JP2020187940A - Fuel cell system - Google Patents

Abstract

To provide a fuel cell system in which waste-heat from fuel cells is available for heating operation.SOLUTION: A fuel cell system includes a fuel cell 11, a refrigeration heat transfer medium pump 61, a radiator 64, a refrigeration passage part 69, a heat exchanger 75 for warming, a passage part 79 for warming, and warming adjustment parts 71, 72. The fuel cell system includes a control section for controlling the fuel cell and the warming adjustment parts. The control section includes a heat utilization control section for controlling the warming adjustment parts so as to feed refrigeration heat transfer medium to the passage part for warming, in the heat utilization mode, and controlling the warming adjustment parts so as not to feed refrigeration heat transfer medium to the passage part for warming, in the standby mode. The control section includes a power generation control section for controlling power generation of the fuel cells so that the target temperature of the fuel cell in the heat utilization mode becomes higher than the target temperature of the fuel cell in the standby mode. With such an arrangement, a fuel cell system in which waste-heat from fuel cells is available for heating operation can be obtained.SELECTED DRAWING: Figure 7

Description

The disclosure herein relates to a fuel cell system.

Patent Document 1 discloses a fuel cell system that uses the heat generated by the fuel cell as a heat source. In this fuel cell system, the calorific value is controlled by controlling the current target value and the voltage target value of the fuel cell, and the heat generated by the fuel cell via the cooling medium is used as the heat source of the heating device. There is. Further, this fuel cell system has a plurality of modes having different power generation efficiencies. The contents of the prior art document are incorporated by reference as an explanation of the technical elements in this specification.

JP-A-2009-32605

In the structure of the prior art document, the calorific value of the fuel cell is controlled so as to generate heat of the calculated required calorific value. Here, when the fuel cell is deprived of heat from the surroundings, the temperature of the fuel cell itself or the temperature of the cooling medium may not rise as expected. Therefore, depending on the surrounding conditions of the fuel cell, even if the amount of heat generated from the fuel cell is appropriate, the heat required for the heat source of the heating device may not be supplied. Further improvements are required in the fuel cell system in the above-mentioned viewpoint or in other viewpoints not mentioned.

One object disclosed is to provide a fuel cell system in which the exhaust heat of the fuel cell can be used for heating operation.

The fuel cell system disclosed here includes a fuel cell (11) that is cooled by heat exchange with a cooling heat medium, a heat medium pump (61) that circulates the cooling heat medium, a cooling heat medium, and air. A radiator (64) that cools the cooling heat medium by exchanging heat between the two, and a cooling flow path portion (69) that connects the fuel cell, the heat medium pump, and the radiator to form a flow path portion through which the cooling heat medium circulates. ), A heating heat exchanger (75) that can be used as a heat source when performing heating operation, and a high temperature flow path portion (69h) that is a portion from the fuel cell to the radiator in the cooling flow path portion. A heating flow path portion (79) forming a flow path portion through which the cooling heat medium flows to the heating heat exchanger, and a heating adjustment unit (71) that controls the amount of the cooling heat medium flowing through the heating flow path portion. , 72) and a control unit (90) that controls the fuel cell and the heating adjustment unit, and the control unit is for heating in the heat utilization mode, which is a mode in which the exhaust heat from the fuel cell is used for the heating operation. In the standby mode, which is a mode in which the heating adjustment unit is controlled so that the cooling heat medium flows through the flow path and the exhaust heat from the fuel cell is not used for the heating operation, the cooling heat medium is flowed through the heating flow path. The heat utilization control unit (91) that controls the heating adjustment unit so as not to be present, and the fuel cell power generation are controlled so that the target temperature of the fuel cell in the heat utilization mode is higher than the target temperature of the fuel cell in the standby mode. It is equipped with a power generation control unit (93).

According to the disclosed fuel cell system, a power generation control unit that controls power generation of the fuel cell so that the target temperature of the fuel cell in the heat utilization mode becomes higher than the target temperature of the fuel cell in the standby mode is provided. Therefore, the temperature of the fuel cell in the heat utilization mode can be made higher than the temperature of the fuel cell in the standby mode. Therefore, in the heat utilization mode, the exhaust heat of the fuel cell having a higher temperature than that in the standby mode can be supplied to the heating heat exchanger via the cooling heat medium. Therefore, it is possible to provide a fuel cell system in which the exhaust heat of the fuel cell can be used for heating operation.

The disclosed aspects of this specification employ different technical means to achieve their respective objectives. The claims and the reference numerals in parentheses described in this section exemplify the correspondence with the parts of the embodiments described later, and are not intended to limit the technical scope. The objectives, features, and effects disclosed herein will be made clearer by reference to the subsequent detailed description and accompanying drawings.

It is a block diagram which shows the fuel cell system. It is a block diagram concerning the control of a fuel cell system. It is a flowchart about heating operation of a fuel cell system. It is explanatory drawing for demonstrating the flow of the cooling water in the standby mode when the battery cooling is not performed. It is explanatory drawing for demonstrating the flow of cooling water in the standby mode at the time of battery cooling. It is a flowchart of step S110 of FIG. It is explanatory drawing for demonstrating the flow of cooling water in a heat utilization mode when battery cooling is not performed. It is explanatory drawing for demonstrating the flow of cooling water in a heat utilization mode at the time of battery cooling. It is a flowchart about the heating operation of the fuel cell system in 2nd Embodiment.

A plurality of embodiments will be described with reference to the drawings. In a plurality of embodiments, functionally and / or structurally corresponding parts and / or associated parts may be designated with the same reference code or reference codes having a hundreds or more different digits. References can be made to the description of other embodiments for the corresponding and / or associated parts.

The first embodiment the fuel cell system 1 is mounted on, for example, a fuel cell hybrid vehicle (FCHV) and generates electric power to be supplied to a traveling motor. In addition, as a stationary fuel cell system, electricity and heat are taken out at the same time to supply hot water and heat. In the following, a case where the fuel cell system 1 is used as the fuel cell system 1 for a vehicle mounted on a vehicle will be described as an example.

The fuel cell system 1 is a system that generates electricity by a chemical reaction between a fuel gas and an oxidant gas in a fuel cell. In the following, a case where hydrogen is used as the fuel gas and air containing oxygen is used as the oxidant gas will be described as an example.

In FIG. 1, the fuel cell system 1 includes a fuel cell 11, a hydrogen supply unit 20, a hydrogen decompression unit 30, an air supply unit 50, an FC cooling unit 60, and a heating utilization unit 70. The fuel cell 11 includes a fuel cell. The fuel cell is configured to have a positive electrode on one surface of an electrolyte membrane capable of transmitting hydrogen ions and a negative electrode on the other surface. The fuel cell is a polymer electrolyte fuel cell that generates electricity by a chemical reaction by supplying air containing oxygen that functions as an oxidant to the positive electrode and hydrogen that functions as a reducing agent to the negative electrode. The fuel cell 11 is configured such that a plurality of fuel cell cells overlap each other via a separator. The fuel cell 11 is also called FC or FC stack.

The hydrogen supply unit 20 is a part for supplying hydrogen as a fuel to the fuel cell 11 in the fuel cell system 1. The hydrogen supply unit 20 includes a filling unit 21 and a hydrogen storage unit 25. The filling portion 21 is a portion forming a filling port which is an opening that functions as an inlet for hydrogen when the fuel cell system 1 is filled with hydrogen from the hydrogen station. The hydrogen storage unit 25 is a device for storing high-pressure hydrogen. The hydrogen storage unit 25 has a plurality of tanks.

The hydrogen supply unit 20 includes a filling flow path unit 29u that connects the filling unit 21 and the hydrogen storage unit 25 to provide a hydrogen flow path unit. The filling flow path portion 29u includes a distribution portion 22 for distributing and flowing hydrogen into each of the plurality of tanks. The distribution unit 22 is provided with a filling side pressure sensor 22p for measuring the pressure of hydrogen.

The hydrogen supply unit 20 includes a high-pressure flow path unit 29d that forms a part of a flow path unit for supplying hydrogen from the hydrogen storage unit 25 toward the fuel cell 11. The high-pressure flow path portion 29d includes a tank on-off valve 26 for controlling the flow of hydrogen between the hydrogen storage portion 25 and the fuel cell 11. The tank on-off valve 26 is an electrically driven valve whose opening degree can be electrically controlled. The tank on-off valve 26 is also called a tank shut valve. The high-pressure flow path portion 29d includes a merging portion 28 for merging hydrogen flowing out from a plurality of tanks toward the fuel cell 11. The merging portion 28 is provided with a high pressure sensor 28p for measuring the pressure of hydrogen.

The hydrogen decompression unit 30 is provided between the hydrogen supply unit 20 and the fuel cell 11. The hydrogen decompression unit 30 is a portion for reducing the pressure of hydrogen in the process of supplying hydrogen to the fuel cell 11 in the fuel cell system 1. The hydrogen decompression unit 30 includes two decompression devices, a regulator 31 and an injector 35.

The regulator 31 is a device that reduces the high-pressure hydrogen flowing through the high-pressure flow path portion 29d to a medium pressure that is lower than the high pressure. The regulator 31 is a mechanical drive valve that keeps the pressure difference between the upstream side and the downstream side of the regulator 31 at a predetermined value. However, as the regulator 31, an electric drive valve whose opening degree can be electrically controlled may be used to electrically control the pressure difference between the upstream side and the downstream side.

The injector 35 is a device that reduces the pressure of hydrogen that has become medium pressure by the regulator 31 to a low pressure that is lower than the medium pressure. The injector 35 is configured by arranging a plurality of electric drive valves whose opening degree can be electrically controlled in parallel. The injector 35 is composed of, for example, three electrically driven valves. The injector 35 functions as a device for controlling the amount of hydrogen flowing through the fuel cell 11. In other words, when the amount of hydrogen consumed by the fuel cell 11 is small, the number of valves in the injector 35 to be opened is reduced. On the other hand, when the amount of hydrogen consumed by the fuel cell 11 is large, the number of valves to be opened is increased among the valves constituting the injector 35. In this way, the amount of hydrogen flowing into the fuel cell 11 is controlled by controlling the number of valves to be opened among the plurality of valves constituting the injector 35.

The hydrogen decompression unit 30 includes a medium pressure flow path portion 39u that connects the high pressure flow path portion 29d and the injector 35 to provide a hydrogen flow path portion. The regulator 31 is located on the boundary between the high pressure flow path portion 29d and the medium pressure flow path portion 39u. The medium pressure flow path portion 39u is provided with a medium pressure sensor 33p for measuring the pressure of hydrogen.

The hydrogen decompression unit 30 includes a low pressure flow path portion 39d that connects the medium pressure flow path portion 39u and the fuel cell 11 to provide a hydrogen flow path portion. The injector 35 is located on the boundary between the medium pressure flow path portion 39u and the low pressure flow path portion 39d. The low pressure flow path portion 39d is provided with a low pressure sensor 36p for measuring the pressure of hydrogen.

In the fuel cell system 1, hydrogen flows toward the fuel cell 11 in the order of the high pressure flow path portion 29d, the medium pressure flow path portion 39u, and the low pressure flow path portion 39d while gradually reducing the pressure. However, the pressure of hydrogen is not limited to the case where the pressure drops in three stages of high pressure, medium pressure and low pressure.

The fuel cell system 1 includes a hydrogen circulation unit that circulates hydrogen that has not been used in the chemical reaction in the fuel cell 11. The hydrogen circulation unit includes a hydrogen pump 41 and a drain valve 43. The hydrogen pump 41 is a fluid transport device for sucking hydrogen flowing out from the fuel cell 11 and returning it to the low pressure flow path portion 39d. The hydrogen pump 41 is an electric pump whose output magnitude can be electrically controlled. The drain valve 43 is a device for draining water generated by a chemical reaction between hydrogen and oxygen in the fuel cell 11. When draining water, the drain valve 43 may also exhaust some hydrogen at the same time as draining. The hydrogen pump 41 provides an example of an auxiliary machine.

The hydrogen circulation section includes a hydrogen circulation flow path section 49 that connects the fuel cell 11, the hydrogen pump 41, and the drain valve 43 to allow a fluid such as hydrogen to flow. The hydrogen circulation flow path portion 49 connects the hydrogen and water outflow portion of the fuel cell 11 to the low pressure flow path portion 39d to form a flow path portion in which the fluid circulates.

The air supply unit 50 is a part for supplying air containing oxygen, which is an oxidizing agent, to the fuel cell 11 in the fuel cell system 1. The air supply unit 50 includes an air cleaner 51 and an air compressor 52. The air cleaner 51 is a device for removing foreign matter contained in air. A filter is provided inside the air cleaner 51 to remove foreign matter from the air passing through the air cleaner 51. The air compressor 52 is a device that compresses the sucked air and sends it to the fuel cell 11. The air compressor 52 is an electric compressor capable of electrically controlling operation control. The air compressor 52 provides an example of an auxiliary machine.

The air supply unit 50 includes an air flow path unit 59 that connects the fuel cell 11, the air cleaner 51, and the air compressor 52 to allow a fluid such as air to flow. The air flow path portion 59 includes a flow path portion for supplying air to the fuel cell 11 and a flow path portion for discharging the air flowing through the fuel cell 11 to the outside. A muffler 58 is provided in a portion of the air flow path portion 59 until the air flowing through the fuel cell 11 is discharged to the outside. The muffler 58 is a device for appropriately discharging a fluid from the inside to the outside of the fuel cell system 1.

The portion of the air flow path portion 59 until the air flowing through the fuel cell 11 is discharged to the outside is connected to the drain valve 43. Therefore, after the water and hydrogen drained from the drain valve 43 and the air flowing through the fuel cell 11 merge, they pass through the muffler 58 and are discharged to the outside.

The air flow path portion 59 includes a hydrogen dilution flow path portion that allows air to flow through the muffler 58 without passing through the fuel cell 11. The air flow path portion 59 is provided with a shunt valve 53 that controls the amount of air flowing through the hydrogen dilution flow path portion. The shunt valve 53 increases the amount of air flowing through the hydrogen dilution flow path when the amount of hydrogen discharged from the drain valve 43 is large. As a result, the hydrogen discharged from the muffler 58 to the outside is diluted to prevent the concentration of hydrogen discharged to the outside from becoming too high. A pressure regulating valve 54 is provided in the air flow path portion 59. The amount of air supplied to the fuel cell 11 is adjusted by controlling the opening degree of the pressure adjusting valve 54. The shunt valve 53 and the pressure regulating valve 54 are electrically driven valves whose opening degree can be electrically controlled. The shunt valve 53 provides an example of an auxiliary machine. The pressure regulating valve 54 provides an example of an auxiliary machine.

The air flow path portion 59 is provided with an intake air temperature sensor 51t that measures the temperature of the intake air that is the air compressed by the air compressor 52. The intake air temperature sensor 51t is provided on the upstream side of the air flow with respect to the air cleaner 51. The air flow meter 59 is provided with an air flow meter 51s for measuring the amount of intake air flowing. The air flow meter 51s is provided between the air cleaner 51 and the air compressor 52.

The FC cooling unit 60 is a portion of the fuel cell system 1 for cooling the fuel cell 11 that generates heat as a result of power generation. The FC cooling unit 60 includes a cooling water pump 61, a radiator 64, and a blower 66. The cooling water pump 61 is a pump for flowing cooling water through the fuel cell 11. The cooling water pump 61 is an electric pump whose output magnitude can be electrically controlled. The cooling water provides an example of a cooling heat medium. Instead of the cooling water, a refrigerant that cools the fuel cell 11 by utilizing the phase change between the gas phase and the liquid phase may be used as the cooling heat medium. Further, the cooling heat medium is not limited to a liquid such as cooling water, and a gas may be used. The cooling water pump 61 provides an example of a heat medium pump. The cooling water pump 61 provides an example of an auxiliary machine.

The radiator 64 is a device for cooling the cooling water by exchanging heat between the cooling water and air. The blower 66 is a device that controls the amount of air flowing through the radiator 64 to control the cooling effect of the cooling water by the radiator 64. The blower 66 is an electric blower whose rotation speed can be electrically controlled. The blower 66 provides an example of an auxiliary machine.

The FC cooling unit 60 includes a cooling flow path unit 69 that connects the fuel cell 11, the cooling water pump 61, and the radiator 64 in a ring shape. The cooling flow path portion 69 includes a bypass flow path portion 69i for circulating the cooling water to the fuel cell 11 without passing through the radiator 64. The bypass flow path portion 69i is provided with a bypass valve 63 that controls the amount of cooling water flowing through the bypass flow path portion 69i. The bypass valve 63 provides an example of an auxiliary machine.

The cooling flow path portion 69 is provided with a high temperature temperature sensor 62t on the downstream side of the flow of cooling water from the fuel cell 11 and on the upstream side of the bypass valve 63. The high temperature temperature sensor 62t is a sensor that measures the temperature of the cooling water that has become hot due to heat exchange with the fuel cell 11 that is a heat generating component. The temperature of the fuel cell 11 can be estimated from the temperature measured by the high temperature temperature sensor 62t. The cooling flow path portion 69 is provided with a low temperature temperature sensor 65t on the downstream side of the flow of cooling water with respect to the radiator 64 and on the upstream side of the connection portion of the cooling flow path portion 69 with the bypass flow path portion 69i. ing. The low temperature temperature sensor 65t is a sensor that measures the temperature of the cooling water that has become cold due to heat exchange with the radiator 64. The temperature of the radiator 64 can be estimated from the temperature measured by the low temperature temperature sensor 65t.

The heating utilization unit 70 is a portion of the fuel cell system 1 for utilizing the exhaust heat of the fuel cell 11 that generates heat with power generation for the heating operation. The heating utilization unit 70 includes a heating pump 72, an electric heater 73, and a heating heat exchanger 75. The heating pump 72 is a pump for flowing cooling water through the heating heat exchanger 75. The heating pump 72 is an electric pump whose output magnitude can be electrically controlled. The electric heater 73 is a heating device for heating the cooling water. The electric heater 73 can control the magnitude of the output by controlling the magnitude of the electric current. The heating pump 72 provides an example of an auxiliary machine. The heating pump 72 provides an example of a heating adjusting unit. The electric heater 73 provides an example of an auxiliary machine.

The heating heat exchanger 75 is a device for heating the blown air by exchanging heat between the cooling water and the blown air toward the room. However, the heating heat exchanger 75 does not have to directly heat the blown air. For example, when a heating system having a heater core for heating in which engine cooling water flows inside is provided separately from the fuel cell system 1, heat exchange is performed by exchanging heat between liquids in the heating heat exchanger 75. Can be used as a vessel. In this case, the heating heat exchanger 75 functions as a heat exchanger that exchanges heat between the engine cooling water that cools the engine and the cooling water that cools the fuel cell 11.

The heating utilization unit 70 includes a heating flow path unit 79 that connects the heating pump 72, the electric heater 73, and the heat exchanger 75 for heating. The heating flow path portion 79 is connected to the high temperature flow path portion 69h, which is a portion of the cooling flow path portion 69 from the fuel cell 11 to the radiator 64. In other words, the cooling water can flow from the high temperature flow path portion 69h into the heating flow path portion 79, and the cooling water that has flowed through the heating flow path portion 79 can flow into the high temperature flow path portion 69h again. The heating flow path portion 79 includes an annular connection flow path portion 79r that connects the heating flow path portion 79 in an annular shape. The annular connection flow path portion 79r is provided with a heating valve 71 that controls the amount of cooling water flowing through the annular connection flow path portion 79r. In other words, the heating valve 71 is a valve device that switches whether or not cooling water flows through the annular connection flow path portion 79r. The heating valve 71 is a valve device that switches whether or not to guide the cooling water flowing through the cooling flow path portion 69 to the heating flow path portion 79. The heating valve 71 provides an example of an auxiliary machine. The heating valve 71 provides an example of a heating adjusting unit.

The cooling flow path portion 69 is provided with a heating temperature sensor 74t on the downstream side of the flow of cooling water from the electric heater 73 and on the upstream side of the heating heat exchanger 75. The heating temperature sensor 74t is a sensor that measures the temperature of the cooling water that has become hot due to being heated by the fuel cell 11 or the electric heater 73. The heating temperature sensor 74t is a sensor that measures the temperature of the cooling water immediately before flowing into the heating heat exchanger 75.

The flow of power generation in the fuel cell system 1 will be described below. When starting power generation in the fuel cell 11, the tank on-off valve 26 is opened so that the hydrogen stored in the hydrogen storage unit 25 can flow out from the hydrogen storage unit 25. The high-pressure hydrogen flowing out of the hydrogen storage unit 25 is decompressed by the regulator 31 to reach a medium pressure state. After that, the medium-pressure hydrogen is depressurized by the injector 35 and becomes a low-pressure state. The low pressure hydrogen is supplied to the negative electrode of the fuel cell 11.

Further, when the fuel cell 11 starts power generation, the air compressor 52 is driven to supply the compressed air to the positive electrode of the fuel cell 11. Inside the fuel cell 11, the supplied hydrogen and air cause a chemical reaction between hydrogen and oxygen to generate electricity. At this time, the fuel cell 11 also generates heat as electricity is generated.

A part of the hydrogen flowing into the fuel cell 11 is used for a chemical reaction in the fuel cell 11 to generate water. Of the hydrogen that has flowed into the fuel cell 11, the hydrogen that has not been used for the chemical reaction in the fuel cell 11 circulates in the hydrogen circulation flow path 49 and flows into the fuel cell 11 again. The fluid containing water generated by the chemical reaction, hydrogen not used in the reaction, and the like passes through the muffler 58 and flows out to the outside of the fuel cell system 1.

When power generation is not performed, the tank on-off valve 26 and the injector 35 are closed and the hydrogen supply from the hydrogen storage unit 25 is stopped. Further, the driving of the hydrogen pump 41 and the air compressor 52 is stopped. As a result, the recirculation of hydrogen and the supply of oxygen to the fuel cell 11 are stopped.

When the temperature of the fuel cell 11 exceeds the cooling start temperature, the cooling water pump 61 is driven to start cooling the fuel cell 11. At this time, the bypass valve 63 is controlled so that the cooling water flows through the radiator 64. Further, the blower 66 is controlled to flow air to the radiator 64. As a result, the cooling water that has cooled the fuel cell 11 and whose temperature has risen can be cooled by the radiator 64 to lower the temperature, and then flowed back to the fuel cell 11.

FIG. 2 is a diagram showing a control system. The control device (ECU) in this specification may also be referred to as an electronic control unit (Electronic Control Unit). The control device is provided by (a) an algorithm as a plurality of logics called if-then-else form, or (b) a trained model tuned by machine learning, for example, an algorithm as a neural network.

The control device is provided by a control system that includes at least one computer. The control system may include multiple computers linked by data communication equipment. The computer includes at least one hardware processor, which is a processor of hardware. The hardware processor can be provided by (i), (ii), or (iii) below.

(I) The hardware processor may be at least one processor core that executes a program stored in at least one memory. In this case, the computer is provided by at least one memory and at least one processor core. The processor core is called a CPU: Central Processing Unit, a GPU: Graphics Processing Unit, RISC-CPU, or the like. Memory is also called a storage medium. Memory is a non-transitional and substantive storage medium that non-temporarily stores "programs and / or data" that can be read by a processor. The storage medium is provided by a semiconductor memory, a magnetic disk, an optical disk, or the like. The program may be distributed by itself or as a storage medium in which the program is stored.

(Ii) The hardware processor may be a hardware logic circuit. In this case, the computer is provided by a digital circuit that includes a large number of programmed logic units (gate circuits). The digital circuit is a logic circuit array, for example, ASIC: Application-Specific Integrated Circuit, FPGA: Field Programmable Gate Array, PGA: Programmable Gate Array, CPLD: Complex Program, etc. Digital circuits may include memory for storing programs and / or data. Computers may be provided by analog circuits. Computers may be provided by a combination of digital and analog circuits.

(Iii) The hardware processor may be a combination of the above (i) and the above (ii). (I) and (ii) are arranged on different chips or on a common chip. In these cases, the part (ii) is also called an accelerator.

Control devices, signal sources, and controlled objects provide various elements. At least some of those elements can be called blocks, modules, or sections. Moreover, the elements contained in the control system are called functional means only when intentionally.

The controls and techniques described in this disclosure are realized by a dedicated computer provided by configuring a processor and memory programmed to perform one or more functions embodied by a computer program. You may. Alternatively, the controls and methods thereof described in this disclosure may be implemented by a dedicated computer provided by configuring the processor with one or more dedicated hardware logic circuits. Alternatively, the controls and techniques described in this disclosure combine a processor and memory programmed to perform one or more functions with a processor composed of one or more hardware logic circuits. It may be realized by one or more dedicated computers configured by. Further, the computer program may be stored in a computer-readable non-transitional tangible recording medium as an instruction executed by the computer.

In FIG. 2, each pressure sensor 22p, 28p, 33p, 36p, each temperature sensor 51t, 62t, 65t, 74t, and an air flow meter 51s are connected to the control unit 90. The control unit 90 acquires the filling side pressure measured by the filling side pressure sensor 22p. The control unit 90 acquires the high pressure on the supply side measured by the high pressure sensor 28p. The control unit 90 acquires the medium pressure supply side pressure measured by the medium pressure sensor 33p. The control unit 90 acquires the low pressure on the supply side measured by the low pressure sensor 36p. The control unit 90 acquires the intake air temperature measured by the intake air temperature sensor 51t. The control unit 90 acquires the cooling water temperature immediately after the fuel cell 11 is discharged, which is measured by the high temperature temperature sensor 62t. The control unit 90 acquires the cooling water temperature immediately after the radiator 64 is discharged, which is measured by the low temperature temperature sensor 65t. The control unit 90 acquires the temperature of the cooling water immediately before flowing into the heating heat exchanger 75 measured by the heating temperature sensor 74t. The control unit 90 acquires the intake air flow rate measured by the air flow meter 51s.

Pumps 61 and 72, a bypass valve 63, a blower 66, a heating valve 71, and an electric heater 73 are connected to the control unit 90. The control unit 90 controls the cooling water pump 61 to control the amount of cooling water flowing through the cooling flow path unit 69. The control unit 90 controls the heating pump 72 to control the amount of cooling water flowing through the heating flow path portion 79. The control unit 90 controls the opening degree of the bypass valve 63 to control the amount of cooling water flowing through the bypass flow path unit 69i. The control unit 90 controls the blower 66 to control the amount of air flowing through the radiator 64. The control unit 90 controls the opening degree of the heating valve 71 to control the amount of cooling water flowing through the heating flow path unit 79. The control unit 90 controls the output of the electric heater 73 to control the temperature of the cooling water flowing through the heating flow path unit 79.

An air conditioning sensor 81 and an air conditioning switch 82 are connected to the control unit 90. The air conditioning sensor 81 is a sensor that acquires information necessary for air conditioning operation. The air conditioning sensor 81 includes, for example, an outside air temperature sensor that measures the outside air temperature. The air-conditioning sensor 81 includes, for example, an indoor temperature sensor that measures the temperature inside the vehicle interior, which is an air-conditioning target space. The air conditioning sensor 81 includes, for example, a solar radiation amount sensor for measuring the amount of solar radiation. The air conditioning switch 82 is a switch for the user to set the air conditioning operation. The air conditioning switch 82 includes, for example, a switch for switching on / off of an air conditioning operation request. The air conditioning switch 82 includes, for example, a switch for switching a set temperature in air conditioning operation. The air conditioning switch 82 includes, for example, a switch for switching the air volume in the air conditioning operation. The air conditioning switch 82 includes, for example, a switch for switching between an inside air circulation mode and an outside air introduction mode in air conditioning operation.

The fuel cell 11, the tank on-off valve 26, the injector 35, and the hydrogen pump 41 are connected to the control unit 90. The control unit 90 controls the fuel cell 11 to control the amount of power generation and the amount of heat generated. The control unit 90 controls the opening degree of the tank on-off valve 26 to control the amount of hydrogen supplied to the fuel cell 11. The control unit 90 controls the injector 35 to control the amount of hydrogen supplied to the fuel cell 11. The control unit 90 controls the hydrogen pump 41 to control the amount of hydrogen circulating in the hydrogen circulation flow path unit 49.

An air compressor 52, a shunt valve 53, and a pressure regulating valve 54 are connected to the control unit 90. The control unit 90 controls the air compressor 52 to control the amount of air supplied to the fuel cell 11. The control unit 90 controls the shunt valve 53 to control the amount of air supplied to the fuel cell 11. The control unit 90 controls the pressure adjusting valve 54 to control the amount of air supplied to the fuel cell 11.

A battery 88 is connected to the control unit 90. The battery 88 is a device for storing the electric energy generated by the fuel cell 11 and the regenerative energy generated when the vehicle decelerates. The control unit 90 acquires the remaining capacity stored in the battery 88. Further, the control unit 90 discharges the battery 88 and charges the battery 88. Here, the remaining capacity indicates the ratio of the charge amount currently stored to the battery capacity that the battery 88 can store. For example, when the remaining capacity is 50%, half of the battery capacity of the battery 88 is stored. When the remaining capacity is less than the target remaining capacity, the fuel cell 11 generates electricity to charge the battery 88. On the other hand, when the remaining capacity is equal to or larger than the target remaining capacity, the fuel cell 11 basically does not generate electricity, and the battery 88 discharges the traveling motor or the like and charges the regenerative energy. The remaining capacity is also referred to as SOC (System Of Charge).

The control unit 90 includes a heat utilization control unit 91, a determination unit 92, and a power generation control unit 93. The control unit 90 can execute the heating operation in the heat utilization mode using the exhaust heat from the fuel cell 11 by using the heat utilization control unit 91, the determination unit 92, and the power generation control unit 93. The heat utilization control unit 91 controls the opening degree of the heating valve 71, the driving of the heating pump 72, and the like. The determination unit 92 makes a determination to determine the control content based on the information acquired by each sensor and the calculated information. The power generation control unit 93 controls the presence / absence of power generation and the amount of power generation of the fuel cell 11.

The heating operation in the fuel cell system 1 will be described below. In FIG. 3, when it is determined that there is a request for a heating operation using the fuel cell 11 as a heat source, the heating operation using the fuel cell 11 is started. When the heating operation is started, the value of each sensor is acquired in step S101. More specifically, in order to grasp the amount of power generated by the fuel cell 11 and the temperature of the fuel cell 11, information about the fuel cell 11 is acquired. Further, in order to grasp the state of the heating operation, the air conditioning sensor 81 is used to acquire information such as the temperature inside the vehicle interior. After acquiring the value of each sensor, the process proceeds to step S102.

In step S102, it is determined whether or not the exhaust heat of the fuel cell 11 can be used for heating. Whether or not the exhaust heat of the fuel cell 11 can be used is determined by whether or not various stop conditions are satisfied. An example of the stop condition is whether or not the impedance of the fuel cell 11 is equal to or higher than a predetermined value. When the impedance of the fuel cell 11 is equal to or higher than a predetermined value, it can be determined that the fuel cell 11 does not have an appropriate amount of water and is in a dry state. If power generation is continued in a dry state of the fuel cell 11, the deterioration of the fuel cell 11 becomes severe. Therefore, when the impedance of the fuel cell 11 is equal to or higher than a predetermined value, it is necessary to stop the power generation, and it is determined that the stop condition is satisfied.

An example of the stop condition is whether or not the high load state in which the calorific value of the fuel cell 11 is equal to or higher than a predetermined value is continuously continued for a predetermined time. When the high load state of the fuel cell 11 is continuously continued for a predetermined time, it can be determined that the temperature of the fuel cell 11 may rise too much and the fuel cell 11 may not be driven properly. Therefore, when the high load state of the fuel cell 11 is continuously continued for a predetermined time, it is necessary to stop the power generation, and it is determined that the stop condition is satisfied.

An example of the stop condition is whether or not the temperature of the radiator 64 is equal to or higher than a predetermined temperature. When the temperature of the radiator 64 is high, it can be determined that the ability to cool the fuel cell 11 is insufficient. Therefore, when the temperature of the radiator 64 is equal to or higher than the predetermined temperature, it is necessary to stop the power generation, and it is determined that the stop condition is satisfied. The temperature of the radiator 64 is measured using a low temperature temperature sensor 65t.

An example of the stop condition is whether or not the outside air temperature is equal to or higher than a predetermined temperature. When the outside air temperature is high, it can be determined that the required heating capacity can be obtained without executing the heat utilization mode utilizing the exhaust heat of the fuel cell 11. Therefore, when the outside air temperature is equal to or higher than the predetermined temperature, it is determined that the stop condition is satisfied. If it is determined that the exhaust heat of the fuel cell 11 can be used for heating, the process proceeds to step S110. On the other hand, if it is determined that the exhaust heat of the fuel cell 11 cannot be used for heating, the process proceeds to step S130. In other words, if it is determined that the stop condition is not satisfied, the process proceeds to step S110, and if it is determined that the stop condition is satisfied, the process proceeds to step S130.

In step S130, the standby mode is executed. The standby mode is a mode in which the exhaust heat of the fuel cell 11 is not used for the heating operation. FIG. 4 shows the flow of cooling water in the FC cooling unit 60 and the heating utilization unit 70 in the standby mode when the fuel cell 11 is at a low temperature. In other words, it is a figure for demonstrating the standby mode when battery cooling is not performed. In the cooling flow path portion 69 and the heating flow path portion 79 in the figure, the portion shown by the solid line indicates the portion through which the cooling water is flowing. On the other hand, the portion shown by the broken line indicates the portion where the cooling water does not flow.

Since the temperature of the fuel cell 11 is low, it is not necessary for the FC cooling unit 60 to cool the fuel cell 11, and the cooling water pump 61 is not driven. In other words, the cooling water is not flowing through the cooling flow path portion 69. On the other hand, in order to perform the heating operation, the opening degree of the heating valve 71 is controlled so that the cooling water flows through the annular connection flow path portion 79r. Further, the heating pump 72 and the electric heater 73 are driven. As a result, the high-temperature cooling water heated by the electric heater 73 can be circulated in the heating flow path portion 79, and the heating heat exchanger 75 can function as a heat source for the heating operation.

The standby mode when the fuel cell 11 has a low temperature may be executed when a stop condition such as, for example, the outside air temperature is equal to or higher than a predetermined temperature is satisfied. In the standby mode when the fuel cell 11 is at a low temperature, the fuel cell 11 is not cooled, so that the fuel cell 11 can be warmed up while performing the heating operation.

FIG. 5 shows the flow of cooling water in the FC cooling unit 60 and the heating utilization unit 70 in the standby mode when the fuel cell 11 has a high temperature. In other words, it is a figure for demonstrating the standby mode in the case of performing battery cooling. In the cooling flow path portion 69 and the heating flow path portion 79 in the figure, the portion shown by the solid line indicates the portion through which the cooling water is flowing. On the other hand, the portion shown by the broken line indicates the portion where the cooling water does not flow.

Since the temperature of the fuel cell 11 is high, it is necessary to cool the fuel cell 11 by the FC cooling unit 60, and the cooling water pump 61 is driven. Further, the opening degree of the bypass valve 63 is controlled so that the cooling water does not flow into the bypass flow path portion 69i. As a result, the cooling water can continue to cool the fuel cell 11 by repeating the cycle in which the cooling water cools the fuel cell 11 and then is cooled by the radiator 64. On the other hand, the opening degree of the heating valve 71 is controlled so that the cooling water flows into the annular connection flow path portion 79r without guiding the cooling water from the cooling flow path portion 69. Further, by driving the heating pump 72 and the electric heater 73, the high-temperature cooling water heated by the electric heater 73 is circulated in the heating flow path portion 79, and the heating heat exchanger 75 is used for heating operation. It can function as a heat source.

The standby mode when the fuel cell 11 has a high temperature may be executed when a stop condition such that the impedance of the fuel cell 11 is equal to or higher than a predetermined value is satisfied. In the standby mode when the fuel cell 11 has a high temperature, the cooling of the fuel cell 11 and the heating operation using the heating heat exchanger 75 as a heat source are performed independently. Therefore, the cooling capacity of the fuel cell 11 is not easily affected by the heating operation. In other words, by controlling the output of the cooling water pump 61 and the rotation speed of the blower 66, the FC cooling unit 60 can easily exert the cooling capacity required for the fuel cell 11 appropriately. After executing the standby mode, the process proceeds to step S131.

In step S110 of FIG. 3, the heat utilization mode is executed. The heat utilization mode is a mode in which the exhaust heat generated by driving the fuel cell 11 is utilized for the heating operation. The details of the heat utilization mode will be described in detail later. After executing the heat utilization mode, the process proceeds to step S121.

In step S121, the amount of power generated by the fuel cell 11 is acquired. In the heat utilization mode, the heat generated by the power generation of the fuel cell 11 is used for the heating operation, so that the fuel cell 11 is generating electricity. After acquiring the amount of power generation, the process proceeds to step S122.

In step S122, it is determined whether or not the amount of power generation is excessive. Whether or not the amount of power generation is excessive is determined in consideration of the amount of power generated by the fuel cell 11, the remaining capacity of the power stored in the battery 88, and the amount of power consumed by the entire vehicle. To do. More specifically, when the remaining capacity of the battery 88 has reached the target remaining capacity and the amount of power generation exceeds the amount of power consumption, if the current amount of power generation is continued, the power cannot be consumed appropriately. Can be judged. In this case, it is determined that the amount of power generation is excessive, and the process proceeds to step S123. On the other hand, when the amount of power generation is less than the amount of power consumption, it can be judged that the power can be consumed appropriately even if the current amount of power generation is continued. In this case, it is determined that the amount of power generation is not excessive, and the process proceeds to step S131.

In step S123, the power consumption of the auxiliary machine is increased. An example of a method of increasing the power consumption of the auxiliary machine is to increase the output of the electric heater 73. In this case, the current flowing through the electric heater 73 is made larger than the current flowing through the electric heater 73 in the standby mode to increase the power consumption of the electric heater 73. Alternatively, when a plurality of electric heaters 73 are provided, the power consumption may be increased by increasing the number of electric heaters 73 through which an electric current flows. According to this, it is possible to increase the power consumption and raise the temperature of the cooling water flowing through the heating heat exchanger 75 to increase the heating capacity.

An example of a method of increasing the power consumption of the auxiliary machine is to increase the output of the blower 66. In this case, the power consumption of the blower 66 is increased by lengthening the rotation speed and the driving time of the blower 66. According to this, it is possible to increase the power consumption and increase the amount of air flowing through the radiator 64 to lower the temperature of the cooling water inside the radiator 64 more quickly. At this time, the upper limit rotation speed of the blower 66 may be set higher than in the normal state in which the power consumption of the auxiliary machine is not increased. When the upper limit rotation speed of the blower 66 is set higher than that in the normal state, it is preferable to increase the output of the electric blower for blowing air into the room during the air conditioning operation. According to this, the loud driving sound due to the high rotation of the blower 66 can be masked by the blowing sound of the air conditioner air blown into the room. Therefore, it is possible to prevent the indoor comfort from being lowered by the driving sound of the blower 66.

An example of a method of increasing the power consumption of the auxiliary machine is to increase the output of the cooling water pump 61. In this case, the discharge amount of the cooling water pump 61 is increased to increase the power consumption of the cooling water pump 61. According to this, if the battery is cooled, the battery can be cooled more effectively. When the battery is not cooled, the opening degree of the bypass valve 63 is controlled so as to flow through the bypass flow path portion 69i, so that the cooling water pump of the radiator 64 keeps the cooling water cold. The power consumption at 61 can be increased.

An example of a method of increasing the power consumption of the auxiliary machine is to increase the output of the hydrogen pump 41 and the output of the air compressor 52. Alternatively, the shunt valve 53, the pressure regulating valve 54, and the bypass valve 63 are opened and closed. Alternatively, it is to increase the output of a light source such as a headlight or an interior light. Alternatively, the output of the electric fan for sending wind into the room during air conditioning operation is increased. In this case, headlights, interior lights, electric fans, and the like provide an example of auxiliary equipment. After increasing the power consumption of the auxiliary machine, the process proceeds to step S131.

In step S131, the on / off of the heating request is determined. When the heating operation is turned off by the operation of the air conditioning switch 82 by the user, it can be determined that the heating request is off. Alternatively, when the vehicle cannot travel due to the operation of the key switch by the user, it can be determined that the heating request is off. Alternatively, if it is determined that the heating operation does not need to be continued any more because the target temperature is reached as a result of the heating operation, it can be determined that the heating request is off. If it is determined that the heating request is off, the heating operation is terminated.

When the heating operation is turned on by the operation of the air conditioning switch 82 by the user, it can be determined that the heating request is on. Further, in the automatic air conditioning mode or the like, when it is determined that the heating operation is necessary to maintain the set temperature regardless of the user's operation, it can be determined that the heating request is on. If it is determined that the heating request is on, the process returns to step S101 to continue a series of heating operations.

The control in the heat utilization mode will be described below. In FIG. 6, when the heat utilization mode is executed, power generation is started in step S111. That is, hydrogen and oxygen are supplied to the fuel cell 11 to cause a chemical reaction to obtain electric energy. The target temperature of the fuel cell 11 in the heat utilization mode is at least a temperature higher than the target temperature of the fuel cell 11 in the standby mode. For example, when the target temperature of the fuel cell 11 in the standby mode is 60 ° C., the target temperature of the fuel cell 11 in the heat utilization mode is set to 65 ° C., which is higher than 60 ° C.

Further, the target temperature of the fuel cell 11 in the heat utilization mode is a temperature higher than the target temperature of the heating heat exchanger 75. For example, when the target temperature of the heating heat exchanger 75 is 60 ° C., the target temperature of the fuel cell 11 is set to 65 ° C., which is higher than 60 ° C. Here, the specific value of the target temperature is a value that changes depending on the set temperature of the heating operation, the room temperature, the outside air temperature, the amount of solar radiation, and the like, and is not limited to the above-mentioned specific value. Further, in consideration of heating by the electric heater 73, the target temperature of the fuel cell 11 may be set to a temperature lower than the target temperature of the heating heat exchanger 75.

The calorific value of the fuel cell 11 is set to be equal to or greater than the calorific value required to complete the heating operation by the heating heat exchanger 75. Here, the amount of heat required to complete the heating operation can be calculated from information such as the target temperature, the current room temperature, and the heat capacity of the room to be heated. By securing a large amount of overshoot, which is an amount of heat that exceeds the amount of heat required to complete the heating operation, it is easy to complete the heating in a short time. However, in consideration of heating by the electric heater 73, the calorific value of the fuel cell 11 may be set to a value less than the calorific value required to complete the heating operation. After starting the power generation, the process proceeds to step S112.

In step S112, the battery temperature is acquired. Since the fuel cell 11 has started power generation, the temperature of the fuel cell 11 changes due to heat generated by the power generation. After acquiring the changing battery temperature, the process proceeds to step S113.

In step S113, it is determined whether or not the battery temperature is lower than the predetermined temperature. If the battery temperature is lower than the predetermined temperature, it is determined that the fuel cell 11 is in a low temperature state that does not require battery cooling, and the process proceeds to step S114. On the other hand, if the battery temperature is equal to or higher than the predetermined temperature, it is determined that the fuel cell 11 is in a high temperature state requiring battery cooling, and the process proceeds to step S115.

In step S114, a heating connection is performed. In the heating connection, the opening degree of the heating valve 71 is controlled so as to guide the cooling water flowing through the cooling flow path portion 69 to the heating flow path portion 79. Further, since the cooling operation is not performed, the opening degree of the bypass valve 63 is controlled so that the cooling water flows through the bypass flow path portion 69i. In this state, the cooling water pump 61 and the heating pump 72 are driven. However, if a sufficient amount of cooling water circulation can be secured by driving only one of the cooling water pump 61 and the heating pump 72, only one of them may be driven.

FIG. 7 shows the flow of cooling water in the FC cooling unit 60 and the heating utilization unit 70 in the state of being connected to heating. In other words, it is a figure for demonstrating the heat utilization mode when the battery cooling is not performed. In the cooling flow path portion 69 and the heating flow path portion 79 in the figure, the portion shown by the solid line indicates the portion through which the cooling water is flowing. On the other hand, the portion shown by the broken line indicates the portion where the cooling water does not flow.

The cooling water sent from the cooling water pump 61 is heated by the exhaust heat of the fuel cell 11 and then flows into the heating flow path portion 79. The cooling water is heated by the electric heater 73 in the process of flowing through the heating flow path portion 79, and the temperature further rises. However, if the amount of heat required for the heating operation can be covered only by heating by the exhaust heat of the fuel cell 11, it is not necessary to heat the fuel cell 73 with the electric heater 73. The high-temperature cooling water that has passed through the electric heater 73 exchanges heat with the air sent into the room in the process of flowing through the heating heat exchanger 75 to generate hot air for heating. The cooling water whose temperature has dropped due to heat exchange with air returns to the cooling flow path portion 69, flows through the bypass flow path portion 69i, is sucked into the cooling water pump 61 again, and is sent toward the fuel cell 11. The cooling water is cooled by the heating heat exchanger 75 in the process of flowing through the flow path, but the temperature tends to be relatively high. In other words, it is easy to effectively heat the heat exchanger 75 for heating. After executing the heating connection, the process proceeds to step S116.

In step S115 of FIG. 6, both battery cooling and heating connection are performed. In this case, the opening degree of the heating valve 71 is controlled so as to guide the cooling water flowing through the cooling flow path portion 69 to the heating flow path portion 79. Further, in order to perform the cooling operation, the opening degree of the bypass valve 63 is controlled so that the cooling water does not flow into the bypass flow path portion 69i. In this state, the cooling water pump 61 and the heating pump 72 are driven. However, if a sufficient amount of cooling water circulation can be secured by driving only one of the cooling water pump 61 and the heating pump 72, only one of them may be driven.

FIG. 8 shows the flow of cooling water in the FC cooling unit 60 and the heating utilization unit 70 in a state where the battery cooling and the heating connection are performed at the same time. In other words, it is a figure for demonstrating the heat utilization mode in the case of performing battery cooling. In the cooling flow path portion 69 and the heating flow path portion 79 in the figure, the portion shown by the solid line indicates the portion through which the cooling water is flowing. On the other hand, the portion shown by the broken line indicates the portion where the cooling water does not flow.

The cooling water sent from the cooling water pump 61 is heated by the exhaust heat of the fuel cell 11 and then flows toward the heating flow path portion 79. The cooling water is heated by the electric heater 73 in the process of flowing through the heating flow path portion 79, and the temperature further rises. However, if the amount of heat required for the heating operation can be covered only by heating the fuel cell 11 by exhaust heat, the electric heater 73 does not have to heat the fuel cell 11. The high-temperature cooling water that has passed through the electric heater 73 exchanges heat with the air sent into the room in the process of flowing through the heating heat exchanger 75 to generate hot air for heating. The cooling water whose temperature has dropped due to heat exchange with air returns to the cooling flow path portion 69, is cooled by the radiator 64, is sucked into the cooling water pump 61 again, and is sent toward the fuel cell 11. Since the cooling water is cooled by the heating heat exchanger 75 and the radiator 64 in the process of flowing through the flow path, the temperature tends to be lower than when the battery is not cooled. In other words, it is easy to properly cool the fuel cell 11. After executing the battery cooling and heating connection, the process proceeds to step S116.

In step S116 of FIG. 6, it is determined whether or not the high heat generation condition is satisfied. Here, the high heat generation condition is a condition for determining whether or not to reduce the power generation efficiency of the fuel cell 11 and secure a large amount of heat generation. An example of a high heat generation condition is a temperature difference between the temperature on the heat source side, which is the temperature of the cooling water immediately after flowing out of the fuel cell 11, and the temperature on the utilization side, which is the temperature of the cooling water immediately before flowing into the heat exchanger 75 for heating. Is more than or equal to the predetermined temperature difference. When the temperature difference between the heat source side temperature and the utilization side temperature is equal to or greater than the predetermined temperature difference, it is determined that it is necessary to secure a large amount of heat generation in the fuel cell 11, and it is determined that the high heat generation condition is satisfied. To do. On the other hand, when the temperature difference between the heat source side temperature and the utilization side temperature is less than the predetermined temperature difference, it is determined that it is not necessary to secure a large amount of heat generation in the fuel cell 11, and the high heat generation condition is not satisfied. Is determined.

An example of the high heat generation condition is whether or not the temperature of the fuel cell 11 is lower than the high heat generation allowable temperature set below the target temperature. The high heat generation allowable temperature is, for example, a temperature set to be about 5 ° C. lower than the target temperature of the fuel cell 11. If the temperature of the fuel cell 11 is lower than the high heat generation permitted temperature, it is determined that there is still room for raising the temperature of the fuel cell 11 from the present, and it is determined that the high heat generation condition is satisfied. On the other hand, if the temperature of the fuel cell 11 is equal to or higher than the high heat generation permitted temperature, it is determined that there is not much room left to raise the temperature of the fuel cell 11 from the present level, and it is determined that the high heat generation condition is not satisfied. Here, the high heat generation allowable temperature may be set to the same temperature as the target temperature.

An example of the high heat generation condition is whether or not the remaining capacity of the battery 88 is equal to or greater than the predetermined remaining capacity. Here, the predetermined remaining capacity is a value set to be equal to or less than the target remaining capacity. If the remaining capacity is equal to or greater than the predetermined remaining capacity, it is considered that the current remaining capacity is already close to the target remaining capacity. Therefore, it is determined that it is necessary to generate a large amount of heat with a small amount of power generation, and it is determined that the high heat generation condition is satisfied. On the other hand, if the remaining capacity of the battery 88 is less than the predetermined remaining capacity, it is considered that there is still a margin from the current remaining capacity to the target remaining capacity. Therefore, it is determined that it is preferable to continue high-efficiency power generation, and it is determined that the high heat generation condition is not satisfied. If it is determined that the high heat generation condition is satisfied, the process proceeds to step S117. On the other hand, if it is determined that the high heat generation condition is not satisfied, the process proceeds to step S118.

In step S117, the high heat generation mode is executed. The high heat generation mode is a mode in which the amount of heat generated is kept high instead of keeping the power generation efficiency of the fuel cell 11 low. In other words, the high heat generation mode is a low efficiency power generation mode in which the amount of power obtained is small relative to the amount of heat generated. Specifically, the opening degree of the pressure adjusting valve 54 is controlled to reduce the amount of air supplied to the fuel cell 11. As a result, the supply amount of oxygen required for the chemical reaction between hydrogen and oxygen can be reduced to inhibit the chemical reaction. In other words, the current value at a predetermined voltage value decreases, so that the power generation efficiency decreases. The method of reducing the amount of air supplied to the fuel cell 11 is not limited to the opening degree control of the pressure regulating valve 54. For example, the amount of air supplied to the fuel cell 11 may be reduced by reducing the amount of air discharged from the air compressor 52.

By generating electricity in the high heat generation mode, which generates a large amount of heat, more heat can be obtained in a short time as compared with the case where power generation is performed in the low heat generation mode. Therefore, the heating time required to reach the target temperature can be shortened, and the user's comfort can be easily improved. After executing the high heat generation mode, the control of the heat utilization mode is terminated while maintaining the high heat generation mode.

In step S118, the low heat generation mode is executed. The low heat generation mode is a mode in which the amount of heat generated is kept low by maintaining high power generation efficiency in the fuel cell 11. In other words, the low heat generation mode is a high efficiency power generation mode in which a large amount of electric power is obtained with respect to the amount of heat generated. Specifically, the amount of air supplied to the fuel cell 11 and the amount of hydrogen are set to the optimum amount. In other words, it is in a state where the power generation efficiency is higher than that in the high heat generation mode.

By generating electricity in a low heat generation mode with high power generation efficiency, the consumption of hydrogen, which is a fuel, can be kept low. Therefore, by shortening the time for executing the high heat generation mode and securing a long time for executing the low heat generation mode, the vehicle can travel a long distance. After executing the low heat generation mode, the control of the heat utilization mode is terminated while maintaining the low heat generation mode.

According to the above-described embodiment, the power generation control unit 93 for controlling the power generation of the fuel cell 11 so that the target temperature of the fuel cell 11 in the heat utilization mode becomes higher than the target temperature of the fuel cell 11 in the standby mode is provided. .. Therefore, when heating is performed using the exhaust heat of the fuel cell 11, it is easy to perform the heating operation by utilizing a large amount of the exhaust heat of the fuel cell 11. Therefore, the temperature of the air-conditioned space can be quickly brought close to the target temperature. In particular, since the target temperature of the fuel cell 11 is controlled, the exhaust heat of the fuel cell 11 can be easily used for the heating operation as compared with the case of controlling the calorific value of the fuel cell 11.

In the heat utilization mode, the heating valve 71 is controlled so that the cooling water flows from the cooling flow path portion 69 to the heating flow path portion 79, and in the standby mode, the cooling flow path portion 69 is cooled to the heating flow path portion 79. It is provided with a heat utilization control unit 91 that controls a heating valve 71 and a heating pump 72 so that water does not flow. Therefore, the heating operation can be executed properly depending on whether the heating is performed by using the exhaust heat of the fuel cell 11 or the heating is performed without using the exhaust heat of the fuel cell 11. By heating using the exhaust heat of the fuel cell 11, the heat discarded as the exhaust heat can be effectively utilized in the heating operation. On the other hand, by heating without utilizing the exhaust heat of the fuel cell 11, the fuel cell 11 is thermally affected by the heating operation, and the cooling capacity of the fuel cell 11 is insufficient to control the temperature of the fuel cell 11. It is possible to suppress the situation where the above cannot be performed properly.

The target temperature of the fuel cell 11 in the heat utilization mode is higher than the target temperature of the heating heat exchanger 75. Therefore, by raising the temperature of the fuel cell 11 to the target temperature, the temperature of the cooling water heated by the fuel cell 11 tends to be higher than the temperature required when the temperature reaches the heating heat exchanger 75. Therefore, the amount of heat generated by the electric heater 73 or the like other than the exhaust heat of the fuel cell 11 can be reduced. Further, since the heating capacity can be changed by changing the size of the exhaust heat of the fuel cell 11, the dedicated parts used for the heating operation such as the electric heater 73 can be miniaturized or reduced.

The calorific value of the fuel cell 11 in the heat utilization mode is equal to or greater than the calorific value required to complete the heating operation by the heating heat exchanger 75. Therefore, the amount of heat generated other than the exhaust heat of the fuel cell 11 can be reduced. A large amount of heat can be generated by the fuel cell 11, and the temperature of the air-conditioned space can reach the target temperature in a short time. In particular, when the heat utilization mode can be executed by switching between the high heat generation mode and the low heat generation mode, a large amount of heat can be generated in a short time by using the high heat generation mode to secure the heat required for heating. Therefore, it is possible to quickly switch to the low heat generation mode with high power generation efficiency after the high heat generation mode. Therefore, it is easy to secure a short time for executing the high heat generation mode with low power generation efficiency and a long time for executing the low heat generation mode with high power generation efficiency.

The control unit 90 controls the auxiliary machine so that the power consumption of the auxiliary machine in the heat utilization mode is larger than the power consumption of the auxiliary machine in the standby mode. Therefore, it is easy to appropriately use the electric power generated by the heat generated by the fuel cell 11 in the auxiliary machine. Therefore, it is possible to suppress the limitation of heat generation of the fuel cell 11 due to the inability to consume the electric power generated by the fuel cell 11.

The control unit 90 controls the electric heater 73 so that the output of the electric heater 73 in the heat utilization mode is larger than the output of the electric heater 73 in the standby mode. Therefore, heating can be promoted by using the generated electric power while generating heat in the fuel cell 11 for heating. Therefore, heating can be performed quickly to the target temperature.

The control unit 90 controls the blower 66 so that the output of the blower 66 in the heat utilization mode is larger than the output of the blower 66 in the standby mode. Therefore, the temperature of the cooling water inside the radiator 64 can be lowered by using the generated electric power while generating heat in the fuel cell 11 for heating. Therefore, the fuel cell 11 can be cooled while generating heat in the fuel cell 11. In particular, when a control that temporarily consumes a large amount of electric power such as a sudden start or sudden acceleration of a vehicle is performed, the amount of power generated by the fuel cell 11 may increase and the temperature of the fuel cell 11 may rise sharply. .. Therefore, it is very important to store low-temperature cooling water that can quickly cool the fuel cell 11 inside the radiator 64 when the fuel cell system 1 is mounted on a vehicle.

The control unit 90 controls the opening degree of the bypass valve 63 so that the amount of cooling water flowing through the bypass flow path portion 69i in the heat utilization mode is larger than the amount of cooling water flowing through the bypass flow path portion 69i in the standby mode. To do. Therefore, in the heat utilization mode, among the heat generated by the fuel cell 11, the heat radiated from the radiator 64 can be reduced. Therefore, most of the heat generated by the fuel cell 11 can be used for the heating operation.

When the control unit 90 determines that the high heat generation condition is satisfied in the heat utilization mode, it controls the fuel cell 11 in the high heat generation mode, and when it determines that the high heat generation condition is not satisfied, the control unit 90 controls the fuel cell 11. , The fuel cell 11 is controlled in the low heat generation mode. Therefore, the high heat generation mode and the low heat generation mode can be appropriately used to quickly and efficiently perform the heating operation in the heat utilization mode.

When the temperature of the fuel cell 11 is lower than the high heat generation allowable temperature in the heat utilization mode, the control unit 90 controls the fuel cell 11 in the high heat generation mode, and the temperature of the fuel cell 11 is equal to or higher than the high heat generation permission temperature. In some cases, the fuel cell 11 is controlled in the low heat generation mode. Therefore, the heating operation can be completed quickly by using the high heat generation mode. In addition, the low heat generation mode, which is a mode with high power generation efficiency, can be used to perform heating operation while maintaining high efficiency power generation. In particular, if the temperature of the fuel cell 11 is lower than the high heat generation allowable temperature, there is a large room for the temperature of the fuel cell 11 to rise. Therefore, by using the high heat generation mode, the temperature of the fuel cell 11 can be raised in a short time. , Easy to increase heating capacity quickly.

The control unit 90 executes the standby mode when the determination unit 92 determines that the stop condition is satisfied. Therefore, when the heat utilization mode should not be executed, the failure of the fuel cell 11 and the unnecessary deterioration of the power generation efficiency of the fuel cell 11 can be suppressed by executing the standby mode.

Second Embodiment This embodiment is a modification based on the preceding embodiment as a basic embodiment. In this embodiment, the target remaining capacity of the battery 88 is increased when it is determined that the amount of power generation is excessive. A portion different from the above-described embodiment will be described with reference to FIG. In FIG. 9, the same step number is assigned to the same process as in FIG. 3 of the above-described embodiment. Therefore, it can be applied with reference to the above-described embodiment.

After starting the heating operation, control at each step is executed. When the heat utilization mode is being executed and it is determined in step S122 that the amount of power generated by the fuel cell 11 is excessive, the process proceeds to step S223.

In step S223, the charge control of the battery 88 is changed. More specifically, the target remaining capacity, which is the target value of the remaining capacity of the battery 88, is increased. For example, when the amount of power generation is not excessive or the target remaining capacity in the standby mode is 50%, the target remaining capacity is increased to 70%. By increasing the target remaining capacity, a large amount of electric power generated by the fuel cell 11 can be stored in the battery 88. However, the specific value for increasing the target remaining capacity is not limited to the above-mentioned value. After increasing the target remaining capacity, the process proceeds to step S131 to determine whether the heating request is on or off.

In step S223, the target remaining capacity of the battery 88 may be increased and the auxiliary power consumption may be increased. According to this, the amount of electric power generated by the fuel cell 11 stored in the battery 88 can be increased, and the electric power consumption in the auxiliary machine can be increased. Therefore, it is easy to secure energy used for heating by continuing power generation and heat generation by the fuel cell 11.

According to the above-described embodiment, the control unit 90 controls the battery 88 so that the target remaining capacity of the battery 88 in the heat utilization mode is larger than the target remaining capacity of the battery 88 in the standby mode. Therefore, more electric power generated by the fuel cell 11 can be stored in the battery 88. Therefore, by appropriately storing the electric power generated by the fuel cell 11 in the battery 88, it is easy to continue the power generation and heat generation in the fuel cell 11. Therefore, it is easy to secure a long time during which the heat utilization mode can be executed.

In step S223, the charge output to the battery 88 may be increased instead of increasing the target remaining capacity of the battery 88. Here, the charging output is the output of the fuel cell 11, which is a device that supplies electric power to the battery 88 when charging the battery 88. For example, when the amount of power generation is not excessive or the charge output in the standby mode is 5 kW, the charge output is increased to 10 kW. By increasing the charging output, the charging speed for charging the battery 88 becomes faster. By increasing the charging output to the battery 88, the fuel cell 11 can temporarily output a large amount of electric power. Therefore, it is easy to quickly execute heating by increasing the amount of power generation and the amount of heat generated by the fuel cell 11. However, the specific value of the charge output is not limited to the above-mentioned value.

In another embodiment, in the air flow path portion 59, an air cooling device such as an intercooler may be provided between the air compressor 52 and the fuel cell 11. According to this, the air compressed by the air compressor 52 and whose temperature has risen can be cooled and then flowed to the fuel cell 11. Therefore, it is easy to suppress the temperature rise of the fuel cell 11. Therefore, it is easy to suppress the deterioration of the fuel cell 11 and maintain a state in which the power generation efficiency is high.

The bypass flow path portion 69i may be provided with an ion exchanger. According to this, the insulation property of the cooling water for cooling the fuel cell 11 can be stably secured. Therefore, it is easy to improve the safety of the fuel cell system 1.

Disclosure in this specification, drawings and the like is not limited to the illustrated embodiments. The disclosure includes exemplary embodiments and modifications by those skilled in the art based on them. For example, disclosure is not limited to the parts and / or element combinations shown in the embodiments. Disclosure can be carried out in various combinations. The disclosure can have additional parts that can be added to the embodiment. The disclosure includes the parts and / or elements of the embodiment omitted. Disclosures include replacements or combinations of parts and / or elements between one embodiment and the other. The technical scope disclosed is not limited to the description of the embodiments. Some technical scopes disclosed are indicated by the statements of the claims and should be understood to include all modifications within the meaning and scope equivalent to the statements of the claims.

Disclosure in the description, drawings, etc. is not limited by the description of the scope of claims. The disclosure in the specification, drawings, etc. includes the technical ideas described in the claims, and further covers a wider variety of technical ideas than the technical ideas described in the claims. Therefore, various technical ideas can be extracted from the disclosure of the description, drawings, etc. without being bound by the description of the claims.

1 Fuel cell system, 11 Fuel cell, 41 Hydrogen pump (auxiliary machine), 52 Air compressor (auxiliary machine), 53 Divergence valve (auxiliary machine), 54 Pressure regulation valve (auxiliary machine), 60 FC cooling unit, 61 Cooling water Pump (heat medium pump, auxiliary equipment), 63 Bypass valve (auxiliary equipment), 64 Radiator, 66 Blower (auxiliary equipment), 69 Cooling flow path, 69i Bypass flow path, 69h High temperature flow path, 70 Heating utilization section , 71 Heating valve (auxiliary equipment, heating adjustment unit), 72 Heating pump (auxiliary equipment, heating adjustment unit), 73 Electric heater (auxiliary equipment), 75 Heat exchanger for heating, 79 Flow path for heating, 79r Circular connection flow path, 88 battery, 90 control, 91 heat utilization control, 92 judgment, 93 power generation control

Claims (10)

A fuel cell (11) that is cooled by heat exchange with a cooling heat medium, and
A heat medium pump (61) that circulates the cooling heat medium and
A radiator (64) that cools the cooling heat medium by exchanging heat between the cooling heat medium and air.
A cooling flow path portion (69) that connects the fuel cell, the heat medium pump, and the radiator to form a flow path portion through which the cooling heat medium circulates.
A heat exchanger for heating (75) that can be used as a heat source for heating operation,
It is provided in connection with a high temperature flow path portion (69h) which is a portion of the cooling flow path portion from the fuel cell to the radiator, and forms a flow path portion through which the cooling heat medium flows to the heating heat exchanger. The heating flow path (79) and
A heating adjusting unit (71, 72) that controls the amount of the cooling heat medium flowing through the heating flow path unit, and
A control unit (90) for controlling the fuel cell and the heating adjustment unit is provided.
The control unit
In the heat utilization mode, which is a mode in which the exhaust heat from the fuel cell is used for the heating operation, the heating adjustment unit is controlled so that the cooling heat medium flows from the cooling flow path portion to the heating flow path portion. In the standby mode, which is a mode in which the exhaust heat from the fuel cell is not used for the heating operation, the heating adjusting unit is controlled so that the cooling heat medium does not flow from the cooling flow path portion to the heating flow path portion. Heat utilization control unit (91)
A fuel cell including a power generation control unit (93) that controls power generation of the fuel cell so that the target temperature of the fuel cell in the heat utilization mode becomes higher than the target temperature of the fuel cell in the standby mode. system. The fuel cell according to claim 1, wherein the power generation control unit controls the power generation of the fuel cell so that the target temperature of the fuel cell in the heat utilization mode becomes higher than the target temperature of the heating heat exchanger. system. The power generation control unit controls the power generation of the fuel cell so that the heat generation amount of the fuel cell in the heat utilization mode becomes equal to or more than the heat amount required to complete the heating operation by the heating heat exchanger. Item 2. The fuel cell system according to item 2. Auxiliary equipment (41, 52, 53, 54, 61, 63, 66, 71, 72, 73) that consumes the electric power generated by the fuel cell is provided.
The control unit controls the auxiliary machine so that the power consumption of the auxiliary machine in the heat utilization mode is larger than the power consumption of the auxiliary machine in the standby mode. The fuel cell system described in either. The auxiliary machine is an electric heater (73) that can be used as a heat source when performing a heating operation.
The fuel cell system according to claim 4, wherein the control unit controls the electric heater so that the output of the electric heater in the heat utilization mode is larger than the output of the electric heater in the standby mode. A battery (88) for storing the electric power generated by the fuel cell is provided.
The control unit controls the battery so that the target remaining capacity of the battery in the heat utilization mode is larger than the target remaining capacity of the battery in the standby mode according to any one of claims 1 to 5. The described fuel cell system. A battery (88) for storing the electric power generated by the fuel cell is provided.
Any of claims 1 to 5, wherein the power generation control unit controls the fuel cell so that the charge output to the battery in the heat utilization mode is larger than the charge output to the battery in the standby mode. The fuel cell system described in Crab. A blower (66) for flowing air through the radiator is provided.
The fuel cell system according to any one of claims 1 to 7, wherein the control unit controls the blower to cool the cooling heat medium stored in the radiator in the heat utilization mode. The heat utilization mode has a high heat generation mode and a low heat generation mode in which the amount of heat generated by the fuel cell is smaller than that of the high heat generation mode.
In the heat utilization mode, when the temperature of the fuel cell is lower than the high heat generation permitted temperature set to be equal to or lower than the target temperature, the power generation control unit controls the power generation of the fuel cell in the high heat generation mode. The fuel cell system according to any one of claims 1 to 8, wherein when the temperature of the fuel cell is equal to or higher than the high heat generation permit temperature, the power generation of the fuel cell is controlled in the low heat generation mode. The control unit includes a determination unit (92) for determining whether or not a stop condition, which is a condition for not performing the heat utilization mode, is satisfied.
The fuel cell system according to any one of claims 1 to 9, wherein the control unit executes the standby mode when the determination unit determines that the stop condition is satisfied.

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