JP6451535B2 - Thermal management device - Google Patents

Description

  The present invention relates to an apparatus for managing heat.

  Conventionally, Patent Document 1 describes a vehicle thermal management device that selectively passes hot water generated by a condenser of a refrigeration cycle and cold water generated by an evaporator of a refrigeration cycle to a plurality of thermal devices using a valve unit. Has been. The plurality of heat devices are an electric device, a heat exchanger for air conditioning, a heat accumulator, and the like.

  In this prior art, the temperature of a some thermal apparatus is adjusted, when the hot water or cold water produced | generated by the refrigerating cycle flows through a several thermal apparatus.

International Publication No. 2011/015426

  In the above prior art, the volume of water varies as the temperature of the water changes. When the volume of water changes, the pressure in the water circuit changes. If the pressure in the water circuit rises too much, the heat exchanger or the like will be damaged. If the pressure in the water circuit decreases too much, cavitation occurs or the water hose is crushed, leading to a decrease in the water flow rate.

  Therefore, a reserve tank is required to buffer the volume fluctuation of water. The reserve tank is a container for storing excess water. The reserve tank can buffer the fluctuation in the volume of water, thereby suppressing the pressure fluctuation in the water circuit.

  However, in the above prior art, water pipes and water hoses are frequently used in the water circuit, and a large amount of water is sealed in the water circuit, so that the volume fluctuation amount of water accompanying the temperature change of water becomes very large. . Therefore, it is necessary to increase the capacity of the reserve tank in order to sufficiently buffer the volume fluctuation of water.

  When the capacity of the reserve tank is increased, there are problems such as deterioration in mountability, an increase in weight, a heat transfer delay due to an increase in the heat capacity of water, and an increase in the amount of water discarded during water exchange.

  In view of the above points, an object of the present invention is to suppress pressure fluctuation of a heat medium without increasing the capacity of a reserve tank.

In order to achieve the above object, in the invention described in claim 1,
Pumps (11, 12) for sucking and discharging the heat medium;
Circulation channels (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass channel (50, 51) in which the heat medium flows by bypassing a part of the circulation channel;
Pressure adjusting means (20, 55, 57, 82) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to the reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium relative to the pressure adjusting means (20) Pressure loss ratio adjusting means (21, 23, 84, etc.) for adjusting the pressure loss ratio, which is a ratio divided by the pressure loss of the downstream flow path (50b, 51b) located on the downstream side of the heat medium from the pressure adjusting means (20). 85, 87 )
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low ,
The pressure loss ratio adjusting means (21, 23, 84, 85, 87) is characterized by reducing the pressure loss of the downstream flow path (50b, 51b) when the heat medium is injected from the outside .

  According to this, when the temperature or pressure of the heat medium is high, the difference between the discharge pressure of the pump (11, 12) and the reference pressure can be reduced, so that the discharge pressure of the pump (11, 12) is prevented from rising excessively. it can.

  On the other hand, when the temperature or pressure of the heat medium is low, the difference between the suction pressure of the pump (11, 12) and the reference pressure can be reduced, so that the suction pressure of the pump (11, 12) can be suppressed from being excessively lowered.

In order to achieve the above object, in the invention according to claim 9,
Pumps (11, 12) for sucking and discharging the heat medium;
Circulation channels (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass channel (50, 51) in which the heat medium flows by bypassing a part of the circulation channel;
Pressure adjusting means (20, 55, 57, 82) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to the reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium relative to the pressure adjusting means (20) Pressure loss ratio adjusting means for adjusting the pressure loss ratio (the ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means (20, 55, 57, 82)) 88, 89),
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low,
The pressure loss ratio adjusting means is a member (88) that forms the upstream channel (50a, 51a) and a member (89) that forms the downstream channel (50b, 51b),
The member (88) forming the upstream channel (50a, 51a) is softer in structure or material as compared to the member (89) forming the downstream channel (50b, 51b). It is characterized by.
Thus, the same effect as that attained by the 1st aspect can be attained.
In order to achieve the above object, in the invention according to claim 10,
Pumps (11, 12) for sucking and discharging the heat medium;
Circulation channels (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass channel (50, 51) in which the heat medium flows by bypassing a part of the circulation channel;
Pressure adjusting means (20, 55, 57, 82) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to the reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium relative to the pressure adjusting means (20) Pressure loss ratio adjusting means for adjusting the pressure loss ratio (the ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means (20, 55, 57, 82)) 85)
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low,
The pressure loss ratio adjusting means is a valve (85) that adjusts the opening degree of at least one of the upstream channel (50a, 51a) and the downstream channel (50b, 51b),
The valve (85) has a mechanism (85a, 85d) that changes the opening degree of the flow path according to the pressure of the heat medium.
Thus, the same effect as that attained by the 1st aspect can be attained.
In order to achieve the above object, in the invention according to claim 11,
Pumps (11, 12) for sucking and discharging the heat medium;
Circulation channels (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass channel (50, 51) in which the heat medium flows by bypassing a part of the circulation channel;
Pressure adjusting means (20, 55, 57, 82) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to the reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium relative to the pressure adjusting means (20) Pressure loss ratio adjusting means for adjusting the pressure loss ratio (the ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means (20, 55, 57, 82)) 85)
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low,
The pressure loss ratio adjusting means is a valve (85) that adjusts the opening degree of at least one of the upstream channel (50a, 51a) and the downstream channel (50b, 51b),
The valve (85) has a mechanism (85a, 85d, 85e) that changes the opening degree of the flow path according to the temperature of the heat medium.
Thus, the same effect as that attained by the 1st aspect can be attained.
In order to achieve the above object, in the invention according to claim 12,
Pumps (11, 12) for sucking and discharging the heat medium;
Circulation channels (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass channel (50, 51) in which the heat medium flows by bypassing a part of the circulation channel;
Pressure adjusting means (20, 55, 57, 82) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to the reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium relative to the pressure adjusting means (20) Pressure loss ratio adjusting means for adjusting the pressure loss ratio (the ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means (20, 55, 57, 82)) 21, 23)
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low,
The pressure loss ratio adjusting means is a valve (21, 23) that adjusts the opening of at least one of the upstream channel (50a, 51a) and the downstream channel (50b, 51b),
The valves (21, 23) have a valve body that changes the opening degree of the flow path, and an electric drive means that drives the valve body,
And detecting means (61, 62, 63) for detecting at least one of the pressure and temperature of the heat medium;
Control means (60) for controlling the operation of the valves (21, 23) based on the detection results of the detection means (61, 62, 63),
When the pump (11, 12) is started, the control means (60) is configured to reduce the pressure loss ratio so as to reduce the pressure loss in the upstream flow path (50a, 51a) and the pressure loss in the downstream flow path (50b, 51b). The operation of the adjusting means (21, 23) is controlled.
Thus, the same effect as that attained by the 1st aspect can be attained.
In order to achieve the above object, in the invention according to claim 13,
Pumps (11, 12) for sucking and discharging the heat medium;
Circulation channels (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass channel (50, 51) in which the heat medium flows by bypassing a part of the circulation channel;
Pressure adjusting means (55) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to a reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium relative to the pressure adjusting means (20) Pressure loss ratio adjusting means (21, 23, 84, etc.) for adjusting the pressure loss ratio, which is a ratio divided by the pressure loss of the downstream flow path (50b, 51b) located on the downstream side of the heat medium relative to the pressure adjusting means (55). 85, 87, 88, 89),
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low,
The pressure adjusting means (55)
A tank portion (55a) that communicates with the bypass flow path (50, 51) and stores the heat medium;
A reserve tank having a pressure adjusting valve (55c) for sealing the tank (55a) and adjusting the pressure of the heat medium by taking air in and out of the tank (55a),
Furthermore, the tank channel (56a) communicates with the upstream channel (50a, 51a) and the downstream channel (50b, 51b), and the tank channel (56) through which the heat medium flowing into and out of the tank unit (55a) flows. ).
Thus, the same effect as that attained by the 1st aspect can be attained.
In order to achieve the above object, the invention according to claim 14 provides:
Pumps (11, 12) for sucking and discharging the heat medium;
Circulation channels (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass channel (50, 51) in which the heat medium flows by bypassing a part of the circulation channel;
Pressure adjusting means (20, 55) communicating with the bypass channel (50, 51) and adjusting the pressure of the heat medium to the reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium relative to the pressure adjusting means (20) Pressure loss ratio adjusting means (21, 23,) for adjusting the pressure loss ratio, which is a ratio divided by the pressure loss of the downstream flow paths (50b, 51b) located on the downstream side of the heat medium from the pressure adjusting means (20, 55). 84, 85, 87, 88, 89)
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low,
The pressure adjusting means (20, 55)
Tank portions (20a, 20b, 55a) that communicate with the bypass flow paths (50, 51) and store the heat medium;
The tank parts (20a, 20b, 55a) are sealed, and pressure adjusting valves (20c, 55c) for adjusting the pressure of the heat medium by taking air in and out of the tank parts (20a, 20b, 55a). Reserve tank,
The pumps are a first pump (11) and a second pump (12),
The circulation channel is a first circulation channel in which the first pump (11) is arranged, and a second circulation channel in which the second pump (12) is arranged,
The bypass channel (50, 51) includes a first bypass channel (50) in which the heat medium flows bypassing a part of the first circulation channel, and a heat medium bypasses a part of the second circulation channel. A second bypass flow path (51) flowing through
Furthermore, a communication flow path (52) that connects the first bypass flow path (50, 51) and the second bypass flow path (50, 51) is provided.
The pressure adjusting means (20, 55) is characterized in that it communicates with both the first bypass channel (50) and the second bypass channel (51).
Thus, the same effect as that attained by the 1st aspect can be attained.
In order to achieve the above object, the invention according to claim 17 provides:
Pumps (11, 12) for sucking and discharging the heat medium;
Circulation channels (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass channel (50, 51) in which the heat medium flows by bypassing a part of the circulation channel;
Pressure adjusting means (57) communicating with the bypass channel (50, 51) and adjusting the pressure of the heat medium to a reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium relative to the pressure adjusting means (20) Pressure loss ratio adjusting means (21, 23, 84, etc.) for adjusting the pressure loss ratio, which is a ratio divided by the pressure loss of the downstream flow path (50b, 51b) located on the downstream side of the heat medium from the pressure adjusting means (57). 85, 87, 88, 89),
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low,
Pressure adjustment means
A tank portion (57a) communicating with the bypass flow path (50, 51) and storing the heat medium;
A reserve tank (57) having a pressure adjusting valve (57c) for adjusting the pressure of the heat medium by taking in and out the heat medium between the bypass flow path (50, 51) and the tank part (57a);
The pumps are a first pump (11) and a second pump (12),
The circulation channel is a first circulation channel in which the first pump (11) is arranged, and a second circulation channel in which the second pump (12) is arranged,
The bypass channel (50, 51) includes a first bypass channel (50) in which the heat medium flows bypassing a part of the first circulation channel, and a heat medium bypasses a part of the second circulation channel. A second bypass flow path (51) flowing through
Furthermore, a communication flow path (52) for communicating the first bypass flow path (50) and the second bypass flow path (51) is provided,
The pressure regulating valve (57c) is arranged in the communication channel (52).
Thus, the same effect as that attained by the 1st aspect can be attained.
In addition, the code | symbol in the bracket | parenthesis of each means described in this column and the claim shows the correspondence with the specific means as described in embodiment mentioned later.

It is a whole block diagram of the thermal management apparatus for vehicles in 1st Embodiment. It is a block diagram which shows the electric control part of the thermal management system for vehicles in 1st Embodiment. It is a whole block diagram of the thermal management apparatus for vehicles in 2nd Embodiment. It is a whole block diagram of the thermal management apparatus for vehicles in 3rd Embodiment. It is a whole block diagram of the thermal management apparatus for vehicles in 4th Embodiment. It is sectional drawing which shows the pressure loss adjustment throttle of the thermal management apparatus for vehicles in 4th Embodiment. It is sectional drawing which shows the pressure-loss adjustment valve of the thermal management apparatus for vehicles in 4th Embodiment. It is sectional drawing which shows the pressure-loss adjustment valve of the thermal management apparatus for vehicles in 5th Embodiment. It is a block diagram which shows the connection structure of the four-way valve and reserve tank of the thermal management apparatus for vehicles in 6th Embodiment. It is sectional drawing which shows the member which forms the upstream flow path of the thermal management apparatus for vehicles in 7th Embodiment. It is sectional drawing which shows the member which forms the downstream flow path of the thermal management apparatus for vehicles in 7th Embodiment.

  Hereinafter, embodiments will be described with reference to the drawings. In the following embodiments, the same or equivalent parts are denoted by the same reference numerals in the drawings.

(First embodiment)
The vehicle thermal management apparatus 10 shown in FIG. 1 is used to adjust various devices and vehicle interiors included in a vehicle to an appropriate temperature. In the present embodiment, the vehicle thermal management device 10 is applied to a hybrid vehicle that obtains vehicle driving force from an engine and a driving electric motor. The engine is an internal combustion engine. The electric motor for traveling is a motor generator.

  The hybrid vehicle of this embodiment is configured as a plug-in hybrid vehicle. A plug-in hybrid vehicle is a hybrid vehicle that can charge power supplied from an external power source to a vehicle-mounted battery mounted on the vehicle when the vehicle is stopped. The external power source is a commercial power source. The in-vehicle battery is a rechargeable battery. The battery is, for example, a lithium ion battery.

  The driving force output from the engine is used not only for driving the vehicle, but also for operating the generator. And the electric power generated with the generator and the electric power supplied from the external power supply can be stored in the battery. The battery can also store, as regenerative energy, electric power regenerated by the traveling electric motor during deceleration or downhill.

  The electric power stored in the battery is supplied not only to the electric motor for traveling but also to various in-vehicle devices including the electric components constituting the vehicle thermal management device 10.

  The plug-in hybrid vehicle charges the battery from an external power source when the vehicle is stopped before the vehicle starts running, so that the remaining battery charge SOC of the battery becomes equal to or greater than a predetermined reference running balance as at the start of driving. When the vehicle is in the EV travel mode. The EV travel mode is a travel mode in which the vehicle travels by the driving force output from the travel electric motor.

  On the other hand, when the remaining battery charge SOC of the battery is lower than the reference running remaining amount during vehicle travel, the HV travel mode is set. The HV travel mode is a travel mode in which the vehicle travels mainly by the driving force output from the engine. When the vehicle travel load becomes high, the travel electric motor is operated to assist the engine.

  In the plug-in hybrid vehicle of this embodiment, the fuel consumption of the engine is suppressed with respect to a normal vehicle that obtains the driving force for vehicle travel only from the engine by switching between the EV travel mode and the HV travel mode in this way. This improves vehicle fuel efficiency. Switching between the EV traveling mode and the HV traveling mode is controlled by a driving force control device (not shown).

  As shown in FIG. 1, the vehicle thermal management device 10 includes a first pump 11, a second pump 12, a radiator 13, a cooling water cooler 14, a cooling water heater 15, a cooler core 16, a heater core 17, and a first thermal device. 18, a second thermal device 19, a reserve tank 20, a first switching valve 21, a second switching valve 22, a third switching valve 23 and a fourth switching valve 24.

  The first pump 11 and the second pump 12 are electric pumps that suck and discharge cooling water. The cooling water is a fluid as a heat medium. In the present embodiment, as the cooling water, a liquid containing at least ethylene glycol, dimethylpolysiloxane or nanofluid, or an antifreeze liquid is used.

  The first pump 11 and the second pump 12 are flow rate adjusting means for adjusting the flow rate of the cooling water flowing through each cooling water circulation device.

  The radiator 13, the cooling water cooler 14, the cooling water heater 15, the cooler core 16, the heater core 17, the first heat device 18 and the second heat device 19 are cooling water circulation devices through which the cooling water flows.

  The radiator 13 is a cooling water outside air heat exchanger that exchanges heat between cooling water and outside air. Outside air is air outside the passenger compartment. By flowing cooling water having a temperature equal to or higher than the outside air temperature to the radiator 13, heat can be radiated from the cooling water to the outside air. By flowing cooling water below the outside air temperature through the radiator 13, it is possible to absorb heat from the outside air to the cooling water. In other words, the radiator 13 can exhibit a function as a radiator that radiates heat from the cooling water to the outside air and a function as a heat absorber that absorbs heat from the outside air to the cooling water.

  The radiator 13 is a heat transfer device that has a flow path through which cooling water flows and that transfers heat to and from the cooling water whose temperature is adjusted by the cooling water cooler 14 or the cooling water heater 15.

  The outdoor blower 30 is an outside air blower that blows outside air to the radiator 13. The outdoor blower 30 is an electric blower. The radiator 13 and the outdoor blower 30 are disposed in the foremost part of the vehicle. For this reason, the traveling wind can be applied to the radiator 13 when the vehicle is traveling. The outdoor blower 30 is a flow rate adjusting unit that adjusts the flow rate of the outside air flowing through the radiator 13.

  The cooling water cooler 14 and the cooling water heater 15 are cooling water temperature adjusting heat exchangers that adjust the temperature of the cooling water by exchanging heat of the cooling water. The cooling water cooler 14 is a cooling water cooling heat exchanger that cools the cooling water. The cooling water heater 15 is a cooling water heating heat exchanger that heats the cooling water.

  The cooling water cooler 14 is a heat medium heat absorber that absorbs heat from the cooling water to the low pressure side refrigerant by exchanging heat between the low pressure side refrigerant of the refrigeration cycle 31 and the cooling water. The cooling water cooler 14 is an evaporator of the refrigeration cycle 31. The cooling water cooler 14 is a low pressure side heat exchanger of the refrigeration cycle 31.

  The refrigeration cycle 31 is a vapor compression refrigeration machine including a compressor 32, a cooling water heater 15, an expansion valve 33, and a cooling water cooler 14. In the refrigeration cycle 31 of the present embodiment, a chlorofluorocarbon refrigerant is used as the refrigerant, which constitutes a subcritical refrigeration cycle. The subcritical refrigeration cycle is a refrigeration cycle in which the high-pressure side refrigerant pressure does not exceed the critical pressure of the refrigerant.

  The compressor 32 is an electric compressor driven by electric power supplied from a battery, and sucks, compresses and discharges the refrigerant of the refrigeration cycle 31.

  The cooling water heater 15 is a condenser that condenses the high-pressure side refrigerant by exchanging heat between the high-pressure side refrigerant discharged from the compressor 32 and the cooling water. The cooling water heater 15 is a high-pressure side heat exchanger of the refrigeration cycle 31.

  The expansion valve 33 is a decompression unit that decompresses and expands the liquid-phase refrigerant that has flowed out of the cooling water heater 15. The expansion valve 33 includes a temperature sensing unit that detects the degree of superheat of the coolant cooler 14 outlet-side refrigerant based on the temperature and pressure of the coolant cooler 14 outlet-side refrigerant. This is a temperature type expansion valve that adjusts the throttle passage area by a mechanical mechanism so that the degree of superheat falls within a predetermined range.

  The cooling water cooler 14 is an evaporator that evaporates the low-pressure refrigerant by exchanging heat between the low-pressure refrigerant decompressed and expanded by the expansion valve 33 and the cooling water. The gas phase refrigerant evaporated in the cooling water cooler 14 is sucked into the compressor 32 and compressed.

  The refrigeration cycle 31 is a cooling water cooling and heating means having a cooling water cooler 14 for cooling the cooling water and a cooling water heater 15 for heating the cooling water. In other words, the refrigeration cycle 31 is a low-temperature cooling water generating means for generating low-temperature cooling water by the cooling water cooler 14 and a high-temperature cooling water generating means for generating high-temperature cooling water by the cooling water heater 15.

  In the radiator 13, the cooling water is cooled by outside air, whereas in the cooling water cooler 14, the cooling water is cooled by the low-pressure refrigerant of the refrigeration cycle 31. For this reason, the temperature of the cooling water cooled by the cooling water cooler 14 can be made lower than the temperature of the cooling water cooled by the radiator 13. Specifically, the radiator 13 cannot cool the cooling water to a temperature lower than the outside air temperature, whereas the cooling water cooler 14 can cool the cooling water to a temperature lower than the outside air temperature.

  The cooler core 16 and the heater core 17 are heat medium air heat exchange that adjusts the temperature of the blown air by exchanging heat between the cooling water whose temperature is adjusted by the cooling water cooler 14 and the cooling water heater 15 and the blown air to the vehicle interior. It is a vessel.

  The cooler core 16 is an air cooling heat exchanger that exchanges heat between cooling water and air blown into the vehicle interior to cool and dehumidify the air blown into the vehicle interior. The heater core 17 is an air heating heat exchanger that heats the air blown into the vehicle interior by exchanging heat between the air blown into the vehicle cabin and the cooling water.

  The cooler core 16 and the heater core 17 are accommodated in a case (not shown) of an indoor air conditioning unit of the vehicle air conditioner. The case of the indoor air conditioning unit forms an air passage for the blown air blown into the vehicle interior.

  An inside air inlet and an outside air inlet are formed on the most upstream side of the air flow in the case. The inside air suction port introduces inside air into the case. The outside air intake port introduces outside air into the case.

  An indoor blower is disposed in the case. The indoor blower is a blowing unit that blows the inside air sucked from the inside air suction port and the outside air sucked from the outside air suction port toward the vehicle interior. The indoor blower is an electric blower that drives a centrifugal multiblade fan with an electric motor. The centrifugal multiblade fan is a sirocco fan.

  A blower outlet that blows blown air into the vehicle interior, which is a space to be air-conditioned, is formed in the most downstream part of the case air flow. Specifically, a defroster outlet, a face outlet, and a foot outlet are provided as the outlet.

  The defroster air outlet blows conditioned air toward the inner surface of the vehicle front window glass. The face air outlet blows conditioned air toward the upper body of the passenger. The air outlet blows air-conditioned air toward the passenger's feet.

  The first heat device 18 and the second heat device 19 are heat transfer devices that have a flow path through which the cooling water flows and perform heat transfer with the cooling water. The first thermal device 18 and the second thermal device 19 are temperature adjustment target devices whose temperature is adjusted by cooling water.

  For example, the 1st thermal equipment 18 and the 2nd thermal equipment 19 are a cooling water cooling water heat exchanger, an inverter, a heat exchanger for battery temperature control, an oil heat exchanger, etc.

  The cooling water cooling water heat exchanger is a heat exchanger that exchanges heat between the cooling water of the vehicle heat management apparatus 10 and the cooling water of the engine cooling circuit. The engine cooling circuit is a cooling water circulation circuit for cooling the engine. The cooling water of the engine cooling circuit is an engine heat medium.

  The inverter is a power conversion device that converts DC power supplied from a battery into an AC voltage and outputs the AC voltage to a traveling electric motor. The inverter is a heat generating device that generates heat as it operates. The amount of heat generated by the inverter changes depending on the traveling state of the vehicle.

  The heat exchanger for battery temperature control is a heat exchanger that is disposed in the air blowing path to the battery and exchanges heat between the blown air and the cooling water. The battery temperature control heat exchanger is a heat medium air heat exchanger that exchanges heat between the heat medium and air. A battery is a heat-generating device that generates heat when activated.

  The oil heat exchanger is a heat exchanger that adjusts the temperature of oil by exchanging heat between engine oil or transmission oil and cooling water.

  The reserve tank 20 is a heat medium storage unit that stores cooling water. The reserve tank 20 is pressure adjusting means for adjusting the pressure of the cooling water in the cooling water circuit to the reference pressure.

  The reserve tank 20 includes a first tank portion 20a, a second tank portion 20b, and a pressure adjustment valve 20c. The 1st tank part 20a and the 2nd tank part 20b are comprised by the pressure vessel which stores cooling water.

  The internal spaces of the first tank portion 20a and the second tank portion 20b communicate with each other at an upper portion in the direction of gravity. Accordingly, the internal pressure of the first tank portion 20a and the internal pressure of the second tank portion 20b are the same.

  The pressure adjusting valve 20c is a pressure adjusting means for adjusting the internal pressures of the first tank portion 20a and the second tank portion 20b within a preset pressure range. The pressure regulating valve 20c is a cap member that seals the first tank portion 20a and the second tank portion 20b. The pressure regulating valve 20c regulates the pressure by taking air in and out of the first tank portion 20a and the second tank portion 20b.

  By storing excess cooling water in the first tank portion 20a and the second tank portion 20b, it is possible to suppress a decrease in the amount of cooling water circulating in each flow path. Inside the first tank portion 20a and the second tank portion 20b, bubbles mixed in the cooling water are separated.

  By adjusting the internal pressure of the first tank portion 20a and the second tank portion 20b by the pressure adjusting valve 20c, it is possible to maintain an appropriate pressure against an abnormal increase / decrease in pressure due to expansion / contraction due to a temperature change of the cooling water. .

  The first pump 11 is arranged in the first pump flow path 41. The second pump 12 is disposed in the second pump flow path 42. The radiator 13 is disposed in the radiator flow path 43.

  The cooling water cooler 14 is disposed in the cooling water cooler flow path 44. The cooling water cooler flow path 44 is branched from a portion of the first pump flow path 41 on the cooling water discharge side of the first pump 11. The cooling water heater 15 is disposed in the cooling water heater flow path 45. The cooling water heater channel 45 is branched from a portion of the second pump channel 42 on the downstream side of the cooling water flow with respect to the second pump 12.

  The cooler core 16 is disposed in the cooler core flow path 46. The heater core 17 is disposed in the heater core flow path 47.

  The first thermal device 18 is disposed in the first thermal device channel 48. The second thermal device 19 is disposed in the second thermal device channel 49.

  The first tank portion 20 a of the reserve tank 20 is disposed in the first bypass flow path 50. Therefore, the cooling water of the first bypass channel 50 circulates in the first tank portion 20a.

  The second tank portion 20 b of the reserve tank 20 is disposed in the second bypass flow path 51. Therefore, the cooling water of the second bypass channel 51 circulates in the second tank portion 20b.

  The first bypass channel 50 and the second bypass channel 51 are communicated with each other by a communication channel 52. The communication flow path 52 includes a portion of the first bypass flow path 50 on the downstream side of the cooling water flow with respect to the first tank portion 20a, and a second flow path of the second bypass flow passage 51 with respect to the downstream side of the cooling water flow with respect to the second tank portion 20b. Are connected to each other.

  The third bypass flow path 53 is a cooling water flow path in which cooling water flows bypassing the radiator 13, the cooler core 16, the heater core 17, and the first thermal device 18.

  Each flow path 41-53 is formed with piping or a hose. The pipe is formed of a hard material such as metal and does not expand or contract depending on the cooling water pressure. The hose is formed of a flexible material such as rubber, and expands and contracts according to the cooling water pressure.

  In this example, the radiator channel 43, the cooler core channel 46, the heater core channel 47, the first thermal device channel 48, the second thermal device channel 49, the first bypass channel 50, and the second bypass. Most of the flow path 51 and the communication flow path 52 are formed of flexible hoses.

  1st pump flow path 41, 2nd pump flow path 42, radiator flow path 43, cooling water cooler flow path 44, cooling water heater flow path 45, cooler core flow path 46, heater core flow path 47, The first thermal device channel 48, the second thermal device channel 49, the first bypass channel 50, and the second bypass channel 51 are the first switching valve 21, the second switching valve 22, and the third switching valve 23. And connected to one of the fourth switching valves 24.

  The first switching valve 21, the second switching valve 22, the third switching valve 23, and the fourth switching valve 24 are cooling water flow switching means for switching the flow of cooling water. The first switching valve 21, the second switching valve 22, the third switching valve 23, and the fourth switching valve 24 are circulation switching means for switching the cooling water circulation state.

  The first switching valve 21 has a first inlet 21a and a second inlet 21b as cooling water inlets, and a first outlet 21c, a second outlet 21d and a third outlet 21c as cooling water outlets.

  The second switching valve 22 has a first inlet 22a and a second inlet 22b as cooling water inlets, and a first outlet 22c, a second outlet 22d, a third outlet 22e, a fourth outlet 22f and a cooling water outlet, and It has a fifth outlet 22g.

  The third switching valve 23 has a first outlet 23a and a second outlet 23b as cooling water outlets, and a first inlet 23c, a second inlet 23d, and a third inlet 23e as cooling water inlets.

  The fourth switching valve 24 includes a first outlet 24a and a second outlet 24b as cooling water outlets, and a first inlet 24c, a second inlet 24d, a third inlet 24e, a fourth inlet 24f, and a cooling water inlet. It has a fifth inlet 24g.

  One end of a first pump flow path 41 is connected to the first inlet 21 a of the first switching valve 21. In other words, the cooling water discharge side of the first pump 11 is connected to the first inlet 21 a of the first switching valve 21.

  One end of a second pump flow path 42 is connected to the second inlet 21 b of the first switching valve 21. In other words, the cooling water discharge side of the second pump 12 is connected to the second inlet 21 b of the first switching valve 21.

  One end of a second heat equipment flow channel 49 is connected to the first outlet 21 c of the first switching valve 21. In other words, the cooling water inlet side of the second thermal device 19 is connected to the first outlet 21 c of the first switching valve 21.

  One end of the first bypass passage 50 is connected to the second outlet 21 d of the first switching valve 21. In other words, the cooling water inlet side of the first tank portion 20a is connected to the second outlet 21d of the first switching valve 21.

  One end of the second bypass passage 51 is connected to the third outlet 21 e of the first switching valve 21. In other words, the cooling water inlet side of the second tank portion 20 b is connected to the third outlet 21 e of the first switching valve 21.

  The other end of the cooling water cooler flow path 44 is connected to the first inlet 22 a of the second switching valve 22. In other words, the cooling water outlet side of the cooling water cooler 14 is connected to the first inlet 22 a of the second switching valve 22.

  The other end of the cooling water heater channel 45 is connected to the second inlet 22 b of the second switching valve 22. In other words, the cooling water outlet side of the cooling water heater 15 is connected to the second inlet 22 b of the second switching valve 22.

  One end of a radiator flow path 43 is connected to the first outlet 22 c of the second switching valve 22. In other words, the cooling water inlet side of the radiator 13 is connected to the first outlet 22 c of the second switching valve 22.

  One end of a cooler core flow path 46 is connected to the second outlet 22d of the second switching valve 22. In other words, the cooling water inlet side of the cooler core 16 is connected to the second outlet 22 d of the second switching valve 22.

  One end of a heater core channel 47 is connected to the third outlet 22 e of the second switching valve 22. In other words, the cooling water inlet side of the heater core 17 is connected to the third outlet 22e of the second switching valve 22.

  One end of a first heat equipment flow path 48 is connected to the fourth outlet 22 f of the second switching valve 22. In other words, the cooling water inlet side of the first thermal device 18 is connected to the fourth outlet 22 f of the second switching valve 22.

  One end of a third bypass channel 53 is connected to the fifth outlet 22g of the second switching valve 22.

  The other end of the first pump flow path 41 is connected to the first outlet 23 a of the third switching valve 23. In other words, the cooling water suction side of the first pump 11 is connected to the first outlet 23 a of the third switching valve 23.

  The other end of the second pump flow path 42 is connected to the second outlet 23 b of the third switching valve 23. In other words, the cooling water suction side of the second pump 12 is connected to the second inlet 23 b of the third switching valve 23.

  The other end of the second heat equipment flow channel 49 is connected to the first inlet 23 c of the third switching valve 23. In other words, the cooling water outlet side of the second thermal device 19 is connected to the first inlet 23 c of the third switching valve 23.

  The other end of the first bypass channel 50 is connected to the second inlet 23 d of the third switching valve 23. In other words, the cooling water outlet side of the first tank portion 20 a is connected to the second inlet 23 d of the third switching valve 23.

  The other end of the second bypass passage 51 is connected to the third inlet 23 e of the third switching valve 23. In other words, the cooling water outlet side of the second tank portion 20 b is connected to the third inlet 23 e of the third switching valve 23.

  The other end of the first pump flow path 41 is connected to the first outlet 24 a of the fourth switching valve 24. In other words, the cooling water suction side of the first pump 11 is connected to the first outlet 24 a of the fourth switching valve 24. That is, the other end of the first pump flow path 41 is branched into the third switching valve 23 side and the fourth switching valve 24 side.

  The other end of the second pump flow path 42 is connected to the second outlet 24 b of the fourth switching valve 24. In other words, the cooling water suction side of the second pump 12 is connected to the second outlet 24 b of the fourth switching valve 24. That is, the other end of the second pump flow path 42 is branched into the third switching valve 23 side and the fourth switching valve 24 side.

  The other end of the radiator flow path 43 is connected to the first inlet 24 c of the fourth switching valve 24. In other words, the coolant outlet side of the radiator 13 is connected to the first inlet 24 c of the fourth switching valve 24.

  The other end of the cooler core channel 46 is connected to the second inlet 24 d of the fourth switching valve 24. In other words, the cooling water outlet side of the cooler core 16 is connected to the second inlet 24 d of the fourth switching valve 24.

  The other end of the heater core channel 47 is connected to the third inlet 24 e of the fourth switching valve 24. In other words, the coolant outlet side of the heater core 17 is connected to the third inlet 24 e of the fourth switching valve 24.

  The other end of the first heat equipment flow path 48 is connected to the fourth inlet 24 f of the fourth switching valve 24. In other words, the cooling water outlet side of the first thermal device 18 is connected to the fourth inlet 24 f of the fourth switching valve 24.

  The other end of the third bypass passage 53 is connected to the fifth inlet 24g of the fourth switching valve 24.

  The 1st switching valve 21, the 2nd switching valve 22, the 3rd switching valve 23, and the 4th switching valve 24 have the structure which can switch arbitrarily or selectively the communication state of each inlet and each outlet.

  Specifically, the first switching valve 21 has a state in which the cooling water discharged from the first pump 11 flows into each of the second thermal device 19, the first tank unit 20a, and the second tank unit 20b, 2 has a valve body for switching between a state in which the cooling water discharged from the pump 12 flows in and a state in which the cooling water discharged from the first pump 11 and the cooling water discharged from the second pump 12 do not flow in. .

  The second switching valve 22 has a state in which the cooling water discharged from the first pump 11 flows into each of the radiator 13, the cooler core 16, the heater core 17, the first thermal device 18, and the third bypass flow path 53. A valve body that switches between a state in which the cooling water discharged from the pump 12 flows in and a state in which the cooling water discharged from the first pump 11 and the cooling water discharged from the second pump 12 do not flow in is provided.

  The third switching valve 23 is in a state where the cooling water flows out to the first pump 11 and the cooling water flows out to the second pump 12 for each of the second thermal equipment 19, the first tank unit 20a, and the second tank unit 20b. And a valve body that switches between a state in which the cooling water does not flow out to the first pump 11 and the second pump 12.

  The fourth switching valve 24 is in a state in which cooling water flows out to the first pump 11 and to the second pump 12 for each of the radiator 13, the cooler core 16, the heater core 17, the first thermal device 18, and the third bypass passage 53. A valve body that switches between a state in which the cooling water flows out and a state in which the cooling water does not flow out to the first pump 11 and the second pump 12 is provided.

  Each valve body of the 1st switching valve 21, the 2nd switching valve 22, the 3rd switching valve 23, and the 4th switching valve 24 can adjust valve opening. Thereby, the flow rate of the cooling water flowing through the radiator 13, the cooler core 16, the heater core 17, the first thermal device 18, the second thermal device 19, the first tank portion 20a, the second tank portion 20b, and the third bypass flow path 53 is adjusted. it can.

  That is, the 1st switching valve 21, the 2nd switching valve 22, the 3rd switching valve 23, and the 4th switching valve 24 are the radiator 13, the cooler core 16, the heater core 17, the 1st thermal equipment 18, the 2nd thermal equipment 19, and the 1st. It is a flow rate adjusting means for adjusting the flow rate of the cooling water for each of the tank portion 20a, the second tank portion 20b, and the third bypass flow path 53.

  The first switching valve 21 mixes the cooling water discharged from the first pump 11 and the cooling water discharged from the second pump 12 at an arbitrary flow rate ratio, and the radiator 13, the cooler core 16, the heater core 17, The first heat device 18, the second heat device 19, the first tank portion 20 a, the second tank portion 20 b, and the third bypass channel 53 can be made to flow.

  That is, the 1st switching valve 21 and the 2nd switching valve 22 are the radiator 13, the cooler core 16, the heater core 17, the 1st thermal equipment 18, the 2nd thermal equipment 19, the 1st tank part 20a, the 2nd tank part 20b, and the 3rd. A flow rate ratio adjusting unit that adjusts the flow rate ratio between the cooling water cooled by the cooling water cooler 14 and the cooling water heated by the cooling water heater 15 for each of the bypass channels 53.

  The 1st switching valve 21, the 2nd switching valve 22, the 3rd switching valve 23, and the 4th switching valve 24 may be formed integrally, and the valve body drive source may be shared. The 1st switching valve 21, the 2nd switching valve 22, the 3rd switching valve 23, and the 4th switching valve 24 may be comprised by the combination of many valves.

  Next, the electric control part of the thermal management apparatus 10 for vehicles is demonstrated based on FIG. The control device 60 is composed of a well-known microcontroller including a CPU, ROM, RAM, etc. and its peripheral circuits, and performs various calculations and processing based on an air conditioning control program stored in the ROM, and is connected to the output side. The control means controls the operation of various control target devices.

  The control target devices controlled by the control device 60 are the first pump 11, the second pump 12, the first switching valve 21, the second switching valve 22, the third switching valve 23, the fourth switching valve 24, and the like.

  Of the control device 60, hardware and software for controlling the operation of various control target devices connected to the output side constitute control means for controlling the operation of each control target device.

  The hardware and software for controlling the operations of the first pump 11 and the second pump 12 in the control device 60 are pump control means 60a. The pump control means 60a is a flow rate control means for controlling the flow rate of the cooling water flowing through each cooling water circulation device.

  The hardware and software for controlling the operation of the first switching valve 21, the second switching valve 22, the third switching valve 23, and the fourth switching valve 24 in the control device 60 are the switching valve control means 60b. The switching control means 60b is also a circulation switching control means for switching the cooling water circulation state. The switching control means 60b is also a flow rate control means for controlling the flow rate of the cooling water flowing through each cooling water circulation device.

  The hardware and software for controlling the operation of the compressor 32 in the control device 60 is a compressor control means 60c. The compressor control unit 60 c is a refrigerant flow rate control unit that controls the flow rate of the refrigerant discharged from the compressor 32.

  Each control means 60 a, 60 b, 60 c may be configured separately from the control device 60.

  A detection signal of the sensor group is input to the input side of the control device 60. The sensor group includes a first water temperature sensor 61, a second water temperature sensor 62, a circuit pressure sensor 63, a water level sensor 64, an outside air temperature sensor 65, a radiator temperature sensor 66, a cooler core temperature sensor 67, a heater core temperature sensor 68, and a first thermal equipment temperature. The sensor 69, the second thermal equipment temperature sensor 70, and the like.

  The first water temperature sensor 61 is a temperature detection unit that detects the temperature of the cooling water circulated by the first pump 11. For example, the first water temperature sensor 61 detects the temperature of the cooling water flowing out from the cooling water cooler 14.

  The second water temperature sensor 62 is a temperature detection unit that detects the temperature of the cooling water circulated by the second pump 12. For example, the second water temperature sensor 62 detects the temperature of the cooling water flowing out from the cooling water heater 15.

  The circuit pressure sensor 63 is a reference pressure detection unit that detects a reference pressure of the cooling water circuit. For example, the circuit pressure sensor 63 detects the pressure in the communication channel 52.

  The water level sensor 64 is a liquid level detection unit that detects the water level of the cooling water in the reserve tank 20. The outside air temperature sensor 65 is an outside air temperature detecting unit that detects the outside air temperature.

  The radiator temperature sensor 66 is temperature detection means for detecting the temperature of the radiator 13. For example, the radiator temperature sensor 66 is a fin thermistor that detects the temperature of the heat exchange fins of the radiator 13, a water temperature sensor that detects the temperature of cooling water flowing through the radiator 13, or the like.

  The cooler core temperature sensor 67 is temperature detection means for detecting the temperature of the cooler core 16. For example, the cooler core temperature sensor 67 is a fin thermistor that detects the temperature of heat exchange fins of the cooler core 16, a water temperature sensor that detects the temperature of cooling water flowing through the cooler core 16, or the like.

  The heater core temperature sensor 68 is temperature detection means for detecting the temperature of the heater core 17. For example, the heater core temperature sensor 68 is a fin thermistor that detects the temperature of heat exchange fins of the heater core 17, a water temperature sensor that detects the temperature of cooling water flowing through the heater core 17, or the like.

  The first thermal device temperature sensor 69 is a temperature detection unit that detects the temperature of the first thermal device 18. For example, the first thermal device temperature sensor 69 is a water temperature sensor that detects the temperature of the cooling water flowing through the first thermal device 18.

  The second thermal device temperature sensor 70 is a temperature detection unit that detects the temperature of the second thermal device 19. For example, the second thermal equipment temperature sensor 70 is a water temperature sensor or the like that detects the temperature of cooling water flowing through the second thermal equipment 19.

  The control device 60 estimates the refrigerant pressure of the refrigeration cycle 31 based on the outside air temperature, the temperature of the cooling water, the rotational speed of the compressor 32, and the like. The control device 60 may estimate the refrigerant pressure of the refrigeration cycle 31 based on the temperature of the cooler core 16.

  Next, the operation in the above configuration will be described. The control device 60 controls the operation of the first pump 11, the second pump 12, the compressor 32, the first switching valve 21, the second switching valve 22, the third switching valve 23, the fourth switching valve 24, and the like, It can be switched to various operating modes.

  For example, a low temperature side cooling water circuit and a high temperature side cooling water circuit are formed. In the low-temperature side cooling water circuit, the cooling water sucked and discharged by the first pump 11 includes a cooling water cooler 14, a radiator 13, a cooler core 16, a heater core 17, a first thermal device 18, a second thermal device 19, It is a cooling water circuit that circulates between at least one of the first tank part 20a and the second tank part 20b.

  In the high temperature side cooling water circuit, the cooling water sucked and discharged by the second pump 12 includes a cooling water heater 15, a radiator 13, a cooler core 16, a heater core 17, a first thermal device 18, a second thermal device 19, It is a cooling water circuit that circulates between at least one of the first tank part 20a and the second tank part 20b.

  When each of the radiator 13, the cooler core 16, the heater core 17, the first thermal device 18, the second thermal device 19, the first tank unit 20a and the second tank unit 20b is connected to the low temperature side cooling water circuit, the high temperature side By switching the case of being connected to the cooling water circuit depending on the situation, the radiator 13, the cooler core 16, the heater core 17, the first thermal device 18, the second thermal device 19, the first tank portion 20a and the second tank portion 20b. Can be adjusted to an appropriate temperature according to the situation.

  When the radiator 13 is connected to the low temperature side cooling water circuit, the heat pump operation of the refrigeration cycle 31 can be performed. That is, in the low temperature side cooling water circuit, the cooling water cooled by the cooling water cooler 14 flows through the radiator 13, so that the cooling water absorbs heat from the outside air by the radiator 13.

  Then, the cooling water that has absorbed heat from the outside air by the radiator 13 exchanges heat with the refrigerant of the refrigeration cycle 31 by the cooling water cooler 14 and dissipates heat. Therefore, in the cooling water cooler 14, the refrigerant of the refrigeration cycle 31 absorbs heat from the outside air through the cooling water.

  The refrigerant that has absorbed heat from the outside air in the cooling water cooler 14 exchanges heat with the cooling water in the high-temperature side cooling water circuit in the cooling water heater 15 to dissipate heat. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

  When the radiator 13 is connected to the high temperature side cooling water circuit, the cooling water heated by the cooling water heater 15 flows through the radiator 13, so that the heat of the cooling water can be radiated to the outside air by the radiator 13.

  When the cooler core 16 is connected to the low temperature side cooling water circuit, the cooling water cooled by the cooling water cooler 14 flows through the cooler core 16, so that the air blown into the vehicle compartment can be cooled and dehumidified by the cooler core 16. That is, the passenger compartment can be cooled and dehumidified.

  When the heater core 17 is connected to the high temperature side cooling water circuit, the cooling water heated by the cooling water heater 15 flows through the heater core 17, so that the air blown into the vehicle compartment can be heated by the heater core 17. That is, the passenger compartment can be heated.

  When the 1st thermal equipment 18 is connected to the low temperature side cooling water circuit, since the cooling water cooled with the cooling water cooler 14 flows through the 1st thermal equipment 18, the 1st thermal equipment 18 can be cooled. In other words, since the cooling water in the low-temperature side cooling water circuit can absorb heat from the first heat device 18, a heat pump operation that pumps up waste heat of the first heat device 18 can be realized.

  When the 1st thermal equipment 18 is connected to the high temperature side cooling water circuit, since the cooling water heated with the cooling water heater 15 flows through the 1st thermal equipment 18, the 1st thermal equipment 18 can be heated. Therefore, the 1st thermal equipment 18 can be heated and warmed up.

  When the 2nd thermal equipment 19 is connected to the low temperature side cooling water circuit, since the cooling water cooled with the cooling water cooler 14 flows through the 2nd thermal equipment 19, the 2nd thermal equipment 19 can be cooled. In other words, since the cooling water in the low-temperature side cooling water circuit can absorb heat from the second heat device 19, a heat pump operation for pumping up waste heat of the second heat device 19 can be realized.

  When the 2nd thermal equipment 19 is connected to the high temperature side cooling water circuit, since the cooling water heated with the cooling water heater 15 flows through the 2nd thermal equipment 19, the 2nd thermal equipment 19 can be heated and warmed up.

  1st pump flow path 41, 2nd pump flow path 42, radiator flow path 43, cooling water cooler flow path 44, cooling water heater flow path 45, cooler core flow path 46, heater core flow path 47, Of the first thermal device channel 48, the second thermal device channel 49, and the third bypass channel 53, the channel constituting the low temperature side cooling water circuit is the cooling water sucked and discharged by the first pump 11. Constitutes a first circulation flow path through which is circulated.

  1st pump flow path 41, 2nd pump flow path 42, radiator flow path 43, cooling water cooler flow path 44, cooling water heater flow path 45, cooler core flow path 46, heater core flow path 47, Of the first thermal device channel 48, the second thermal device channel 49, and the third bypass channel 53, the channel constituting the high temperature side cooling water circuit is the cooling water sucked and discharged by the second pump 12. Constitutes a first circulation flow path through which is circulated.

  The first bypass channel 50 is a first bypass channel through which cooling water flows while bypassing a part of the first circulation channel. The second bypass channel 51 is a second bypass channel through which the cooling water flows while bypassing a part of the second circulation channel.

  Hereinafter, the flow path located on the upstream side of the cooling water flow from the first tank portion 20 a of the reserve tank 20 in the first bypass flow path 50 is referred to as an upstream flow path 50 a, and the reserve of the first bypass flow path 50 is reserved. A flow path located on the downstream side of the coolant flow with respect to the first tank portion 20a of the tank 20 is referred to as a downstream flow path 50b.

  The first switching valve 21 is a pressure loss adjusting unit that adjusts the pressure loss of the upstream flow path 50a. The third switching valve 23 is a pressure loss adjusting unit that adjusts the pressure loss of the downstream channel 50b. The first switching valve 21 and the third switching valve 23 are pressure loss non-adjusting means that adjusts the pressure loss ratio obtained by dividing the pressure loss of the upstream flow path 50a by the pressure loss of the downstream flow path 50b.

  The control device 60 controls the operation of the first switching valve 21 and the third switching valve 23 so that the opening degree of the upstream flow path 50a and the opening degree of the downstream flow path 50b are adjusted independently. Thereby, the pressure loss of the upstream flow path 50a and the pressure loss of the downstream flow path 50b are adjusted independently. Therefore, the first pressure loss ratio which is a ratio obtained by dividing the pressure loss of the upstream flow path 50a by the pressure loss of the downstream flow path 50b is adjusted.

  Specifically, the control device 60 compares the temperature or pressure of the cooling water circulating through the first bypass passage 50 with a low temperature or pressure when the cooling water circulating through the first bypass passage 50 is low. To reduce the first pressure loss ratio.

  That is, when the temperature or pressure of the cooling water circulating through the first bypass channel 50 is high, the opening degree of the upstream channel 50a is relatively increased by the first switching valve 21 and the downstream side is decreased by the third switching valve 23. The opening degree of the flow path 50b is made relatively small.

  Thereby, the pressure loss between the pump discharge side and the first tank portion 20a of the reserve tank 20 is reduced, and the pressure loss between the first tank portion 20a of the reserve tank 20 and the pump suction side is increased. Therefore, since the pump discharge pressure is close to the cooling water pressure in the first tank portion 20a of the reserve tank 20, the pump discharge pressure can be kept low. That is, since the pressure of the cooling water circuit can be kept low, it is possible to suppress damage to the devices in the circuit and a reduction in the service life.

  When the temperature or pressure of the cooling water circulating through the first bypass flow path 50 is low, the opening degree of the upstream flow path 50a is relatively reduced by the first switching valve 21 and the downstream side is decreased by the third switching valve 23. The opening degree of the flow path 50b is relatively increased.

  Thereby, the pressure loss between the pump discharge side and the first tank portion 20a of the reserve tank 20 increases, and the pressure loss between the first tank portion 20a of the reserve tank 20 and the pump suction side decreases. Therefore, since the pump suction pressure is close to the cooling water pressure in the first tank portion 20a of the reserve tank 20, the pump suction pressure can be increased. That is, since it can suppress that the pressure of a cooling water circuit falls below atmospheric pressure and becomes negative pressure, it can suppress that cavitation and hose crushing generate | occur | produce.

  Similarly, with respect to the second bypass flow path 51, the pressure loss of the upstream flow path 51a located on the upstream side of the second tank portion 20b of the reserve tank 20 is also reduced from the second tank portion 20b of the reserve tank 20. The pressure of the cooling water circuit can be adjusted by controlling the second pressure loss ratio, which is the ratio divided by the pressure loss of the downstream flow path 51b located on the downstream side, by the first switching valve 21 and the third switching valve 23. .

  Hereinafter, the first bypass channel 50 or the second bypass channel 51 is referred to as bypass channels 50 and 51, and the first pump 11 or the second pump 12 is referred to as pumps 11 and 12.

  In the present embodiment, the first switching valve 21 and the third switching valve 23 use the pressure loss of the upstream flow paths 50a, 51a of the bypass flow paths 50, 51 to the downstream flow path 50b of the bypass flow paths 50, 51, When the temperature or pressure of the cooling water is high, the pressure loss ratio, which is the ratio divided by the pressure loss of 51b, is made smaller than when the temperature or pressure of the cooling water is low.

  According to this, when the temperature or pressure of the cooling water is high, the difference between the discharge pressure of the pumps 11 and 12 and the reference pressure can be reduced, so that the discharge pressure of the pumps 11 and 12 can be suppressed from increasing too much.

  On the other hand, when the temperature or pressure of the cooling water is low, the difference between the suction pressure of the pumps 11 and 12 and the reference pressure can be reduced, so that the suction pressure of the pumps 11 and 12 can be prevented from being excessively lowered. Therefore, it is possible to suppress a decrease in flow rate due to the occurrence of cavitation, scraping of the pump impeller, and progress of pipe corrosion.

  In the present embodiment, the first switching valve 21 and the third switching valve 23 cool at least one of the upstream flow paths 50a and 51a and the downstream flow paths 50b and 51b of the bypass flow paths 50 and 51, respectively. Adjust based on water temperature or pressure. Thereby, a pressure loss ratio can be adjusted reliably.

  Specifically, when the temperature or pressure of the cooling water is high, the first switching valve 21 and the third switching valve 23 indicate the degree of opening of the downstream flow paths 50b and 51b when the temperature or pressure of the cooling water is low. Make it small compared. Thereby, it can suppress reliably that the discharge pressure of the pumps 11 and 12 rises too much.

  Specifically, when the temperature or pressure of the cooling water is high, the first switching valve 21 and the third switching valve 23 indicate the degree of opening of the upstream flow paths 50a and 51a when the temperature or pressure of the cooling water is low. Increase compared to Thereby, it can suppress reliably that the suction pressure of the pumps 11 and 12 falls too much.

  In the present embodiment, the first switching valve 21 and the third switching valve 23 reduce the pressure loss of the downstream flow paths 50b and 51b when cooling water is injected from the outside. Thereby, the injection | pouring property of cooling water can be improved.

  The case where the cooling water is injected from the outside includes, for example, the case where the pressure adjustment valve 20c of the reserve tank 20 is removed, the case where a water injection mode command is received from the vehicle diagnostic machine, and the time when the vehicle is assembled.

  If the downstream channels 50b and 51b are thicker than the upstream channels 50a and 51a, the pressure loss of the downstream channels 50b and 51b is lower than the pressure loss of the upstream channels 50a and 51a. The cooling water injection property can be further improved.

  In the present embodiment, the reserve tank 20 includes tank portions 20a and 20b that store cooling water, and a pressure adjustment valve 20c that seals the tank portions 20a and 20b.

  According to this, since the reserve tank 20 is a hermetically sealed type, it is possible to suppress cooling water evaporation reduction and oxidation, and reduce the cooling water replacement frequency. Moreover, since the tank portions 20a and 20b have air chambers, a pressure buffering function can be exhibited. Therefore, even if the coolant temperature of the coolant circuit fluctuates greatly and the volume changes, the pressure fluctuation range of the coolant circuit can be suppressed.

  Moreover, since the air mixed in the cooling water circuit can be collected in the reserve tank 20, the air escape performance in the cooling water can be enhanced.

  Further, by varying the pressure loss ratio between the upstream flow paths 50a and 51a and the downstream flow paths 50b and 51b of the bypass flow paths 50 and 51, the pressure fluctuation of the cooling water can be changed without increasing the capacity of the reserve tank 20. Therefore, the reserve tank 20 can be downsized as compared with the case where the pressure loss ratio is not varied. As a result, the mountability of the vehicle thermal management device 10 on a vehicle can be improved.

  In the present embodiment, the tank portions 20a and 20b of the reserve tank 20 have an inlet port through which the cooling water flows into the upstream flow channels 50a and 51a and an outlet port through which the cooling water flows into the downstream flow channels 50b and 51b. Have.

  According to this, since the reserve tank 20 is a circulation type reserve tank in which the cooling water of the bypass passages 50 and 51 circulates in the tank portions 20a and 20b, the gas-liquid separation performance can be improved.

  In the present embodiment, the reserve tank 20 communicates with both the first bypass channel 50 and the second bypass channel 51.

  According to this, since one reserve tank 20 can be shared by the low temperature cooling water circuit and the high temperature cooling water circuit, the configuration can be simplified. Moreover, the pressure reference point of both the low temperature cooling water circuit and the high temperature cooling water circuit can be provided in the reserve tank 20.

  In the present embodiment, the interior of the reserve tank 20 is separated into a tank part for the low-temperature cooling water circuit and a tank part for the high-temperature cooling water circuit, and both tank parts communicate with each other. The difference can be eliminated.

  In this embodiment, the 1st switching valve 21 adjusts the opening degree of the upstream flow paths 50a and 51a, and the 3rd switching valve 23 adjusts the opening degree of the downstream flow paths 50b and 51b.

  Specifically, the first switching valve 21 and the third switching valve 23 include a valve body that changes the opening degree of the flow path, and an electric drive unit that drives the valve body. The control device 60 controls the operation of the first switching valve 21 and the third switching valve 23 based on the detection result of at least one of the first water temperature sensor 61, the second water temperature sensor 62, and the circuit pressure sensor 63.

  In this embodiment, when the pumps 11 and 12 are activated, the control device 60 reduces the pressure loss in the upstream flow paths 50a and 51a and the pressure loss in the downstream flow paths 50b and 51b. And the operation of the third switching valve 23 is controlled. According to this, the air bleeding property can be improved when the pumps 11 and 12 are started.

  When the pumps 11 and 12 are activated, the control device 60 does not change the pressure loss ratio obtained by dividing the pressure loss of the upstream flow paths 50a and 51a by the pressure loss of the downstream flow paths 50b and 51b. It is desirable to reduce the pressure loss of 51a and the pressure loss of the downstream flow paths 50b and 51b.

  When it is determined that the water level of the cooling water in the reserve tank 20 detected by the water level sensor 64 exceeds a predetermined water level, the control device 60 reduces the pressure loss of the upstream flow paths 50a and 51a to the downstream flow paths 50b and 51b. The operation of the first switching valve 21 and the third switching valve 23 is controlled so that the pressure loss ratio, which is the ratio divided by the pressure loss, increases.

  According to this, when the cooling water is likely to overflow from the reserve tank 20, the difference between the suction pressure of the pumps 11 and 12 and the reference pressure is reduced. Therefore, the discharge pressure of the pumps 11 and 12 is increased and the hose on the pump discharge side is increased. Piping can be expanded with cooling water pressure. As a result, since the internal volume of the hose pipe can be increased, the cooling water in the reserve tank 20 moves into the cooling water circuit by an amount corresponding to the increase in the internal volume of the cooling water circuit, and the water level in the reserve tank 20 is increased. As a result, it is possible to prevent the cooling water from overflowing from the reserve tank 20.

  Cooling water is likely to overflow from the reserve tank 20 when the soak temperature is higher than expected and the amount of expansion of the cooling water is large, or when the amount of cooling water is larger than the specified amount and the hot soak state is reached. This is the case.

  When it is determined that the water level of the cooling water in the reserve tank 20 detected by the water level sensor 64 is lower than the predetermined water level, the control device 60 determines the pressure loss of the upstream side channels 50a and 51a as the downstream side channels 50b and 51b. The operation of the first switching valve 21 and the third switching valve 23 is controlled so that the pressure loss ratio, which is the ratio divided by the pressure loss, is reduced.

  According to this, when the cooling water in the reserve tank 20 is insufficient and the pumps 11 and 12 may suck air, the difference between the discharge pressure of the pumps 11 and 12 and the reference pressure is reduced. The hose pipe on the pump suction side can be contracted by lowering the cooling water pressure. As a result, since the internal volume of the hose pipe can be reduced, the cooling water in the reserve tank 20 moves into the cooling water circuit by an amount corresponding to the reduction in the internal volume of the cooling water circuit, and the water level in the reserve tank 20 As a result, the pumps 11 and 12 can be prevented from sucking air.

  There is a possibility that the pumps 11 and 12 may suck air because the cooling water in the reserve tank 20 is insufficient. When the soak temperature is lower than expected and the shrinkage amount of the cooling water increases, This may be the case when the amount of water is less than the specified amount or the cooling water is reduced due to a minute leak, or when the vehicle is suddenly braked or accelerated, the fluid level fluctuates due to changes in inertial force or the direction of gravitational action when climbing or descending a steep slope.

(Second Embodiment)
In the first embodiment, the circulation type reserve tank 20 is provided. However, in the present embodiment, as shown in FIG. 3, a non-circulation type reserve tank 55 is provided.

  The reserve tank 55 has a tank portion 55a and a pressure adjustment valve 55c. The tank part 55a is a heat medium storage means for storing cooling water. The tank part 55a is composed of a pressure vessel that stores cooling water.

  The pressure adjustment valve 55c is a cap member that seals the tank portion 55a. The pressure adjustment valve 55c is a pressure adjustment means for adjusting the internal pressure of the tank portion 55a within a preset pressure range. The pressure adjustment valve 55c adjusts the pressure by taking air in and out of the tank portion 55a.

  By storing excess cooling water in the tank portion 55a, it is possible to suppress a decrease in the amount of cooling water circulating through each flow path. Inside the tank portion 55a, bubbles mixed in the cooling water are separated.

  By adjusting the internal pressure of the tank portion 55a by the pressure adjustment valve 55c, it is possible to maintain an appropriate pressure against an abnormal increase / decrease in pressure due to expansion / contraction due to a temperature change of the cooling water.

  A tank portion 55 a of the reserve tank 55 is connected to the communication channel 52 via a tank channel 56. The communication channel 52 is a cooling water channel that communicates the first bypass channel 50 and the second bypass channel 51.

  In the present embodiment, the communication channel 56 communicates the tank portion 55a of the reserve tank 55 with the upstream channels 50a and 51a and the downstream channels 50b and 51b of the bypass channels 50 and 51. The cooling water flowing into and out of the tank portion 55 a flows through the tank channel 56.

  As described above, the reserve tank 55 may be a non-circulation type reserve tank in which the cooling water of the bypass flow paths 50 and 51 does not circulate in the tank portion 55a.

(Third embodiment)
In the second embodiment, the sealed reserve tank 55 is provided. In the present embodiment, as shown in FIG. 4, a simple sealed reserve tank 57 is provided.

  The reserve tank 57 has a tank portion 57a, a tank flow path 57b, and a pressure adjustment valve 57c. The tank part 57a is a heat medium storage unit that stores cooling water. The tank part 57a is a container opened to the atmosphere. The internal pressure of the tank portion 57a is the same as the atmospheric pressure.

  The tank part 57a is connected to the pressure regulating valve 57c through the tank channel 57b. The pressure adjustment valve 57 c is disposed in the communication channel 52.

  The reserve tank 57 is a pressure adjusting means for adjusting the internal pressure of the communication flow path 52 within a preset pressure range. The pressure regulating valve 57c opens when the internal pressure of the communication flow path 52 deviates from a preset pressure range, and connects the communication flow path 52 and the tank portion 58a. The pressure adjustment valve 57c adjusts the pressure by taking cooling water in and out between the communication flow path 52 and the tank portion 57a.

  By storing surplus cooling water in the tank part 58a, it is possible to suppress a decrease in the amount of cooling water circulating through each flow path. Inside the tank part 58a, bubbles mixed in the cooling water are separated.

  The pressure adjustment valve 57c adjusts the internal pressure of the communication flow path 52, so that an appropriate pressure can be maintained against an abnormal increase / decrease in pressure due to expansion / contraction due to the temperature change of the cooling water.

  In the present embodiment, the reserve tank 57 includes a tank part 57a for storing cooling water, and a pressure adjusting valve 57c for taking in and out the cooling water between the bypass channels 50 and 51 and the tank part 57a.

  According to this, since the reserve tank 57 is a simple sealed type, a pressure vessel is not necessary, and the tank volume can be reduced and the tank thickness can be reduced and reduced in weight as compared with the sealed type reserve tank.

  When it is determined that the temperature or pressure of the cooling water exceeds or exceeds a predetermined value, the control device 60 controls the operation of the first switching valve 21 and the third switching valve 23 so as to reduce the pressure loss ratio.

  According to this, when it is determined that the temperature or pressure of the cooling water exceeds or exceeds a predetermined value, the cooling water pressure at the pressure adjustment valve 57c can be brought close to the pump discharge pressure, so that the pressure adjustment valve 57c is opened. It is possible to improve the air bleedability by making the valve.

  In the present embodiment, the pressure adjustment valve 57 c of the reserve tank 57 is disposed in the communication channel 52 that communicates the first bypass channel 50 and the second bypass channel 51.

  According to this, since one reserve tank 57 can be shared by the low temperature cooling water circuit and the high temperature cooling water circuit, the configuration can be simplified. Moreover, the pressure reference point of both the low temperature cooling water circuit and the high temperature cooling water circuit can be used as the pressure regulating valve 57c.

(Fourth embodiment)
In the above embodiment, the low temperature side cooling water circuit and the high temperature side cooling water circuit are formed. In this embodiment, as shown in FIG. 5, the low temperature side cooling water circuit is formed, and the high temperature side cooling water circuit is formed. Not.

  The condenser 35 that is a high-pressure side heat exchanger of the refrigeration cycle 31 condenses the high-pressure side refrigerant by exchanging heat between the high-pressure side refrigerant discharged from the compressor 32 and the outside air. The outdoor blower 30 is an outside air blower that blows outside air to the condenser 35.

  The radiator 13 is a heat transfer device that has a flow path through which cooling water flows and that transfers heat to and from the cooling water whose temperature is adjusted by the cooling water cooler 14 or the cooling water heater 15.

  The outdoor blower 30 is an outside air blower that blows outside air to the condenser 35 and the engine radiator 80. The outdoor blower 30, the condenser 35, and the engine radiator 80 are disposed in the foremost part of the vehicle. For this reason, traveling wind can be applied to the condenser 35 and the engine radiator 80 when the vehicle is traveling.

  The refrigeration cycle 31 includes an internal heat exchanger 36. The internal heat exchanger 36 is a heat exchanger that exchanges heat between the refrigerant flowing out of the condenser 35 and the refrigerant flowing out of the cooling water cooler 14.

  In the refrigeration cycle 31, an intake refrigerant sensor 71, a discharge refrigerant sensor 72, and a refrigerant temperature sensor 73 are arranged. The suction refrigerant sensor 71 detects the pressure and temperature of the refrigerant sucked into the compressor 32. The discharge refrigerant sensor 72 detects the pressure and temperature of the refrigerant discharged from the compressor 32. The refrigerant temperature sensor 73 detects the temperature of the refrigerant that has flowed out of the condenser 35. In other words, the refrigerant temperature sensor 73 detects the degree of supercooling of the refrigerant that has flowed out of the condenser 35. Detection signals from these sensors 71 to 73 are input to the control device 60.

  A heater core 37 is disposed on the downstream side of the air flow of the cooler core 16 in the case (not shown) of the indoor air conditioning unit of the vehicle air conditioner. The heater core 37 is a heat exchanger that exchanges heat between the cooling water of the engine cooling circuit and the air blown into the passenger compartment.

  A bypass flow path 81 is connected between the cooling water outlet side of the cooling water cooler 14 and the cooling water suction side of the first pump 11. The bypass flow path 81 is a cooling water flow path in which the cooling water that has flowed out from the cooling water cooler 14 bypasses the cooler core 16 and the first thermal device 18 and flows to the cooling water suction side of the first pump 11.

  A reserve tank 82 is disposed in the bypass channel 81. The reserve tank 82 has a tank portion 82a and a pressure adjustment valve 82c. The tank part 82a is a heat medium storage unit that stores cooling water. The tank part 82a is a pressure vessel that stores cooling water.

  The pressure regulating valve 82c is a cap member that seals the tank portion 82a. The pressure adjustment valve 82c is a pressure adjustment means for adjusting the internal pressure of the tank portion 82a within a preset pressure range.

  By storing excess cooling water in the tank portion 82a, it is possible to suppress a decrease in the amount of cooling water circulating through each flow path. Inside the tank portion 82a, bubbles mixed in the cooling water are separated.

  By adjusting the internal pressure of the tank portion 82a by the pressure adjustment valve 82c, it is possible to maintain an appropriate pressure against an abnormal increase / decrease in pressure due to expansion / contraction due to the temperature change of the cooling water.

  An air vent pipe 83 is provided between the cooler core 16 and the first thermal device 18 and the tank portion 82 a of the reserve tank 82. The air vent pipe 83 is an air pipe for extracting the air accumulated in the cooler core 16 and the first thermal device 18 to the tank portion 82 a of the reserve tank 82.

  A pressure loss adjusting throttle 84 is disposed in the upstream flow path 81 a located on the upstream side of the coolant flow in the bypass flow path 81 from the reserve tank 82. The upstream flow path 81 a is a part of the bypass flow path 81 that is located on the upstream side of the coolant flow with respect to the reserve tank 82.

  As shown in FIG. 6, the pressure loss adjusting throttle 84 is a variable throttle having a valve body that adjusts the throttle opening of the upstream flow path 81. The valve body is driven by driving means such as an electric actuator (not shown). The operation of the drive means for driving the valve body is controlled by the control device 60.

  The pressure loss adjusting throttle 84 is an inlet side pressure loss adjusting unit that adjusts the pressure loss of the upstream flow path 81a. The pressure loss adjusting throttle 84 is also disposed in the air vent pipe 83.

  A pressure loss adjusting valve 85 is disposed in the downstream flow path 81b located on the downstream side of the coolant flow in the bypass flow path 81 from the reserve tank 82.

  As shown in FIG. 7, the pressure loss adjusting valve 85 is a diaphragm valve having a diaphragm 85a and a valve body 85b. The pressure loss adjusting valve 85 is an outlet side pressure loss adjusting unit that adjusts the pressure loss of the downstream side flow path 81b.

  The diaphragm 85a partitions the cooling water flow path 85c of the pressure loss adjusting valve 85 and the gas chamber 85d. Gas is sealed in the gas chamber 85d at a predetermined pressure. The gas is an inert gas such as nitrogen gas or helium gas. The gas chamber 85d may be open to the atmosphere.

  The diaphragm 85a is deformed according to the pressure difference between the cooling water flowing into the cooling water channel 85c and the gas in the gas chamber 85d. The valve body 85b is displaced according to the deformation of the diaphragm 85a to adjust the opening degree of the cooling water flow path 85c.

  When the cooling water pressure increases, the valve body 85b decreases the opening degree of the cooling water flow path 85c, so that the pressure loss increases. When the cooling water pressure decreases, the valve body 85b increases and decreases the opening degree of the cooling water flow path 85c, so that the pressure loss decreases.

  In the present embodiment, the pressure loss adjusting valve 85 includes mechanisms 85a and 85d that change the opening of the flow path according to the pressure of the cooling water. According to this, since the drive means for driving the pressure loss adjusting valve 85 is unnecessary, the configuration can be simplified.

(Fifth embodiment)
In the fourth embodiment, the diaphragm 85a of the pressure loss adjusting valve 85 is deformed according to the pressure difference between the cooling water flowing into the cooling water flow path 85c and the gas in the gas chamber 85d. In this embodiment, FIG. As described above, the diaphragm 85a of the pressure loss adjusting valve 85 is deformed according to the expansion / contraction of the thermal expansion material 85e. That is, the pressure loss adjusting valve 85 of the present embodiment is a thermostat valve that changes the opening degree of the flow path according to the temperature of the cooling water.

  The thermal expansion material 85e is disposed on the surface of the diaphragm 85a opposite to the gas chamber 85d. The thermal expansion material 85e expands and contracts when heat is transmitted from the cooling water in the cooling water flow path 85c. The heat of the cooling water in the cooling water passage 85c is transmitted to the thermal expansion material 85e via the shaft of the valve body 85b.

  In the present embodiment, the pressure loss adjusting valve 85 includes mechanisms 85a, 85d, and 85e that change the opening degree of the flow path according to the temperature of the cooling water. According to this, since the drive means for driving the pressure loss adjusting valve 85 is unnecessary, the configuration can be simplified.

(Sixth embodiment)
In the fourth and fifth embodiments, the pressure loss is adjusted by the pressure loss adjusting throttle 84 and the pressure loss adjusting valve 85, but in this embodiment, the pressure loss is adjusted by a four-way valve 87 as shown in FIG.

  The four-way valve 87 is disposed on the upstream side and the downstream side of the coolant flow in the reserve tank 82 in the bypass flow path 81. The four-way valve 87 has an upstream inlet 87a, an upstream outlet 87b, a downstream inlet 87c, and a downstream outlet 87d.

  The upstream side inlet 87 a is an inlet of the cooling water on the upstream side of the cooling water flow of the reserve tank 82. The upstream outlet 87 b is an outlet for cooling water on the upstream side of the cooling water flow in the reserve tank 82. The downstream side inlet 87 c is an inlet for cooling water on the downstream side of the cooling water flow in the reserve tank 82. The downstream outlet 87d is an outlet for cooling water on the downstream side of the cooling water flow in the reserve tank 82.

  The four-way valve 87 has a valve body (not shown) that switches communication / blocking of the upstream inlet 87a, the upstream outlet 87b, the downstream inlet 87c, and the downstream outlet 87d.

  The valve body of the four-way valve 87 is driven by driving means such as an electric actuator (not shown). The operation of the driving means for driving the valve body of the four-way valve 87 is controlled by the control device 60.

  When the cooling water is at a high temperature, the control device 60 allows the upstream inlet 87a and the upstream outlet 87b to communicate with each other with a large opening, and the downstream inlet 87c and the downstream outlet 87d are blocked or opened with a small opening. The four-way valve 87 is switched so as to communicate with each other.

  As a result, the pressure loss on the upstream side of the cooling water flow in the reserve tank 82 is reduced, and the pressure loss on the downstream side of the cooling water flow in the reserve tank 82 is increased. Accordingly, the pressure loss ratio is reduced, and the pressure of the cooling water circuit can be kept low. The pressure loss ratio is a ratio obtained by dividing the pressure loss on the upstream side of the cooling water flow in the reserve tank 82 by the pressure loss on the downstream side of the cooling water flow in the reserve tank 82.

  When the cooling water is at a low temperature, the control device 60 blocks the upstream inlet 87a and the upstream outlet 87b or communicates with a small opening, while the downstream inlet 87c and the downstream outlet 87d have a large opening. The four-way valve 87 is switched so as to communicate with each other.

  As a result, the pressure loss on the upstream side of the cooling water flow in the reserve tank 82 increases, and the pressure loss on the downstream side of the cooling water flow in the reserve tank 82 decreases. Therefore, the pressure loss ratio is increased, and it is possible to suppress the pressure of the cooling water circuit from being lower than the atmospheric pressure and becoming negative.

  When injecting cooling water into the cooling water circuit at the time of maintenance, etc., the upstream inlet 87a and the upstream outlet 87b are fully open, and the downstream inlet 87c and the downstream outlet 87d are fully open. The valve 87 is switched.

  As a result, the pressure loss on the upstream side of the cooling water flow in the reserve tank 82 is minimized, and the pressure loss on the downstream side of the cooling water flow in the reserve tank 82 is minimized. Therefore, water injection to the cooling water circuit can be improved.

(Seventh embodiment)
In this embodiment, as shown in FIGS. 10 and 11, the structure and material of the member 88 that forms the upstream flow path 81a and the member 89 that forms the downstream flow path 81b are different.

  The member 88 that forms the upstream flow path 81a is thin, and the member 89 that forms the downstream flow path 81b is thick.

  The member 88 forming the upstream flow path 81a is an elastic pipe molded from a resin or a rubber material, and the member 89 forming the downstream flow path 81b is a hard pipe molded from a hard material such as metal. May be.

  The member 88 forming the upstream flow path 81a may be made of a material having a high linear expansion coefficient, and the member 89 forming the downstream flow path 81b may be made of a material having a low linear expansion coefficient.

  According to this, the member 88 that forms the upstream flow path 81a is more likely to thermally expand as the temperature becomes higher, and more easily expand as the pressure becomes higher than the member 89 that forms the downstream flow path 81b. Therefore, when the temperature and pressure are increased, the diameter of the upstream flow path 81a is increased and the pressure loss is reduced, so that the pressure loss ratio is reduced and the pressure of the cooling water circuit can be kept low.

  The member 88 forming the upstream flow path 81a shrinks and becomes harder as the temperature becomes lower, so the upstream flow path 81a becomes narrower. Therefore, in the case of low temperature or low pressure, the pressure loss ratio becomes large, and it is possible to suppress the pressure of the cooling water circuit from being lower than the atmospheric pressure and becoming negative.

  According to the present embodiment, the pressure loss ratio can be adjusted according to the temperature or pressure of the cooling water without using a driving means such as an actuator, so that the configuration can be simplified.

  In the present embodiment, the member 88 forming the upstream flow paths 50a and 51a and the member 89 forming the downstream flow paths 50b and 51b are pressure loss ratio adjusting means for adjusting the pressure loss ratio. That is, the member 88 that forms the upstream flow paths 50a and 51a is softer structurally or in material than the member 89 that forms the downstream flow paths 50b and 51b.

  According to this, since the driving means for driving the pressure loss ratio adjusting means is unnecessary, the configuration can be simplified.

(Other embodiments)
The above embodiments can be combined as appropriate. The above embodiment can be variously modified as follows, for example.

  (1) It is desirable that the upstream ends of the upstream flow paths 50a, 51a, 81a of the bypass flow paths 50, 51, 81 are arranged as high as possible in the direction of gravity. According to this, since the upstream ends of the upstream flow paths 50a, 51a, 81a are arranged at locations where the air easily collects in the cooling water flow path, the air in the cooling water is sent to the reserve tanks 20, 55, 57, 82. Gas-liquid separation performance can be enhanced.

The upstream flow paths 50a, 51a, 81a of the bypass flow paths 50, 51, 81 desirably extend upward in the gravity direction from the upstream end toward the downstream end. As a result, if a plurality of the upstream flow paths 50a, 51a, 81a of the bypass flow paths 50, 51, 81 that can efficiently discharge the air in the cooling water to the reserve tanks 20, 55, 57, 82 are provided, More air can be fed into the reserve tanks 20, 55, 57, 82.

  (2) In each of the above embodiments, cooling water is used as a heat medium for adjusting the temperature of the temperature adjustment target device, but various media such as oil may be used as the heat medium.

  A nanofluid may be used as the heat medium. A nanofluid is a fluid in which nanoparticles having a particle size of the order of nanometers are mixed. By mixing the nanoparticles with the heat medium, the following effects can be obtained in addition to the effect of lowering the freezing point and making the antifreeze liquid like cooling water using ethylene glycol.

  That is, the effect of improving the thermal conductivity in a specific temperature range, the effect of increasing the heat capacity of the heat medium, the effect of preventing the corrosion of metal pipes and the deterioration of rubber pipes, and the heat medium at an extremely low temperature The effect which improves the fluidity | liquidity of can be acquired.

  Such effects vary depending on the particle configuration, particle shape, blending ratio, and additional substance of the nanoparticles.

  According to this, since the thermal conductivity can be improved, it is possible to obtain the same cooling efficiency even with a small amount of heat medium as compared with the cooling water using ethylene glycol.

  Moreover, since the heat capacity of the heat medium can be increased, the amount of cold storage heat due to the sensible heat of the heat medium itself can be increased.

  Even if the compressor 32 is not operated by increasing the amount of cold storage heat, it is possible to control the temperature and temperature of the equipment using the cold storage heat for a certain amount of time. Motorization becomes possible.

  The aspect ratio of the nanoparticles is preferably 50 or more. This is because sufficient thermal conductivity can be obtained. The aspect ratio is a shape index that represents the ratio of the vertical and horizontal dimensions of the nanoparticles.

  Nanoparticles containing any of Au, Ag, Cu and C can be used. Specifically, Au nanoparticle, Ag nanowire, CNT, graphene, graphite core-shell nanoparticle, Au nanoparticle-containing CNT, and the like can be used as the constituent atoms of the nanoparticle.

  CNT is a carbon nanotube. The graphite core-shell nanoparticle is a particle body having a structure such as a carbon nanotube surrounding the atom.

  (3) In the refrigeration cycle 31 of each of the above embodiments, a chlorofluorocarbon refrigerant is used as the refrigerant. However, the type of the refrigerant is not limited to this, and natural refrigerant such as carbon dioxide, hydrocarbon refrigerant, or the like is used. It may be used.

  The refrigeration cycle 31 of each of the above embodiments constitutes a subcritical refrigeration cycle in which the high-pressure side refrigerant pressure does not exceed the critical pressure of the refrigerant, but the supercritical refrigeration cycle in which the high-pressure side refrigerant pressure exceeds the critical pressure of the refrigerant. May be configured.

11 First pump (pump)
12 Second pump (pump)
20 Reserve tank (pressure adjusting means)
21 1st switching valve (pressure loss ratio adjustment means)
23 Third switching valve (pressure loss ratio adjusting means)
41 First pump flow path (circulation flow path)
42 Second pump channel (circulation channel)
43 Flow path for radiator (circulation flow path)
49 Second heat equipment channel (circulation channel)
50 First bypass channel (bypass channel)
51 Second bypass channel (bypass channel)
50a, 51a Upstream channel 50b, 51b Downstream channel

Claims (21)

Pumps (11, 12) for sucking and discharging the heat medium;
A circulation channel (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass passage (50, 51) through which the heat medium flows by bypassing a part of the circulation passage;
Pressure adjusting means (20, 55, 57, 82) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to a reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium from the pressure adjusting means (20) is reduced to the bypass flow paths (50, 51). 51), the pressure loss ratio which is a ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means (20, 55, 57, 82). Pressure loss ratio adjusting means (21, 23, 84, 85, 87 ) for
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low ,
The pressure loss ratio adjusting means (21, 23, 84, 85, 87) reduces the pressure loss of the downstream channel (50b, 51b) when the heat medium is injected from the outside. Thermal management device. The pressure adjusting means (20, 55)
Tank portions (20a, 20b, 55a) that communicate with the bypass flow path (50, 51) and store the heat medium;
Pressure regulating valves (20c, 55c) that seal the tank parts (20a, 20b, 55a) and adjust the pressure of the heat medium by taking air in and out of the tank parts (20a, 20b, 55a). The heat management device according to claim 1 , wherein the heat management device is a reserve tank (20). A tank flow in which the tank (55a) communicates with the upstream flow path (50a, 51a) and the downstream flow path (50b, 51b) and through which the heat medium flowing into and out of the tank section (55a) flows. The thermal management device according to claim 2 , further comprising a passage (56). In the tank parts (20a, 20b, 55a), the heat medium flows out into the inlet of the upstream flow path (50a, 51a) into which the heat medium flows and the downstream flow path (50b, 51b). The heat management apparatus according to claim 2 , further comprising an outlet. The pumps are a first pump (11) and a second pump (12),
The circulation channel is a first circulation channel in which the first pump (11) is arranged, and a second circulation channel in which the second pump (12) is arranged,
The bypass flow path (50, 51) includes a first bypass flow path (50) in which the heat medium flows by bypassing a part of the first circulation flow path, and a heat medium in the second circulation flow path. A second bypass flow path (51) that flows while bypassing a part,
And a communication channel (52) that communicates the first bypass channel (50, 51) and the second bypass channel (50, 51).
The pressure adjusting means (20,55) is any one of claims 2 to 4, characterized in that in communication with both the first bypass passage (50) and the second bypass passage (51) The thermal management apparatus according to one. The pressure adjusting means is
A tank portion (57a) that communicates with the bypass flow path (50, 51) and stores the heat medium;
A reserve tank (57) having a pressure adjusting valve (57c) for adjusting the pressure of the heat medium by taking in and out the heat medium between the bypass channel (50, 51) and the tank part (57a). The thermal management apparatus according to claim 1 , wherein Control means (60) for controlling the operation of the pressure loss ratio adjusting means (21, 23) to reduce the pressure loss ratio when it is determined that the temperature or pressure of the heat medium exceeds or exceeds a predetermined value. The thermal management apparatus according to claim 6 , further comprising: The pumps are a first pump (11) and a second pump (12),
The circulation channel is a first circulation channel in which the first pump (11) is arranged, and a second circulation channel in which the second pump (12) is arranged,
The bypass flow path (50, 51) includes a first bypass flow path (50) in which the heat medium flows by bypassing a part of the first circulation flow path, and a heat medium in the second circulation flow path. A second bypass flow path (51) that flows while bypassing a part,
And a communication channel (52) that communicates the first bypass channel (50) and the second bypass channel (51).
The thermal management device according to claim 6 or 7 , wherein the pressure regulating valve (57c) is disposed in the communication channel (52). Pumps (11, 12) for sucking and discharging the heat medium;
A circulation channel (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass passage (50, 51) through which the heat medium flows by bypassing a part of the circulation passage;
Pressure adjusting means (20, 55, 57, 82) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to a reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium from the pressure adjusting means (20) is reduced to the bypass flow paths (50, 51). 51), the pressure loss ratio which is a ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means (20, 55, 57, 82). and a pressure loss ratio adjusting means (8 8,89) which,
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low ,
The pressure loss ratio adjusting means is a member (88) that forms the upstream flow path (50a, 51a) and a member (89) that forms the downstream flow path (50b, 51b),
The member (88) forming the upstream flow path (50a, 51a) is softer structurally or in material than the member (89) forming the downstream flow path (50b, 51b). thermal management apparatus characterized by there. Pumps (11, 12) for sucking and discharging the heat medium;
A circulation channel (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass passage (50, 51) through which the heat medium flows by bypassing a part of the circulation passage;
Pressure adjusting means (20, 55, 57, 82) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to a reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium from the pressure adjusting means (20) is reduced to the bypass flow paths (50, 51). 51), the pressure loss ratio which is a ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means (20, 55, 57, 82). Pressure loss ratio adjusting means ( 85 ),
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low ,
The pressure loss ratio adjusting means is a valve (85) that adjusts the opening of at least one of the upstream channel (50a, 51a) and the downstream channel (50b, 51b),
The said valve | bulb (85) has a mechanism (85a, 85d) which changes the opening degree of a flow path according to the pressure of the said heat medium, The heat management apparatus characterized by the above-mentioned. Pumps (11, 12) for sucking and discharging the heat medium;
A circulation channel (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass passage (50, 51) through which the heat medium flows by bypassing a part of the circulation passage;
Pressure adjusting means (20, 55, 57, 82) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to a reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium from the pressure adjusting means (20) is reduced to the bypass flow paths (50, 51). 51), the pressure loss ratio which is a ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means (20, 55, 57, 82). Pressure loss ratio adjusting means ( 85 ),
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low ,
The pressure loss ratio adjusting means is a valve (85) that adjusts the opening of at least one of the upstream channel (50a, 51a) and the downstream channel (50b, 51b),
The said valve (85) has a mechanism (85a, 85d, 85e) which changes the opening degree of a flow path according to the temperature of the said heat medium, The heat management apparatus characterized by the above-mentioned. Pumps (11, 12) for sucking and discharging the heat medium;
A circulation channel (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass passage (50, 51) through which the heat medium flows by bypassing a part of the circulation passage;
Pressure adjusting means (20, 55, 57, 82) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to a reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium from the pressure adjusting means (20) is reduced to the bypass flow paths (50, 51). 51), the pressure loss ratio which is a ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means (20, 55, 57, 82). Pressure loss ratio adjusting means (21, 23 ) for
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low ,
The pressure loss ratio adjusting means is a valve (21, 23) that adjusts the opening degree of at least one of the upstream channel (50a, 51a) and the downstream channel (50b, 51b),
The valves (21, 23) include a valve body that changes the opening degree of the flow path, and electric drive means that drives the valve body,
And detecting means (61, 62, 63) for detecting at least one of the pressure and temperature of the heat medium;
Control means (60) for controlling the operation of the valve (21, 23) based on the detection result of the detection means (61, 62, 63) ,
The control means (60) reduces the pressure loss of the upstream flow path (50a, 51a) and the pressure loss of the downstream flow path (50b, 51b) when the pump (11, 12) is activated. As described above, the operation of the pressure loss ratio adjusting means (21, 23) is controlled . Pumps (11, 12) for sucking and discharging the heat medium;
A circulation channel (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass passage (50, 51) through which the heat medium flows by bypassing a part of the circulation passage;
Pressure adjusting means ( 55 ) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to a reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium from the pressure adjusting means (20) is reduced to the bypass flow paths (50, 51). 51) Pressure loss ratio adjusting means (51) for adjusting the pressure loss ratio, which is a ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means ( 55 ). 21, 23, 84, 85, 87, 88, 89),
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low ,
The pressure adjusting means (55)
A tank portion (55a) that communicates with the bypass flow path (50, 51) and stores the heat medium;
A reserve tank having a pressure adjusting valve (55c) for sealing the tank part (55a) and adjusting the pressure of the heat medium by taking air in and out of the tank part (55a);
Furthermore, the said heat medium which flows in and out of the said tank part (55a) flows through the said tank part (55a), the said upstream flow path (50a, 51a), and the said downstream flow path (50b, 51b). A thermal management device comprising a tank channel (56) . Pumps (11, 12) for sucking and discharging the heat medium;
A circulation channel (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass passage (50, 51) through which the heat medium flows by bypassing a part of the circulation passage;
Pressure adjusting means (20, 55 ) communicating with the bypass channel (50, 51) and adjusting the pressure of the heat medium to a reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium from the pressure adjusting means (20) is reduced to the bypass flow paths (50, 51). 51) Pressure loss ratio adjustment for adjusting a pressure loss ratio which is a ratio divided by the pressure loss of the downstream flow path (50b, 51b) located on the downstream side of the heat medium from the pressure adjusting means (20, 55 ). Means (21, 23, 84, 85, 87, 88, 89),
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low ,
The pressure adjusting means (20, 55)
Tank portions (20a, 20b, 55a) that communicate with the bypass flow path (50, 51) and store the heat medium;
Pressure regulating valves (20c, 55c) that seal the tank parts (20a, 20b, 55a) and adjust the pressure of the heat medium by taking air in and out of the tank parts (20a, 20b, 55a). And a reserve tank having
The pumps are a first pump (11) and a second pump (12),
The circulation channel is a first circulation channel in which the first pump (11) is arranged, and a second circulation channel in which the second pump (12) is arranged,
The bypass flow path (50, 51) includes a first bypass flow path (50) in which the heat medium flows by bypassing a part of the first circulation flow path, and a heat medium in the second circulation flow path. A second bypass flow path (51) that flows while bypassing a part,
And a communication channel (52) that communicates the first bypass channel (50, 51) and the second bypass channel (50, 51).
The thermal management device , wherein the pressure adjusting means (20, 55) communicates with both the first bypass channel (50) and the second bypass channel (51) . A tank flow in which the tank (55a) communicates with the upstream flow path (50a, 51a) and the downstream flow path (50b, 51b) and through which the heat medium flowing into and out of the tank section (55a) flows. 15. Thermal management device according to claim 14 , characterized in that it comprises a path (56). In the tank parts (20a, 20b, 55a), the heat medium flows out into the inlet of the upstream flow path (50a, 51a) into which the heat medium flows and the downstream flow path (50b, 51b). The heat management apparatus according to claim 15 , further comprising an outlet. Pumps (11, 12) for sucking and discharging the heat medium;
A circulation channel (41, 42, 43, 44, 45, 46, 47, 48, 49, 53) through which the heat medium circulates;
A bypass passage (50, 51) through which the heat medium flows by bypassing a part of the circulation passage;
Pressure adjusting means ( 57 ) communicating with the bypass flow path (50, 51) and adjusting the pressure of the heat medium to a reference pressure;
Among the bypass flow paths (50, 51), the pressure loss of the upstream flow paths (50a, 51a) located on the upstream side of the heat medium from the pressure adjusting means (20) is reduced to the bypass flow paths (50, 51). 51) Pressure loss ratio adjusting means (51) for adjusting the pressure loss ratio, which is the ratio divided by the pressure loss of the downstream flow path (50b, 51b) located downstream of the heat medium from the pressure adjusting means ( 57 ). 21, 23, 84, 85, 87, 88, 89),
The pressure loss ratio adjusting means reduces the pressure loss ratio when the temperature or pressure of the heat medium is high compared to when the temperature or pressure of the heat medium is low ,
The pressure adjusting means is
A tank portion (57a) that communicates with the bypass flow path (50, 51) and stores the heat medium;
A reserve tank (57) having a pressure adjusting valve (57c) for adjusting the pressure of the heat medium by taking in and out the heat medium between the bypass channel (50, 51) and the tank part (57a). And
The pumps are a first pump (11) and a second pump (12),
The circulation channel is a first circulation channel in which the first pump (11) is arranged, and a second circulation channel in which the second pump (12) is arranged,
The bypass flow path (50, 51) includes a first bypass flow path (50) in which the heat medium flows by bypassing a part of the first circulation flow path, and a heat medium in the second circulation flow path. A second bypass flow path (51) that flows while bypassing a part,
And a communication channel (52) that communicates the first bypass channel (50) and the second bypass channel (51).
The thermal management device, wherein the pressure regulating valve (57c) is disposed in the communication channel (52) . Control means (60) for controlling the operation of the pressure loss ratio adjusting means (21, 23) to reduce the pressure loss ratio when it is determined that the temperature or pressure of the heat medium exceeds or exceeds a predetermined value. The thermal management apparatus according to claim 17 , further comprising: The pressure loss ratio adjusting means adjusts the opening degree of at least one of the upstream flow path (50a, 51a) and the downstream flow path (50b, 51b) based on the temperature or pressure of the heat medium. The thermal management device according to claim 13 , wherein the thermal management device is a thermal management device. The pressure loss ratio adjusting means (21, 23, 84, 85, 87) is configured such that when the temperature or pressure of the heat medium is high, the downstream flow path ( The thermal management device according to claim 19 , wherein the opening degree of 50b, 51b) is reduced. When the temperature or pressure of the heat medium is high, the pressure loss ratio adjusting means (21, 23, 84, 85, 87) is compared with the case where the temperature or pressure of the heat medium is low. The thermal management device according to claim 19 or 20 , wherein the opening degree of 50a, 51a) is increased.

Images