JP2004155295A - Air conditioning system for automobile - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide sufficiently high cooling capability by making use of air pole exhaust gas expanded by an expander in an air conditioning system for a fuel cell automobile. <P>SOLUTION: The expander (23) is connected with a fuel cell (70) to expand the air pole off gas with the expander (23). During an expansion process of the expander (23), temperature of the air pole off gas lowers, and vapor in the air pole off gas is condensed to generate condensed water. The lower temperature air pole off gas after being expanded and the condensed water generated by the expander (23) are supplied to a vapor cooling heat exchanger (14). The air supplied into a cabin (80) is also introduced into the vapor cooling heat exchanger (14). The air pole off gas absorbs heat from the supplied air and temperature rises in the vapor cooling heat exchanger (14), and the condensed water absorbs heat from the supplied air to be evaporated. The supplied air cooled by the vapor cooling heat exchanger (14) is sent into the cabin (80). <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an air conditioning system for a fuel cell vehicle.
[0002]
[Prior art]
In recent years, fuel cells have attracted attention as power sources for automobiles. In fuel cells for automobiles, air as an oxidizing agent is often pressurized to about 2 to 3 atmospheres in order to reduce the size thereof. Therefore, the air electrode off-gas of about 2 to 3 atm is discharged from the air electrode of the fuel cell. Then, the air electrode off-gas is discharged to the outside of the vehicle after the pressure is reduced to the atmospheric pressure.
[0003]
Patent Literature 1 discloses that an expander is used to reduce the air electrode off-gas. In other words, power recovery is performed by expanding the air electrode off-gas with an expander, and the power recovered for compressing the air supplied to the fuel cell is used to reduce the power required for air compression.
[0004]
During the expansion process in the expander, the temperature of the air electrode off-gas decreases. Therefore, Patent Literature 2 discloses performing air conditioning in a vehicle cabin by using an air electrode off-gas after expansion. That is, the low-temperature air electrode off-gas sent from the expander is heat-exchanged with the supply air to the vehicle interior, and the supply air is cooled and sent to the vehicle interior to cool the vehicle interior.
[0005]
[Patent Document 1]
JP 2000-149972
[Patent Document 2]
JP 2001-30742A
[0006]
[Problems to be solved by the invention]
However, there is a problem that a sufficient cooling capacity cannot be obtained simply by exchanging the air electrode off-gas from the expander with the supply air, as disclosed in Patent Document 2. This problem will be described.
[0007]
For example, when the air electrode offgas having a relative humidity of 90% and a pressure of 2 atm at 50 ° C. is adiabatically expanded (isentropic expansion) to 1 atm, the temperature of the air electrode offgas after expansion is reduced only to about 10 ° C. This is because heat of condensation is released when water vapor in the air electrode off-gas condenses during the expansion process. For this reason, the temperature difference between the supply air to be cooled and the air electrode off-gas after expansion cannot be made very large, and the supply air cannot be cooled to a very low temperature, so that there is a problem that sufficient cooling capacity cannot be obtained.
[0008]
The present invention has been made in view of such a point, and an object of the present invention is to provide an air conditioning system used for a fuel cell vehicle with sufficient cooling capacity by utilizing an air electrode exhaust gas expanded by an expander. To get.
[0009]
[Means for Solving the Problems]
The invention of claim 1 is directed to an air conditioning system mounted on an automobile using a fuel cell (70) as a power source. A compressor (20) for compressing the air supplied to the fuel cell (70); and a condenser for cooling the air electrode off-gas discharged from the fuel cell (70) and condensing moisture in the air electrode off-gas. A pre-cooler (13), an expander (23) for expanding the air electrode off-gas sent from the condensing pre-cooler (13) to recover power, an air electrode off-gas after expansion and condensed water generated in the expansion process Is supplied from the expander (23), and an air supply cooler (14) that cools air supplied to the vehicle interior by using the sensible heat of the supplied air electrode off-gas and the heat of evaporation of condensed water. It is provided.
[0010]
According to a second aspect of the present invention, in the vehicle air-conditioning system according to the first aspect, the supply air cooler (14) is such that the condensed water generated by the expander (23) flows by gravity. It is arranged below.
[0011]
According to a third aspect of the present invention, in the vehicle air conditioning system according to the first aspect, air supplied from the compressor (20) to the fuel cell (70) by using the condensed water generated by the condensing precooler (13). Humidification is possible.
[0012]
According to a fourth aspect of the present invention, in the automotive air conditioning system according to the first aspect, the condensed water generated by the condensing precooler (13) is supplied to the air supply cooler (14) to reduce the evaporation heat of the condensed water. It can be used for cooling supply air.
[0013]
According to a fifth aspect of the present invention, in the vehicle air conditioning system according to the fourth aspect, a water tank (50) for storing condensed water generated by the condensing pre-cooler (13) is provided, and the supply air cooler (14) evaporates. The condensed water that has not been collected can be collected in the water tank (50).
[0014]
According to a sixth aspect of the present invention, in the vehicle air conditioning system according to the first aspect, the condensing precooler (13) cools the air electrode off-gas by exchanging heat with cooling air.
[0015]
According to a seventh aspect of the present invention, in the automotive air conditioning system according to the sixth aspect, the condensed water generated by the condensing precooler (13) is supplied to the cooling air, and the heat of evaporation of the condensed water is cooled to the air electrode off-gas. It is available for
[0016]
The invention according to claim 8 is the vehicle air conditioning system according to claim 1, wherein the temperature sensor (65) for measuring the temperature of the air electrode off-gas sent from the expander (23), and the temperature sensor (65). ) Is provided with a control means (61) for performing a control operation for controlling the operation of the automotive air-conditioning system so that the value measured in the step (b) becomes equal to or more than a predetermined value.
[0017]
According to a ninth aspect of the present invention, in the automotive air conditioning system according to the eighth aspect, the upstream and downstream of the condensing precooler (13) are communicated so that the air electrode off-gas bypasses the condensing precooler (13). The control means (61) includes a bypass passage (43) that can change the proportion of the air electrode off-gas discharged from the fuel cell (70) that bypasses the condensation precooler (13). The operation of adjusting the proportion of the air electrode off-gas discharged from 70) that bypasses the condensation precooler (13) is performed as a control operation.
[0018]
According to a tenth aspect of the present invention, in the vehicle air conditioning system according to the eighth aspect, the condensing precooler (13) cools the air electrode off-gas by exchanging heat with cooling air, while the control means (61) includes: The operation of adjusting the supply amount of the cooling air to the condensation precooler (13) is performed as a control operation.
[0019]
According to an eleventh aspect of the present invention, in the automotive air conditioning system according to the eighth aspect, the condensing pre-cooler (13) cools the air electrode off-gas by exchanging heat with cooling air while cooling the condensing pre-cooler (13). The condensed water generated in the above is supplied to the cooling air, and the heat of evaporation of the condensed water can be used for cooling the air electrode off-gas. The control means (61) controls the supply amount of the condensed water to the cooling air. Is performed as a control operation.
[0020]
According to a twelfth aspect of the present invention, in the vehicle air conditioning system according to the first aspect, the air electrode off-gas communicates upstream and downstream of the expander (23) so as to bypass the expander (23), and condenses and pre-cools. A bypass passage (45) that can change the ratio of the air electrode off-gas that is sent from the device (13) and bypasses the expander (23), and the cooling capacity obtained by the supply air cooler (14) are adjusted. For this purpose, a control means (63) for adjusting the proportion of the air electrode off-gas sent from the condensation precooler (13) that bypasses the expander (23) is provided.
[0021]
According to a thirteenth aspect, in the automotive air conditioning system according to the first aspect, the high-pressure air discharged from the compressor (20) is provided upstream of the fuel cell (70) such that the high-pressure air bypasses the fuel cell (70). The bypass passage (41), which allows the downstream to communicate and can change the ratio of the high-pressure air that bypasses the fuel cell (70), and the above-described supply air cooler (14) so that a predetermined cooling capacity can be obtained. Control means for adjusting the amount of air taken in by the compressor (20) and adjusting the proportion of the high-pressure air that bypasses the fuel cell (70) in accordance with the amount of power required by the fuel cell (70) (62).
[0022]
According to a fourteenth aspect of the present invention, in the vehicle air conditioning system according to the first aspect, the expander (23) is directly connected to the compressor (20) by the drive shaft (24), and the power recovered by the expander (23). Are used for driving the compressor (20).
[0023]
According to a fifteenth aspect of the present invention, in the automotive air conditioning system according to the first aspect, a plurality of compressors (21, 22) are provided, while the first compressor (21) uses only power obtained by the electric motor. The driven and compressed air is supplied to the second compressor (22), and the second compressor (22) is driven only by the power recovered by the expander (23) to convert the compressed air into fuel. The battery is supplied to the battery (70).
[0024]
-Action-
According to the first aspect of the present invention, the air compressed by the compressor (20) is supplied to the gas passage on the air side of the fuel cell (70). While flowing through the gas passage on the air electrode side, oxygen in the air is consumed by the battery reaction. The air electrode off-gas discharged from the fuel cell (70) is sent to the condensing precooler (13) to be cooled. At this time, in the condensation precooler (13), water vapor contained in the air electrode off-gas is condensed to generate condensed water. Thereafter, the air electrode off-gas is sent to the expander (23) and expands.
[0025]
In the expansion process in the expander (23), the temperature of the air electrode off-gas is reduced, and water vapor contained in the air electrode off-gas is condensed to generate condensed water. The condensed water generated by the expander (23) is sent to the air supply cooler (14) together with the air electrode off-gas after expansion. In the supply air cooler (14), the supply air to the vehicle interior radiates heat to both the air electrode off-gas and the condensed water. That is, in the supply air cooler (14), the air electrode off-gas absorbs heat from the supply air and rises in temperature, while condensed water absorbs heat from the supply air and evaporates. Then, the automotive air conditioning system (10) of the present invention supplies the supply air cooled by the air supply cooler (14) to the vehicle interior to cool the interior of the vehicle interior.
[0026]
According to the second aspect of the present invention, the supply air cooler (14) is disposed below the expander (23). Therefore, even if the condensed water generated by the expander (23) becomes relatively large water droplets, the condensed water surely flows down toward the air supply cooler (14) installed below.
[0027]
According to the third aspect of the present invention, the condensed water generated by the condensing precooler (13) is used to humidify the air supplied to the fuel cell (70). For example, in a solid polymer electrolyte fuel cell (70), it is necessary to keep the electrolyte membrane in a wet state by humidifying the supplied air in advance. Therefore, in such a case, the air supplied to the fuel cell (70) is humidified in advance by using the condensed water generated by the condensing precooler (13).
[0028]
According to the fourth aspect of the present invention, the air conditioning system for automobiles (14) can supply not only the condensed water generated by the expander (23) but also the condensed water generated by the condensing pre-cooler (13) to the air supply cooler (14). 10) is configured. If the temperature of the supply air is not sufficiently reduced even when all of the condensed water generated in the expander (23) evaporates in the charge air cooler (14), the condensed water generated in the condensate precooler (13) is removed. It is preferable that the supply air is supplied to the supply air cooler (14) and the supply air is cooled using the latent heat of the condensed water.
[0029]
According to the fifth aspect of the present invention, the condensed water generated by the condensing precooler (13) is temporarily stored in the water tank (50). Condensed water that has not evaporated in the supply air cooler (14), that is, condensed water that is supplied in excess of the amount required for cooling the supply air, is collected in the water tank (50). As described above, the condensed water surplus in the supply air cooler (14) is once collected in the water tank (50), and then used for cooling the supply air.
[0030]
In the invention of claim 6, the condensing precooler (13) is configured as an air-cooled type. That is, in the condensation pre-cooler (13), the air electrode off-gas releases heat to the cooling air and is cooled.
[0031]
In the invention according to claim 7, the automotive air conditioning system (10) is configured so that the condensed water generated by the condensation precooler (13) can be supplied to the cooling air. In other words, the condensing precooler (13) may not be able to sufficiently cool the air electrode off-gas only by the sensible heat of the cooling air. Therefore, in such a case, the condensed water generated on the air electrode off-gas side of the condensing pre-cooler (13) is supplied to the cooling air, and the condensing pre-cooler (13) uses the cooling air for cooling the air electrode off-gas. Utilizes not only the sensible heat of the water but also the latent heat of condensed water.
[0032]
In the invention according to claim 8, the temperature of the air electrode off-gas sent from the expander (23) is measured by the temperature sensor (65). Further, the control means (61) performs a predetermined control operation. That is, the control means (61) controls the automotive air-conditioning system (in order to maintain the measured value obtained by the temperature sensor (65), that is, the temperature of the air electrode off-gas sent from the expander (23) at a predetermined value or more. The operation of 10) is controlled.
[0033]
According to the ninth aspect of the present invention, the control means (61) performs, as a control operation, an operation of adjusting the ratio of the air electrode off-gas discharged from the fuel cell (70) that bypasses the condensation precooler (13). For example, when the measurement value obtained by the temperature sensor (65) is lower than a predetermined value, the control means (61) cools the air electrode off-gas sent to the expander (23) by the condensation pre-cooler (13). Reduce the percentage of things. Then, the temperature of the air electrode off-gas at the inlet of the expander (23) increases, and the temperature of the air electrode off-gas sent from the expander (23) also increases. Conversely, when the measured value obtained by the temperature sensor (65) is higher than a predetermined value, the control means (61) controls the condensing precooler (of the air electrode off-gas sent to the expander (23)). 13) Increase the percentage of what is cooled. Then, the temperature of the air electrode off-gas at the inlet of the expander (23) decreases, and the temperature of the air electrode off-gas sent from the expander (23) also decreases.
[0034]
According to the tenth aspect of the present invention, the condensing precooler (13) is configured as an air-cooled type. That is, in the condensation pre-cooler (13), the air electrode off-gas releases heat to the cooling air and is cooled. In the present invention, the control means (61) performs an operation of adjusting the amount of cooling air supplied to the condensation precooler (13) as a control operation. For example, when the measured value obtained by the temperature sensor (65) is lower than a predetermined value, the control means (61) reduces the supply amount of the cooling air to the condensation precooler (13). Then, the temperature of the air electrode off-gas sent from the condensation precooler (13) to the expander (23) increases, and the temperature of the air electrode off-gas sent from the expander (23) also increases. Conversely, when the measured value obtained by the temperature sensor (65) is higher than a predetermined value, the control means (61) increases the supply amount of the cooling air to the condensation precooler (13). Then, the temperature of the air electrode off-gas sent from the condensation precooler (13) to the expander (23) decreases, and the temperature of the air electrode off-gas sent from the expander (23) also decreases.
[0035]
According to the eleventh aspect, the condensing precooler (13) is configured to be air-cooled. That is, in the condensation pre-cooler (13), the air electrode off-gas releases heat to the cooling air and is cooled. In the present invention, the automotive air-conditioning system (10) is configured so that the condensed water generated by the condensing precooler (13) can be supplied to the cooling air. In other words, the condensing precooler (13) may not be able to sufficiently cool the air electrode off-gas only by the sensible heat of the cooling air. Therefore, in such a case, the condensed water generated on the air electrode off-gas side of the condensing pre-cooler (13) is supplied to the cooling air, and the condensing pre-cooler (13) uses the cooling air for cooling the air electrode off-gas. Utilizes not only the sensible heat of the water but also the latent heat of condensed water.
[0036]
In the eleventh aspect of the present invention, the control means (61) performs an operation of adjusting the amount of condensed water supplied to the cooling air as a control operation. For example, when the measurement value obtained by the temperature sensor (65) is lower than a predetermined value, the control unit (61) reduces the supply amount of the condensed water to the cooling air. Then, the amount of condensed water used for cooling the air electrode off-gas in the condensation pre-cooler (13) decreases, and the temperature of the air electrode off-gas sent from the condensation pre-cooler (13) to the expander (23) increases. The temperature of the air electrode off-gas sent from the expander (23) also increases. Conversely, when the measured value obtained by the temperature sensor (65) is higher than a predetermined value, the control means (61) increases the supply amount of the condensed water to the cooling air. Then, the amount of condensed water used for cooling the air electrode off-gas in the condensation pre-cooler (13) increases, and the temperature of the air electrode off-gas sent from the condensation pre-cooler (13) to the expander (23) decreases. The temperature of the air electrode off-gas sent from the expander (23) also decreases.
[0037]
In the twelfth aspect of the invention, the control means (63) performs an operation of adjusting the ratio of the air electrode off-gas sent from the condensation precooler (13) that bypasses the expander (23). For example, if the cooling capacity obtained by the air supply cooler (14) is excessive with respect to the cooling load of the passenger compartment, the control means (63) controls the air electrode off gas sent to the air supply cooler (14). Reduce the proportion of what expands with the expander (23). Then, the temperature of the air electrode off-gas flowing into the charge air cooler (14) increases, and the cooling capacity obtained by the charge air cooler (14) decreases. Conversely, if the cooling capacity obtained by the air supply cooler (14) is too small for the cooling load of the passenger compartment, the control means (63) is sent to the air supply cooler (14). The proportion of the air electrode off-gas that expands in the expander (23) is increased. Then, the temperature of the air electrode off-gas flowing into the charge air cooler (14) decreases, and the cooling capacity obtained by the charge air cooler (14) increases.
[0038]
In the thirteenth aspect, the control means (62) performs an operation of adjusting the amount of air sucked by the compressor (20). For example, if the cooling capacity obtained by the supply air cooler (14) is excessive with respect to the cooling load of the passenger compartment, the control means (62) reduces the amount of air sucked into the compressor (20). Then, the supply amount of the air electrode off-gas to the air supply cooler (14) decreases, and the cooling capacity obtained by the air supply cooler (14) decreases. Conversely, if the cooling capacity obtained by the air supply cooler (14) is too small for the cooling load of the vehicle interior, the control means (62) reduces the air intake amount of the compressor (20). increase. Then, the supply amount of the air electrode off-gas to the air supply cooler (14) increases, and the cooling capacity obtained by the air supply cooler (14) increases.
[0039]
Further, in the thirteenth aspect, the control means (62) performs an operation of adjusting the ratio of high-pressure air that bypasses the fuel cell (70). That is, when the air intake amount of the compressor (20) is adjusted in accordance with the cooling load of the passenger compartment, the fuel cell (70) increases the amount of the high-pressure air required to generate the required electric power by the fuel cell (70). In some cases, the supply amount of high-pressure air to 70) becomes excessive. Therefore, in such a case, the control means (62) increases the amount of high-pressure air flowing into the bypass passage (41), and does not change the cooling capacity obtained by the supply air cooler (14). The supply amount of high-pressure air to (70) is reduced.
[0040]
According to the fourteenth aspect, the expander (23) and the compressor (20) are directly connected by the drive shaft (24). The power recovered in the expander (23) is used as power for compressing air in the compressor (20).
[0041]
In the invention according to claim 15, a plurality of compressors (21, 22) are provided in the vehicle air conditioning system (10). Among them, the first compressor (21) is driven only by the electric motor to compress the air. On the other hand, the second compressor (22) is driven only by the power recovered by the expander (23). The second compressor (22) sucks the air compressed by the first compressor (21) and further compresses the air. Then, the air discharged from the second compressor (22) is supplied to the fuel cell (70).
[0042]
Embodiment 1 of the present invention
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0043]
As shown in FIG. 1, the air conditioning system (10) of the present embodiment is mounted on an automobile using a fuel cell (70) as a power source. The air conditioning system (10) uses air required for operation of the fuel cell (70), and performs air conditioning in the vehicle compartment (80) without using a so-called Freon refrigerant or the like.
[0044]
The fuel cell (70) is of a solid polymer electrolyte type and constitutes a fuel cell stack in which a number of unit cells are stacked. In the fuel cell (70), a large number of fuel electrode side gas flow paths (71) and a large number of air electrode side gas flow paths (72) are formed corresponding to each unit cell. In the fuel cell (70), the hydrogen flowing through the fuel electrode side gas flow path (71) comes into contact with the fuel electrode (anode) of the unit cell, and the air flowing through the air electrode side gas flow path (72) becomes Contact with air electrode (cathode).
[0045]
A cooling water circuit (73) is connected to the fuel cell (70). The cooling water circuit (73) is a closed circuit in which a fuel cell (70), a radiator (74), and a circulation pump (75) are sequentially arranged, and is filled with cooling water. Then, by circulating the cooling water in the cooling water circuit (73), the fuel cell (70) is maintained at a predetermined operating temperature.
[0046]
The fuel electrode side gas flow path (71) of the fuel cell (70) is arranged in the middle of the fuel side passage (76). Hydrogen gas is supplied to the fuel cell (70) through the fuel-side passage (76). A fuel humidifier (77) is provided upstream of the fuel cell (70) in the fuel-side passage (76). The fuel humidifier (77) is for humidifying the hydrogen gas introduced into the fuel cell (70) in advance and keeping the electrolyte membrane of the fuel cell (70) wet.
[0047]
The air electrode side gas flow path (72) of the fuel cell (70) is arranged in the middle of the air side passage (11). Air containing oxygen as an oxidant is supplied to the fuel cell (70) through the air side passage (11). On the upstream side of the fuel cell (70) in the air side passage (11), a compressor (20) and a temperature control humidification heat exchanger (12) are provided. On the other hand, a condensing heat exchanger (13), an expander (23), and an evaporative cooling heat exchanger (14) are provided downstream of the fuel cell (70) in the air-side passage (11). The air side passage (11) is provided with a first bypass passage (41) and a second bypass passage (43).
[0048]
The compressor (20) is for suctioning and compressing air, and is composed of various fluid machines such as a turbo type and a scroll type. The compressor (20) has a suction side communicating with the outside of the vehicle, and a discharge side thereof is connected to the temperature control humidification heat exchanger (12).
[0049]
The temperature controlled humidification heat exchanger (12) is arranged between the compressor (20) and the fuel cell (70). The temperature control humidification heat exchanger (12) is configured to perform temperature control and humidification on high-pressure air supplied to the fuel cell (70) in advance. Specifically, the temperature control humidification heat exchanger (12) adjusts the temperature of the high-pressure air, for example, by exchanging heat with the outside air. Further, the temperature control humidification heat exchanger (12) humidifies the high-pressure air by spraying water.
[0050]
The condensation heat exchanger (13) is connected to a fuel cell (70). The air electrode off-gas discharged from the air electrode side gas flow path (72) of the fuel cell (70) is introduced into the condensation heat exchanger (13). Outside air taken in by the cooling fan (30) is sent into the condensation heat exchanger (13) as cooling air. The condensing heat exchanger (13) exchanges heat between the air electrode off-gas and the cooling air, and constitutes a condensing precooler. That is, in the condensing heat exchanger (13), the air electrode off-gas is cooled by heat exchange with the cooling air, and at the same time, the water contained in the air electrode off-gas is condensed to generate condensed water.
[0051]
The expander (23) is composed of various fluid machines such as a turbo type and a scroll type, and is disposed downstream of the condensing heat exchanger (13). An air electrode off-gas is introduced into the expander (23) from the condensation heat exchanger (13). In the expander (23), the air electrode off-gas expands and internal energy of the air electrode off-gas is recovered as rotational power. In the expansion process of the expander (23), at the same time as the temperature of the air electrode off-gas decreases, the water vapor contained in the air electrode off-gas condenses to generate condensed water.
[0052]
The evaporative cooling heat exchanger (14) is arranged downstream of the expander (23) and below the expander (23). The air electrode off-gas expanded by the expander (23) is introduced into the evaporative cooling heat exchanger (14). Further, supply air is fed into the evaporative cooling heat exchanger (14) through the supply side passage (35). This air supply side passage (35) will be described later. The evaporative cooling heat exchanger (14) exchanges heat between the air electrode off-gas or condensed water and the supplied air, and cools the supplied air using the sensible heat of the air electrode off-gas and the condensed water evaporation heat. It constitutes a supply air cooler.
[0053]
The inlet end of the air supply side passage (35) is bifurcated, and one of the branches is opened in the vehicle interior (80) and the other is opened out of the vehicle interior (80). In the supply-side passage (35), a damper (36) is provided at a location where the branch pipe on the inlet end side joins. This damper (36) is for changing the ratio of the inside air and outside air taken into the air supply side passage (35). An air supply fan (37) is provided between the damper (36) and the evaporative cooling heat exchanger (14) in the air supply side passage (35). Furthermore, the outlet end of the air supply side passageway (35) opens into the vehicle interior (80).
[0054]
One end of the first bypass passage (41) is connected via the first three-way valve (42) immediately before the fuel cell (70), and the other end is connected immediately after the fuel cell (70). Operating the first three-way valve (42) of the first bypass passage (41) changes the distribution ratio of high-pressure air to the fuel cell (70) and the first bypass passage (41).
[0055]
The second bypass passage (43) has one end connected immediately before the condensing heat exchanger (13) via the second three-way valve (44), and the other end connected immediately after the condensing heat exchanger (13). Have been. When the second three-way valve (44) of the second bypass passage (43) is operated, the distribution ratio of the air electrode off-gas to the condensing heat exchanger (13) and the second bypass passage (43) changes.
[0056]
The compressor (20) and the expander (23) are connected by one drive shaft (24). The drive shaft (24) is provided with a motor (25). Although not shown, electric power is supplied to the motor (25) via an inverter. The rotation speed of the motor (25) is variable by changing the output frequency of the inverter.
[0057]
The air conditioning system (10) is further provided with a water tank (50), a water receiving pipe (51), a water supply pipe (52), and a collection pipe (58).
[0058]
The water receiving pipe (51) has an inlet end connected between the condensing heat exchanger (13) and the expander (23) in the air-side passage (11), and an outlet end connected to the water tank (50). It is connected. The condensed water generated in the condensing heat exchanger (13) is sent to the water tank (50) through the water receiving pipe (51). The water tank (50) stores the condensed water sent.
[0059]
The water supply pipe (52) has an inlet end connected to the water tank (50) and a water supply pump (53) for sucking up condensed water stored in the water tank (50). Further, the water supply pipe (52) is branched into four at the outlet end side thereof, and includes a fuel humidifier (77), a temperature control humidification heat exchanger (12), and a condensing heat exchanger in a cooling air passage. The upstream side of (13) and the evaporative cooling heat exchanger (14) are connected via electromagnetic valves (54, 55, 56, 57), respectively. The amount of condensed water supplied to the fuel humidifier (77) is controlled by operating the first solenoid valve (54), and the amount of condensed water supplied to the temperature controlled humidifying heat exchanger (12) is controlled by operating the second solenoid valve (55). The supply amount of the condensed water is controlled by operating the third electromagnetic valve (56), and the supply amount of the condensed water to the cooling air is controlled by operating the fourth electromagnetic valve (57). The supply amount of the condensed water to each varies.
[0060]
The air conditioning system (10) includes a temperature sensor (65) and a controller (60). The temperature sensor (65) is for measuring the temperature of the air electrode off-gas sent from the expander (23), and is provided immediately after the expander (23) in the air-side passage (11). I have. On the other hand, the controller (60) includes a first control unit (61) and a second control unit (62).
[0061]
The measurement value obtained by the temperature sensor (65), that is, the temperature of the air electrode off-gas at the outlet of the expander (23) is input to the first controller (61) of the controller (60). The first control unit (61) constitutes control means for controlling the operation of the air conditioning system (10) such that the input measurement value of the temperature sensor (65) is equal to or more than a predetermined value (for example, 0 ° C.). I have.
[0062]
The first control unit (61) is configured to appropriately perform three control operations to maintain the measurement value of the temperature sensor (65) at or above a predetermined value. Specifically, the first control unit (61) determines the proportion of the air electrode off-gas discharged from the fuel cell (70) that bypasses the condensation heat exchanger (13) by operating the second three-way valve (44). The adjustment operation is performed as a first control operation. The first control unit (61) performs an operation of adjusting the rotation speed of the cooling fan (30) to adjust the supply amount of the cooling air to the condensing heat exchanger (13), as a second control operation. Do as. Further, the first control unit (61) performs an operation of adjusting the amount of condensed water supplied to the cooling air by adjusting the opening of the third solenoid valve (56) as a third control operation.
[0063]
The second control unit (62) of the controller (60) adjusts the rotation speed of the motor (25) and the ratio of high-pressure air that bypasses the fuel cell (70) to the first three-way valve (62). The control means performs the operation of adjusting by the operation of 42). The operation of the second control unit (62) is performed in consideration of the output power required for the fuel cell (70) and the air conditioning load in the passenger compartment (80).
[0064]
-Driving operation-
The operation of the air conditioning system (10) will be described. The values of pressure, temperature, relative humidity and the like shown below are all examples.
[0065]
Atmospheric pressure (0.1 MPa) outside air taken into the air side passage (11) is sucked into the compressor (20) and compressed to a pressure of 0.28 MPa. The high-pressure air discharged from the compressor (20) is sent to a temperature control humidification heat exchanger (12).
[0066]
In the temperature control humidification heat exchanger (12), the high-pressure air exchanges heat with the outside air or the like, and its temperature becomes a value (for example, about 80 ° C.) suitable for the operation of the fuel cell (70). Further, condensed water is supplied to the temperature controlled humidification heat exchanger (12) from the water tank (50) through the water supply pipe (52). The temperature control humidification heat exchanger (12) humidifies the high-pressure air by spraying the supplied condensed water. The humidification of the high-pressure air in the temperature control humidification heat exchanger (12) is performed in order to increase the humidity of the high-pressure air in advance to keep the electrolyte membrane of the fuel cell (70) in a wet state.
[0067]
Assuming that the first three-way valve (42) is in a state of closing the first bypass passage (41) side, all of the high-pressure air whose temperature has been adjusted and humidified by the temperature-adjusting humidification heat exchanger (12) is completely removed. The air is introduced into the air electrode side gas flow path (72) of the fuel cell (70). In the air electrode side gas flow path (72), oxygen in the high-pressure air is consumed by the battery reaction. From the air electrode side gas flow path (72), a high temperature and high humidity air electrode off gas provided with water vapor generated by the battery reaction, specifically, an air electrode off gas having a temperature of 80 ° C. and a relative humidity of 90% or more is supplied. Is discharged.
[0068]
Assuming that the second three-way valve (44) closes the second bypass passage (43), all of the air electrode off-gas discharged from the fuel cell (70) is condensed heat exchanger (13). Is introduced to In the condensing heat exchanger (13), the air electrode off-gas is cooled by exchanging heat with the cooling air, and the water in the air electrode off-gas condenses to condensed water. At this time, the condensed water supplied from the water tank (50) through the water supply pipe (52) is sprayed in advance on the cooling air introduced into the condensing heat exchanger (13). For this reason, in the condensation heat exchanger (13), the condensed water sprayed on the cooling air absorbs heat from the air electrode off-gas and evaporates. That is, in the condensing heat exchanger (13), the air electrode off-gas is cooled using not only the sensible heat of the cooling air but also the latent heat of the condensed water sprayed on the cooling air. Then, an air electrode off-gas having a temperature of 40 ° C. and a relative humidity of 100% is sent out from the condensation heat exchanger (13).
[0069]
The air electrode off-gas sent from the condensation heat exchanger (13) flows into the expander (23). In the expander (23), the air electrode off-gas at a pressure of 0.28 MPa expands to a pressure of 0.1 MPa, and the internal energy of the air electrode off-gas is converted into rotational power of the drive shaft (24). The power recovered by the expander (23) is used together with the power obtained by the motor (25) to drive the compressor (20).
[0070]
In the expansion process of the expander (23), at the same time as the temperature of the air electrode off-gas decreases, the water vapor in the air electrode off-gas condenses to generate condensed water. The condensed water in the form of mist or fine droplets is sent out from the expander (23) together with the air electrode off-gas at a temperature of 2 ° C. and a relative humidity of 100%.
[0071]
The air electrode off-gas and the condensed water sent from the expander (23) are introduced into the evaporative cooling heat exchanger (14). Further, the condensed water in the water tank (50) is supplied to the evaporative cooling heat exchanger (14) as necessary. Furthermore, the supply air supplied into the cabin (80) is introduced into the evaporative cooling heat exchanger (14) through the supply side passage (35).
[0072]
In the evaporative cooling heat exchanger (14), the air electrode off-gas absorbs heat from the supplied air and rises in temperature, and the condensed water absorbs heat from the air electrode off-gas and evaporates. That is, in the evaporative cooling heat exchanger (14), the supply air is cooled using the sensible heat of the air electrode off-gas and the evaporative heat of the condensed water. The supply air cooled by the evaporative cooling heat exchanger (14) is supplied into the vehicle interior (80). On the other hand, water vapor generated by evaporating the air electrode off-gas and condensed water that has absorbed heat from the supply air is discharged outside the vehicle. Condensed water that has not evaporated in the evaporative cooling heat exchanger (14) is returned to the water tank (50) through the recovery pipe (58).
[0073]
−Control operation of controller−
First, the operation of the first control unit (61) of the controller (60) will be described. As described above, the measurement value obtained by the temperature sensor (65) is input to the first control unit (61). The first control unit (61) maintains the air electrode gas temperature at the outlet of the expander (23) at 0 ° C. or higher to prevent the condensed water generated in the expander (23) from freezing. The first to third control operations are appropriately selected, or the first to third control operations are appropriately combined.
[0074]
The first control unit (61) performs the first control operation to operate the second three-way valve (44), and to determine the amount of the air electrode off-gas flowing into the condensation heat exchanger (13) and the condensation heat exchanger (13). ) And the amount of air electrode off-gas bypassed. For example, if the measurement value obtained by the temperature sensor (65) is too low, the first control unit (61) cools the condensing heat exchanger (13) out of the air electrode off-gas sent to the expander (23). Reduce the percentage of things. Then, the temperature of the air electrode off-gas at the inlet of the expander (23) increases, and the temperature of the air electrode off-gas sent from the expander (23) also increases. On the other hand, when the measurement value obtained by the temperature sensor (65) is too high, the first control unit (61) determines whether the condensation heat exchanger ( 13) Increase the percentage of what is cooled. Then, the temperature of the air electrode off-gas at the inlet of the expander (23) decreases, and the temperature of the air electrode off-gas sent from the expander (23) also decreases.
[0075]
The first control unit (61) adjusts the supply amount of the cooling air to the condensation heat exchanger (13) by adjusting the rotation speed of the cooling fan (30) as a second control operation. Perform the operation. For example, when the measurement value obtained by the temperature sensor (65) is too low, the first control unit (61) reduces the supply amount of the cooling air to the condensation heat exchanger (13). Then, the temperature of the air electrode off-gas sent from the condensation heat exchanger (13) to the expander (23) increases, and the temperature of the air electrode off-gas sent from the expander (23) also increases. On the contrary, when the measurement value obtained by the temperature sensor (65) is too high, the first control unit (61) increases the supply amount of the cooling air to the condensation heat exchanger (13). Then, the temperature of the air electrode off-gas sent from the condensation heat exchanger (13) to the expander (23) decreases, and the temperature of the air electrode off-gas sent from the expander (23) also decreases.
[0076]
Further, the first control section (61) performs, as a third control operation, an operation of adjusting the amount of condensed water supplied to the cooling air. For example, when the measurement value obtained by the temperature sensor (65) is too low, the first control unit (61) reduces the supply amount of the condensed water to the cooling air. Then, the amount of condensed water used for cooling the air electrode off-gas in the condensing heat exchanger (13) decreases, and the temperature of the air electrode off-gas sent from the condensing heat exchanger (13) to the expander (23) increases. As a result, the temperature of the air electrode off-gas sent from the expander (23) also increases. On the contrary, when the measurement value obtained by the temperature sensor (65) is too high, the first control unit (61) increases the supply amount of the condensed water to the cooling air. Then, the amount of condensed water used for cooling the air electrode off-gas in the condensing heat exchanger (13) increases, and the temperature of the air electrode off-gas sent from the condensing heat exchanger (13) to the expander (23) decreases. As a result, the temperature of the air electrode off-gas sent from the expander (23) also decreases.
[0077]
As described above, when the first control unit (61) performs a predetermined control operation, the temperature of the air electrode off-gas at the outlet of the expander (23) changes, and the condensed water generated by the expander (23) freezes. Be avoided. Here, when the temperature of the air electrode off-gas at the outlet of the expander (23) changes, the temperature of the air electrode off-gas introduced into the evaporative cooling heat exchanger (14) also changes, and the evaporative cooling heat exchanger (14) changes the temperature. The resulting cooling capacity changes. Accordingly, the cooling operation can be adjusted by the control operation of the first control section (61).
[0078]
Next, the operation of the second control unit (62) of the controller (60) will be described.
[0079]
The second control unit (62) performs an operation of adjusting the rotation speed of the motor (25) by operating the output frequency of the inverter in order to adjust the amount of air sucked by the compressor (20). For example, if the cooling capacity obtained by the evaporative cooling heat exchanger (14) is excessive with respect to the cooling load of the cabin (80), the second control unit (62) sets the air intake amount of the compressor (20). Reduce. Then, the supply amount of the air electrode off-gas to the evaporative cooling heat exchanger (14) decreases, and the cooling capacity obtained by the evaporative cooling heat exchanger (14), that is, the cooling capacity, decreases. However, in this case, the air intake amount of the compressor (20) must be maintained at a value equal to or larger than the air amount necessary for the fuel cell (70) to generate the required electric power. On the other hand, if the cooling capacity obtained by the evaporative cooling heat exchanger (14) is too small for the cooling load of the vehicle compartment (80), the second control unit (62) sets the compressor (20). ) Increase the air intake volume. Then, the supply amount of the air electrode off-gas to the evaporative cooling heat exchanger (14) increases, and the cooling capacity obtained by the evaporative cooling heat exchanger (14), that is, the cooling capacity, increases.
[0080]
The second control section (62) operates the first three-way valve (42) to operate the amount of high-pressure air flowing into the fuel cell (70) and the amount of high-pressure air flowing into the first bypass passage (41). And adjust. That is, when the air intake amount of the compressor (20) is adjusted according to the cooling load of the vehicle compartment (80), the amount of high-pressure air required for the fuel cell (70) to generate the required power is: The supply amount of high-pressure air to the fuel cell (70) may be excessive. Therefore, in such a case, the second control unit (62) increases the amount of high-pressure air flowing into the first bypass passage (41) and changes the cooling capacity obtained by the evaporative cooling heat exchanger (14). Without reducing the supply of high-pressure air to the fuel cell (70).
[0081]
-Effects of Embodiment 1-
According to the first embodiment, not only the sensible heat of the air electrode off-gas expanded by the expander (23) but also the condensation generated by the expander (23) is used to cool the supply air in the evaporative cooling heat exchanger (14). The latent heat of water can also be used. Therefore, the amount of heat radiation of the supply air in the evaporative cooling heat exchanger (14) can be increased as compared with the case where only the sensible heat of the air electrode off-gas is used for cooling the supply air. Therefore, according to the present embodiment, the cooling capacity of the air conditioning system (10) can be increased as compared with the related art.
[0082]
This point will be described with reference to the psychrometric chart of FIG. Here, the state of the air electrode off-gas introduced into the evaporative cooling heat exchanger (14) is the state at point A (temperature 2 ° C., relative humidity 100%). The description will be made on the assumption that the temperature is increased to 21 ° C. after replacement.
[0083]
When only the sensible heat of the air electrode off-gas is used for cooling the supply air, the state of the air electrode off-gas at the outlet of the evaporative cooling heat exchanger (14) is the state at point B '(temperature 21 ° C., relative humidity 30%) It becomes. The cooling capacity obtained in this case is the specific enthalpy difference Q between the point B ′ and the point A. ₁ Is multiplied by the mass flow rate of the air electrode off-gas.
[0084]
On the other hand, when the sensible heat of the air electrode off-gas and the heat of evaporation of the condensed water are used for cooling the supply air, the state of the air electrode off-gas at the outlet of the evaporative cooling heat exchanger (14) is the state of point B Temperature 21 ° C., relative humidity 95%). The cooling capacity obtained in this case is the specific enthalpy difference Q between the point B and the point A. ₂ Is multiplied by the mass flow rate of the air electrode off-gas. Thus, according to the present embodiment, the enthalpy difference at the entrance and exit of the evaporative cooling heat exchanger (14) can be increased, and the cooling capacity of the air conditioning system (10) can be increased.
[0085]
Further, in the present embodiment, since the evaporative cooling heat exchanger (14) is disposed below the expander (23), the condensed water generated by the expander (23) is reliably sent to the air supply cooler. Becomes possible. Therefore, according to this embodiment, the heat of evaporation of the condensed water generated by the expander (23) can be reliably used for cooling the supply air in the evaporative cooling heat exchanger (14), and the air conditioning system (10) ) Can be sufficiently exhibited.
[0086]
Further, according to the present embodiment, the temperature of the air electrode off-gas at the outlet of the expander (23) can be reliably maintained at a predetermined value or more by the control operation performed by the first control unit (61) of the controller (60). It becomes possible. Here, depending on the operation state of the air conditioning system (10), the temperature of the air electrode off-gas at the outlet of the expander (23) may be considerably low (for example, about -10 ° C). In such a case, the condensed water generated in the expansion process in the expander (23) freezes, which may hinder the flow of the air electrode off-gas and hinder the operation of the air conditioning system (10). . On the other hand, according to the present embodiment, it is possible to maintain the temperature of the air electrode off-gas at the outlet of the expander (23) to such an extent that no problem occurs due to freezing of the condensed water. Therefore, according to the present embodiment, the operation of the air conditioning system (10) can be reliably continued.
[0087]
Further, according to the present embodiment, the control operation performed by the second control unit (62) of the controller (60) does not change the cooling capacity obtained by the evaporative cooling heat exchanger (14), and the fuel cell (70) does not change. ) Can be adjusted. Therefore, according to the present embodiment, for example, even when the operation of the fuel cell (70) is in a partial load state and the amount of high-pressure air to be supplied to the fuel cell (70) is small, the air-conditioning system (10) is exerted. Sufficient cooling capacity can be secured.
[0088]
-Modification of Embodiment 1-
As described above, in this embodiment, the temperature of the air electrode gas at the outlet of the expander (23) is kept at 0 ° C. or higher to prevent the condensed water from freezing. You don't have to. That is, even if the condensed water is frozen, if the ice generated by the freezing is snow-like fine particles, the particle-like ice can flow together with the air electrode off-gas. For this reason, depending on the structure and operating conditions of the expander (23), the operation of the air conditioning system (10) may be continued even if the condensed water is slightly frozen. Therefore, in such a case, the lower limit of the air electrode gas temperature at the outlet of the expander (23) is set lower than 0 ° C., and freezing of the condensed water is performed within a range where the operation of the air conditioning system (10) can be continued. May be tolerated.
[0089]
Further, in the present embodiment, the supply air cooled by the evaporative cooling heat exchanger (14) is supplied into the passenger compartment (80) for cooling, but the condensing heat exchanger (13) performs the air electrode off-gas. It is also possible to perform heating using cooling air that has exchanged heat with the air. That is, instead of the supply air cooled by the evaporative cooling heat exchanger (14), the cooling air heated by the condensing heat exchanger (13) is guided into the vehicle interior (80), and May be heated.
[0090]
Embodiment 2 of the present invention
The second embodiment of the present invention differs from the first embodiment in that a third bypass passage (45) is added to the air-side passage (11) and a third control unit (63) is added to the controller (60). is there. Here, differences between the present embodiment and the first embodiment will be described.
[0091]
As shown in FIG. 3, one end of the third bypass passage (45) is connected immediately before the expander (23), and the other end is connected immediately after the expander (23). The third bypass passage (45) is provided with a control valve (46) whose opening is variable. The control valve (46) controls the proportion of the air electrode off-gas sent out of the condensing heat exchanger (13) into the third bypass passage (45), and restricts and expands the air electrode off-gas (equal enthalpy). (Expansion).
[0092]
On the other hand, the third control unit (63) of the controller (60) adjusts the proportion of the air electrode off-gas sent out of the condensing heat exchanger (13) into the third bypass passage (45) by the control valve (46). ) Constitutes a control means for adjusting by the opening degree control. The third control unit (63) performs an opening operation of the control valve (46) to adjust the cooling capacity obtained by the evaporative cooling heat exchanger (14), that is, the cooling capacity of the air conditioning system (10). .
[0093]
For example, if the cooling capacity obtained by the evaporative cooling heat exchanger (14) is excessive with respect to the cooling load of the cabin (80), the third control unit (63) sends the evacuation cooling heat exchanger (14) to the evaporative cooling heat exchanger (14). The proportion of the air cathode off-gas that is expanded by the expander (23) is reduced. Then, since the temperature of the air electrode off-gas hardly changes when passing through the third bypass passage (45), the temperature of the air electrode off-gas flowing into the evaporative cooling heat exchanger (14) increases, and the evaporative cooling heat exchanger (14) The resulting cooling capacity is reduced. On the other hand, if the cooling capacity obtained by the evaporative cooling heat exchanger (14) is too small for the cooling load of the cabin (80), the third control unit (63) sets the evaporative cooling heat exchanger The proportion of the air electrode off-gas sent to the vessel (14) that is expanded by the expander (23) is increased. Then, the temperature of the air electrode off-gas flowing into the evaporative cooling heat exchanger (14) decreases, and the cooling capacity obtained by the evaporative cooling heat exchanger (14) increases.
[0094]
Third Embodiment of the Invention
Embodiment 3 of the present invention is different from Embodiment 1 in that two compressors (21, 22) are provided in the air-side passage (11). Here, differences between the present embodiment and the first embodiment will be described.
[0095]
As shown in FIG. 4, in the air-side passage (11) of the present embodiment, a first compressor (21) and a second compressor (22) are arranged in series. The first compressor (21) is connected to the motor (25). Electric power is supplied to this motor (25) via an inverter (not shown), as in the first embodiment. The first compressor (21) is driven only by the motor (25) and sucks and compresses outside air from outside the vehicle. On the other hand, the second compressor (22) is connected to the expander (23) via a drive shaft (24). The second compressor (22) is driven only by the power recovered by the expander (23), and sucks the air discharged from the first compressor (21) to further compress it. The high pressure air discharged from the second compressor (22) is supplied to the fuel cell (70).
[0096]
【The invention's effect】
According to the present invention, not only the sensible heat of the air electrode off-gas expanded by the expander (23) but also the latent heat of condensed water generated by the expander (23) is used for cooling the supply air in the air supply cooler (14). Can also be used. For this reason, compared with the case where only the sensible heat of the air electrode off-gas is used for cooling the supply air, the heat radiation amount of the supply air in the supply air cooler (14) can be increased. Therefore, according to the present invention, the cooling capacity of the automotive air conditioning system (10) can be increased as compared with the related art.
[0097]
According to the invention of claim 2, it is possible to reliably send the condensed water generated by the expander (23) to the air supply cooler (14). Therefore, according to the present invention, the heat of evaporation of the condensed water generated by the expander (23) can be reliably used for cooling the supply air in the supply air cooler (14), and the automotive air conditioning system (10) ) Can be sufficiently exhibited.
[0098]
According to the third to fifth and seventh aspects of the present invention, the condensed water generated by the condensing precooler (13) can be effectively used for the operation of the fuel cell (70) and the air conditioning system. In particular, according to the invention of claim 4, it is possible to use the condensed water generated in the condensing precooler (13) for cooling the supply air in the air supply cooler (14). According to each of the fifth and seventh aspects of the present invention, the temperature of the air electrode off-gas sent from the condensing precooler (13) to the expander (23) using the condensed water generated in the condensing precooler (13). Can be kept low, and the air electrode off-gas after expansion can be kept at a low temperature. Therefore, according to the fourth, fifth and seventh aspects of the present invention, the condensed water generated by the condensing pre-cooler (13) can be used to sufficiently secure the cooling capacity of the air conditioning system.
[0099]
According to each of the eighth to eleventh aspects, the temperature of the air electrode off-gas at the outlet of the expander (23) can be reliably maintained at a predetermined value or more by the control operation of the control means (61). Here, depending on the operation state of the automotive air conditioning system (10), the temperature of the air electrode off-gas at the outlet of the expander (23) may be considerably low (for example, about -10 ° C). In such a case, the condensed water generated in the expansion process in the expander (23) freezes and forms a large mass, which hinders the flow of the air electrode off-gas and hinders the operation of the automotive air conditioning system (10). May come. On the other hand, according to each of the above-mentioned inventions, it is possible to maintain the temperature of the air electrode off-gas at the outlet of the expander (23) to such an extent that no problem occurs due to freezing of the condensed water. Therefore, according to these inventions, it is possible to reliably continue the operation of the automotive air conditioning system (10).
[0100]
According to the twelfth aspect, the cooling capacity exerted by the automotive air conditioning system (10) can be accurately adjusted by the operation of the control means (63). Therefore, according to the present invention, the cooling capacity of the vehicle air conditioning system (10) can be adjusted according to the cooling load of the vehicle compartment, and the comfort of the vehicle compartment can be further improved.
[0101]
According to the thirteenth aspect, the control means (62) performs a predetermined operation, so that the high-pressure air is supplied to the fuel cell (70) without changing the cooling capacity obtained by the air supply cooler (14). The feed rate can be adjusted. Therefore, according to the present invention, for example, even when the operation of the fuel cell (70) is in a partial load state and the amount of high-pressure air to be supplied to the fuel cell (70) is small, the automotive air-conditioning system (10) can be used. The cooling capacity to be exhibited can be sufficiently secured.
[0102]
According to the fourteenth and fifteenth aspects, the power recovered by the expander (23) can be used for driving the compressor (20). Therefore, according to these inventions, the energy to be supplied from the outside to compress the air can be reduced, and the efficiency of the automotive air conditioning system (10) can be improved.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of an air conditioning system according to a first embodiment.
FIG. 2 is a psychrometric chart for explaining effects of the first embodiment.
FIG. 3 is a schematic configuration diagram of an air conditioning system according to a second embodiment.
FIG. 4 is a schematic configuration diagram of an air conditioning system according to a third embodiment.
[Explanation of symbols]
(13) Condensing heat exchanger (condensing precooler)
(14) Evaporative cooling heat exchanger (air supply cooler)
(20) Compressor
(21) First compressor (first compressor)
(22) Second compressor (second compressor)
(23) Expander
(41) First bypass passage (bypass passage)
(43) Second bypass passage (bypass passage)
(45) Third bypass passage (bypass passage)
(50) Water tank
(61) First control unit (control means)
(62) Second control unit (control means)
(63) Third control unit (control means)
(65) Temperature sensor
(70) Fuel cell

Claims (15)

An air conditioning system mounted on an automobile powered by a fuel cell (70),
A compressor (20) for compressing air supplied to the fuel cell (70);
A condensing pre-cooler (13) for cooling the air electrode off-gas discharged from the fuel cell (70) and condensing moisture in the air electrode off-gas;
An expander (23) for recovering power by expanding the air electrode off-gas sent from the condensation precooler (13);
The air electrode off-gas after expansion and condensed water generated in the expansion process are supplied from the expander (23), and the sensible heat of the supplied air electrode off-gas and the heat of evaporation of the condensed water are supplied to the vehicle interior. An air conditioning system for a vehicle, comprising: a supply air cooler (14) for cooling supply air. The vehicle air conditioning system according to claim 1,
The supply air cooler (14) is an automotive air conditioning system arranged below the expander (23) such that condensed water generated by the expander (23) flows by gravity. The vehicle air conditioning system according to claim 1,
An air conditioning system for automobiles, which is capable of humidifying air supplied from a compressor (20) to a fuel cell (70) by using condensed water generated by a condensation precooler (13). The vehicle air conditioning system according to claim 1,
An automotive air conditioning system in which condensed water generated by a condensing pre-cooler (13) is supplied to an air supply cooler (14), and the heat of evaporation of the condensed water can also be used for cooling supply air. The vehicle air conditioning system according to claim 4,
A water tank (50) for storing condensed water generated by the condensing precooler (13);
An automotive air-conditioning system in which condensed water that has not evaporated in the supply air cooler (14) can be collected in the water tank (50). The vehicle air conditioning system according to claim 1,
The condensing pre-cooler (13) is an automotive air conditioning system that cools the air electrode off-gas by exchanging heat with cooling air. The automotive air conditioning system according to claim 6,
An automotive air conditioning system in which the condensed water generated by the condensing precooler (13) is supplied to cooling air, and the heat of evaporation of the condensed water can be used for cooling the air electrode off-gas. The vehicle air conditioning system according to claim 1,
A temperature sensor (65) for measuring the temperature of the air electrode off-gas sent from the expander (23),
A vehicle air conditioning system comprising: a control unit (61) for performing a control operation for controlling operation of the vehicle air conditioning system such that a value measured by the temperature sensor (65) becomes a predetermined value or more. The vehicle air conditioning system according to claim 8,
The upstream and downstream of the condensing precooler (13) are communicated so that the cathode pregas bypasses the condensing precooler (13), and the condensing precooler ( 13) a bypass passage (43) capable of changing the ratio of bypasses,
The control means (61) is an automotive air conditioning system in which an operation of adjusting a ratio of an air electrode off-gas discharged from the fuel cell (70) that bypasses the condensation precooler (13) is performed as a control operation. The vehicle air conditioning system according to claim 8,
The condensing precooler (13) cools the air electrode off-gas by exchanging heat with cooling air,
The control unit (61) is an air conditioning system for an automobile in which an operation of adjusting a supply amount of cooling air to the condensation precooler (13) is performed as a control operation. The vehicle air conditioning system according to claim 8,
The condensing precooler (13) cools the air electrode off-gas by exchanging heat with cooling air,
The condensed water generated by the condensing precooler (13) is supplied to cooling air, and the heat of evaporation of the condensed water can be used for cooling the air electrode off-gas,
The control means (61) is an automotive air conditioning system in which the operation of changing the supply amount of condensed water to the cooling air is performed as a control operation. The vehicle air conditioning system according to claim 1,
The upstream and downstream sides of the expander (23) are communicated so that the air electrode off-gas bypasses the expander (23), and the expander (23) of the air electrode off-gas sent from the condensing precooler (13) is used. A bypass passage (45) capable of changing the ratio of the one that bypasses the
Control means for adjusting the proportion of the air electrode off-gas which is delivered from the condensation pre-cooler (13) and which bypasses the expander (23), in order to adjust the cooling capacity obtained by the charge air cooler (14) (63) An air conditioning system for automobiles comprising: The vehicle air conditioning system according to claim 1,
The high-pressure air discharged from the compressor (20) communicates upstream and downstream of the fuel cell (70) so as to bypass the fuel cell (70), and bypasses the fuel cell (70) of the high-pressure air. A bypass passage (41) capable of changing the proportion of objects;
The amount of air taken in by the compressor (20) is adjusted so that a predetermined cooling capacity is obtained by the air supply cooler (14), and the proportion of the high-pressure air that bypasses the fuel cell (70) is adjusted. A vehicle air-conditioning system comprising a control means (62) for adjusting the amount of power generation required for the fuel cell (70). The vehicle air conditioning system according to claim 1,
An automotive air conditioning system in which an expander (23) is directly connected to a compressor (20) by a drive shaft (24) and uses power recovered by the expander (23) to drive the compressor (20). The vehicle air conditioning system according to claim 1,
While a plurality of compressors (21, 22) are provided,
The first compressor (21) supplies compressed air driven by only the power obtained by the electric motor to the second compressor (22),
The second compressor (22) is an automotive air conditioning system that is driven only by the power recovered by the expander (23) and supplies compressed air to the fuel cell (70).

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