hydrogen storage B tank is connected with the liquid inlet of the standard liquid hydrogen storage A tank and the liquid inlet of the hydrogen storage tank through a liquid return pipeline;

the standard liquid hydrogen storage tank A and an exhaust valve for supplying the hydrogen storage tank are connected with the special exhaust pipeline through a manifold, and the exhaust valve of the standard liquid hydrogen storage tank B is connected with the special exhaust pipeline through a hose;

the liquid outlet of the hydrogen storage tank is respectively connected with the liquid feeding ports of the standard liquid hydrogen storage tank A and the standard liquid hydrogen storage tank B through a manifold;

the standard liquid hydrogen storage B tank is arranged on the high-precision weighing unit;

and a helium gas diffuser and a liquid hydrogen diffuser are arranged in the standard hydrogen storage tank.

2. The liquid hydrogen pump-driven mass method liquid hydrogen flow rate standard device according to claim 1, characterized in that:

the detected flowmeter is arranged in the vacuum cold box.

3. The liquid hydrogen pump-driven mass method liquid hydrogen flow rate standard device according to claim 1, characterized in that:

the high-pressure driving gas source adopts a low-temperature high-pressure helium source, is composed of a high-pressure gas cylinder and a compressor, and is used for purging and precooling the whole liquid hydrogen flow standard device.

4. The liquid hydrogen pump-driven mass-method liquid hydrogen flow rate standard device according to claim 1, characterized in that:

liquid nitrogen or liquid helium is filled in the supercooling box, and the test pipeline in the supercooling box is cooled forcibly.

5. The liquid hydrogen pump-driven mass method liquid hydrogen flow rate standard device according to claim 1, characterized in that:

the clutch mechanism of the standard liquid hydrogen storage B tank adopts a double-layer vacuum heat insulation quick plugging mode, and is used for reducing heat leakage of a system and avoiding influence on a quality measurement result of the standard liquid hydrogen storage B tank.

6. The liquid hydrogen pump-driven mass method liquid hydrogen flow rate standard device according to claim 1, characterized in that:

the supply hydrogen storage tank realizes timely supplement of liquid hydrogen in the standard hydrogen storage tank by matching a self-pressurization device with a liquid level meter and a pressure gauge.

7. The liquid hydrogen pump-driven mass method liquid hydrogen flow rate standard device according to claim 1, characterized in that:

and a proportional regulating valve is arranged on the pipeline of the low-temperature liquid hydrogen pump set and used for obtaining verification flow points with different sizes and realizing stepless regulation.

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