CN210956859U

CN210956859U - Space-saving hydrogen fuel cell, engine and automobile

Info

Publication number: CN210956859U
Application number: CN201922498320.5U
Authority: CN
Inventors: 支明照
Original assignee: Shenzhen Hynovation Technologies Co ltd
Current assignee: Shenzhen Hynovation Technologies Co ltd
Priority date: 2019-12-31
Filing date: 2019-12-31
Publication date: 2020-07-07
Anticipated expiration: 2029-12-31

Abstract

The utility model discloses a hydrogen fuel cell, engine and car of saving space. The above space-saving hydrogen fuel cell includes: the hydrogen gas supply system, the air supply system, the first cooling system, the distribution manifold part and the box body, wherein a plurality of galvanic piles are arranged in the box body, and the distribution manifold part comprises a first distribution manifold and a second distribution manifold; the hydrogen supply system is arranged on the first side of the box body, the air supply system is arranged on the second side of the box body, the first cooling system is arranged on the third side of the box body, and the distribution manifold part is arranged on the fourth side of the box body; the distribution manifold portion is communicated with the electric pile, and the hydrogen gas supply system, the air supply system and the first cooling system are communicated with the distribution manifold portion. The utility model discloses a hydrogen fuel cell compact structure makes the condition of the part distribution complicacy that exists among the hydrogen fuel cell usually, pipeline cross distribution improve to some extent, can reduce hydrogen fuel cell's volume to save space.

Description

Space-saving hydrogen fuel cell, engine and automobile

Technical Field

The utility model belongs to the technical field of the hydrogen fuel cell and specifically relates to a save space's hydrogen fuel cell, engine and car are related to.

Background

A fuel cell is a device that converts chemical energy of fuel into electric energy, also called an electrochemical generator, which is a fourth power generation technology following hydroelectric power generation, thermal power generation, and atomic power generation. The fuel cell converts the Gibbs free energy in the chemical energy of the fuel into electric energy through electrochemical reaction without the limitation of Carnot cycle effect, so the energy conversion efficiency is high. The hydrogen fuel cell uses hydrogen and oxygen as raw materials and has no mechanical transmission part, so that the hydrogen fuel cell has no noise pollution, and discharges water, air and a small amount of hydrogen, thereby having no pollution to the environment. Therefore, hydrogen fuel cells are receiving more and more attention in terms of energy safety and environmental pollution, and are also applied more and more widely. In the hydrogen fuel cell, it is necessary to supply air through an air system, hydrogen through a hydrogen system, and cooling water through a cooling system. Because the three systems have various components, the positions of the components are not planned in the conventional hydrogen fuel cells, so that the distribution of the components in the whole cell is complicated, and a plurality of pipelines are crossed, so that the whole cell has a large volume and a large occupied space.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. Therefore, the utility model provides a save space's hydrogen fuel cell, this hydrogen fuel cell compact structure makes the condition of the part distribution complicacy that exists among the hydrogen fuel cell usually, pipeline cross distribution improve to some extent, can reduce hydrogen fuel cell's volume to save space.

The utility model discloses still provide an engine, the fuel cell occupation space in this engine is less for this engine occupation space is also less.

The utility model discloses still provide an automobile, the engine occupation space in this automobile is less for the space that is used for placing the engine in this automobile can reduce.

In a first aspect, an embodiment of the present invention provides a space-saving hydrogen fuel cell, including:

the fuel cell system comprises a hydrogen gas supply system, an air supply system, a first cooling system, a distribution manifold part and a box body, wherein a plurality of galvanic piles are arranged in the box body, and the distribution manifold part comprises a first distribution manifold and a second distribution manifold;

the hydrogen gas supply system is arranged on a first side of the box body, the air supply system is arranged on a second side of the box body, the first cooling system is arranged on a third side of the box body, and the distribution manifold part is arranged on a fourth side of the box body;

the distribution manifold portion with the pile intercommunication, hydrogen air supply system, air supply system and first cooling system all with distribution manifold portion intercommunication.

The utility model discloses hydrogen fuel cell who saves space has following beneficial effect at least: the hydrogen gas supply system, the air supply system, the first cooling system and the distribution manifold are respectively arranged on the four sides of the box body, so that the components are arranged more neatly, the possibility of cross distribution of pipelines of all the parts is reduced, the volume of the hydrogen fuel cell can be reduced to a certain extent, the space is saved, and the hydrogen gas supply system is convenient to overhaul one part of the hydrogen gas supply system and is not easy to be interfered by other parts.

According to the utility model discloses a hydrogen fuel cell of space-saving of other embodiments, hydrogen gas supply system includes first hydrogen pipe, second hydrogen pipe, third hydrogen pipe, fourth hydrogen pipe, fifth hydrogen pipe, first hydrogen circulating pump, gas-liquid separation portion and hydrogen source portion, first hydrogen circulating pump with gas-liquid separation portion all is located on the second hydrogen pipe, the both ends of first hydrogen pipe respectively with hydrogen source portion first distribution manifold intercommunication, the both ends of second hydrogen pipe respectively with second distribution manifold first hydrogen pipe intercommunication, the both ends of third hydrogen pipe all with second hydrogen pipe intercommunication, just hydrogen in the third hydrogen pipe only can one-way flow in gas-liquid separation portion, the fourth hydrogen pipe with gas-liquid separation portion intercommunication, the both ends of fifth hydrogen pipe respectively with the second hydrogen pipe, The fourth air pipe is communicated.

According to other embodiments of the present invention, the space-saving hydrogen fuel cell further comprises a third hydrogen pipe located below the second hydrogen pipe, and the gas-liquid separation portion is located below the third hydrogen pipe.

According to the utility model discloses a save space's hydrogen fuel cell of other embodiments, hydrogen gas air supply system still includes sixth hydrogen pipe and second hydrogen circulating pump, the second hydrogen circulating pump is located on the sixth hydrogen pipe, the both ends of sixth hydrogen pipe all with second hydrogen pipe intercommunication.

According to the utility model discloses a hydrogen fuel cell in space-saving of other embodiments, air gas supply system includes first air pipe, second air pipe, third air pipe, air compressor machine, intercooler and humidifier, the both ends of first air pipe respectively with the air compressor machine first distribution manifold intercommunication, just the intercooler with the humidifier all is located on the first air pipe, the both ends of second air pipe respectively with second distribution manifold the humidifier intercommunication, the third air pipe with the humidifier intercommunication.

According to the utility model discloses a hydrogen fuel cell of space-saving of other embodiments, the air supply system still includes fourth air pipe and fifth air pipe, the both ends of fourth air pipe respectively with the second air pipe third air pipe intercommunication, the both ends of fifth air pipe respectively with the third air pipe first air pipe intercommunication, just the fifth air pipe with the intercommunication department of first air pipe is equipped with the air valve.

According to the utility model discloses a hydrogen fuel cell in space-saving of other embodiments, first cooling system includes first cooling tube, second cooling tube, third cooling tube, water pump and thermostat, the both ends of first cooling tube respectively with the water pump the second distribution manifold intercommunication, the both ends of second cooling tube respectively with first cooling tube the intercooler intercommunication, the both ends of third cooling tube respectively with first distribution manifold the thermostat intercommunication, still be equipped with the valve that drains on the second cooling tube, still be equipped with cooling tube exhaust valve on the third cooling tube.

According to the utility model discloses a space-saving hydrogen fuel cell of other embodiments, first cooling system still includes fourth cooling tube, fifth cooling tube, sixth cooling tube, seventh cooling tube, eighth cooling tube, deionizer, water tank, heater and radiator, the deionizer is located on the second cooling tube, the heater is located on the seventh cooling tube, the both ends of fourth cooling tube respectively with the intercooler the third cooling tube intercommunication, the both ends of fifth cooling tube respectively with the radiator the thermostat intercommunication, the both ends of sixth cooling tube respectively with the water pump the radiator intercommunication, the both ends of seventh cooling tube respectively with the thermostat the sixth cooling tube intercommunication, the both ends of eighth cooling tube respectively with the water tank the sixth cooling tube intercommunication.

In a second aspect, an embodiment of the present invention provides an engine comprising a space-saving hydrogen fuel cell as described above.

The utility model discloses the engine has following beneficial effect at least: the hydrogen gas supply system, the air supply system, the first cooling system and the distribution manifold are respectively arranged on the four sides of the box body, so that the components are arranged more neatly, the possibility of cross distribution of pipelines of all parts is reduced, the volume of the hydrogen fuel cell can be reduced to a certain extent, and the volume of an engine comprising the hydrogen fuel cell is smaller.

In a third aspect, an embodiment of the present invention provides an automobile, including the engine described above.

The utility model discloses car has following beneficial effect at least: the engine including the hydrogen fuel cell is small in size, so that the space for placing the engine in the automobile can be reduced.

Drawings

Fig. 1 is a schematic view of the overall structure of a hydrogen fuel cell in the first embodiment;

FIG. 2 is a schematic view of a hydrogen gas supply system in the first embodiment;

FIG. 3 is a schematic configuration diagram of a hydrogen gas supply system in the first embodiment;

FIG. 4 is a schematic view of an air supply system in a first embodiment;

FIG. 5 is a schematic configuration diagram of an air supply system in the first embodiment;

FIG. 6 is a schematic view of a first cooling air supply system in a first embodiment;

FIG. 7 is a schematic view of a second cooling air supply system in the first embodiment;

fig. 8 is a schematic configuration diagram of a first cooling air supply system in the first embodiment.

Detailed Description

The conception and the resulting technical effects of the present invention will be described clearly and completely with reference to the following embodiments, so that the objects, features and effects of the present invention can be fully understood. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and other embodiments obtained by those skilled in the art without inventive labor based on the embodiments of the present invention all belong to the protection scope of the present invention.

In the description of the embodiments of the present invention, if an orientation description is referred to, for example, the directions or positional relationships indicated by "upper", "lower", "front", "rear", "left", "right", etc. are based on the directions or positional relationships shown in the drawings, only for convenience of description and simplification of description, but not for indicating or implying that the indicated device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the description of the embodiments of the present invention, if a feature is referred to as being "disposed", "fixed", "connected", or "mounted" on another feature, it can be directly disposed, fixed, or connected to the other feature or indirectly disposed, fixed, connected, or mounted on the other feature. In the description of the embodiments of the present invention, if "a plurality" is referred to, it means one or more, if "a plurality" is referred to, it means two or more, if "greater than", "less than" or "more than" is referred to, it is understood that the number is not included, and if "more than", "less than" or "within" is referred to, it is understood that the number is included. If reference is made to "first" or "second", this should be understood to distinguish between features and not to indicate or imply relative importance or to implicitly indicate the number of indicated features or to implicitly indicate the precedence of the indicated features.

Referring to fig. 1, the hydrogen fuel cell in the present embodiment includes a tank 100, a hydrogen gas supply system 200, an air supply system 300, a first cooling system 400, a second cooling system 500, and a distribution manifold portion 600, and a plurality of stacks, in the present embodiment, two stacks, are provided in the tank 100. The distribution manifold portion 600 includes a first distribution manifold 610 and a second distribution manifold 620. The hydrogen gas supply system 200 is provided at a first side of the tank 100, the air supply system 300 is provided at a second side of the tank 100, the first cooling system 400 is provided at a third side of the tank 100, and the distribution manifold portion 600 is provided at a fourth side of the tank 100. The hydrogen supply system 200 is used for supplying hydrogen to 2 electric piles, the air supply system 300 is used for supplying air to 2 electric piles, and the first cooling system 400 is used for supplying cooling water to 2 electric piles and an intercooler. The second cooling system 500 is used to provide cooling water to the air compressor and the air compressor controller. The first distribution manifold 610 is used for distributing hydrogen and air into two parts, respectively flowing into the two stacks, and collecting cooling water flowing out of the two stacks and then flowing out. The second distribution manifold 620 is configured to collect hydrogen and air flowing out of the two stacks, respectively, and distribute the cooling water into two portions, which flow into the two stacks, respectively.

Referring to fig. 2 and 3, the hydrogen gas supply system 200 in the present embodiment includes a first hydrogen pipe 210, a second hydrogen pipe 220, a third hydrogen pipe 230, a fourth hydrogen pipe 240, a fifth hydrogen pipe 250, a sixth hydrogen pipe 260, a first hydrogen circulation pump 271, a second hydrogen circulation pump 272, a gas-liquid separation portion 280, and a hydrogen source portion 290. The first hydrogen circulation pump 271 and the gas-liquid separation unit 280 are both located on the second hydrogen pipe 220, and the second hydrogen circulation pump 272 is provided on the sixth hydrogen pipe 260. Both ends of the first hydrogen pipe 210 are respectively communicated with the hydrogen source part 290 and the first distribution manifold 610, and the hydrogen source part 290 is a hydrogen tank. A pressure sensor, a hydrogen filter, an on-off solenoid valve, a proportional solenoid valve, etc. are further disposed on the first hydrogen pipe 210 at a position close to the hydrogen source portion 290, which are the prior art and therefore will not be described again. Both ends of the second hydrogen pipe 220 are respectively communicated with the second distribution manifold 620 and the first hydrogen pipe 210, both ends of the third hydrogen pipe 230 are respectively communicated with the second hydrogen pipe 220, the fourth hydrogen pipe 240 is communicated with the gas-liquid separation part 280, both ends of the fifth hydrogen pipe 250 are respectively communicated with the second hydrogen pipe 220 and the fourth hydrogen pipe 240, and both ends of the sixth hydrogen pipe 260 are respectively communicated with the second hydrogen pipe 220. Sensors are respectively arranged on the first hydrogen pipe 210 and the second hydrogen pipe 220 close to the galvanic pile and are respectively used for monitoring parameters such as pressure, temperature and the like of hydrogen flowing into and out of the galvanic pile.

The hydrogen in the hydrogen source 290 flows into the first distribution manifold 610 through the first hydrogen pipe 210, and flows into the two stacks for reaction after being distributed by the first distribution manifold 610. The excess hydrogen from the two stacks is collected by the second distribution manifold 620 and flows into the second hydrogen pipe 220. A part of moisture may remain in the hydrogen gas flowing out after the reaction, and the gas-liquid separating part 280 may separate the part of moisture. In this embodiment, the gas-liquid separation part 280 is a water separator, and a liquid level sensor is further disposed on the water separator, so that when the water level in the water separator exceeds a set value, a worker can be timely reminded to discharge the water in the water separator through the fourth air pipe 240. The dried hydrogen after the moisture is separated flows back to the first hydrogen pipe 210 through the second hydrogen pipe 220 under the suction force of the first hydrogen circulating pump 271, and flows into the electric pile again for reaction, so that the hydrogen utilization rate is improved. Preferably, in the present embodiment, two hydrogen circulation portions (the first hydrogen circulation pump 271 and the second hydrogen circulation pump 272, respectively) are provided in parallel to increase the pumping amount.

The third hydrogen pipe 230 is located below the second hydrogen pipe 220, and the gas-liquid separating unit 280 is located below the third hydrogen pipe 230. Therefore, under the action of gravity, the water remaining in the second hydrogen pipe 220 flows downward through the third hydrogen pipe 230 into the gas-liquid separating portion 280, so as to prevent the second hydrogen pipe 220 from accumulating liquid. A check valve is provided at this point, and only the hydrogen gas in the third hydrogen pipe 230 can flow into the gas-liquid separating portion 280. In addition, after the reaction is finished, a part of nitrogen may be mixed in the hydrogen, and in order to avoid excessive nitrogen in the hydrogen flowing back to the stack, after a certain period of time, a valve on the fifth hydrogen pipe 250 may be opened, so that a part of the hydrogen in the second hydrogen pipe 220 flows into the fourth hydrogen pipe 240 through the fifth hydrogen pipe 250 and is discharged.

Referring to fig. 4 and 5, the air supply system 300 in the present embodiment includes a first air pipe 310, a second air pipe 320, a third air pipe 330, a fourth air pipe 340, a fifth air pipe 350, an air filter 360, an air compressor 370, an intercooler 380, a humidifier 390, a muffler 3100, an air compressor controller 3110, and a purge pipe 3120. Both ends of the first air pipe 310 are respectively communicated with the air compressor 370 and the first distribution manifold 610, both ends of the second air pipe 320 are respectively communicated with the second distribution manifold 620 and the humidifier 390, the third air pipe 330 is communicated with the humidifier 390, both ends of the fourth air pipe 340 are respectively communicated with the second air pipe 320 and the third air pipe 330, and both ends of the fifth air pipe 350 are respectively communicated with the third air pipe 330 and the first air pipe 310. An air valve is provided at the communication between the fifth air pipe 350 and the first air pipe 310. The intercooler 380 and the humidifier 390 are both located on the first air pipe 310.

Preferably, the air in the air compressor 370 is filtered by the air filter 360 and then flows in to improve the air quality. The air pressure flowing into the air compressor 370 is compressed, cooled by the intercooler 380, humidified by the humidifier 390, and then flows into the first distribution manifold 610. In the first distribution manifold 610, air is divided into two portions, which flow into the two stacks, respectively, for reaction. The surplus air from the two stacks is collected by the second distribution manifold 620 and flows into the second air pipe 320. The third air pipe 330 may be opened to adjust the amount and pressure of air in the humidifier 390, thereby adjusting the amount and pressure of air entering the stack. Since the air passes through the third air pipe 330 when being discharged to the outside, a muffler 3100 is provided at the end of the third air pipe 330 to reduce noise. Since moisture may be entrained in the outgoing air, this portion of the outgoing air re-enters the humidifier 390 to further humidify the fresh air entering the humidifier 390 to improve the humidification efficiency. If the humidity in the outgoing air is too high, the fourth air duct 340 may be opened so that the outgoing air does not flow back to the humidifier 390 but is directly discharged through the third air duct 330. The fourth exhaust pipe 340 has a small pipe diameter, preferably, a diameter in the range of 6mm to 25 mm. In addition, if the pressure of the inflow air is too high, the fifth air pipe 350 may be opened to discharge a portion of the air to the third air pipe 330 through the fifth air pipe 350, so as to prevent the inflow air from being too high, and when the pressure is too high, the system may vibrate greatly. In addition, a purging tube 3120 is provided, an inlet of the purging tube 3120 is communicated with the first air tube 310, and after the reaction is finished, the purging tube 3120 may be opened to allow air to flow through the respective pipes and the stack from the purging tube 3120 to remove residual gas therefrom.

Referring to fig. 6 and 8, the first cooling system 400 in the present embodiment includes a first cooling pipe 410, a second cooling pipe 420, a third cooling pipe 430, a fourth cooling pipe 440, a fifth cooling pipe 450, a sixth cooling pipe 460, a seventh cooling pipe 470, an eighth cooling pipe 480, a deionizer 490, a water tank 4100, a thermostat 4110, a water pump 4120, a heater 4130, and a radiator 4140. The deionizer 490 is provided on the second cooling tube 420, and the heater 4130 is provided on the seventh cooling tube 470. Both ends of the first cooling pipe 410 are respectively communicated with the water pump 4120 and the second distribution manifold 620, both ends of the second cooling pipe 420 are respectively communicated with the first cooling pipe 410 and the intercooler 380, both ends of the third cooling pipe 430 are respectively communicated with the first distribution manifold 610 and the thermostat 4110, both ends of the fourth cooling pipe 440 are respectively communicated with the intercooler 380 and the third cooling pipe 430, both ends of the fifth cooling pipe 450 are respectively communicated with the radiator 4140 and the thermostat 4110, both ends of the sixth cooling pipe 460 are respectively communicated with the water pump 4120 and the radiator 4140, both ends of the seventh cooling pipe 470 are respectively communicated with the thermostat 4110 and the sixth cooling pipe 460, and both ends of the eighth cooling pipe 480 are respectively communicated with the water tank 4100 and the sixth cooling pipe 460.

The cooling water is pumped into the first cooling pipe 410 by a water pump 4120, and a part of the cooling water flows into the second distribution manifold 620, and after being divided into two parts in the second distribution manifold 620, the two parts flow into the two cell stacks, respectively, for cooling. The other part flows into the intercooler 380 through the second cooling pipe 420, and cools the intercooler 380. The deionizer 490 at the second cooling pipe 420 can remove harmful ions from the cooling water entering the intercooler 380. The cooling water flowing out of the two stacks flows into the first distribution manifold 610, is collected, and flows into the third cooling pipe 430 after being collected. The cooling water flowing out of the intercooler 380 is also collected into the third cooling pipe 430, and the two cooling waters are merged and then reach the thermostat 4110, and flow into different branches according to different temperatures. The thermostat 4110 is provided with a three-way valve, and when the temperature of the cooling water is lower than a set temperature, the cooling water flows into the seventh cooling pipe 470, and is heated by the heater 4130, and the heated cooling water is pumped into the first cooling pipe 410 again by the water pump 4120. When the temperature of the cooling water is higher than the set temperature, the cooling water flows into the radiator 4140 through the fifth cooling pipe 450, and is cooled by the radiator 4140, and the cooled cooling water is again sucked and flows into the first cooling pipe 410 through the water pump 4120. The above-mentioned cooling water flow is a closed-loop flow, but inevitably, there are gaps at some positions, and the cooling water may be evaporated and reduced after a period of use, and at this time, the eighth cooling pipe 480 may be opened to supplement the cooling water through the water tank 4100. In addition, a drain valve 421 is provided in the second cooling pipe 420, and deionized wastewater can be discharged by opening the drain valve 421. The third cooling pipe 430 is further provided with a cooling pipe exhaust valve 431, and the air staying in the third cooling pipe 430 can be exhausted by opening the valve.

Because the cooling requirement temperature of the air compressor and the air compressor controller is different from the cooling requirement temperature of the intercooler, two sets of cooling systems are used for cooling. Referring to fig. 7, a second cooling system 500 in the present embodiment is similar in structure and principle to the first cooling system 400. The second cooling system 500 includes a ninth cooling pipe 510, a tenth cooling pipe 520, an eleventh cooling pipe 530, a twelfth cooling pipe 540, a thirteenth cooling pipe 550, a second water pump 560, a second radiator 570, a second water tank 580, and the like. The flow direction of the cooling water is similar to that of the first cooling system, and therefore, the description thereof is omitted.

The distribution manifold portion 600 is omitted from the schematic diagram of hydrogen gas, air, and cooling water, and the hydrogen gas is described by taking the example of the hydrogen gas flowing into the first distribution manifold 610. The first distribution manifold 610 is provided with two hydrogen inflow sub-runners and a hydrogen inflow main runner, and the two hydrogen inflow sub-runners are both communicated with the hydrogen inflow main runner. The hydrogen inflow main channel is communicated with the end of the first hydrogen pipe 210, and the two hydrogen inflow sub channels are respectively communicated with the two stacks. The hydrogen gas in the hydrogen source part 290 flows through the first hydrogen pipe 210, flows into the first distribution manifold 610 from the hydrogen inflow main flow channel, and respectively enters the two cell stacks through the two hydrogen inflow branch flow channels, thereby completing the distribution of the hydrogen gas. The second distribution manifold 620 has flow channels for hydrogen to flow out, and has the same structure as the first distribution manifold 610, except that the flow direction of hydrogen is reversed, and thus the description thereof is omitted. The inflow and outflow of air and cooling water is similar to that of hydrogen, and thus, the description thereof is omitted.

The embodiment also provides an engine which comprises the hydrogen fuel cell. An automobile is also provided, which comprises the engine.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art. Furthermore, the embodiments of the present invention and features of the embodiments may be combined with each other without conflict.

Claims

1. A space-saving hydrogen fuel cell, comprising:

2. The space-saving hydrogen fuel cell according to claim 1, wherein the hydrogen gas supply system includes a first hydrogen gas pipe, a second hydrogen gas pipe, a third hydrogen gas pipe, a fourth hydrogen gas pipe, a fifth hydrogen gas pipe, a first hydrogen gas circulation pump, a gas-liquid separation portion, and a hydrogen source portion, the first hydrogen gas circulation pump and the gas-liquid separation portion are both located on the second hydrogen gas pipe, both ends of the first hydrogen gas pipe are respectively communicated with the hydrogen source portion and the first distribution manifold, both ends of the second hydrogen gas pipe are respectively communicated with the second distribution manifold and the first hydrogen gas pipe, both ends of the third hydrogen gas pipe are respectively communicated with the second hydrogen gas pipe, and hydrogen gas in the third hydrogen gas pipe can only flow into the gas-liquid separation portion in one direction, the fourth hydrogen gas pipe is communicated with the gas-liquid separation portion, both ends of the fifth hydrogen gas pipe are respectively communicated with the second hydrogen gas pipe, The fourth air pipe is communicated.

3. The space-saving hydrogen fuel cell according to claim 2, wherein the third hydrogen pipe is located below the second hydrogen pipe, and the gas-liquid separation portion is located below the third hydrogen pipe.

4. The space-saving hydrogen fuel cell according to claim 2, wherein the hydrogen gas supply system further includes a sixth hydrogen pipe and a second hydrogen circulation pump, the second hydrogen circulation pump is disposed on the sixth hydrogen pipe, and both ends of the sixth hydrogen pipe are communicated with the second hydrogen pipe.

5. The space-saving hydrogen fuel cell according to claim 1, wherein the air supply system includes a first air pipe, a second air pipe, a third air pipe, an air compressor, an intercooler, and a humidifier, both ends of the first air pipe are respectively communicated with the air compressor and the first distribution manifold, and the intercooler and the humidifier are both located on the first air pipe, both ends of the second air pipe are respectively communicated with the second distribution manifold and the humidifier, and the third air pipe is communicated with the humidifier.

6. The space-saving hydrogen fuel cell according to claim 5, wherein the air supply system further comprises a fourth air tube and a fifth air tube, both ends of the fourth air tube are respectively communicated with the second air tube and the third air tube, both ends of the fifth air tube are respectively communicated with the third air tube and the first air tube, and an air valve is provided at a communication position of the fifth air tube and the first air tube.

7. The space-saving hydrogen fuel cell according to claim 5, wherein the first cooling system includes a first cooling pipe, a second cooling pipe, a third cooling pipe, a water pump and a thermostat, two ends of the first cooling pipe are respectively communicated with the water pump and the second distribution manifold, two ends of the second cooling pipe are respectively communicated with the first cooling pipe and the intercooler, two ends of the third cooling pipe are respectively communicated with the first distribution manifold and the thermostat, the second cooling pipe is further provided with a water drain valve, and the third cooling pipe is further provided with a cooling pipe exhaust valve.

8. The space-saving hydrogen fuel cell according to claim 7, wherein the first cooling system further comprises a fourth cooling pipe, a fifth cooling pipe, a sixth cooling pipe, a seventh cooling pipe, an eighth cooling pipe, a deionizer, a water tank, a heater, and a radiator, the deionizer is arranged on the second cooling pipe, the heater is arranged on the seventh cooling pipe, two ends of the fourth cooling pipe are respectively communicated with the intercooler and the third cooling pipe, two ends of the fifth cooling pipe are respectively communicated with the radiator and the thermostat, the two ends of the sixth cooling pipe are respectively communicated with the water pump and the radiator, the two ends of the seventh cooling pipe are respectively communicated with the thermostat and the sixth cooling pipe, and the two ends of the eighth cooling pipe are respectively communicated with the water tank and the sixth cooling pipe.

9. An engine comprising the space-saving hydrogen fuel cell of any one of claims 1 to 8.

10. An automobile comprising the engine of claim 9.