WO2020093405A1 - Cooling circulation system for fuel cell - Google Patents

Abstract

Disclosed is a cooling circulation system for a fuel cell. The system comprises a cooling system (10), the cooling system (10) comprising a cell reactor (5) used for power generation using an electrochemical reaction between air and hydrogen, a water pump (12), a heat dissipator (13), a constant-temperature three-way valve (14), and a pipeline. The cell reactor (5), the water pump (12), the heat dissipator (13) and the constant-temperature three-way valve (14) are connected through the pipeline, and at least part of the pipeline is a heating pipeline (15). The heating pipeline (15) is directly used for heating a coolant for the fuel cell, so as to not only optimize the heating and circulating performance of the coolant, but also improve the operating efficiency of the fuel cell. In addition, the system has a simple and compact structure, and does not increase the volume of the fuel cell, thereby saving on the space and costs of the fuel cell.

Description

Fuel cell cooling circulation system Technical field:

The invention relates to a fuel cell cooling cycle system.

Background technique:

Existing fuel cells include a battery reactor that generates electricity using an electrochemical reaction, a cooling system that reduces the temperature of the battery reactor, and a fuel cell system controller that controls the battery reactor and the cooling system. The battery reactor includes a battery reactor and an air extraction device. The air extraction device sends air to the battery reactor. The battery reactor uses the electrochemical reaction between the hydrogen stored in the gas cylinder and the oxygen in the air to generate electrical energy. In this process The medium battery reactor will emit a large amount of reaction by-products-heat and water, where the heat is taken away by the cooling system, but the water will remain on the fuel cell proton exchange membrane. In a low-temperature environment, the water remaining on the fuel cell proton exchange membrane after the battery reactor is shut down will freeze, thereby destroying the fuel cell proton exchange membrane. At the same time, the optimal operating temperature of the fuel cell is between 60 ℃ -70 ℃, the reliability of the fuel cell is insufficient at low temperatures, and the waiting time for starting at low temperature cold start is too long to quickly increase the temperature of the fuel cell. Will seriously affect the efficiency of the fuel cell.

In order to solve the above problems, the Chinese Patent Publication No. CN108615916A discloses a fuel cell. By adding a separate heater to the circuit of the fuel cell cooling system, the heater is equipped with a heating element inside. After the heating element is energized, it will flow into The coolant of the heater is heated to solve the problem of low fuel cell operating efficiency caused by low temperature during low temperature startup, but the technology also has the following problems: On the one hand, the coolant heating and circulation performance of the existing heater Poor, affecting the efficiency of the fuel cell; on the other hand, due to the larger volume of the heater, occupying the fuel cell space, resulting in increased fuel cell costs.

Summary of the invention:

The object of the present invention is to provide a fuel cell cooling circulation system, which can not only optimize the heating and circulation performance of the cooling liquid, but also have a simple and compact structure.

A fuel cell cooling cycle system includes a cooling system. The cooling system includes a battery reactor, a water pump, a radiator, a thermostatic three-way valve, and a pipeline that generate electricity using an electrochemical reaction of air and hydrogen. The battery reactor, a water pump, The radiator and the constant temperature three-way valve are connected by a pipeline, and the pipeline is at least partly a heating pipeline.

The above heating pipe includes a pipe body and a heating unit. The pipe body includes a pipe wall, an inner wall surface and an outer wall surface, and the heating unit is provided in the pipe wall or on the inner wall surface or the outer wall surface.

The cross-sectional shape of the above-mentioned heat generating unit is circular, arc or square.

The above-mentioned heat generating units are plural, and the heat generating units are arranged at intervals along the longitudinal direction of the pipe body.

The above-mentioned heat generating units are plural, and the heat generating units are arranged at intervals along the circumferential direction of the pipe body.

The above-mentioned heating unit is a self-heating device or an electric heating device.

The above electric heating device is a resistance wire or a heating chip, a microwave device or a PTC heating element.

The pipeline between the heat generating pipeline and the battery reactor is connected through a three-way joint or a straight-through joint.

The above-mentioned electric heating device is electrically connected to the external power source through the pipe body or the three-way joint or the straight-through joint.

A first temperature sensor is provided at the coolant inlet of the battery reactor, a second temperature sensor is provided at the coolant outlet of the battery reactor, the coolant outlet of the battery reactor is connected to the coolant inlet of the water pump, and the water pump The coolant outlet of the radiator is connected to the coolant inlet of the radiator. The coolant outlet of the radiator is connected to the second valve port of the thermostatic three-way valve. The first valve port of the thermostatic three-way valve is connected to the coolant outlet of the water pump. The third valve port of the through valve is connected to the coolant inlet of the battery reactor.

The pipeline connecting the third valve port of the thermostatic three-way valve and the coolant inlet of the battery reactor is at least partially a heat generating pipeline.

An electromagnetic three-way valve is provided between the water pump and the radiator, one of the interfaces of the electromagnetic three-way valve is connected to the coolant inlet of the battery reactor through a pipeline, and the electromagnetic three-way valve is connected to the coolant inlet of the battery reactor At least part of the connected pipes are heating pipes.

The above-mentioned electromagnetic three-way valve includes a first interface, a second interface and a third interface, the first interface is connected to the coolant outlet of the water pump, the second interface and the coolant inlet of the radiator and the first valve port of the constant temperature three-way valve The third interface is connected to the coolant inlet of the battery reactor.

The above-mentioned cooling system further includes a coolant replenishment circuit. The coolant replenishment circuit includes a deionization filter, an expansion tank, and a pressure sensor. One end of the deionization filter is connected to the coolant inlet of the battery reactor through a pipe. The deionization filter The other end is connected to the expansion water tank, and the other end of the expansion water tank is connected to the coolant inlet of the water pump. The pressure sensor is located in the cooling system and detects the coolant hydraulic pressure of the cooling system.

An electromagnetic valve is connected between the cooling liquid inlet of the battery reactor and the deionization filter.

Compared with the prior art, the present invention has the following effects:

1) The pipeline is at least partly a heating pipe, and the heating pipe is directly used to heat the cooling fluid of the fuel cell, which can not only optimize the heating and circulation performance of the cooling fluid, thereby improving the working efficiency of the fuel cell; and the structure is simple and compact, not Will increase the volume of the fuel cell, thereby saving fuel cell space and cost.

2) The heating pipe includes a pipe body and a heating unit. The pipe body includes a pipe wall, an inner wall surface and an outer wall surface. The heating unit is provided in the pipe wall. By setting the heating unit in the pipe wall, not only can the heating be rapid, but also the sealing effect Good; the heating unit is located on the inner wall surface of the pipe body and can be heated quickly. The heating unit is in direct contact with the coolant and the contact area is large, so as to improve the heating efficiency; the heating unit is located on the outer wall surface of the pipe body, which not only realizes heating, but also facilitates the heating unit Installation and replacement.

3) The heating unit is ring-shaped, arc-shaped or square. The ring-shaped heating unit can wrap or cover the entire length of the pipe body, so that the temperature of the cooling liquid can be quickly raised, and the heating effect is good; the arc-shaped heating unit can be more Close to the pipe body, which makes the installation convenient and low cost; square heating unit, when the pipe body is not cylindrical or round, can be better installed flexibly according to needs.

4) The heating units are arranged at intervals along the length of the pipe body, and can be heated all the way along the flow direction of the liquid, with less loss.

5) The heat generating units are arranged at intervals along the circumferential direction of the pipe body, and the circumferential distribution can make the liquid evenly heated.

6) The heating unit is a self-heating device. The self-heating device does not need to add other energy supply devices. The structure is simple; the electric heating device is more mature, safe and effective to use this heating unit, and the heating unit can be uniformly controlled according to demand. .

7) The heating unit is a resistance wire or a heating sheet or a microwave device or a PTC heating body. The common heating unit is used. When the heating unit needs to be replaced, it can be replaced at any time, saving cost and time.

8) The pipeline between the heating pipeline and the battery reactor is connected by a three-way joint or a straight joint. Different joints are used according to actual needs, which not only facilitates installation and replacement, but also reduces costs, and uses ordinary pipelines in parts that do not require heating. , Use heating pipes for the parts that need to be heated.

9) The electric heating device is electrically connected to an external power source through a pipe body or a three-way joint or a straight joint. By connecting an external power source to the pipe body or a three-way joint or a straight joint, wiring and replacement can be more convenient.

10) A first temperature sensor is provided at the coolant inlet of the battery reactor, and a second temperature sensor is provided at the coolant outlet of the battery reactor. The coolant outlet of the battery reactor is connected to the coolant inlet of the water pump. The coolant outlet of the water pump is connected to the coolant inlet of the radiator. The coolant outlet of the radiator is connected to the second valve port of the thermostatic three-way valve. The first valve port of the thermostatic three-way valve is connected to the coolant outlet of the water pump. The third port of the three-way valve is connected to the coolant inlet of the battery reactor. The constant temperature three-way valve is used to control the flow direction of the coolant in the cooling system. The design and structure are simple, and the battery work efficiency is high.

11) The pipe connecting the third valve port of the thermostatic three-way valve and the battery reactor coolant inlet is at least partly a heating pipe, the heating pipe is installed in a reasonable position, the heating effect is good, and the energy consumption loss is small.

12) An electromagnetic three-way valve is provided between the water pump and the radiator, and one interface of the electromagnetic three-way valve is connected to the coolant inlet of the battery reactor through a pipeline, and the electromagnetic three-way valve is connected to the coolant inlet of the battery reactor At least part of the connected pipeline is a heating pipeline. The electromagnetic three-way valve is used to switch between the cold start and the normal working state of the battery reactor. When the cold start starts, the electromagnetic three-way valve is opened, and the heating pipe is connected to heat the coolant; when the temperature reaches normal After the work is required, the heating pipe is cut off by closing the electromagnetic three-way valve, and the radiator or constant temperature three-way valve is connected to enter the normal working state, so that the cold start of the fuel cell cooling cycle system and the normal working state are quickly switched to improve heating or heat dissipation effectiveness.

13) The cooling system further includes a coolant supplement circuit, the coolant supplement circuit includes a deionization filter, an expansion tank, and a pressure sensor. The coolant supplement circuit is used to balance the hydraulic pressure of the cooling system and the supplement of coolant, and deionization The filter can filter the ions in the cooling liquid; the pressure sensor is located at the cooling liquid outlet of the battery reactor, and the detection of the hydraulic pressure is more accurate.

14) A solenoid valve is connected between the coolant inlet of the battery reactor and the deionization filter. The pressure sensor detects the coolant hydraulic pressure of the cooling system. The fuel cell system controller can control the solenoid valve according to the coolant hydraulic pressure to ensure the cooling system. Hydraulic pressure is normal.

BRIEF DESCRIPTION:

1 is a structural block diagram of a fuel cell cooling cycle system provided by Embodiment 1 of the present invention;

2 is a structural block diagram of another fuel cell cooling cycle system provided in Embodiment 1 of the present invention;

FIG. 3 is a structural diagram of a heating pipe provided in Embodiment 1 of the present invention;

4 is a structural diagram of a heating pipe provided by Embodiment 2 of the present invention;

5 is a structural diagram of a heating pipe provided by Embodiment 3 of the present invention;

6a to 6c are structural diagrams of a heating pipe according to Embodiment 4 of the present invention;

7 is a block diagram of a fuel cell cooling cycle system according to Embodiment 5 of the present invention;

8 is a block diagram of a fuel cell cooling cycle system according to Embodiment 6 of the present invention;

9 is a block diagram of the preferred configuration of the fuel cell cooling cycle system of FIG. 8;

10 is a block diagram of a fuel cell cooling cycle system according to Embodiment 7 of the present invention;

FIG. 11 is a block diagram showing a preferred configuration of the fuel cell cooling cycle system of FIG. 10.

detailed description:

The present invention will be described in further detail below through specific embodiments and drawings.

Embodiment 1: As shown in FIGS. 1 to 3, a fuel cell cooling cycle system includes a cooling system 10 including a battery reactor 5, a water pump 12, and heat dissipation using the electrochemical reaction of air and hydrogen to generate electricity 13, thermostat three-way valve 14 and pipeline, the battery reactor 5, the water pump 12, the radiator 13, and the thermostat three-way valve 14 are connected by a pipeline, the pipeline is at least partially a heating pipe 15, the heating pipe 15 It includes a pipe body 151 and a heating unit 152. The pipe body 151 includes a pipe wall 1511, an inner wall surface 1512 and an outer wall surface 1513. The heating unit 152 is disposed in the pipe wall 1511 or on the inner wall surface 1512 or the outer wall surface 1513. The cross-sectional shape of the heating unit 152 is circular. The heating unit 152 may be an electric heating device such as a resistance wire or a heating sheet or a microwave device or a PTC heating element. The heating unit 152 may also be a self-heating device such as: Metal magnesium, sodium hydroxide, metal vanadium, metal titanium, etc.

Embodiment 2: As shown in FIG. 4, this embodiment is further improved on the basis of Embodiment 1. The heating unit is arc-shaped, and the heating unit 152 is provided at any position of the pipe body, for example: In the wall 1511, or on the inner wall surface 1512 or the outer wall surface 1513, the heating unit 152 may be one or more; when there are multiple heating units 152, the heating units 152 are circumferentially spaced along the pipe body 151 Configuration, the interval configuration may be uniformly distributed or irregularly distributed.

Embodiment 3: As shown in FIG. 5, this embodiment is further improved on the basis of Embodiment 1. The heating unit is square, and the heating unit 152 is provided at any position of the pipe body, for example: at the wall 1511 In the middle or on the inner wall surface 1512 or the outer wall surface 1513, the heating unit 152 may be one or more; when there are multiple heating units 152, the heating units 152 are spaced along the circumferential direction of the pipe body 151, The interval configuration method may be uniformly distributed or irregularly distributed.

Embodiment 4: As shown in FIGS. 6a to 6c, this embodiment is further improved on the basis of Embodiment 1. The heating unit 152 is provided at any position of the pipe body, for example: in the pipe wall 1511 or inside On the wall surface 1512 or the outer wall surface 1513, the heating unit 152 may be one or more. When the heating unit 152 is multiple, the multiple heating units 152 are arranged at intervals along the length of the pipe body 151. The interval configuration method can be uniformly distributed or irregularly distributed.

Embodiment 5: As shown in FIG. 7, this embodiment is further improved on the basis of Embodiment 1 to Embodiment 4. The pipeline between the heating pipe 15 and the battery reactor 5 is passed through a three-way joint 16 or a straight joint (FIG. (Not shown in the figure), the electric heating device is electrically connected to an external power source (not shown in the figure) through the pipe body 151 or the three-way connector 16 or the straight-through connector (not shown in the figure).

Embodiment 6: As shown in FIGS. 8 to 9, this embodiment is further improved on the basis of Embodiments 1 to 4, the first temperature sensor 31 and the battery reactor 5 are provided at the coolant inlet of the battery reactor 5 A second temperature sensor 32 is provided at the coolant outlet. The coolant outlet of the battery reactor 5 is connected to the coolant inlet of the water pump 12. The coolant outlet of the water pump 12 is connected to the coolant inlet of the radiator 13. The liquid outlet is connected to the second valve port 142 of the thermostatic three-way valve 14, the first valve port 141 of the thermostatic three-way valve 14 is connected to the coolant outlet of the water pump 12, and the third valve port 143 of the thermostatic three-way valve 14 is connected to the battery reactor 5 is connected to the coolant inlet, the third valve port 143 of the thermostatic three-way valve 14 is connected to the coolant inlet of the battery reactor 5 at least in part is a heating pipe 15, the cooling system 10 further includes a coolant supplement circuit 20 The coolant replenishment circuit 20 includes a deionization filter 24, an expansion water tank 22, and a pressure sensor 23. One end of the deionization filter 24 is connected to the coolant inlet of the battery reactor 5 through a pipe, and the deionization filter The other end of 24 is connected to the expansion water tank 22, and the other end of the expansion water tank 22 is connected to the coolant inlet of the water pump 12, the expansion water tank is located at the highest point of the cooling system 10, the pressure sensor 23 is located in the cooling system 10 and detects the cooling of the cooling system 10 In hydraulic pressure, a solenoid valve 21 is connected between the coolant inlet of the battery reactor 5 and the deionizing filter 24.

Embodiment 7: As shown in FIGS. 10 to 11, this embodiment is further improved on the basis of Embodiments 1 to 4, the first temperature sensor 31 and the battery reactor are provided at the coolant inlet of the battery reactor 5 A second temperature sensor 32 is provided at the coolant outlet of 5, the coolant outlet of the battery reactor 5 is connected to the coolant inlet of the water pump 12, the coolant outlet of the water pump 12 is connected to the coolant inlet of the radiator 13, the radiator The coolant outlet of 13 is connected to the second valve port 142 of the thermostatic three-way valve 14, the first valve port 141 of the thermostatic three-way valve 14 is connected to the coolant outlet of the water pump 12, and the third valve port 143 of the thermostatic three-way valve 14 Connected to the coolant inlet of the battery reactor 5, an electromagnetic three-way valve 17 is provided between the water pump 12 and the radiator 13, and one of the interfaces of the electromagnetic three-way valve 17 is connected to the coolant inlet of the battery reactor 5 through a pipe. The pipeline connecting the electromagnetic three-way valve 17 and the coolant inlet of the battery reactor 5 is at least partially a heating pipe 15. The electromagnetic three-way valve 17 includes a first port 171, a second port 172, and a third port 173. The first Interface 171 Connected to the coolant outlet of the water pump 12, the second port 172 is connected to the coolant inlet of the radiator 13 and the first valve port 141 of the thermostatic three-way valve 14, and the third port 173 is connected to the coolant inlet of the battery reactor 5 when cold When starting, the electromagnetic three-way valve 17 is opened, and the heating pipe 15 is connected to heat the coolant; when the temperature reaches the normal working requirements, the heating pipe 15 is cut off by closing the electromagnetic three-way valve 17, the radiator 13 or the thermostatic three-way is connected The valve 14 enters the normal working state, and the coolant replenishment circuit 20 includes a deionization filter 24, an expansion water tank 22, and a pressure sensor 23. One end of the deionization filter 24 is connected to the coolant inlet of the battery reactor 5 through a pipeline, and the deionization filter The other end of the device 24 is connected to the expansion water tank 22, the other end of the expansion water tank 22 is connected to the coolant inlet of the water pump 12, the expansion water tank is located at the highest point of the cooling system, the pressure sensor 23 is located in the cooling system 10 and detects the cooling system 10 The coolant is hydraulically pressured, and a solenoid valve 21 is connected between the coolant inlet of the battery reactor 5 and the deionizing filter 24.

The above embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited thereto, and any other changes, modifications, substitutions, combinations, and simplifications made without departing from the spirit and principles of the present invention are equivalent The replacement methods are all included in the protection scope of the present invention.

Claims (15)

A fuel cell cooling cycle system includes a cooling system (10), the cooling system (10) includes a battery reactor (5), a water pump (12), and a radiator (13) that generate electricity using the electrochemical reaction of air and hydrogen , A constant temperature three-way valve (14) and a pipeline, the battery reactor (5), a water pump (12), a radiator (13), and a constant temperature three-way valve (14) are connected by a pipeline, characterized in that: the pipeline At least part of it is a heating pipe (15). The fuel cell cooling cycle system according to claim 1, characterized in that the heat generating pipe (15) includes a pipe body (151) and a heat generating unit (152), and the pipe body (151) includes a pipe wall ( 1511), the inner wall surface (1512) and the outer wall surface (1513), the heating unit (152) is provided in the tube wall (1511) or on the inner wall surface (1512) or the outer wall surface (1513). The fuel cell cooling cycle system according to claim 2, characterized in that the cross-sectional shape of the heat generating unit (152) is circular, arc-shaped, or square. A fuel cell cooling cycle system according to claim 3, characterized in that there are a plurality of heat generating units (152), and the plurality of heat generating units (152) are arranged at intervals along the longitudinal direction of the pipe body (151). A fuel cell cooling cycle system according to claim 3, characterized in that there are a plurality of heat generating units (152), and the plurality of heat generating units (152) are arranged at intervals along the circumferential direction of the pipe body (151). A fuel cell cooling cycle system according to claim 2, wherein the heating unit (152) is a self-heating device or an electric heating device. A fuel cell cooling cycle system according to claim 6, wherein the electric heating device is a resistance wire or a heating sheet or a microwave device or a PTC heating body. A fuel cell cooling cycle system according to claim 1 or 2 or 3 or 4 or 5 or 6 or 7, characterized in that the pipeline between the heat generating pipe (15) and the battery reactor (5) passes through three Through connector (16) or straight connector. A fuel cell cooling cycle system according to claim 6 or 7, characterized in that the electric heating device is electrically connected to an external power source through a pipe body (151) or a three-way joint (16) or a through joint. A fuel cell cooling cycle system according to claim 1 or 2 or 3 or 4 or 5 or 6 or 7, characterized in that: a first temperature sensor is provided at the coolant inlet of the battery reactor (5) ( 31), a second temperature sensor (32) is provided at the coolant outlet of the battery reactor (5), the coolant outlet of the battery reactor (5) is connected to the coolant inlet of the water pump (12), and the water pump (12) ) Coolant outlet is connected to the radiator inlet of the radiator (13), the radiator outlet of the radiator (13) is connected to the second valve port (142) of the thermostatic three-way valve (14), the thermostatic three-way valve (14) ) The first valve port (141) is connected to the coolant outlet of the water pump (12), and the third valve port (143) of the thermostatic three-way valve (14) is connected to the coolant inlet of the battery reactor (5). A fuel cell cooling cycle system according to claim 10, characterized in that: the third valve port (143) of the thermostatic three-way valve (14) is connected to the coolant inlet of the battery reactor (5) at least The part is the heating pipe (15). A fuel cell cooling circulation system according to claim 10, characterized in that: an electromagnetic three-way valve (17) and an electromagnetic three-way valve (17) are provided between the water pump (12) and the radiator (13) One of the interfaces is connected to the coolant inlet of the battery reactor (5) through a pipeline, and the pipeline connected between the electromagnetic three-way valve (17) and the coolant inlet of the battery reactor (5) is at least partially a heating pipe (15) . The fuel cell cooling cycle system according to claim 12, wherein the electromagnetic three-way valve (17) includes a first port (171), a second port (172) and a third port (173), The first port (171) is connected to the coolant outlet of the water pump (12), and the second port (172) is connected to the coolant inlet of the radiator (13) and the first valve port (141) of the thermostatic three-way valve (14), The third interface (173) is connected to the coolant inlet of the battery reactor (5). A fuel cell cooling cycle system according to claim 13, characterized in that the cooling system (10) further includes a coolant supplement circuit (20), and the coolant supplement circuit (20) includes a deionizing filter (24), expansion water tank (22) and pressure sensor (23), one end of the deionization filter (24) is connected to the coolant inlet of the battery reactor 5 through the pipeline, and the other end of the deionization filter (24) is connected to the expansion water tank (22) ) Connection, the other end of the expansion water tank (22) is connected to the coolant inlet of the water pump (12), the pressure sensor (23) is located in the cooling system (10) and detects the coolant hydraulic pressure of the cooling system (10). A fuel cell cooling cycle system according to claim 14, characterized in that: a solenoid valve (21) is connected between the coolant inlet of the cell reactor (5) and the deionizing filter (24).

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