JP2020117048A - Temperature adjustment device - Google Patents

Abstract

To provide a temperature adjustment device capable of preventing air from remaining inside a heat medium circulation circuit where a heat medium is circulated.SOLUTION: A three-way valve 13 for switching a circuit configuration of a heat medium circulation circuit 10 is capable of switching to: a first pattern for circulating cooling water pressure-fed by a second pump 16b between a water-coolant heat exchanger 14a of a heat pump cycle 14 and a heater core 15; a second pattern for circulating cooling water pressure-fed by a first pump 16a between a cooling water passage 11 of an engine EG and the heater core 15; and a third pattern capable of supplying both a flow channel in which cooling water flows when switching to the first pattern, and a flow channel in which cooling water flows when switching to the second pattern.SELECTED DRAWING: Figure 1

Description

The present invention relates to a temperature adjusting device that adjusts the temperature of a fluid whose temperature is to be adjusted.

BACKGROUND ART Conventionally, Patent Document 1 discloses a temperature adjusting device applied to a vehicle heat utilization device. The temperature control device of Patent Document 1 heats the air blown into the vehicle interior, which is the space to be air-conditioned, to heat the vehicle interior. Therefore, the temperature control target fluid in the temperature control device of Patent Document 1 is blown air.

More specifically, the temperature control device of Patent Document 1 includes a heat medium circulation circuit that circulates cooling water of an internal combustion engine (that is, an engine). Further, an engine cooling water passage, a heater core, a water-refrigerant heat exchanger of a heat pump cycle, a three-way valve, etc. are connected to the heat medium circulation circuit.

The heater core is a heat exchange unit for heating, which heats the blast air by exchanging heat between the cooling water that is the heat medium and the blast air that is the temperature adjustment target fluid. The heat pump cycle is a temperature adjusting unit that heats the cooling water using the high pressure refrigerant as a heat source. The three-way valve is a switching unit that switches a cooling water flow pattern (in other words, a circuit configuration) in the heat medium circulation circuit.

Then, in the temperature adjusting device of Patent Document 1, when the temperature of the cooling water is equal to or higher than a predetermined temperature, the cooling water is switched to a normal mode pattern in which the cooling water is circulated between the cooling water passage of the engine and the heater core. Further, when the temperature of the cooling water is lower than the predetermined temperature, the heat pump cycle is operated to switch to the warm air mode pattern in which the cooling water is circulated between the water-refrigerant heat exchanger and the heater core.

As a result, the temperature adjustment device of Patent Document 1 can heat the blown air to realize heating of the passenger compartment regardless of the operating state of the engine.

JP 2007-223418 A

By the way, in the heat medium circulation circuit of Patent Document 1, when the pattern is switched to the warm-up mode, the cooling water heated by the water-refrigerant heat exchanger is diverted to the cooling water passage of the engine to the heater core. Inflow. Further, in the heat medium circulation circuit of Patent Document 1, when the pattern is switched to the normal mode, the entire amount of cooling water flowing out from the cooling water passage of the engine is flowed into the heater core.

In order to realize such pattern switching, in the heat medium circulation circuit of Patent Document 1, the cooling water flowing out from the cooling water passage of the engine flows backward to the cooling water outlet side of the water-refrigerant heat exchanger. Equipped with a check valve to prohibit.

However, this type of check valve will not open unless an appropriate differential pressure across the front and rear is secured. Therefore, in the heat medium circulation circuit having the check valve, it is difficult to sufficiently remove the air in the heat medium circulation circuit when injecting the cooling water into the heat medium circulation circuit. Furthermore, when the temperature of the blown air is adjusted, if the air remaining in the heat medium circulation circuit moves into the heat exchanger such as the heater core, the heat exchange performance of the heat exchanger such as the heater core is adversely affected. there is a possibility.

The present invention has been made in view of the above points, and an object thereof is to provide a temperature adjusting device capable of suppressing air from remaining in a heat medium circulation circuit for circulating a heat medium.

In order to achieve the above object, the temperature adjusting device according to claim 1 is a heat medium circulation circuit (10) for circulating a heat medium, a main temperature adjusting unit (EG) for adjusting the temperature of the heat medium, and a heat medium. Of the fluid to be temperature-controlled by exchanging heat between the heat medium whose temperature has been adjusted and the fluid to be temperature-adjusted by at least one of the main temperature adjusting portion and the sub-temperature adjusting portion. A heat exchange section (15) for adjusting the temperature, a main pump (16a) that operates at least when the heat medium whose temperature has been adjusted by the main temperature adjustment section is pressure-fed to the heat exchange section, and at least a sub temperature adjustment section. A sub-pump (16b) that operates when the temperature-adjusted heat medium is pressure-fed to the heat exchange unit, and a switching unit (13) that switches the circuit configuration of the heat medium circulation circuit (10).

Furthermore, the switching unit changes the circuit configuration of the heat medium circulation circuit to
A first pattern for circulating the heat medium pumped by the sub pump between the sub temperature adjusting unit and the heat exchanging unit,
A second pattern for circulating the heat medium pumped by the main pump between the main temperature adjusting section and the heat exchanging section,
The heat medium pumped by at least one of the main pump and the sub-pump has a flow path through which the heat medium flows when switched to the first pattern and a flow path through which the heat medium flows when switched to the second pattern. Switch to the third pattern that can be supplied to both parties.

According to this, since the switching unit (13) is provided, even if the heat medium circulation circuit (10) does not have a check valve, the circuit configuration of the heat medium circulation circuit (10) is the first pattern. It is possible to switch to the second pattern.

Therefore, the temperature of the heat medium is surely adjusted by switching between the first pattern and the second pattern according to the temperature adjusting ability of the heat medium of the main temperature adjusting unit (EG) and the sub temperature adjusting unit (14). be able to. As a result, the temperature of the fluid whose temperature is to be adjusted can be appropriately adjusted in the heat exchange section.

Furthermore, the switching unit (13) can switch the circuit configuration of the heat medium circulation circuit (10) to the third pattern. In the third pattern, the heat medium can be supplied to both the flow channel in which the heat medium flows when switched to the first pattern and the flow channel in which the heat medium flows when switched to the second pattern.

Therefore, it is possible to prevent air from remaining in the heat medium circulation circuit (10) when pouring the heat medium into the heat medium circulation circuit (10).

It should be noted that the reference numerals in parentheses for each means described in this column and in the claims are an example showing the correspondence with specific means described in the embodiments described later.

It is a whole block diagram of the temperature adjusting device of 1st Embodiment. It is sectional drawing which shows the state in the auxiliary heat source mode of the three-way valve of 1st Embodiment. It is sectional drawing which shows the state in the main heat source mode of the three-way valve of 1st Embodiment. It is sectional drawing which shows the state in the air bleeding mode of the three-way valve of 1st Embodiment. It is a whole block diagram which shows the flow pattern of the cooling water at the time of the auxiliary heat source mode of the temperature adjusting device of 1st Embodiment. It is the whole block diagram which shows the flow pattern of the cooling water in the main heat source mode of the temperature control apparatus of 1st Embodiment. It is the whole block diagram which shows the flow pattern of the cooling water in the air venting mode of the temperature control apparatus of 1st Embodiment. It is a whole block diagram of the temperature adjusting device of 2nd Embodiment. It is a whole block diagram of the temperature adjusting device of 3rd Embodiment. It is a whole block diagram which shows the flow pattern of the cooling water at the time of the auxiliary heat source mode of the temperature adjusting device of 3rd Embodiment. It is a whole block diagram which shows the flow pattern of the cooling water at the time of the main heat source mode of the temperature adjusting device of 3rd Embodiment. It is the whole block diagram which shows the flow pattern of the cooling water at the time of the air venting mode of the temperature control apparatus of 3rd Embodiment. It is a whole block diagram of the temperature adjusting device of 4th Embodiment. It is the whole air-conditioner lineblock diagram for vehicles of a 5th embodiment.

A plurality of embodiments for carrying out the present invention will be described below with reference to the drawings. In each embodiment, the same reference numerals may be given to portions corresponding to the matters described in the preceding embodiments, and duplicate description may be omitted. In the case where only a part of the configuration is described in each embodiment, the other embodiments described above can be applied to the other part of the configuration. Not only the combination of the parts clearly showing that the respective embodiments can be specifically combined, but also the combination of the embodiments with each other partially even if not clearly indicated unless the combination causes any trouble. Is also possible.

(First embodiment)
1st Embodiment of 1st Embodiment of the temperature adjusting device 1 which concerns on this invention is described using FIGS. The temperature adjusting device 1 of the present embodiment is applied to a hybrid vehicle that obtains a driving force for traveling from an engine (that is, an internal combustion engine) EG and an electric motor for traveling. Further, the hybrid vehicle of the present embodiment is a so-called plug-in hybrid vehicle capable of charging the battery with the electric power supplied from the external power source (for example, commercial power source) when the vehicle is stopped.

In this type of plug-in hybrid vehicle, the driving mode can be switched. Specifically, when the remaining battery charge SOC of the battery is equal to or greater than a predetermined reference remaining charge KSOC, the EV traveling mode is set. The EV traveling mode is a traveling mode in which the vehicle travels mainly by the driving force of the traveling electric motor. On the other hand, when the remaining charge SOC is lower than the reference remaining charge KSOC, the HV traveling mode is set. The HV traveling mode is a traveling mode in which the vehicle travels mainly by the driving force of the engine EG.

Of course, even in the EV traveling mode, when the vehicle traveling load becomes high, the engine EG is operated to assist the traveling electric motor. Even in the HV traveling mode, when the vehicle traveling load becomes high, the traveling electric motor is operated to assist the engine EG.

In the plug-in hybrid vehicle, the vehicle fuel consumption can be improved by switching between the EV traveling mode and the HV traveling mode in this way as compared with an ordinary vehicle that obtains the driving force for vehicle traveling only from the engine EG.

The temperature adjusting device 1 of the present embodiment heats the air blown into the vehicle interior that is the air-conditioned space to heat the vehicle interior. Therefore, the blown air is the temperature control target fluid of the temperature control device 1. The temperature adjusting device 1 also includes a heat medium circulation circuit 10 that circulates the cooling water of the engine EG that is a heat medium. As the cooling water, a solution containing ethylene glycol, dimethylpolysiloxane, a nanofluid or the like, an antifreeze liquid, or the like can be adopted.

The heat medium circulation circuit 10 includes a cooling water passage 11 of the engine EG, a three-way valve 13, a water-refrigerant heat exchanger 14a of the heat pump cycle 14, a heater core 15, a first pump 16a, a second pump 16b, a radiator 17, and a thermostat 18. Etc. are connected.

The cooling water passage 11 of the engine EG is formed in a cylinder block and a cylinder head that form the engine EG. Therefore, when the cooling water is circulated in the cooling water passage 11 during the operation of the engine EG, the cooling water can absorb the exhaust heat of the engine EG to cool the engine EG.

In other words, the cooling water is heated by the exhaust heat of the engine EG when flowing through the cooling water passage 11. Therefore, the engine EG of the present embodiment serves as a main temperature adjusting unit that adjusts the temperature of the cooling water.

The cooling water outlet of the cooling water passage 11 is connected to the inlet of the branch portion 12a. The branch portion 12a is formed of a three-way joint. The branch portion 12a branches the flow of the cooling water flowing out from the cooling water passage 11. One inflow/outlet side of the three-way valve 13 is connected to one outflow port of the branch portion 12a. The cooling water inlet side of the radiator 17 is connected to the other outlet of the branch portion 12a.

The three-way valve 13 is a switching unit that switches the flow pattern (in other words, circuit configuration) of the cooling water in the heat medium circulation circuit 10. The three-way valve 13 is an electric switching valve that has three inlets and outlets and connects at least two of the three inlets and outlets. The operation of the three-way valve 13 is controlled by a control signal output from the control device 30 described later. The detailed configuration of the three-way valve 13 will be described later.

The cooling water inlet side of the water-refrigerant heat exchanger 14 a of the heat pump cycle 14 is connected to another inflow/outlet port of the three-way valve 13. The water-refrigerant heat exchanger 14a heats the cooling water by exchanging heat between the high pressure refrigerant of the heat pump cycle 14 and the cooling water. The heat pump cycle 14 is a vapor compression refrigeration cycle including a compressor, a water-refrigerant heat exchanger 14a, an expansion valve, an evaporator and the like.

Therefore, the heat pump cycle 14 of the present embodiment serves as a sub temperature adjusting unit that adjusts the temperature of the cooling water. The heating capacity of the heat pump cycle 14 is controlled by a control signal output from the control device 30.

The cooling water inlet side of the heater core 15 is connected to the cooling water outlet of the water-refrigerant heat exchanger 14a. The heater core 15 exchanges heat between the cooling water heated in the cooling water passage 11 of the engine EG or the water-refrigerant heat exchanger 14a of the heat pump cycle 14 and the blown air blown into the vehicle interior from an indoor blower (not shown). To heat the blown air. Therefore, the heater core 15 is a heat exchange part for heating.

The cooling water outlet of the heater core 15 is connected to one inlet side of the merging portion 12b. The merging portion 12b is formed of a three-way joint similar to the branching portion 12a. The merging portion 12b merges the flow of the cooling water flowing out from the cooling water outlet of the heater core 15 and the flow of the cooling water flowing out from the cooling water outlet of the radiator 17. Further, the merging unit 12b causes the combined cooling water to flow out to the suction port side of the first pump 16a.

The first pump 16a is a water pump that pumps cooling water to the cooling water passage 11 of the engine EG. The first pump 16a is an electric impeller pump that drives an impeller (that is, an impeller) with an electric motor. The number of rotations (pressure feeding capacity) of the first pump 16a is controlled by a control signal output from the control device 30.

Further, the first pump 16a does not have a check mechanism that prohibits the cooling water flowing from the discharge port from flowing out from the suction port. Therefore, the first pump 16a simply serves as a cooling water passage when it is not operating. That is, in the non-operating first pump 16a, the cooling water that has flowed in from the discharge port can flow out from the suction port.

The discharge port of the first pump 16a is connected to the cooling water inlet side of the cooling water passage 11 of the engine EG. Therefore, the first pump 16a serves as a main pump that operates when at least the cooling water heated in the cooling water passage 11 of the engine EG is pressure-fed to the heater core 15 side.

The radiator 17 is an outdoor heat exchanger that exchanges heat between the cooling water flowing out from the other outlet of the branch portion 12a and the outside air. That is, the radiator 17 can radiate the exhaust heat of the engine EG absorbed by the cooling water to the outside air. The radiator 17 has a so-called closed type reserve tank 17a.

The radiator 17 is also provided with a water injection port 17b for injecting cooling water into the heat medium circulation circuit 10. The water injection port 17b is arranged at the top of the heat medium circulation circuit 10. Therefore, the cooling water injected from the water injection port 17b flows into the heat medium circulation circuit 10 due to the difference in the lift.

The cooling water outlet of the radiator 17 is connected to the other inlet side of the merging portion 12b via a thermostat 18. The thermostat 18 is a flow rate adjusting valve that increases the passage cross-sectional area of the cooling water flow path from the cooling water outlet of the radiator 17 to the confluence portion 12b as the temperature of the cooling water flowing out from the radiator 17 rises. The thermostat 18 is a mechanical mechanism that displaces the valve body by thermowax, the volume of which changes according to the temperature change of the cooling water.

The thermostat 18 adjusts the passage cross-sectional area so that the temperature of the cooling water sucked from the radiator 17 side to the first pump 16a approaches a predetermined reference temperature KTw. The thermostat 18 of the present embodiment has a configuration in which the cooling water passage is not completely closed in order to appropriately detect the temperature of the cooling water flowing out from the radiator 17.

Further, the heat medium circulation circuit 10 has a parallel passage 10a that guides the cooling water flowing out from the heater core 15 to the other one inflow/outflow side of the three-way valve 13 by bypassing the cooling water passage 11 of the engine EG. There is. The second pump 16b is arranged in the parallel path 10a. The second pump 16b sucks the cooling water flowing out from the heater core 15 and pumps it to the three-way valve 13 side.

The basic configuration of the second pump 16b is similar to that of the first pump 16a. Therefore, the second pump 16b simply serves as a cooling water passage when it is not operating. Further, in this embodiment, as the first pump 16a, a pump having a maximum pumping capacity of cooling water larger than that of the second pump 16b is adopted. Therefore, when the first pump 16a and the second pump 16b are rotated at the same rotation speed, the discharge flow rate of the first pump 16a becomes larger than the discharge flow rate of the second pump 16b.

The cooling water pumped from the second pump 16b flows into the heater core 15 via the three-way valve 13 and the water-refrigerant heat exchanger 14a. Therefore, the second pump 16b serves as a sub pump that operates at least when the cooling water heated by the water-refrigerant heat exchanger 14a of the heat pump cycle 14 is pressure-fed to the heater core 15 side.

Next, the detailed configuration of the three-way valve 13 will be described. The three-way valve 13 is, as shown in FIG. 1, a cooling water outlet side of the cooling water passage 11 of the engine EG, a cooling water inlet side of the water-refrigerant heat exchanger 14a of the heat pump cycle 14, and one of the parallel passages 10a. Connected to the exit. Then, two or more of these cooling water inlets and outlets are connected.

In the present embodiment, the cooling water outlet of the water-refrigerant heat exchanger 14a is connected to the cooling water inlet side of the heater core 15. Therefore, the three-way valve 13 is indirectly connected to the cooling water inlet side of the heater core 15 via the water-refrigerant heat exchanger 14a.

More specifically, as shown in FIGS. 2 to 4, the three-way valve 13 has a cylindrical rotary valve portion 131, a body portion 132 that houses the rotary valve portion 131, and a drive portion (not shown). doing. 2 to 4 are axially vertical cross sections of the three-way valve 13.

Inside the rotary valve portion 131, there is formed a communication passage 131a for communicating the cooling water outlet of the cooling water passage 11, the cooling water inlet of the water-refrigerant heat exchanger 14a, and one inflow/outlet of the parallel passage 10a. .. The body portion 132 houses the rotary valve portion 131 rotatably around the central axis. The drive unit is an electric actuator (specifically, a stepping motor) that rotates the rotary valve unit 131 around an axis.

Then, as the drive portion rotationally displaces the rotary valve portion 131 about the axis, as shown in FIG. 2, one inflow/outlet side of the parallel path 10a and the cooling water inlet side of the water-refrigerant heat exchanger 14a are connected. Can be connected. Further, as shown in FIG. 3, the cooling water outlet side of the cooling water passage 11 and the cooling water inlet side of the water-refrigerant heat exchanger 14a can be connected. Further, as shown in FIG. 4, the cooling water outlet of the cooling water passage 11, the cooling water inlet of the water-refrigerant heat exchanger 14a, and one inflow outlet of the parallel passage 10a can be connected to each other.

Next, an outline of the electric control unit of this embodiment will be described. The control device 30 is composed of a well-known microcomputer including a CPU, a ROM, a RAM and the like and its peripheral circuits. Then, various calculations and processing are performed based on the control program stored in the ROM, and the operations of the various controlled devices 13, 14, 16a, 16b and the like connected to the output side are controlled.

An engine side temperature sensor 31, a heating unit side temperature sensor 32, etc. are connected to the input side of the control device 30. The detection signals of these sensor groups are input to the control device 30.

The engine-side temperature sensor 31 is a temperature detection unit that detects the first temperature T1 of a portion of the engine EG on the outlet side of the cooling water passage 11. The engine side temperature sensor 31 is attached to the engine EG. Therefore, even if the cooling water does not flow through the cooling water passage 11, the temperature of the engine EG can be detected. The heating unit side temperature sensor 32 is a temperature detection unit that detects the second temperature T2 of the cooling water that has flowed out of the water-refrigerant heat exchanger 14a.

Further, an operation panel (not shown) is connected to the input side of the control device 30. An operation signal is input to the control device 30 from an operation switch provided on the operation panel.

The operation switches include a heating switch, an air volume setting switch, a temperature setting switch, and the like. The heating switch is a request unit that requests execution or stop of heating. The air volume setting switch is a setting unit that sets the air volume of the air blown into the vehicle interior. The temperature setting switch is a setting unit that sets the temperature inside the vehicle compartment.

The control device 30 of the present embodiment is integrally configured with a control unit that controls various control target devices connected to the output side. Therefore, in the control device 30, the configuration (hardware and software) that controls the operation of each control target device serves as a control unit that controls the operation of each control target device.

For example, in the control device 30, the configuration that controls the pumping capacity of the first pump 16a constitutes a first pump control unit. In the control device 30, the configuration for controlling the pumping capacity of the second pump 16b constitutes a second pump control section. In the control device 30, the configuration that controls the operation of the heat pump cycle 14 constitutes a heat pump cycle control unit.

Next, the operation of the temperature adjusting device 1 of the present embodiment having the above configuration will be described. In the temperature adjustment device 1 of the present embodiment, in order to heat the vehicle interior, it is possible to switch between operation in the auxiliary heat source mode and operation in the main heat source mode.

As described above, the plug-in hybrid vehicle of the present embodiment travels in the EV travel mode when the remaining charge SOC of the battery is equal to or higher than the reference remaining charge KSOC. The EV traveling mode is a traveling mode in which the vehicle is traveling mainly by the driving force of the traveling electric motor, and therefore the engine EG is rarely operated. Therefore, the first temperature T1 is unlikely to rise when traveling in the EV traveling mode.

Therefore, when the execution of heating of the vehicle interior is requested when the first temperature T1 is lower than the predetermined first reference temperature KT1, the control device 30 performs the heating in the auxiliary heat source mode. In the auxiliary heat source mode, the heat pump cycle 14 that is the sub-temperature adjusting unit is operated to perform heating by using the cooling water heated by the water-refrigerant heat exchanger 14a as a heat source.

After that, when the EV drive mode is continued and the remaining charge SOC of the battery becomes lower than the reference remaining charge KSOC, the EV drive mode is switched to. The HV traveling mode is a traveling mode in which the vehicle travels mainly by the driving force of the engine EG. Therefore, when traveling in the HV traveling mode, the first temperature T1 is higher than that in the EV traveling mode.

Therefore, the control device 30 performs heating in the main heat source mode when execution of heating of the vehicle interior is requested when the first temperature T1 is equal to or higher than the first reference temperature KT1. In the main heat source mode, the heat pump cycle 14 that is the sub temperature adjusting unit is stopped, and heating is performed using the cooling water heated in the cooling water passage 11 of the engine EG that is the main temperature adjusting unit as the heat source.

The first reference temperature KT1 is set so that the temperature of the cooling water can be sufficiently used as a heat source for heating the vehicle interior. Hereinafter, each operation mode will be described.

(A) Auxiliary Heat Source Mode In the auxiliary heat source mode, the control device 30 switches the flow pattern of the cooling water in the heat medium circulation circuit 10 to the first pattern.

Specifically, as illustrated in FIG. 2, the control device 30 connects the one inflow/outlet side of the parallel path 10a and the cooling water inlet side of the water-refrigerant heat exchanger 14a so as to connect the three-way valve 13 to each other. Control operation. As a result, the parallel passage 10a is opened, and the cooling water flowing out from the heater core 15 can flow into the parallel passage 10a.

Further, the control device 30 operates the heat pump cycle 14. At this time, the control device 30 adjusts the heating capacity of the heat pump cycle 14 so that the second temperature approaches the target temperature. The target temperature is determined based on the set temperature set by the occupant using the temperature setting switch, the outside air temperature, and the like with reference to the control map stored in advance by the control device 30.

Further, the control device 30 stops the first pump 16a and operates the second pump 16b so as to exert a predetermined pressure feeding capacity. Therefore, in the heat medium circulation circuit 10 of the first pattern, the cooling water pumped from the second pump 16b circulates between the cooling water passage of the water-refrigerant heat exchanger 14a and the heater core 15.

Therefore, in the auxiliary heat source mode, the cooling water pressure-fed from the second pump 16b flows into the cooling water passage of the water-refrigerant heat exchanger 14a via the three-way valve 13, as shown by the thick solid line in FIG. The cooling water that has flowed into the cooling water passage of the water-refrigerant heat exchanger 14 a exchanges heat with the high-pressure refrigerant of the heat pump cycle 14 and is heated.

The cooling water heated by the water-refrigerant heat exchanger 14 a flows into the heater core 15. The cooling water that has flowed into the heater core 15 exchanges heat with the air blown from the indoor blower to radiate heat. Thereby, the blown air is heated. The cooling water flowing out from the heater core 15 flows into the parallel path 10a, is sucked into the second pump 16b, and is pumped again.

Therefore, in the auxiliary heat source mode, even if the engine EG is stopped, the air blown by the heater core 15 can be blown into the vehicle interior to heat the vehicle interior.

Note that FIG. 5 is a drawing corresponding to FIG. 1, and shows the flow of the cooling water by a thick solid line arrow. Further, in FIG. 5, for clarity of illustration, illustration of signal lines and power lines connecting the control device 30 and various control target devices, and signal lines connecting the control device 30 and various sensors is omitted. doing. This also applies to the overall configuration diagram for explaining the following flow pattern.

(B) Main heat source mode In the main heat source mode, the control device 30 switches the flow pattern of the cooling water in the heat medium circulation circuit 10 to the second pattern.

Specifically, as shown in FIG. 3, the controller 30 of the three-way valve 13 connects the cooling water outlet side of the cooling water passage 11 and the cooling water inlet side of the water-refrigerant heat exchanger 14a. Control operation. As a result, the parallel path 10a is closed.

Further, the control device 30 stops the heat pump cycle 14. Further, the control device 30 operates the first pump 16a and stops the second pump 16b so as to exert a predetermined pressure feeding capability. Therefore, in the heat medium circulation circuit 10 of the second pattern, the cooling water pumped from the first pump 16a circulates between the cooling water passage 11 of the engine EG and the heater core 15.

Therefore, in the main heat source mode, the cooling water pumped from the first pump 16a flows into the cooling water passage 11 of the engine EG, as shown by the thick solid line in FIG. The cooling water flowing into the cooling water passage 11 of the engine EG absorbs the exhaust heat of the engine EG and its temperature rises. As a result, the engine EG is cooled.

The cooling water flowing out from the cooling water passage 11 of the engine EG flows into the cooling water passage of the water-refrigerant heat exchanger 14a via the three-way valve 13. In the main heat source mode, the heat pump cycle 14 is stopped. Therefore, the cooling water flowing into the cooling water passage of the water-refrigerant heat exchanger 14a flows out without being heated.

The cooling water flowing out from the water-refrigerant heat exchanger 14 a flows into the heater core 15. The cooling water that has flowed into the heater core 15 exchanges heat with the air blown from the indoor blower to radiate heat. Thereby, the blown air is heated. The cooling water that has flowed out of the heater core 15 is sucked into the first pump 16a via the merging portion 12b and is pressure-fed again.

Further, in the main heat source mode, the first pump 16a is operating. Therefore, the passage cross-sectional area of the thermostat 18 is adjusted according to the temperature of the cooling water flowing out from the radiator 17. Therefore, a part of the cooling water branched at the branch portion 12a flows into the radiator 17 as shown by the thin arrow in FIG. Then, the temperature of the cooling water that flows out from the radiator 17 and is sucked into the first pump 16a approaches the reference temperature KTw.

Therefore, in the main heat source mode, the air blown by the heater core 15 can be blown into the vehicle interior to heat the vehicle interior.

As described above, since the temperature control device 1 of the present embodiment includes the three-way valve 13, the flow patterns of the cooling water in the heat medium circulation circuit 10 are set to the first pattern and the second pattern when heating the vehicle interior. You can switch to the pattern and. That is, even if the heat medium circulation circuit 10 does not have a check valve, the flow patterns can be switched.

Therefore, by operating the heat pump cycle 14 in accordance with the operating state of the engine EG and further switching between the first pattern and the second pattern, the temperature of the cooling water can be sufficiently utilized as a heat source for heating the passenger compartment. It can be reliably adjusted to the temperature. As a result, the temperature of the blown air can be appropriately adjusted by the heater core 15 regardless of the operating state of the engine EG.

By the way, in order to properly adjust the temperature of the blown air as described above, it is necessary to inject the cooling water (that is, the heat medium) into the heat medium circulation circuit 10. However, if air remains in the heat medium circulation circuit 10 when the cooling water is injected, the remaining air moves to the heat exchanger such as the heater core and adversely affects the heat exchange performance in the heat exchanger such as the heater core. May affect.

Therefore, in the temperature adjusting device 1 of the present embodiment, the operation in the air bleeding mode can be performed as the operation mode for injecting the cooling water into the heat medium circulation circuit 10. The air bleeding mode is executed when a service tool (not shown) is connected to a dedicated connector provided in the control device 30. Note that the service tool does not have to be always provided in the vehicle, and may be prepared in a maintenance shop or the like that injects cooling water. The air bleeding mode will be described below.

(C) Air bleeding mode First, prior to the air bleeding mode, cooling water is injected from the water injection port 17b of the radiator 17. As described above, the water injection port 17b is arranged at the top of the heat medium circulation circuit 10. Therefore, the injected cooling water flows into almost the entire area of the heat medium circulation circuit 10 due to the difference in head. After that, by connecting the service tool to the dedicated connector, the operation in the air bleeding mode is executed.

In the air bleeding mode, the control device 30 switches the flow pattern of the cooling water in the heat medium circulation circuit 10 to the third pattern.

Specifically, as shown in FIG. 4, the controller 30 connects the cooling water outlet of the cooling water passage 11, the cooling water inlet of the water-refrigerant heat exchanger 14a, and one inflow outlet of the parallel passage 10a to each other. The operation of the three-way valve 13 is controlled so that As a result, the parallel passage 10a opens, and the cooling water pumped by the first pump 16a can flow into both the water-refrigerant heat exchanger 14a and the parallel passage 10a.

Further, the control device 30 stops the heat pump cycle 14. Further, the control device 30 operates the first pump 16a and stops the second pump 16b so as to exert a predetermined pressure feeding capability.

Thereby, in the third pattern, the cooling water pumped by the first pump 16a can flow from the three-way valve 13 into the water-refrigerant heat exchanger 14a. Further, the cooling water pumped by the first pump 16a can flow from the three-way valve 13 into the parallel passage 10a. At this time, the cooling water flowing from the three-way valve 13 into the parallel passage 10a flows backward in the parallel passage 10a with respect to the second pattern.

Then, in the third pattern, the cooling water pumped by the first pump 16a flows through the cooling water when switched to the first pattern, and the cooling water flows when switched to the second pattern. Can be supplied to both of the flow paths.

Therefore, in the air bleeding mode, as shown by the thick solid line in FIG. 7, the cooling water injected from the water injection port 17b of the radiator 17 is sucked into the first pump 16a. The cooling water pumped from the first pump 16a flows through the cooling water passage 11 of the engine EG and is branched at the branch portion 12a. One flow of the cooling water branched at the branch portion 12a is further divided by the three-way valve 13.

One of the cooling water branched by the three-way valve 13 flows in the order of the water-refrigerant heat exchanger 14 a and the heater core 15. The other cooling water branched by the three-way valve 13 flows through the parallel path 10a. At this time, since the second pump 16b is stopped, the cooling water flowing from the discharge port of the second pump 16b flows backward through the second pump 16b and flows out from the suction port.

The cooling water flowing out of the heater core 15 merges with the cooling water flowing out of the parallel path 10a, and is sucked into the first pump 16a via the merging portion 12b.

The other cooling water branched at the branch portion 12a flows into the radiator 17. Of the cooling water that has flowed into the radiator 17, excess cooling water in the heat medium circulation circuit 10 is stored in the reserve tank 17a. The cooling water flowing out from the radiator 17 is sucked into the first pump 16a via the confluence portion 12b.

As described above, in the temperature control device 1 of the present embodiment, the three-way valve 13 can switch the flow pattern of the cooling water in the heat medium circulation circuit 10 to the third pattern. In the third pattern, the cooling water can be simultaneously supplied to both the flow channel through which the cooling water flows when switched to the first pattern and the flow channel through which the cooling water flows when switched to the second pattern.

At this time, the heat medium circulation circuit 10 of the present embodiment does not have a check valve. Therefore, in the temperature control device 1 of the present embodiment, it is possible to prevent air from remaining in the heat medium circulation circuit 10 when pouring cooling water into the heat medium circulation circuit 10.

Further, the temperature control device 1 of the present embodiment includes the parallel path 10a, and the three-way valve 13 that opens and closes the parallel path 10a is used as the switching unit. According to this, the flow pattern of the cooling water in the heat medium circulation circuit 10 can be reliably switched to the above-described first to third patterns.

Further, the flow direction of the cooling water in the parallel path 10a in the first pattern and the flow direction of the cooling water in the parallel path 10a in the third pattern are different directions. Thereby, the flow direction of the cooling water in the heater core 15 in the first pattern and the flow direction of the cooling water in the heater core 15 in the second pattern can be made the same direction.

Therefore, it is possible to prevent the heat exchange performance of the heater core 15 in the auxiliary heat source mode and the heat exchange performance of the heater core 15 in the main heat source mode from changing.

Further, in the temperature adjusting device 1 of the present embodiment, the second pump 16b, which serves as a cooling water passage when not operating, is arranged in the parallel passage 10a. Therefore, even if the heat medium circulation circuit 10 is switched between the first pattern and the second pattern in order to heat the vehicle interior, the cooling water does not flow backward through the second pump 16b. That is, when heating the vehicle interior, the second pump 16b does not increase the pressure loss of the cooling water.

Further, in the temperature adjusting device 1 of the present embodiment, as the first pump 16a, one having a maximum pumping capacity larger than that of the second pump 16b is adopted. According to this, when switching to the third pattern, it is possible to pump the cooling water so that the first pump 16a having a high pumping capability is used to cause the second pump 16b to flow backward. Therefore, it is possible to prevent air from remaining in the second pump 16b.

Further, in this embodiment, the three-way valve 13 having the rotary valve portion 131 is adopted as the switching portion. According to this, even if there is a pressure difference in the cooling water flowing in and out of each of the outflow and outflow ports of the three-way valve 13, the operation of the rotary valve portion 131 is unlikely to be affected. That is, the first to third patterns can be switched without causing an unnecessary increase in driving force.

Furthermore, since the three-way valve 13 having the rotary valve portion 131 is adopted, it is possible to easily realize a switching portion that connects two or all of the three outflow inlets.

(Second embodiment)
In the present embodiment, as shown in FIG. 8, an example in which the temperature adjusting device 1 is mounted on a fuel cell vehicle will be described. The cooling medium passage 11a of the fuel cell FC is connected to the heat medium circulation circuit 10 of the present embodiment. In this embodiment, the fuel cell FC serves as the main temperature adjusting unit. Other basic configurations and operations are similar to those of the first embodiment. Therefore, also in the temperature adjusting device 1 of the present embodiment, the same effect as that of the first embodiment can be obtained.

(Third Embodiment)
In this embodiment, as shown in FIG. 9, an example in which the switching unit is changed from the first embodiment will be described. In this embodiment, instead of the three-way valve 13, the first opening/closing valve 13a and the second opening/closing valve 13b are used as the switching unit. The first on-off valve 13a and the second on-off valve 13b are electromagnetic valves that are opened and closed by a control voltage output from the control device 30.

The first opening/closing valve 13a is arranged in the cooling water passage extending from the branch portion 12a to the connecting portion 12c at one inflow/outlet of the parallel passage 10a. The connecting portion 12c is formed of a three-way joint similar to the branching portion 12a and the joining portion 12b. The second opening/closing valve 13b is arranged in the cooling water passage extending from the discharge port of the second pump 16b to the connecting portion 12c. Other configurations are similar to those of the first embodiment.

Next, the operation of the temperature adjusting device 1 of the present embodiment having the above configuration will be described. In this embodiment, as in the first embodiment, the auxiliary heat source mode, the main heat source mode, and the air bleeding mode can be executed. Hereinafter, each operation mode will be described.

(A) Auxiliary Heat Source Mode In the auxiliary heat source mode, the control device 30 closes the first on-off valve 13a and opens the second on-off valve 13b, as shown in FIG. Other operations are similar to those of the auxiliary heat source mode of the first embodiment. Therefore, even in the auxiliary heat source mode of this embodiment, the flow pattern of the cooling water in the heat medium circulation circuit 10 can be switched to the first pattern.

(B) Main heat source mode In the main heat source mode, the control device 30 opens the first on-off valve 13a and closes the second on-off valve 13b, as shown in FIG. Other operations are similar to those in the main heat source mode of the first embodiment. Therefore, even in the main heat source mode of this embodiment, the flow pattern of the cooling water in the heat medium circulation circuit 10 can be switched to the second pattern.

(C) Air bleeding mode In the air bleeding mode, the control device 30 opens the first on-off valve 13a and the second on-off valve 13b, as shown in FIG. Other operations are the same as in the air bleeding mode of the first embodiment. Therefore, even in the air bleeding mode of this embodiment, the flow pattern of the cooling water in the heat medium circulation circuit 10 can be switched to the third pattern.

As described above, the temperature adjusting device 1 of the present embodiment operates in the same manner as the temperature adjusting device 1 described in the first embodiment, and the same effect can be obtained.

(Fourth Embodiment)
In the present embodiment, as shown in FIG. 13, an example in which the arrangement of the second pump 16b is changed from the first embodiment will be described. In the present embodiment, the second pump 16b is arranged in the cooling water passage extending from the three-way valve 13 to the cooling water inlet of the water-refrigerant heat exchanger 14a. The second pump 16b is arranged so as to suck in the cooling water that has flowed out from the three-way valve 13 and pump it to the cooling water inlet side of the water-refrigerant heat exchanger 14a.

Other configurations and operations are similar to those of the first embodiment. The temperature adjusting device 1 of the present embodiment operates in the same manner as the temperature adjusting device 1 described in the first embodiment, and the same effect can be obtained. In the temperature adjusting device 1 of the present embodiment, the second pump 16b may be operated even in the air bleeding mode.

(Fifth Embodiment)
In the present embodiment, an example will be described in which the temperature adjusting device 1a is applied to a vehicle air conditioner 20 shown in the overall configuration diagram of FIG. The vehicle air conditioner 20 heats the passenger compartment by using the heat medium heated by the heat pump cycle 14 as a heat source. Further, the vehicle air conditioner 20 cools the vehicle interior by using the heat medium cooled by the heat pump cycle 14 as a cold heat source.

As described in the first embodiment, the heat pump cycle 14 has the compressor 14d, the water-refrigerant heat exchanger 14a as a radiator, the expansion valve 14b, and the chiller 14c as an evaporator.

The compressor 14d is an electric compressor that draws in low-pressure refrigerant, compresses it, and discharges it. The water-refrigerant heat exchanger 14a is a main temperature adjustment unit that heats the heat medium by exchanging heat between the high-pressure refrigerant discharged from the compressor 14d and the heat medium pumped from the first pump 16a. The expansion valve 14b is a thermal expansion valve that decompresses the high-pressure refrigerant flowing out of the water-refrigerant heat exchanger 14a until it becomes a low-pressure refrigerant. The chiller 14c is a sub-temperature adjusting unit that cools the heat medium by exchanging heat between the low pressure refrigerant decompressed by the expansion valve 14b and the heat medium pumped from the second pump 16b.

Further, the heat medium circulation circuit 10 of the present embodiment has the first sub circulation path 101 for circulating the heat medium pumped from the first pump 16a between the water-refrigerant heat exchanger 14a and the heater core 15. There is. Further, the heat medium circulation circuit 10 has a second auxiliary circulation path 102 for circulating the heat medium pumped from the second pump 16b between the chiller 14c and the cooler core 15a.

The heater core 15 is a heat exchanger that heats the blast air by exchanging heat between the heat medium heated by the water-refrigerant heat exchanger 14a and the blast air blown into the vehicle interior from an indoor blower (not shown). The cooler core 15a is a heat exchanger that cools the blown air by exchanging heat between the heat medium cooled by the chiller 14c and the blown air blown into the vehicle interior from the indoor blower.

Further, an outdoor heat exchanger 19 is connected to the first sub circulation path 101 via a three-way valve 13. More specifically, in the heat medium circulation circuit 10, the heat medium flowing out from the water-refrigerant heat exchanger 14 a flows into at least one of the heater core 15 and the outdoor heat exchanger 19 via the three-way valve 13. Further, the first pump 16a sucks the heat medium flowing out from at least one of the heater core 15 and the outdoor heat exchanger 19.

Similarly, the outdoor heat exchanger 19 is connected to the second auxiliary circulation path 102 via the second three-way valve 13c. More specifically, in the heat medium circulation circuit 10, the heat medium flowing out from the chiller 14c flows into at least one of the cooler core 15a and the outdoor heat exchanger 19 via the second three-way valve 13c. Further, the second pump 16b sucks the heat medium flowing out from at least one of the cooler core 15a and the outdoor heat exchanger 19.

In the following description, the three-way valve 13 will be referred to as a first three-way valve 13 for the sake of clarity. The basic configuration of the second three-way valve 13c is the same as that of the first three-way valve 13. Therefore, in the present embodiment, both the first three-way valve 13 and the second three-way valve 13c constitute a switching unit that switches the circuit configuration of the heat medium circulation circuit 10.

The basic configuration of the outdoor heat exchanger 19 is similar to that of the radiator 17 described in the first embodiment. Therefore, the outdoor heat exchanger 19 is provided with a water injection port 19b for injecting cooling water into the heat medium circulation circuit 10. The water injection port 19b is arranged at the top of the heat medium circulation circuit 10.

Next, the operation of the vehicle air conditioner 20 of this embodiment will be described. The vehicle air conditioner 20 of this embodiment can perform heating and cooling of the vehicle interior. The heating mode and the cooling mode will be described below.

(A) Heating Mode In the heating mode, the control device 30 operates the heat pump cycle 14. Further, the control device 30 operates both the first pump 16a and the second pump 16b.

Further, the control device 30 controls the operation of the first three-way valve 13 so that the heat medium pumped from the first pump 16a circulates between the water-refrigerant heat exchanger 14a and the heater core 15. Further, the control device 30 controls the operation of the second three-way valve 13c so that the heat medium pumped from the second pump 16b circulates between the chiller 14c and the outdoor heat exchanger 19.

Therefore, in the heating mode, the high-pressure refrigerant discharged from the compressor 14d radiates heat to the heat medium on the first sub circulation path 101 side, which is pressure-fed from the first pump 16a in the water-refrigerant heat exchanger 14a. As a result, the heat medium on the first sub circulation path 101 side is heated.

The heat medium heated by the water-refrigerant heat exchanger 14 a flows into the heater core 15 via the first three-way valve 13. The heat medium flowing into the heater core 15 exchanges heat with the blown air and radiates heat to the blown air. Thereby, the blown air is heated. The heat medium flowing out from the heater core 15 is sucked into the first pump 16a and is again pressure-fed to the water-refrigerant heat exchanger 14a.

On the other hand, the low-pressure refrigerant whose pressure has been reduced by the expansion valve 14b absorbs heat from the heat medium on the side of the second auxiliary circulation path 102 that is pressure-fed from the second pump 16b when it is evaporated by the chiller 14c. As a result, the heat medium on the second sub circulation path 102 side is cooled.

The heat medium cooled by the chiller 14c flows into the outdoor heat exchanger 19 via the second three-way valve 13c. The heat medium flowing into the outdoor heat exchanger 19 exchanges heat with the outside air and absorbs heat from the outside air. In other words, the outdoor heat exchanger 19 cools the outside air. The heat medium that has flowed out of the outdoor heat exchanger 19 is sucked into the second pump 16b and is again pressure-fed to the chiller 14c.

That is, in the heating mode, the heat absorbed by the heat medium on the second sub circulation path 102 side from the outside air is moved to the heat medium on the first sub circulation path 101 side by the heat pump cycle 14. Then, the heat transferred to the heat medium on the side of the first sub circulation path 101 is radiated to the blown air by the heater core 15. Therefore, the air in the vehicle compartment can be heated by blowing the blast air heated by the heater core 15 into the vehicle interior.

(B) Cooling Mode In the cooling mode, the control device 30 operates the heat pump cycle 14. Further, the control device 30 operates both the first pump 16a and the second pump 16b.

Further, the control device 30 controls the operation of the first three-way valve 13 so that the heat medium pumped from the first pump 16a circulates between the water-refrigerant heat exchanger 14a and the outdoor heat exchanger 19. To do. Further, the control device 30 controls the operation of the second three-way valve 13c so that the heat medium pumped from the second pump 16b circulates between the chiller 14c and the cooler core 15a.

Therefore, in the cooling mode, the high-pressure refrigerant discharged from the compressor 14d radiates heat to the heat medium on the first sub circulation path 101 side, which is pressure-fed from the first pump 16a in the water-refrigerant heat exchanger 14a. As a result, the heat medium on the first sub circulation path 101 side is heated.

The heat medium heated by the water-refrigerant heat exchanger 14 a flows into the outdoor heat exchanger 19 via the first three-way valve 13. The heat medium that has flowed into the outdoor heat exchanger 19 exchanges heat with the outside air and radiates heat to the outside air. In other words, the outdoor heat exchanger 19 heats the outside air. The heat medium that has flown out of the outdoor heat exchanger 19 is sucked into the first pump 16a and is again sent to the water-refrigerant heat exchanger 14a under pressure.

On the other hand, the low-pressure refrigerant whose pressure has been reduced by the expansion valve 14b absorbs heat from the heat medium on the side of the second auxiliary circulation path 102 that is pressure-fed from the second pump 16b when it is evaporated by the chiller 14c. As a result, the heat medium on the second sub circulation path 102 side is cooled.

The heat medium cooled by the chiller 14c flows into the cooler core 15a via the second three-way valve 13c. The heat medium flowing into the cooler core 15a exchanges heat with the blown air and absorbs heat from the blown air. Thereby, the blown air is cooled. The heat medium flowing out from the cooler core 15a is sucked into the second pump 16b and again sent under pressure to the chiller 14c.

That is, in the cooling mode, the heat absorbed by the heat medium on the second sub circulation path 102 side from the blower air in the cooler core 15a is moved to the heat medium on the first sub circulation path 101 side by the heat pump cycle 14. The heat transferred to the heat medium on the side of the first sub circulation path 101 is radiated to the outside air by the outdoor heat exchanger 19. Therefore, the air in the vehicle compartment can be cooled by blowing the blast air cooled by the cooler core 15a into the vehicle interior.

As described above, in the vehicle air conditioner 20 of the present embodiment, the flow pattern of the cooling water in the heat medium circulation circuit 10 is switched by the first three-way valve 13 and the second three-way valve 13c to heat and cool the vehicle interior. be able to.

Further, the temperature adjusting device 1a of the present embodiment can be operated in the air bleeding mode as in the first embodiment. In this embodiment, the heat medium is injected from the water injection port 19b of the outdoor heat exchanger 19 prior to the air bleeding mode. In the air bleeding mode, the control device 30 stops the heat pump cycle 14. Further, the control device 30 operates either the first pump 16a or the second pump 16b.

Further, the control device 30 controls the operation of the first three-way valve 13 so that the heat medium pumped from the first pump 16a flows into both the heater core 15 and the outdoor heat exchanger 19. Further, the control device 30 controls the operation of the second three-way valve 13c so that the heat medium pumped from the second pump 16b flows into both the cooler core 15a and the outdoor heat exchanger 19.

As a result, in the air bleeding mode, the heat medium pumped by at least one of the first pump 16a and the second pump 16b is divided into a flow path through which the heat medium flows in the cooling mode and a flow path through which the heat medium flows in the heating mode. It becomes possible to supply to both. Therefore, the air bleeding mode can be performed also in the heat medium circulation circuit 10 of the present embodiment.

By the way, in the outdoor heat exchanger 19 of the present embodiment, as described above, in the cooling mode, the outside air is heated by the heat medium heated by the water-refrigerant heat exchanger 14a which is the main temperature adjusting unit. Can be expressed. Further, in the outdoor heat exchanger 19 of the present embodiment, as described above, it can be said that in the heating mode, the outside air is cooled by the heat medium cooled by the chiller 14c that is the sub-temperature adjusting unit. ..

That is, in the present embodiment, it can be considered that the outside air is the temperature adjustment target fluid and the outdoor heat exchanger 19 is the heat exchange unit.

According to this, the heat medium circulation circuit 10 in the heating mode is switched to the first pattern in which the heat medium pumped by the second pump 16b is circulated between the chiller 14c and the outdoor heat exchanger 19. The heat medium circulation circuit 10 in the cooling mode is switched to the second pattern in which the heat medium pumped by the first pump 16a is circulated between the water-refrigerant heat exchanger 14a and the outdoor heat exchanger 19. ..

Further, the heat medium circulation circuit 10 in the air bleeding mode includes a flow path through which the heat medium flows when the heat medium pumped by at least one of the first pump 16a and the second pump 16b is switched to the first pattern. When switched to the second pattern, it is switched to the third pattern in which the heat medium can be supplied to both of the flow paths.

Therefore, also in the temperature adjusting device 1a of the present embodiment, the temperature of the temperature adjustment target fluid can be appropriately adjusted. Furthermore, it is possible to prevent air from remaining in the heat medium circulation circuit 10 when pouring the heat medium into the heat medium circulation circuit 10.

(Other embodiments)
The present invention is not limited to the above-described embodiments, but can be variously modified as follows without departing from the spirit of the present invention.

(1) In the above-described embodiment, an example in which the temperature adjusting device 1, 1a according to the present invention is used to perform air conditioning in the vehicle interior has been described, but the application target of the temperature adjusting device 1, 1a is not limited to this. .. The present invention is widely applicable to a temperature adjustment device that changes the flow pattern of the heat medium in the heat medium circulation circuit 10 in order to adjust the temperature of the temperature adjustment target fluid.

(2) In the above-described first embodiment, an example in which the heat pump cycle 14 is used as the sub-temperature adjustment unit has been described, but the main temperature adjustment unit and the sub-temperature adjustment unit are limited to those disclosed in the above-described embodiment. Not done. For example, an electric heater that generates heat when supplied with electric power may be used as the sub-temperature adjustment unit of the first embodiment.

For example, in the fifth embodiment, a Peltier element may be used instead of the heat pump cycle 14. Then, the surface on the heat radiation side may be used as the main temperature adjustment section, and the surface on the heat absorption side may be used as the sub temperature adjustment section. Further, in the fifth embodiment, the chiller 14c serves as the main temperature adjusting unit, the second pump 16b serves as the main pump, the water-refrigerant heat exchanger 14a serves as the sub-temperature adjusting unit, and the first pump 16a serves as the sub-pump. Good.

Further, the main temperature adjusting unit and the sub temperature adjusting unit are not limited to those that heat the heat medium. The heat medium may be cooled like the chiller 14c of the fifth embodiment.

(3) In the above embodiment, an example in which the operation in the air bleeding mode is performed by connecting the service tool to the control device 30 has been described, but the present invention is not limited to this. For example, the operation panel may be provided with a dedicated switch for requesting execution of the air bleeding mode. Furthermore, the air bleeding mode may be executed by a combination of long pressing of existing switches and simultaneous pressing of a plurality of switches.

(4) During the water injection work or the air bleeding mode described in the above embodiment, so-called racing may be performed in which the engine is operated at a relatively low rotation speed.

1, 1a Temperature control device 10 Heat medium circulation circuit 13, 13c First and second three-way valve (switching part)
13a, 13b 1st, 2nd on-off valve (switching part)
14 Heat pump cycle (sub-temperature control unit)
14a, 14c Water-refrigerant heat exchanger (main temperature adjusting part), chiller (sub temperature adjusting part)
15 Heater core (heat exchange part)
16a, 16b First pump (main pump), second pump (sub pump)
19 Outdoor heat exchanger (heat exchange part)
EG Internal combustion engine (main temperature control unit)
FC fuel cell (main temperature control unit)

Claims (6)

A heat medium circulation circuit (10) for circulating a heat medium,
A main temperature adjusting unit (EG) for adjusting the temperature of the heat medium,
A sub-temperature adjusting unit (14) for adjusting the temperature of the heat medium,
A heat exchange section (15) for adjusting the temperature of the temperature adjustment target fluid by exchanging heat between the heat medium whose temperature has been adjusted and the temperature adjustment target fluid in at least one of the main temperature adjustment section and the sub temperature adjustment section. When,
A main pump (16a) that operates at least when the heat medium whose temperature is adjusted by the main temperature adjusting unit is pressure-fed to the heat exchanging unit;
A sub-pump (16b) that operates at least when the heat medium whose temperature has been adjusted by the sub-temperature adjusting unit is pressure-fed to the heat exchanging unit;
A switching unit (13) for switching the circuit configuration of the heat medium circulation circuit (10),
The switching unit,
A first pattern for circulating the heat medium pumped by the sub pump between the sub temperature adjusting unit and the heat exchanging unit;
A second pattern for circulating the heat medium pumped by the main pump between the main temperature adjusting section and the heat exchanging section;
The heat medium pressure-fed by at least one of the main pump and the sub-pump, and the heat medium when switched to the flow path and the second pattern through which the heat medium flows when switched to the first pattern. A temperature adjusting device that switches to a third pattern that can supply both of the flow paths through which the medium flows. A parallel path (10a) for guiding the heat medium flowing out of the heat exchange section to the heat medium inlet side of the heat exchange section by bypassing the main temperature adjusting section;
The switching unit (13),
In the first pattern, while opening the parallel path, the heat medium flowing out of the heat exchange section is allowed to flow into the parallel path,
In the second pattern, the parallel path is closed,
In the third pattern, while opening the parallel passage, the heat medium pumped by the main pump is caused to flow into both the heat exchanging section and the parallel passage, so that the heat medium pumped by the main pump. Is supplied to both the flow path through which the heat medium flows when switched to the first pattern and the flow path through which the heat medium flows when switched to the second pattern. Temperature control device. The flow direction of the heat medium in the parallel path when switched to the first pattern and the flow direction of the heat medium in the parallel path when switched to the third pattern are different. The temperature control device described. The sub pump is arranged in the parallel path,
The temperature adjusting device according to claim 2, wherein the main pump has a maximum pumping capacity of the heat medium larger than that of the sub pump. The switching unit is a three-way valve (13) that connects at least two of the heat medium outlet side of the main temperature adjusting unit, the heat medium inlet side of the heat exchanging unit, and one inflow outlet of the parallel passage. The temperature adjusting device according to any one of claims 2 to 4. The switching section includes a cylindrical rotary valve section (131) and a body section (132) that rotatably accommodates the rotary valve section around a central axis.
The temperature control according to claim 5, wherein the rotary valve section is formed with a communication path that communicates the outlet of the main temperature control section, the inlet of the heat exchange section, and one inflow/outlet of the parallel path with each other. apparatus.

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