Hydrogen liquefaction system

文档序号:1597253 发布日期:2020-01-07 浏览:16次 中文

阅读说明:本技术 一种氢液化系统 (Hydrogen liquefaction system ) 是由 雷灵龙 熊联友 马佳 汤建成 徐鹏 高金林 刘立强 龚领会 于 2019-10-21 设计创作,主要内容包括:一种氢液化系统,包括氦压缩机单元、第一一级换热器、第二一级换热器、预冷级透平膨胀机组、二级换热器组件、制冷级透平膨胀机组和氢节流阀;氦压缩机单依次连接第一一级换热器、第二一级换热器和二级换热器组件;预冷级透平膨胀机组的入口和第一一级换热器的高压出口连接,其出口和第二一级换热器的低压入口连接;制冷级透平膨胀机组的入口和二级换热器组件的高压出口连接,其出口和二级换热器组件的低压入口连接;第一一级换热器、第二一级换热器和二级换热器组件沿氢传输方向设置;上述氢液化系统,采用惰性气体氦气作为循环工质,相较于氢气作为工质的系统,不需要使用氢气作为冷却工质,进行液化的原料氢气进入系统压力较低,安全性较高。(A hydrogen liquefaction system comprises a helium compressor unit, a first primary heat exchanger, a second primary heat exchanger, a precooling stage turboexpander set, a secondary heat exchanger component, a refrigerating stage turboexpander set and a hydrogen throttle valve; the helium compressor is connected with the first primary heat exchanger, the second primary heat exchanger and the secondary heat exchanger assembly in sequence; the inlet of the precooling stage turbine expansion unit is connected with the high-pressure outlet of the first primary heat exchanger, and the outlet of the precooling stage turbine expansion unit is connected with the low-pressure inlet of the second primary heat exchanger; the inlet of the refrigeration stage turbine expansion unit is connected with the high-pressure outlet of the secondary heat exchanger component, and the outlet of the refrigeration stage turbine expansion unit is connected with the low-pressure inlet of the secondary heat exchanger component; the first primary heat exchanger, the second primary heat exchanger and the secondary heat exchanger assembly are arranged along the hydrogen transmission direction; according to the hydrogen liquefaction system, the inert gas helium is used as the circulating working medium, and compared with a system using hydrogen as the working medium, the hydrogen is not needed to be used as the cooling working medium, the pressure of liquefied raw material hydrogen entering the system is low, and the safety is high.)

1. A hydrogen liquefaction system is characterized by comprising a helium compressor unit, a primary heat exchanger assembly, a precooling stage turboexpander set, a secondary heat exchanger assembly, a refrigerating stage turboexpander set and a hydrogen throttle valve, wherein the primary heat exchanger assembly comprises a first primary heat exchanger and a second primary heat exchanger;

a high-pressure outlet of the helium compressor unit is connected with a high-pressure inlet of the first primary heat exchanger, a high-pressure outlet of the first primary heat exchanger is connected with a high-pressure inlet of the second primary heat exchanger, and a high-pressure outlet of the second primary heat exchanger is connected with a high-pressure inlet of the secondary heat exchanger component;

an inlet of the pre-cooling stage turbine expansion unit is connected with a high-pressure outlet of the first primary heat exchanger, and an outlet of the pre-cooling stage turbine expansion unit is connected with a low-pressure inlet of the second primary heat exchanger;

an inlet of the refrigeration stage turboexpander set is connected with a high-pressure outlet of the secondary heat exchanger component, and an outlet of the refrigeration stage turboexpander set is connected with a low-pressure inlet of the secondary heat exchanger component;

the first primary heat exchanger is provided with a hydrogen inlet, the first primary heat exchanger, the second primary heat exchanger and the secondary heat exchanger assembly are arranged along the hydrogen transmission direction, the secondary heat exchanger assembly is provided with a liquid hydrogen outlet, and the second primary heat exchanger and the secondary heat exchanger assembly are both filled with an orthoparahydrogen catalyst;

the hydrogen throttle valve is arranged at the inlet or the outlet of the secondary heat exchanger at the tail end of the secondary heat exchanger assembly along the hydrogen conveying direction.

2. The hydrogen liquefaction system of claim 1, wherein the helium compressor unit includes a helium compressor assembly and an oil separation assembly disposed between the helium compressor assembly and the first primary heat exchanger.

3. The hydrogen liquefaction system of claim 2, wherein the oil separation assembly comprises a multi-stage coalescing filter, a first-stage activated carbon adsorption cartridge, and a first-stage dust removal filter arranged in sequence.

4. The hydrogen liquefaction system of claim 2, wherein the helium compressor unit further comprises a helium buffer tank, a load control valve, an unload control valve, and a bypass regulator valve, the load control valve and the unload control valve being connected in series, the load control valve being connected to the oil separation assembly, the unload control valve being connected to the helium compressor assembly, one end of the bypass regulator valve being connected to a connection line between the load control valve and the oil separation assembly, the other end of the bypass regulator valve being connected to a connection line between the unload control valve and the helium compressor assembly, the helium buffer tank being connected to a connection line between the load control valve and the unload control valve.

5. The hydrogen liquefaction system of claim 1, wherein the pre-cooling stage turboexpander train is a single stage turbine, a multiple stage turbine in series, or a multiple stage turbine in parallel configuration.

6. The hydrogen liquefaction system of claim 5, wherein the pre-cooling stage turboexpander train includes a first turboexpander and a second turboexpander, the first turboexpander and the second turboexpander being connected in series, an inlet of the first turboexpander being connected to the high pressure outlet of the first primary heat exchanger, an outlet of the second turboexpander being connected to the low pressure inlet of the second primary heat exchanger.

7. The hydrogen liquefaction system of claim 1, wherein the secondary heat exchanger assembly includes a fourth secondary heat exchanger, a third secondary heat exchanger, a second secondary heat exchanger, and a first secondary heat exchanger arranged in that order along the direction of low pressure helium gas reflux.

8. The hydrogen liquefaction system of claim 7, wherein the refrigeration stage turboexpander train is a single stage turbine, a multiple stage turbine in series, or a multiple stage turbine in parallel configuration.

9. The hydrogen liquefaction system of claim 8, wherein the refrigeration stage turboexpander train includes a third turboexpander and a fourth turboexpander, an inlet of the third turboexpander is connected to the high pressure outlet of the first two-stage heat exchanger, an outlet of the third turboexpander is connected to the high pressure inlet of the third two-stage heat exchanger, an inlet of the fourth turboexpander is connected to the high pressure outlet of the third two-stage heat exchanger, and an outlet of the fourth turboexpander is connected to the low pressure inlet of the fourth two-stage heat exchanger.

10. The hydrogen liquefaction system of claim 1, further comprising a first cryogenic adsorber disposed between the high pressure outlet of the second primary heat exchanger and the high pressure inlet of the secondary heat exchanger assembly and a second cryogenic adsorber disposed between the hydrogen outlet of the second primary heat exchanger and the hydrogen inlet of the secondary heat exchanger assembly.

Technical Field

The invention relates to the technical field of hydrogen liquefaction, in particular to a hydrogen liquefaction system.

Background

The hydrogen energy source is a kind of secondary energy source, which has many advantages such as high heat value, no pollution in utilization, etc. The high cost and small transportation capacity of the current gas transportation are a big bottleneck of hydrogen energy storage. The effective utilization of hydrogen energy must first solve a series of problems of preparation, storage and transportation, and application, and storage and transportation are the important key of hydrogen energy application, and are also the main reason of high price of hydrogen gas user end at present. Besides a small amount of hydrogen long-distance transport pipelines are built in Europe at home and abroad, hydrogen storage and transportation mainly depend on two modes of compressed hydrogen and liquid hydrogen storage and transportation in various countries. Compared with other modes, the liquid hydrogen storage and transportation has the following advantages: (1) the storage and transportation cost of the liquid hydrogen is lower; (2) the storage and transportation volume of liquid hydrogen is larger; (3) the storage and transportation purity of the liquid hydrogen is higher; (4) liquid hydrogen pressurized charging is more efficient and less costly.

The hydrogen liquefier is a main device for producing liquid hydrogen, is used for liquefying normal-temperature hydrogen refrigeration into liquid and carrying out orthohydrogen conversion, and is core technical equipment of high-technology industries such as aerospace, hydrogen energy storage and transportation and the like. The hydrogen liquefier adopting the compression throttling linder-hanpson cycle has been independently developed in China, but the liquefier adopts hydrogen as a working medium, and has high operation pressure and poor safety.

Disclosure of Invention

In view of this, it is necessary to provide a hydrogen liquefaction system with better safety.

A hydrogen liquefaction system comprises a helium compressor unit, a primary heat exchanger assembly, a precooling stage turboexpander set, a secondary heat exchanger assembly, a refrigerating stage turboexpander set and a hydrogen throttle valve, wherein the primary heat exchanger assembly comprises a first primary heat exchanger and a second primary heat exchanger;

a high-pressure outlet of the helium compressor unit is connected with a high-pressure inlet of the first primary heat exchanger, a high-pressure outlet of the first primary heat exchanger is connected with a high-pressure inlet of the second primary heat exchanger, and a high-pressure outlet of the second primary heat exchanger is connected with a high-pressure inlet of the secondary heat exchanger component;

an inlet of the pre-cooling stage turbine expansion unit is connected with a high-pressure outlet of the first primary heat exchanger, and an outlet of the pre-cooling stage turbine expansion unit is connected with a low-pressure inlet of the second primary heat exchanger;

an inlet of the refrigeration stage turboexpander set is connected with a high-pressure outlet of the secondary heat exchanger component, and an outlet of the refrigeration stage turboexpander set is connected with a low-pressure inlet of the secondary heat exchanger component;

the first primary heat exchanger is provided with a hydrogen inlet, the first primary heat exchanger, the second primary heat exchanger and the secondary heat exchanger assembly are arranged along the hydrogen transmission direction, the secondary heat exchanger assembly is provided with a liquid hydrogen outlet, and the second primary heat exchanger and the secondary heat exchanger assembly are both filled with an orthoparahydrogen catalyst;

the hydrogen throttle valve is arranged at the inlet or the outlet of the secondary heat exchanger at the tail end of the secondary heat exchanger assembly along the hydrogen conveying direction.

In one embodiment, the helium compressor unit includes a helium compressor assembly and an oil separation assembly disposed between the helium compressor assembly and the first primary heat exchanger.

In one embodiment, the oil separation assembly comprises a multi-stage condensation filter, a primary activated carbon adsorption cylinder and a primary dust removal filter which are arranged in sequence.

In one embodiment, the helium compressor unit further comprises a helium buffer tank, a loading control valve, an unloading control valve and a bypass regulating valve, wherein the loading control valve and the unloading control valve are connected in series, the loading control valve is connected with the oil separation assembly, the unloading control valve is connected with the helium compressor assembly, one end of the bypass regulating valve is connected with a connecting pipeline between the loading control valve and the oil separation assembly, the other end of the bypass regulating valve is connected with a connecting pipeline between the unloading control valve and the helium compressor assembly, and the helium buffer tank is connected with a connecting pipeline between the loading control valve and the unloading control valve.

In one embodiment, the pre-cooling stage turboexpander set is a single stage turbine, a multi-stage turbine series or a multi-stage turbine parallel structure.

In one embodiment, the pre-cooling stage turboexpander set comprises a first turboexpander and a second turboexpander, the first turboexpander and the second turboexpander are connected in series, an inlet of the first turboexpander is connected with a high-pressure outlet of the first primary heat exchanger, and an outlet of the second turboexpander is connected with a low-pressure inlet of the second primary heat exchanger.

In one embodiment, the secondary heat exchanger assembly comprises a fourth secondary heat exchanger, a third secondary heat exchanger, a second secondary heat exchanger and a first secondary heat exchanger which are arranged in sequence along the low-pressure helium gas backflow direction.

In one embodiment, the refrigeration stage turboexpander set is a single stage turbine, a multi-stage turbine series or a multi-stage turbine parallel configuration.

In one embodiment, the refrigeration stage turboexpander set comprises a third turboexpander and a fourth turboexpander, an inlet of the third turboexpander is connected with the high-pressure outlet of the first secondary heat exchanger, an outlet of the third turboexpander is connected with the high-pressure inlet of the third secondary heat exchanger, an inlet of the fourth turboexpander is connected with the high-pressure outlet of the third secondary heat exchanger, and an outlet of the fourth turboexpander is connected with the low-pressure inlet of the fourth secondary heat exchanger.

In one embodiment, the above hydrogen liquefaction system further comprises a first low temperature adsorber disposed between the high pressure outlet of the second primary heat exchanger and the high pressure inlet of the secondary heat exchanger assembly, and a second low temperature adsorber disposed between the hydrogen outlet of the second primary heat exchanger and the hydrogen inlet of the secondary heat exchanger assembly.

Above-mentioned hydrogen liquefaction system, through setting up helium circulation system, adopt inert gas helium as cycle working medium, utilize turboexpander cooling helium, compare in the system of hydrogen as working medium, need not use hydrogen as cooling working medium, and the raw materials hydrogen that carries out the liquefaction gets into system pressure lower, and the security is higher.

Drawings

Fig. 1 is a schematic configuration diagram of a hydrogen liquefaction system according to an embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clear, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. The fixed connection in the present invention includes direct fixed connection and indirect fixed connection.

As shown in fig. 1, the hydrogen liquefaction system of an embodiment includes a helium compressor unit 10, a primary heat exchanger assembly, a pre-cooling stage turboexpander set, a secondary heat exchanger assembly, a refrigeration stage turboexpander set, and a hydrogen throttle 21, wherein the primary heat exchanger assembly includes a first primary heat exchanger HEX1 and a second primary heat exchanger HEX 2.

The high pressure outlet of the helium compressor unit 10 is connected to the high pressure inlet of the first primary heat exchanger HEX1, the high pressure outlet of the first primary heat exchanger HEX1 is connected to the high pressure inlet of the second primary heat exchanger HEX2, and the high pressure outlet of the second primary heat exchanger HEX2 is connected to the high pressure inlet of the secondary heat exchanger assembly.

The inlet of the pre-cooling stage turbine expansion unit is connected with the high-pressure outlet of the first primary heat exchanger HEX1, and the outlet of the pre-cooling stage turbine expansion unit is connected with the low-pressure inlet of the second primary heat exchanger HEX 2.

The inlet of the refrigeration stage turbine expansion unit is connected with the high-pressure outlet of the secondary heat exchanger component, and the outlet of the refrigeration stage turbine expansion unit is connected with the low-pressure inlet of the secondary heat exchanger component.

The first primary heat exchanger HEX1 is provided with a hydrogen inlet, the first primary heat exchanger HEX1, the second primary heat exchanger HEX2 and the secondary heat exchanger assembly are arranged along the hydrogen transmission direction, the secondary heat exchanger assembly is provided with a liquid hydrogen outlet, and the second primary heat exchanger HEX2 and the secondary heat exchanger assembly are both filled with a normal parahydrogen catalyst.

The hydrogen throttle valve 21 is provided at the inlet or outlet of the last secondary heat exchanger of the secondary heat exchanger assembly in the hydrogen transport direction.

In the hydrogen liquefaction system, high-pressure helium gas flows out of a high-pressure outlet of the helium compressor unit 10, enters the first primary heat exchanger HEX1 from a high-pressure inlet of the first primary heat exchanger HEX1 for heat exchange, flows out of a high-pressure outlet of the first primary heat exchanger HEX1 and is divided into two strands, one strand of the two strands of the two; and the other strand of the helium gas enters the secondary heat exchanger assembly and then enters the refrigeration stage turboexpander for adiabatic expansion refrigeration, and the low-temperature helium gas coming out of the refrigeration stage turboexpander flows back to the low-pressure inlet of the secondary heat exchanger assembly to complete helium gas circuit circulation. The hydrogen enters the hydrogen liquefaction system through a hydrogen inlet formed in the first primary heat exchanger HEX1, is sequentially cooled by the low-temperature heat exchangers at all stages, is subjected to adiabatic throttling through a hydrogen throttling valve 21 arranged at an inlet or an outlet of the second heat exchanger at the tail end of the second heat exchanger assembly in the hydrogen transmission direction, and is converted into liquid hydrogen after throttling, and the liquid hydrogen enters the liquid hydrogen storage tank for storage.

Above-mentioned hydrogen liquefaction system, through setting up helium circulation system, adopt inert gas helium as cycle working medium, utilize turboexpander cooling helium, compare in the system of hydrogen as working medium, need not use hydrogen as cooling working medium, and the raw materials hydrogen that carries out the liquefaction gets into system pressure lower, and the security is higher.

In addition, the hydrogen liquefaction system only needs to use a helium circulating system for cooling, adopts a turbo expander to realize precooling in a temperature zone above 80K, does not need liquid nitrogen precooling, reduces the requirement of public facilities, and is suitable for occasions where liquid nitrogen is not available conveniently or is high in price. The turbine expander is used for realizing adiabatic expansion refrigeration, and the refrigeration efficiency is high.

In other embodiments, the primary heat exchanger assembly may comprise more than two primary heat exchangers, i.e. a first primary heat exchanger HEX1, a second primary heat exchanger HEX2, a third primary heat exchanger, etc. The number of the primary heat exchangers of the primary heat exchanger assembly can be set according to actual conditions.

In the embodiment shown in fig. 1, the helium compressor unit 10 comprises a helium compressor assembly and an oil separation assembly 12 provided between the helium compressor assembly and the first primary heat exchanger HEX 1. The oil separation assembly 12 allows a small amount of residual oil (aerosol or water vapor) to be removed, ensuring that the oil content of the helium gas entering the cold box 20 is less than 10 ppb.

Further, the oil separation assembly 12 includes a multi-stage coalescing filter, a first-stage activated carbon adsorption cartridge, and a first-stage dust removal filter, which are sequentially disposed.

In the embodiment shown in fig. 1, the helium compressor unit 10 further includes a helium buffer tank 11, a loading control valve 16, an unloading control valve 18, and a bypass regulator valve 14, the loading control valve 16 and the unloading control valve 18 being connected in series, the loading control valve 16 being connected to the oil separation assembly 12, the unloading control valve 18 being connected to the helium compressor assembly, one end of the bypass regulator valve 14 being connected to a connection line between the loading control valve 16 and the oil separation assembly 12, the other end of the bypass regulator valve 14 being connected to a connection line between the unloading control valve 18 and the helium compressor assembly, the helium buffer tank 11 being connected to a connection line between the loading control valve 16 and the unloading control valve 18.

The helium buffer tank 11, the load control valve 16, the unload control valve 18, and the bypass regulator valve 14 constitute a gas management system, and are disposed on a pry block of the oil separation assembly 12.

When the circulating helium flow of the system changes due to working condition changes such as temperature reduction, liquefaction, refrigeration load change, rewarming and the like of the system, the gas management system automatically adjusts the helium flow in the refrigeration system by filling or recovering helium into the system through the helium buffer tank 11 by adjusting the opening degrees of 143 valves of the loading control valve 16, the unloading control valve 18 and the bypass adjusting valve, so that the pressure stability of high-pressure HP and low-pressure LP is ensured.

It is understood that the pre-cooling stage turboexpander set is a single stage turbine, a multi-stage turbine series or a multi-stage turbine parallel configuration. The structure of the pre-cooling stage turboexpander set can be set according to actual conditions.

In the embodiment shown in fig. 1, the pre-cooling stage turboexpander train comprises a first turboexpander T1 and a second turboexpander T2, the first turboexpander T1 and the second turboexpander T2 being connected in series, the inlet of the first turboexpander T1 being connected to the high-pressure outlet of the first primary heat exchanger HEX1, and the outlet of the second turboexpander T2 being connected to the low-pressure inlet of the second primary heat exchanger HEX 2. In the hydrogen liquefaction system, the application scene of precooling of liquid nitrogen is replaced by the turbine, the requirements on the expansion ratio and the refrigerating capacity of the turbine are very high, and the turbine is difficult to design. And two-stage or multi-stage turbines are connected in series, so that the expansion ratio of each stage of turbine can be obviously reduced, and the design and manufacture of the turboexpander are easy.

In one embodiment, a first control valve 22 is provided before the first turboexpander T1.

In the embodiment shown in fig. 1, the secondary heat exchanger assembly comprises a fourth secondary heat exchanger HEX6, a third secondary heat exchanger HEX5, a second secondary heat exchanger HEX4 and a first secondary heat exchanger HEX3 arranged in that order along the low pressure helium gas recirculation direction.

In one embodiment, the operating temperatures of the first primary heat exchanger HEX1, the second primary heat exchanger HEX2, the first secondary heat exchanger HEX3, the second secondary heat exchanger HEX4, the third secondary heat exchanger HEX5 and the fourth secondary heat exchanger HEX6 are all temperature zones above 20K.

It is understood that the refrigeration stage turboexpander set is a single stage turbine, a multi-stage turbine series or a multi-stage turbine parallel configuration. The structure of the refrigeration stage turboexpander set can be set according to actual conditions.

In the embodiment shown in fig. 1, the refrigeration stage turboexpander train comprises a third turboexpander T3 and a fourth turboexpander T4, the inlet of the third turboexpander T3 being connected to the high-pressure outlet of the first secondary heat exchanger HEX3, the outlet of the third turboexpander T3 being connected to the high-pressure inlet of the third secondary heat exchanger HEX5, the inlet of the fourth turboexpander T4 being connected to the high-pressure outlet of the third secondary heat exchanger HEX5, the outlet of the fourth turboexpander T4 being connected to the low-pressure inlet of the fourth secondary heat exchanger HEX 6. In the hydrogen liquefaction system, the application scene of precooling of liquid nitrogen is replaced by the turbine, the requirements on the expansion ratio and the refrigerating capacity of the turbine are very high, and the turbine is difficult to design. And two-stage or multi-stage turbines are connected in series, so that the expansion ratio of each stage of turbine can be obviously reduced, and the design and manufacture of the turboexpander are easy.

In one embodiment, a second control valve 24 is provided before the third turboexpander T3.

In the embodiment shown in fig. 1, the above-described hydrogen liquefaction system further includes a first low temperature adsorber 26 and a second low temperature adsorber 28, the first low temperature adsorber 26 being disposed between the high pressure outlet of the second primary heat exchanger HEX2 and the high pressure inlet of the secondary heat exchanger assembly, the second low temperature adsorber 28 being disposed between the hydrogen outlet of the second primary heat exchanger HEX2 and the hydrogen inlet of the secondary heat exchanger assembly. The first low temperature adsorber 26 is used to remove contaminant trace gas contaminants such as air. The second low-temperature adsorber 28 is used to remove trace amounts of water, oxygen, nitrogen, hydrocarbons, and other impurities contained in the hydrogen gas.

In one embodiment, the first primary heat exchanger HEX1, the second primary heat exchanger HEX2, the first turboexpander T1, the second turboexpander T2, the first secondary heat exchanger HEX3, the second secondary heat exchanger HEX4, the third secondary heat exchanger HEX5, the fourth secondary heat exchanger HEX6, the first low temperature adsorber, the third turboexpander T3, the fourth turboexpander T4, the second low temperature adsorber, the hydrogen throttle valve 21, and the connecting lines between the above elements are all fixed in the vacuum cooling box 20.

Furthermore, each element arranged in the vacuum cooling box 20 is wrapped by a plurality of layers of heat insulating materials. In one embodiment, the high pressure inlet of the first primary heat exchanger HEX1 and the hydrogen inlet of the first primary heat exchanger HEX1 are each provided with a flow meter. The flowmeter is used for measuring the flow of the helium gas and detecting the running state of the system. The hydrogen flowmeter is used for detecting the supply state of the raw material hydrogen and metering the amount of the product liquid hydrogen.

In one embodiment, thermometers are arranged on the connecting pipelines of two adjacent primary heat exchangers, the connecting pipelines of the adjacent primary heat exchangers and the adjacent secondary heat exchangers and the connecting pipelines of the two adjacent secondary heat exchangers. Through setting up the thermometer, can effectively monitor the exit temperature of each heat exchanger, control more accurately.

In one embodiment, the inlet and outlet ports of the first turbo expander T1, the second turbo expander T2, the third turbo expander T3 and the fourth turbo expander T4 are provided with temperature and pressure gauges. The thermometer and the pressure gauge are arranged at the inlet and the outlet of the transparent expander, so that the whole hydrogen liquefaction system can be controlled more accurately and reliably.

The hydrogen liquefaction system comprises a helium gas circulation pipeline and a hydrogen liquefaction pipeline:

helium circulating pipeline:

high-pressure (HP) helium gas leaving the helium compressor unit 10 enters a first primary heat exchanger HEX1 of the cold box, is cooled to about 120K by low-pressure (LP) helium return gas, flows out of a high-pressure outlet of a first primary heat exchanger HEX1, enters a precooling stage turboexpander set, is cooled to 80K and flows back through a low-pressure inlet of a second primary heat exchanger, the other flow is cooled to about 80K through a second primary heat exchanger HEX2, and is introduced into an 80K first low-temperature adsorber to remove impurity trace gas pollutants such as air. The HP helium flows out of the downstream of the first low-temperature adsorber, enters a first secondary heat exchanger HEX3 for further cooling, then enters a first secondary heat exchanger HEX3 for cooling to a lower temperature, then enters a refrigeration stage turbine expansion unit, is connected in series through two stages of turbines, is subjected to adiabatic expansion refrigeration through an intermediate cooling expansion loop, and is changed into low-temperature low-pressure helium of about 18-20K, and the low-temperature low-pressure helium returns to a low-pressure side inlet of a fourth secondary heat exchanger HEX 6; and the returned low-temperature low-pressure helium sequentially passes through the fourth secondary heat exchanger HEX6, the third secondary heat exchanger HEX5, the second secondary heat exchanger HEX4, the first secondary heat exchanger HEX3, the second primary heat exchanger HEX2 and the first primary heat exchanger HEX1 in a counter-current manner, is discharged out of the cold box after cold energy is recovered, and then returns to the air suction end of the helium compressor unit 10 to be recycled.

A hydrogen liquefaction pipeline:

the raw material hydrogen enters a cold box and is pre-cooled by a first-stage heat exchanger HEX1, then enters a second-stage heat exchanger HEX2 filled with an orthohydrogen catalyst, is cooled to about 80K, and then enters a second low-temperature adsorber to remove impurities such as trace water, oxygen, nitrogen, hydrocarbons and the like. Then, the hydrogen gas sequentially enters a first secondary heat exchanger HEX3, a second secondary heat exchanger HEX4 and a third secondary heat exchanger HEX5 filled with an orthoparahydrogen catalyst to be cooled to about 25K, then enters a throttling valve to be throttled, is depressurized and cooled through a coke-soup effect, is cooled to a temperature below a hydrogen liquefaction point (about 19-22K according to different process pressures) through a fourth secondary heat exchanger HEX6 filled with the orthohydrogen catalyst to become product liquid hydrogen with the parahydrogen content of more than 95%, and enters a liquid hydrogen storage tank, wherein the liquid hydrogen is stored in the liquid hydrogen storage tank 30.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

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