JP2014213664A - Vehicle air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vehicle air conditioner capable of heating air blown into a vehicle cabin using both heat recovered from indoor air discharged to the outside of the vehicle cabin and heat absorbed from outdoor air.SOLUTION: The vehicle air conditioner comprises: heat absorbing means 13, 14, and 16 causing a low-pressure-side refrigerant of a refrigerant cycle 21 to absorb heat from indoor air discharged to an outside of the vehicle cabin, and the low-pressure-side refrigerant to absorb heat from outdoor air; a heat medium heater 15 heating a heat medium by implementing heat exchange between a high-pressure-side refrigerant of the refrigerant cycle 21 and the heat medium; and air heating means 17 heating the air blown into the vehicle cabin by using heat of the heat medium heated by the heat medium heater 15. The heat absorbing means 13, 14, and 16 includes: a heat medium heat sink 14 implementing heat exchange between the low-pressure-side refrigerant and the heat medium to cause the low-pressure-side refrigerant to absorb the heat from the heat medium; and an outdoor air heat sink 13 implementing heat exchange between the heat medium from which the heat is absorbed in the heat medium heat sink 14 and the outdoor air to cause the low-pressure-side refrigerant to absorb the heat from the outdoor air.

Description

  The present invention relates to a vehicle air conditioner that air-conditions a vehicle interior.

  Conventionally, Patent Document 1 describes a vehicle air conditioning system including a refrigerant / coolant heat exchanger that exchanges heat between a refrigerant circulated in a heat pump cycle and a coolant circulated in the coolant cycle.

  In this prior art, the refrigerant compressed by the refrigerant compressor of the heat pump cycle is guided to the second refrigerant condenser side, heat is exchanged with the air blown from the blower, the air is heated, and this air is blown into the vehicle interior. It is designed to be used for heating the passenger compartment.

  The refrigerant radiated and condensed by the second refrigerant condenser is introduced into the refrigerant / coolant heat exchanger through the second expansion valve, absorbed by the coolant on the coolant cycle side, evaporated, and then passed through the accumulator. It is designed to be sucked into the compressor.

  The coolant cycle has a ventilated exhaust heat recovery unit that recovers heat from the air (inside air) exhausted from the vehicle interior to the outside, and the exhaust heat recovered by the ventilated exhaust heat recovery unit is transferred to the refrigerant / coolant heat exchanger. It is collected and used as a heat source for heating of the heat pump cycle.

JP 2010-111269 A

  However, in the above-described conventional technology, heat pump heating that absorbs heat of air outside the vehicle compartment (outside air) and serves as a heat source for heating of the heat pump cycle cannot be performed, and thus the required heating capacity may not be ensured.

  In view of the above points, the present invention provides a vehicle air conditioner capable of heating air blown into a vehicle interior by using both heat recovered from the inside air discharged outside the vehicle interior and heat absorbed from the outside air. The purpose is to do.

In order to achieve the above object, in the invention described in claim 1,
Endothermic means (13, 14, 16, 25) for absorbing heat from the inside air discharged outside the passenger compartment to the low-pressure side refrigerant of the refrigeration cycle (21) and absorbing heat from the outside air to the low-pressure side refrigerant;
A heat medium heater (15) for heating the heat medium by exchanging heat between the high-pressure side refrigerant of the refrigeration cycle (21) and the heat medium;
Air heating means (17, 43, 84) for heating the air blown into the passenger compartment using the heat of the heat medium heated by the heat medium heater (15),
The heat absorption means includes a heat medium heat absorber (14) for heat-exchanging the low-pressure side refrigerant and the heat medium to absorb heat from the heat medium to the low-pressure side refrigerant, and a heat medium absorbed by the heat medium heat absorber (14). It has an external air heat absorber (13) that exchanges heat with the external air and absorbs heat from the external air to the low-pressure side refrigerant.

  According to this, the heat absorption means (13, 14, 16, 25) absorbs heat from the inside air discharged to the outside of the passenger compartment to the low-pressure side refrigerant of the refrigeration cycle (21) and absorbs heat from the outside air to the low-pressure side refrigerant to heat the heat medium. The heater (15) heats the heat medium with the heat absorbed by the heat absorbing means (13, 14, 16, 25), and the air heating means (17, 43, 84) is heated by the heat medium heater (15). The air blown into the passenger compartment is heated by the heat medium that has been used.

  Therefore, the air blown into the vehicle interior can be heated using both the heat recovered from the inside air discharged to the outside of the vehicle interior and the heat absorbed from the outside air.

  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 vehicle thermal management system in 1st Embodiment, and has shown the operating state of the air_conditioning | cooling mode. It is sectional drawing of the indoor air conditioning unit of the vehicle air conditioner in 1st Embodiment, and has shown the operating state of the air_conditioning | cooling mode. 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 system for vehicles in a 1st embodiment, and has shown the operating state of dehumidification heating mode. It is sectional drawing of the indoor air conditioning unit of the vehicle air conditioner in 1st Embodiment, and has shown the operating state of dehumidification heating mode. It is a whole block diagram of the thermal management system for vehicles in 1st Embodiment, and has shown the operating state of the defrost heating mode. It is sectional drawing of the indoor air conditioning unit of the vehicle air conditioner in 1st Embodiment, and has shown the operating state of the defrost heating mode. It is a flowchart explaining the control processing of the thermal management system for vehicles in 1st Embodiment. It is sectional drawing of the indoor air conditioning unit of the vehicle air conditioner in 2nd Embodiment, and has shown the operating state of the air_conditioning | cooling mode. It is a whole block diagram of the thermal management system for vehicles in 2nd Embodiment, and has shown the operating state of dehumidification heating mode. It is a whole block diagram of the thermal management system for vehicles in 2nd Embodiment, and has shown the operating state of ventilation heat recovery heating mode. It is sectional drawing of the indoor air conditioning unit of the vehicle air conditioner in 2nd Embodiment, and has shown the operating state of the defrost heating mode. It is sectional drawing of the indoor air conditioning unit of the vehicle air conditioner in 3rd Embodiment, and has shown the operating state of the air_conditioning | cooling mode. It is XIV-XIV sectional drawing of FIG. 13, FIG. It is a whole block diagram of the thermal management system for vehicles in 3rd Embodiment, and has shown the operating state of dehumidification heating mode. It is a whole block diagram of the thermal management system for vehicles in 3rd Embodiment, and has shown the operating state of ventilation heat recovery heating mode and defrost heating mode. It is XVII-XVII sectional drawing of FIG. It is a whole block diagram of the thermal management system for vehicles in 4th Embodiment, and has shown the operating state of the air_conditioning | cooling mode. It is a whole block diagram of the thermal management system for vehicles in 4th Embodiment, and has shown the operating state of dehumidification heating mode and ventilation heat recovery heating mode. It is sectional drawing of the indoor air conditioning unit of the vehicle air conditioner in 4th Embodiment, and has shown the operating state of the dehumidification heating mode. It is a whole block diagram of the thermal management system for vehicles in 5th Embodiment, and has shown the operating state of the air_conditioning | cooling mode. It is a whole block diagram of the thermal management system for vehicles in 5th Embodiment, and has shown the operating state of dehumidification heating mode and ventilation heat recovery heating mode. It is sectional drawing of the indoor air conditioning unit of the vehicle air conditioner in 5th Embodiment, and has shown the operating state of dehumidification heating mode. It is a whole block diagram of the thermal management system for vehicles in 6th Embodiment, and has shown the operating state of the air_conditioning | cooling mode. It is a whole block diagram of the thermal management system for vehicles in 6th Embodiment, and has shown the operating state of dehumidification heating mode and ventilation heat recovery heating mode. It is sectional drawing of the indoor air conditioning unit of the vehicle air conditioner in 6th Embodiment, and has shown the operating state of dehumidification heating mode. It is a whole block diagram of the thermal management system for vehicles in 7th Embodiment, and has shown the operating state of the air_conditioning | cooling mode. It is a whole block diagram of the thermal management system for vehicles in 7th Embodiment, and has shown the operating state of dehumidification heating mode and ventilation heat recovery heating mode. It is sectional drawing of the indoor air conditioning unit of the vehicle air conditioner in 7th Embodiment, and has shown the operating state of dehumidification heating mode. It is a whole block diagram of the thermal management system for vehicles in 8th Embodiment, and has shown the operating state of the air_conditioning | cooling mode. It is a whole block diagram of the thermal management system for vehicles in 8th Embodiment, and has shown the operating state of dehumidification heating mode and ventilation heat recovery heating mode.

  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 system 10 shown in FIG. 1 is used to adjust various devices and vehicle interiors provided in the vehicle to appropriate temperatures. In the present embodiment, the thermal management system 10 is applied to a hybrid vehicle that obtains driving force for vehicle travel from an engine (internal combustion engine) and a travel electric motor.

  The hybrid vehicle of the present embodiment is configured as a plug-in hybrid vehicle that can charge power supplied from an external power source (commercial power source) when the vehicle is stopped to a battery (vehicle battery) mounted on the vehicle. As the battery, for example, a lithium ion battery can be used.

  The driving force output from the engine is used not only for driving the vehicle but also for operating the generator. The electric power generated by the generator and the electric power supplied from the external power source can be stored in the battery, and the electric power stored in the battery constitutes the thermal management system 10 as well as the electric motor for traveling. It is supplied to various in-vehicle devices such as electric components.

  As shown in FIG. 1, the thermal management system 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, a first switching valve 18, and A second switching valve 19 is provided.

  The first pump 11 and the second pump 12 are electric pumps that suck and discharge cooling water (heat medium). 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 radiator 13, the cooling water cooler 14, the cooling water heater 15, the cooler core 16 and the heater core 17 are cooling water circulation devices (heat medium circulation devices) through which the cooling water flows.

  The radiator 13 is a radiator that radiates heat of the cooling water to the outside air by exchanging heat between the cooling water and outside air of the passenger compartment (hereinafter referred to as outside air). It is also possible for the radiator 13 to absorb heat from the outside air to the cooling water by flowing cooling water below the outside air temperature through the radiator 13. In other words, the radiator 13 can also function as a heat absorber for the outside air that absorbs heat from the outside air to the cooling water.

  The cooling water outlet side of the radiator 13 is connected to the cooling water suction side of the first pump 11. The outdoor blower 20 is an electric blower that blows outside air to the radiator 13. The radiator 13 and the outdoor blower 20 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 cooling water cooler 14 is a low pressure side heat exchanger (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 21 and the cooling water. The cooling water cooler 14 constitutes an evaporator of the refrigeration cycle 21.

  The refrigeration cycle 21 is a vapor compression refrigerator that includes a compressor 22, a cooling water heater 15 as a condenser, an expansion valve 23, and a cooling water cooler 14 as an evaporator. In the refrigeration cycle 21 of the present embodiment, a chlorofluorocarbon refrigerant is used as the refrigerant, and a subcritical refrigeration cycle in which the high-pressure side refrigerant pressure does not exceed the critical pressure of the refrigerant is configured.

  The compressor 22 is an electric compressor driven by electric power supplied from a battery, and sucks, compresses and discharges the refrigerant of the refrigeration cycle 21. The cooling water heater 15 is a high pressure side heat exchanger (heat medium heater) that condenses the high pressure side refrigerant by exchanging heat between the high pressure side refrigerant discharged from the compressor 22 and the cooling water.

  The expansion valve 23 is a decompression unit that decompresses and expands the liquid-phase refrigerant condensed by the cooling water heater 15. The cooling water cooler 14 is a low-pressure side heat exchanger that evaporates the low-pressure refrigerant by exchanging heat between the low-pressure refrigerant decompressed and expanded by the expansion valve 23 and the cooling water. The gas-phase refrigerant evaporated in the cooling water cooler 14 is sucked into the compressor 22 and compressed.

  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 21. 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 temperature of the outside air, whereas the cooling water cooler 14 can cool the cooling water to a temperature lower than the temperature of the outside air.

  The cooler core 16 is a cooling heat exchanger (air cooler) that cools the air blown into the vehicle interior by exchanging heat between the cooling water and the air blown into the vehicle interior. The cooler core 16 is a heat absorber for the inside air that absorbs heat from the inside air (vehicle compartment air) to the cooling water.

  The heater core 17 is a heating heat exchanger (air heater) 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 first pump 11 is disposed in the first pump flow path 31. In the first pump flow path 31, the radiator 13 is disposed on the suction side of the first pump 11. The second pump 12 is disposed in the second pump flow path 32.

  The cooling water cooler 14 is disposed in the cooling water cooler flow path 34. The cooling water heater 15 is disposed in the cooling water heater flow path 35. The cooler core 16 is disposed in the cooler core flow path 36. The heater core 17 is disposed in the heater core flow path 37.

  The first pump flow path 31, the second pump flow path 32, the cooling water cooler flow path 34, the cooling water heater flow path 35, the cooler core flow path 36, and the heater core flow path 37 are the first switching valve 18. And connected to the second switching valve 19.

  The first switching valve 18 and the second switching valve 19 are cooling water flow switching means (heat medium flow switching means) that switches the flow of cooling water.

  The first switching valve 18 has two inlets as cooling water inlets and four outlets as cooling water outlets. The second switching valve 19 has three outlets as cooling water outlets and four inlets as cooling water inlets.

  One end of the first pump flow path 31 is connected to the first inlet of the first switching valve 18. In other words, the cooling water discharge side of the first pump 11 is connected to the first inlet of the first switching valve 18.

  One end of the second pump flow path 32 is connected to the second inlet of the first switching valve 18. In other words, the cooling water discharge side of the second pump 12 is connected to the second inlet of the first switching valve 18.

  One end of the cooling water cooler flow path 34 is connected to the first outlet of the first switching valve 18. In other words, the coolant outlet side of the coolant cooler 14 is connected to the first outlet of the first switching valve 18.

  One end of the coolant heater channel 35 is connected to the second outlet of the first switching valve 18. In other words, the cooling water inlet side of the cooling water heater 15 is connected to the second outlet of the first switching valve 18.

  One end of the cooler core flow path 36 is connected to the third outlet of the first switching valve 18. In other words, the cooling water inlet side of the cooler core 16 is connected to the third outlet of the first switching valve 18.

  One end of a heater core flow path 37 is connected to the fourth outlet of the first switching valve 18. In other words, the coolant outlet side of the heater core 17 is connected to the fourth outlet of the first switching valve 18.

  The other end of the first pump flow path 31 is connected to the first outlet of the second switching valve 19. In other words, the cooling water inlet side of the radiator 13 is connected to the first outlet of the second switching valve 19.

  The other end of the second pump flow path 32 is connected to the second outlet of the second switching valve 19. In other words, the cooling water suction side of the second pump 12 is connected to the second outlet of the second switching valve 19.

  One end of the bypass flow path 38 is connected to the third outlet of the second switching valve 19. The bypass flow path 38 is a bypass means in which cooling water flows bypassing the radiator 13. The other end of the bypass flow path 38 is disposed in a portion of the first pump flow path 31 between the radiator 13 and the first pump 11.

  The other end of the cooling water cooler flow path 34 is connected to the first inlet of the second switching valve 19. In other words, the cooling water outlet side of the cooling water cooler 14 is connected to the first inlet of the second switching valve 19.

  The other end of the coolant heater channel 35 is connected to the second inlet of the second switching valve 19. In other words, the cooling water outlet side of the cooling water heater 15 is connected to the second inlet of the second switching valve 19.

  The other end of the cooler core flow path 36 is connected to the third inlet of the second switching valve 19. In other words, the cooling water outlet side of the cooler core 16 is connected to the third inlet of the second switching valve 19.

  The other end of the heater core flow path 37 is connected to the fourth inlet of the second switching valve 19. In other words, the coolant inlet side of the heater core 17 is connected to the fourth inlet of the second switching valve 19.

  The first switching valve 18 and the second switching valve 19 have a structure that can arbitrarily or selectively switch the communication state between each inlet and each outlet.

  Specifically, the first switching valve 18 is configured so that the cooling water discharged from the first pump 11 flows into each of the cooling water cooler 14, the cooling water heater 15, the cooler core 16, and the heater core 17, and The state where the cooling water discharged from the two pumps 12 flows in and the state where the cooling water discharged from the first pump 11 and the cooling water discharged from the second pump 12 do not flow are switched.

  In the second switching valve 19, 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 cooling water cooler 14, the cooling water heater 15, the cooler core 16, and the heater core 17. And a state in which the cooling water does not flow out to the first pump 11 and the second pump 12. Further, the second switching valve 19 switches between a state in which the cooling water flows out to the radiator 13 and a state in which the cooling water flows out to the bypass passage 38.

  The structure example of the first switching valve 18 and the second switching valve 19 will be briefly described. The first switching valve 18 and the second switching valve 19 include a case forming an outer shell and a valve body accommodated in the case. The cooling water inlet and outlet are formed at predetermined positions of the case, and the communication state between the cooling water inlet and outlet is changed by rotating the valve body.

  The valve body of the first switching valve 18 and the valve body of the second switching valve 19 are independently rotationally driven by separate electric motors. The valve body of the first switching valve 18 and the valve body of the second switching valve 19 may be rotationally driven in conjunction with a common electric motor.

  As shown in FIG. 2, the cooler core 16 and the heater core 17 are accommodated in a case 51 of an indoor air conditioning unit 50 of the vehicle air conditioner.

  The case 51 forms an air passage for the blown air that is blown into the passenger compartment, and is formed of a resin (for example, polypropylene) that has a certain degree of elasticity and is excellent in strength. An inside / outside air switching box 52 is arranged on the most upstream side of the air flow in the case 51. The inside / outside air switching box 52 is an inside / outside air introduction means for switching and introducing inside air (vehicle compartment air) and outside air (vehicle compartment outside air).

  The inside / outside air switching box 52 is formed with an inside air suction port 52a for introducing inside air into the case 51 and an outside air suction port 52b for introducing outside air. An inside / outside air switching door 53 is arranged inside the inside / outside air switching box 52.

  The inside / outside air switching door 53 is an air volume ratio changing unit that changes the air volume ratio between the air volume of the inside air introduced into the case 51 and the air volume of the outside air. Specifically, the inside / outside air switching door 53 continuously adjusts the opening areas of the inside air suction port 52a and the outside air suction port 52b to change the air volume ratio between the inside air volume and the outside air volume. The inside / outside air switching door 53 is driven by an electric actuator (not shown).

  An indoor blower 54 (blower) is arranged on the downstream side of the air flow in the inside / outside air switching box 52. The indoor blower 54 is a blowing unit that blows air (inside air and outside air) sucked through the inside / outside air switching box 52 toward the vehicle interior. The indoor blower 54 is an electric blower that drives a centrifugal multiblade fan 54a (sirocco fan) by an electric motor 54b.

  In the case 51, the cooler core 16 and the heater core 17 are arranged on the downstream side of the air flow of the indoor blower 54. In the case 51, the cooler core 16 is disposed so as to extend substantially in the vertical direction. The blown air from the indoor blower 54 passes through the cooler core 16 in a substantially horizontal direction.

  A bypass passage 51 a is formed in the case 51 above the cooler core 16. The bypass flow path 51a is an air passage through which air flows while bypassing the cooler core 16.

  In the case 51, a drain water discharge port 51 b is formed in a lower part of the cooler core 16. The drain water discharge port 51b is condensed water discharge means for discharging condensed water (drain water) generated in the cooler core 16 to the outside of the vehicle.

  Inside the case 51, a first heater core passage 51c, a second heater core passage 51d, and a heater core bypass passage 51e are formed in the air flow downstream side portion of the cooler core 16.

  The first heater core passage 51c and the second heater core passage 51d are air passages through which air that has passed through the cooler core 16 flows. The heater core 17 is disposed in the first heater core passage 51c and the second heater core passage 51d. Therefore, the heater core 17 is disposed inside the case 51 on the air flow downstream side of the cooler core 16.

  The first heater core passage 51 c and the second heater core passage 51 d are partitioned from each other by a partition plate 55 formed in the case 51. The first heater core passage 51c is formed above the second heater core passage 51d.

  The heater core bypass passage 51 e is an air passage through which air that has passed through the cooler core 16 flows without passing through the heater core 17. The heater core bypass passage 51e is formed above the first heater core passage 51c.

  A first air mix door 56 </ b> A and a second air mix door 56 </ b> B are disposed between the cooler core 16 and the heater core 17 in the case 51.

  The first air mix door 56A and the second air mix door 56B continuously change the air volume ratio between the air flowing into the first heater core passage 51c and the second heater core passage 51d and the air flowing into the heater core bypass passage 51e. This is air volume ratio adjusting means.

  The temperature of the blown-out air blown into the vehicle interior varies depending on the air volume ratio between the air passing through the first heater core passage 51c and the second heater core passage 51d and the air passing through the heater core bypass passage 51e. Accordingly, the first air mix door 56A and the second air mix door 56B are temperature adjusting means for adjusting the temperature of the blown air blown into the vehicle interior.

  The first air mix door 56A and the second air mix door 56B are rotatable plate-like doors and are driven by an electric actuator (not shown).

  The first air mix door 56A can open and close the first heater core passage 51c and the heater core bypass passage 51e. The second air mix door 56B can open and close the second heater core passage 51d.

  A bypass door 57 is disposed inside the case 51 at the outlet of the bypass passage 51a. The bypass door 57 is a rotatable plate-like door and is driven by an electric actuator (not shown).

  The bypass door 57 can open and close the bypass passage 51a. The bypass door 57 can switch between a state in which the air that has passed through the cooler core 16 flows into the first heater core passage 51c and the heater core bypass passage 51e and a state in which the air does not flow into the first heater core passage 51c and the heater core bypass passage 51e. .

  In the case 51, a communication door 58 is disposed at the most downstream portion of the air flow in the first heater core passage 51c and the second heater core passage 51d. The communication door 58 is a rotatable plate-like door and is driven by an electric actuator (not shown).

  The communication door 58 can be switched between a state in which the first heater core passage 51c and the second heater core passage 51d are partitioned and a state in which the first heater core passage 51c and the second heater core passage 51d communicate with each other.

  Air outlets 51f, 51g, and 51h for blowing blown air into the vehicle interior, which is the air-conditioning target space, are disposed at the most downstream portion of the air flow of the case 51. Specifically, as the outlets 51f, 51g, 51h, a defroster outlet 51f, a face outlet 51g, and a foot outlet 51h are provided. The defroster outlet 51f, the face outlet 51g, and the foot outlet 51h are arranged in this order from the upper side to the lower side of the case 51.

  The defroster outlet 51f blows conditioned air toward the inner surface of the vehicle front window glass. The face outlet 51g blows conditioned air toward the upper body of the passenger. The foot outlet 51h blows conditioned air toward the passenger's feet.

  A defroster door 59A, a face door 59B, and a foot door 59C are arranged on the upstream side of the airflow of these air outlets 51f, 51g, 51h. The defroster door 59A, the face door 59B, and the foot door 59C are outlet mode switching means for switching the outlet mode.

  The defroster door 59A adjusts the opening area of the defroster outlet 51f. The face door 59B adjusts the opening area of the face outlet 51g. The foot door 59C adjusts the opening area of the foot outlet 51h.

  The air outlet mode doors 59A, 59B, 59C are connected to a common electric actuator (not shown) via a link mechanism and are driven in conjunction with each other.

  Examples of the outlet mode that is switched by the outlet mode doors 59A, 59B, and 59C include a face mode, a bi-level mode, a foot mode, and a foot defroster mode.

  The face mode is a blowout mode in which the face blowout 51g is fully opened and air is blown from the face blowout 51g toward the upper body of the passenger in the vehicle cabin. The bi-level mode is an air outlet mode in which both the face air outlet 51g and the foot air outlet 51h are opened and air is blown toward the upper body and feet of the passengers in the passenger compartment.

  In the foot mode, the foot outlet 51h is fully opened and the defroster outlet 51f is opened by a small opening so that air is mainly blown from the foot outlet 51h. The foot defroster mode is an air outlet mode in which the foot air outlet 51h and the defroster air outlet 51f are opened to the same extent and air is blown out from both the foot air outlet 51h and the defroster air outlet 51f.

  Next, the electric control part of the thermal management system 10 will be described with reference to FIG. The control device 60 is composed of a well-known microcomputer 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.

  Control target devices controlled by the control device 60 include the first pump 11, the second pump 12, the first switching valve 18, the second switching valve 19, the outdoor blower 20, the compressor 22, the indoor blower 54, and the inside of the case 51. For driving various doors (inside / outside air switching door 53, first air mix door 56A, second air mix door 56B, bypass door 57, communication door 58, defroster door 59A, face door 59B, foot door 59C) Such as an actuator.

  The control device 60 is configured integrally with control means for controlling various control target devices connected to the output side thereof, but has a configuration (hardware and software) for controlling the operation of each control target device. The control means for controlling the operation of each control target device is configured.

  In the present embodiment, the configuration (hardware and software) for controlling the operation of the first switching valve 18 and the second switching valve 19 is the circuit switching control means 60a. The circuit switching control means 60a may be configured separately from the control device 60.

  In the present embodiment, various doors (inside / outside air switching door 53, first air mix door 56A, second air mix door 56B, bypass door 57, communication door 58, defroster door 59A, face door disposed inside case 51 are arranged. 59B, the configuration (hardware and software) for controlling the operation of the foot door 59C) is defined as an air conditioning switching control means 60b. The air conditioning switching control means 60b may be configured separately from the control device 60.

  In the present embodiment, the configuration (hardware and software) for controlling the operation of the first pump 11 and the second pump 12 is the pump control means 60c. The pump control unit 60c is a flow rate control unit that controls the flow rate of the cooling water. The pump control means 60c may be configured separately from the control device 60.

  In this embodiment, the structure (hardware and software) which controls the operation | movement of the indoor air blower 54 is set as the air blower control means 60d. The blower control means 60d is a flow rate control means for controlling the flow rate of the blown air. The blower control means 60d may be configured separately from the control device 60.

  Detection signals of sensor groups such as the inside air sensor 61, the outside air sensor 62, the first water temperature sensor 63, the second water temperature sensor 64, the cooler core temperature sensor 65, and the refrigerant temperature sensor 66 are input to the input side of the control device 60.

  The inside air sensor 61 is detection means (inside air temperature detection means) for detecting the temperature of the inside air (vehicle compartment temperature). The outside air sensor 62 is detection means (outside air temperature detection means) that detects the temperature of the outside air (the temperature outside the passenger compartment).

  The first water temperature sensor 63 is detection means (first heat medium temperature detection means) for detecting the temperature of the cooling water flowing through the first pump flow path 31 (for example, the temperature of the cooling water sucked into the first pump 11). is there.

  The second water temperature sensor 64 is detection means (second heat medium temperature detection means) for detecting the temperature of the cooling water flowing through the second pump flow path 32 (for example, the temperature of the cooling water sucked into the second pump 12). is there.

  The cooler core temperature sensor 65 is detection means (cooler core temperature detection means) that detects the surface temperature of the cooler core 16 (for example, the temperature of the heat exchange fins).

  The refrigerant temperature sensor 66 is detection means (refrigerant temperature detection means) that detects the refrigerant temperature of the refrigeration cycle 21 (for example, the temperature of the refrigerant discharged from the compressor 22).

  On the input side of the control device 60, operation signals from various air conditioning operation switches provided on the operation panel 69 disposed near the instrument panel in the front part of the vehicle interior are input. As various air conditioning operation switches provided on the operation panel 69, an air conditioner switch, an auto switch, an air volume setting switch of the indoor blower 52, a vehicle interior temperature setting switch, and the like are provided.

  The air conditioner switch is a switch for switching on / off (on / off) of air conditioning (cooling or heating). The auto switch is a switch for setting or canceling automatic control of air conditioning. The vehicle interior temperature setting switch is target temperature setting means for setting the vehicle interior target temperature by the operation of the passenger.

  Next, the operation in the above configuration will be described. The control device 60 includes the first pump 11, the second pump 12, the first switching valve 18, the second switching valve 19, the compressor 22, the inside / outside air switching door 53, the first air mix door 56A, the second air mix door 56B, By controlling the operation of the bypass door 57, the communication door 58, the defroster door 59A, the face door 59B, the foot door 59C, and the like, the operation mode can be switched to various modes.

  For example, as various operation modes, the cooling mode shown in FIGS. 1 and 2, the dehumidifying heating mode shown in FIGS. 4 and 5, and the defrosting heating mode shown in FIGS. 6 and 7 are switched.

  The cooling mode shown in FIGS. 1 and 2 is performed mainly when the outside air temperature is high, such as in summer. In the cooling mode, as shown in FIG. 1, the first switching valve 18 and the second switching valve 19 connect the first pump flow path 31 to the cooling water heater flow path 35 and the heater core flow path 37, and The two-pump flow path 32 is connected to the cooling water cooler flow path 34 and the cooler core flow path 36.

  Thus, the first pump 11, the radiator 13, the cooling water heater 15, and the heater core 17 constitute a first cooling water circuit C <b> 1 (first heat medium circuit), and the second pump 12, the cooling water cooler 14, and the cooler core 16. Constitutes the second cooling water circuit C2 (second heat medium circuit).

  In the first cooling water circuit C 1, the cooling water discharged from the first pump 11 flows through the cooling water heater 15, the heater core 17, and the radiator 13 and is sucked into the first pump 11 as indicated by a thick solid arrow in FIG. Is done. In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water cooler 14 and the cooler core 16 and is sucked into the second pump 12 as indicated by a thick dashed line arrow in FIG. .

  In the first cooling water circuit C <b> 1, the cooling water heated by the cooling water heater 15 flows through the radiator 13, so that the heat of the cooling water heated by the cooling water heater 15 is radiated to the outside air by the radiator 13.

  In the second cooling water circuit C2, since the cooling water cooled by the cooling water cooler 14 flows through the cooler core 16, the cooling water cools the air blown into the vehicle interior by the cooler core 16.

  In the cooling mode, as shown in FIG. 2, the first air mix door 56A closes the first heater core passage 51c and opens the heater core bypass passage 51e, and the second air mix door 56B closes the second heater core passage 51d and closes the bypass door. 57 closes the bypass passage 51a, the communication door 58 connects the first heater core passage 51c and the second heater core passage 51d, the defroster door 59A closes the defroster outlet 51f, the face door 59B opens the face outlet 51g, The foot door 59C closes the foot outlet 51h.

  Thus, the air blown into the passenger compartment is cooled by the cooler core 16 and blown out from the face outlet 51 g without being heated by the heater core 17. Therefore, the passenger compartment can be cooled.

  The dehumidifying and heating modes shown in FIGS. 4 and 5 are mainly performed when the outside air temperature is low, such as in winter. In the dehumidifying and heating mode, as shown in FIG. 4, the first switching valve 18 and the second switching valve 19 connect the first pump flow path 31 to the cooling water cooler flow path 34 and the cooler core flow path 36. The second pump flow path 32 is connected to the cooling water heater flow path 35 and the heater core flow path 37.

  Thus, the first pump 11, the radiator 13, the cooling water cooler 14, and the cooler core 16 constitute a first cooling water circuit C 1 (first heat medium circuit), and the second pump 12, the cooling water heater 15, and the heater core 17. Constitutes the second cooling water circuit C2 (second heat medium circuit).

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 flows through the cooling water cooler 14, the cooler core 16 and the radiator 13 and is sucked into the first pump 11 as shown by the thick solid arrows in FIG. Is done. In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water heater 15 and the heater core 17 and is sucked into the second pump 12 as indicated by a thick dotted line arrow in FIG. .

  In the first cooling water circuit C1, since the cooling water cooled by the cooling water cooler 14 flows through the radiator 13 and the cooler core 16, the cooling water cooled by the cooling water cooler 14 absorbs heat from the outside air by the radiator 13, The cooler core 16 cools the air blown into the passenger compartment.

  In the second cooling water circuit C2, since the cooling water heated by the cooling water heater 15 flows through the heater core 17, the cooling water heats the air blown into the vehicle interior by the heater core 17.

  That is, in the dehumidifying heating mode, the refrigerant of the refrigeration cycle 21 absorbs heat from the outside air by the cooling water cooler 14 and dissipates heat to the cooling water of the second cooling water circuit C2 by the cooling water heater 15. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

  In the dehumidifying and heating mode, as shown in FIG. 5, the first air mix door 56A opens the first heater core passage 51c and closes the heater core bypass passage 51e, and the second air mix door 56B opens the second heater core passage 51d and bypasses. The door 57 closes the bypass passage 51a, the communication door 58 connects the first heater core passage 51c and the second heater core passage 51d, the defroster door 59A opens the defroster outlet 51f, and the face door 59B closes the face outlet 51g. The foot door 59C opens the foot outlet 51h.

  Thus, the air blown into the passenger compartment is cooled and dehumidified by the cooler core 16 and then heated by the heater core 17 and blown out from the defroster outlet 51f and the foot outlet 51h. Therefore, the vehicle interior can be dehumidified and heated.

  Since the drain water discharge port 51b is formed in the case 51, a small part of the blown air into the vehicle compartment can be discharged from the drain water discharge port 51b. In the dehumidifying and heating mode, the air discharged from the drain water discharge port 51b is the blown air absorbed by the cooler core 16, so the heat of the air discharged from the drain water discharge port 51b to the outside of the vehicle is recovered and Can be used for heating.

  The defrost heating mode shown in FIGS. 6 and 7 is performed mainly when the outside air temperature is low, such as in winter, and when frost is attached to the surface of the cooler core 16. In the defrost heating mode, as shown in FIG. 6, the first switching valve 18 and the second switching valve 19 connect the first pump flow path 31 to the cooling water cooler flow path 34, The passage 32 is connected to the coolant heater passage 35, the cooler core passage 36, and the heater core passage 37.

  Thus, the first pump 11, the radiator 13, and the cooling water cooler 14 constitute a first cooling water circuit C <b> 1 (first heat medium circuit), and the second pump 12, the cooling water heater 15, the cooler core 16, and the heater core 17. Constitutes the second cooling water circuit C2 (second heat medium circuit).

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 flows through the cooling water cooler 14 and the radiator 13 and is sucked into the first pump 11 as shown by a thick solid arrow in FIG. In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water heater 15, the cooler core 16 and the heater core 17 to the second pump 12 as shown by the thick dashed line arrows in FIG. Inhaled.

  In the first cooling water circuit C1, the cooling water cooled by the cooling water cooler 14 flows through the radiator 13, so that the cooling water cooled by the cooling water cooler 14 absorbs heat from the outside air by the radiator 13.

  In the second cooling water circuit C2, the cooling water heated by the cooling water heater 15 flows through the cooler core 16 and the heater core 17, so that the cooling water melts frost in the cooler core 16 and the cooling water flows into the vehicle interior in the heater core 17. The blast air is heated.

  That is, in the defrost heating mode, as in the dehumidification heating mode, the refrigerant in the refrigeration cycle 21 absorbs heat from the outside air by the cooling water cooler 14 and cools the second cooling water circuit C2 by the cooling water heater 15. Dissipate heat to water. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

  In the defrost heating mode, as shown in FIG. 7, the first air mix door 56A opens the first heater core passage 51c and closes the heater core bypass passage 51e, and the second air mix door 56B opens the second heater core passage 51d. The bypass door 57 opens the bypass passage 51a and partitions the first heater core passage 51c and the heater core bypass passage 51e with respect to the cooler core 16, and the communication door 58 partitions the first heater core passage 51c and the second heater core passage 51d, and the defroster door 59A. Opens the defroster outlet 51f, the face door 59B closes the face outlet 51g, and the foot door 59C opens the foot outlet 51h.

  Thus, a part of the air blown into the vehicle interior is heated by the cooler core 16 and then heated by the heater core 17 and blown out from the foot outlet 51h, and flows out of the air blower into the vehicle interior bypassing the cooler core 16. The blown air is heated by the heater core 17 and blown out from the defroster outlet 51f. Therefore, the vehicle interior can be heated.

  In the defrost heating mode, since the frost is melted by the cooler core 16, the air that has passed through the cooler core 16 contains a lot of water vapor evaporated from the surface of the cooler core 16. On the other hand, the air that flows by bypassing the cooler core 16 does not include water vapor evaporated from the surface of the cooler core 16.

  The air that has passed through the cooler core 16 is blown out from the foot outlet 51h, and the air that has bypassed the cooler core 16 is blown out from the defroster outlet 51f. Therefore, it is possible to prevent the air containing a large amount of water vapor evaporated from the surface of the cooler core 16 from being blown out toward the window glass, and thus to suppress the window glass from being fogged.

  The control device 60 performs the control process shown in the flowchart of FIG. 8 in order to suppress frost from adhering to the surface of the cooler core 16.

  In step S100, it is determined whether or not the surface temperature Tfin of the cooler core 16 detected by the cooler core temperature sensor 65 is less than a predetermined value (for example, less than the freezing point). When it is determined that the surface temperature Tfin of the cooler core 16 is less than the predetermined value, it is determined that frost may adhere to the surface of the cooler core 16 and the process proceeds to step S110.

  In step S110, the operation of the first pump 11 or the second pump 12 is controlled so that the flow rate of the cooling water flowing through the cooler core 16 decreases. In step S110, the operation of the indoor blower 54 may be controlled so that the flow rate of the air flowing through the cooler core 16 increases.

  Thereby, since the surface temperature of the cooler core 16 rises, it can suppress that frost adheres to the surface of the cooler core 16.

  In step S100, the determination may be made based on the temperature related to the surface temperature Tfin of the cooler core 16 instead of the surface temperature Tfin of the cooler core 16.

  In the present embodiment, the cooler core temperature sensor 65 detects a temperature related to the surface temperature of the cooler core 16, and the control device 60 (flow rate control means 60 c, 60 d) is based on the temperature detected by the cooler core temperature sensor 65. It is determined whether or not frost may adhere to the surface of the cooler 16, and when it is determined that frost may adhere to the surface of the cooler core 16, the cooler core 16 is increased so that the surface temperature of the cooler core 16 increases. The flow rate of at least one of air flowing through the cooling water and cooling water is controlled. Thereby, it can suppress that frost adheres to the surface of the cooler core 16.

(Second Embodiment)
In the present embodiment, as shown in FIG. 9, the case 51 of the indoor air conditioning unit 50 is configured to allow the inside air and the outside air to flow separately.

  The centrifugal multiblade fan (sirocco fan) of the indoor blower 54 includes a first fan 54c and a second fan 54d. The first fan 54c is disposed above the second fan 54d.

  The inside / outside air switching box 52 is formed with a second inside air suction port 52 c for introducing inside air into the case 51. Inside the inside / outside air switching box 52, an inside air door 70 for opening and closing the second inside air suction port 52c is disposed.

  In the case 51, a first passage 51i and a second passage 51j are formed in a portion between the indoor blower 54 and the cooler core 16. The first passage 51i is an air passage through which air blown by the first fan 54c flows. The second passage 51j is an air passage through which air blown by the second fan 54d flows.

  The first passage 51 i and the second passage 51 j are partitioned from each other by a partition plate 71 formed in the case 51. The first passage 51i is disposed on the upper side of the second passage 51j.

  The second air mix door 56B can partition the air flow downstream side of the cooler core 16 into a first heater core passage 51c and a second heater core passage 51d.

  An air discharge port 51k is formed in the lower part of the cooler core 16 of the case 51. The air discharge port 51k is air discharge means for discharging the air that has passed through the cooler core 16 to the outside of the vehicle.

  In the case 51, an air discharge passage 51l is formed between the cooler core 16 and the air discharge port 51k. The air discharge passage 51l is an air passage through which air that has passed through the cooler core 16 flows toward the air discharge port 51k.

  A discharge opening / closing door 72 is disposed in the air discharge passage 51l. The discharge opening / closing door 72 is air discharge passage opening / closing means for opening / closing the air discharge passage 51l. In other words, the discharge opening / closing door 72 is an air discharge opening / closing means for opening / closing the air discharge opening 51k.

  The discharge opening / closing door 72 is driven by an electric actuator (not shown). The operation of the electric actuator for the discharge opening / closing door 72 is controlled by the control device 60.

  The indoor air conditioning unit 50 is switched to the cooling mode, the dehumidifying heating mode, and the defrosting heating mode as in the first embodiment. Furthermore, the indoor air conditioning unit 50 is switched to the ventilation heat recovery heating mode.

  In the cooling mode, as shown in FIG. 9, the inside air door 70 closes the second inside air suction port 52c, the first air mix door 56A closes the first heater core passage 51c, opens the heater core bypass passage 51e, and opens the second air mix. The door 56B closes the second heater core passage 51d, the bypass door 57 closes the bypass passage 51a, the communication door 58 connects the first heater core passage 51c and the second heater core passage 51d, and the defroster door 59A opens the defroster outlet 51f. The face door 59B opens the face outlet 51g, the foot door 59C closes the foot outlet 51h, and the discharge opening / closing door 72 closes the air outlet 51k.

  As a result, the air blown by the first fan 54 c and the second fan 54 d of the indoor blower 54 is cooled by the cooler core 16 and blown out from the face outlet 51 g without being heated by the heater core 17. Therefore, the passenger compartment can be cooled.

  In the dehumidifying heating mode, as shown in FIG. 10, the inside / outside air switching door 53 closes the inside air suction port 52a and opens the outside air suction port 52b, the inside air door 70 opens the second inside air suction port 52c, and the first air mix door 56A opens the first heater core passage 51c and closes the heater core bypass passage 51e, and the second air mix door 56B opens the second heater core passage 51d to partition the first heater core passage 51c and the second heater core passage 51d, thereby bypassing the door 57. Closes the bypass passage 51a, the communication door 58 partitions the first heater core passage 51c and the second heater core passage 51d, the defroster door 59A opens the defroster outlet 51f, the face door 59B closes the face outlet 51g, and the foot door 59C Opens the foot outlet 51h, and the discharge opening / closing door 72 is the air outlet 51k. Close.

  Thereby, the outside air blown by the first fan 54c of the indoor blower 54 is heated by the heater core 17 and blown out from the defroster outlet 51f, and the inside air blown by the second fan 54d of the indoor blower 54 is cooled by the cooler core 16. After being cooled and dehumidified, it is heated by the heater core 17 and blown out from the foot outlet 51h. Therefore, the vehicle interior can be dehumidified and heated.

  The ventilation heat recovery heating mode is implemented mainly when the outside air temperature is low, such as in winter. The switching state of the cooling water circuit in the ventilation heat recovery heating mode is the same as in the dehumidifying heating mode shown in FIG.

  In the ventilation heat recovery heating mode, as shown in FIG. 11, the inside / outside air switching door 53 closes the inside air suction port 52a and opens the outside air suction port 52b, the inside air door 70 opens the second inside air suction port 52c, and the first air. The mix door 56A opens the first heater core passage 51c and closes the heater core bypass passage 51e, the second air mix door 56B closes the second heater core passage 51d, and the bypass door 57 opens the bypass passage 51a and opens the first heater core passage 51c and The heater core bypass passage 51e is partitioned from the cooler core 16, the communication door 58 connects the first heater core passage 51c and the second heater core passage 51d, the defroster door 59A opens the defroster outlet 51f, and the face door 59B is the face outlet. 51g is closed, foot door 59C opens foot outlet 51h The discharge opening and closing door 72 is open the air outlet 51k.

  Thereby, the outside air blown by the first fan 54c of the indoor blower 54 is heated by the heater core 17 and blown out from the defroster outlet 51f, and the inside air blown by the second fan 54d of the indoor blower 54 is cooled by the cooler core 16. Heat is absorbed and discharged from the air outlet 51k to the outside of the vehicle. Therefore, the heat of the air discharged outside the vehicle for ventilation can be recovered and used for heating the vehicle interior.

  The case 51 has a structure in which, in the ventilation heat recovery and heating mode, the volume of air discharged outside the vehicle compartment through the air discharge port 51k is equal to or less than the volume of outside air introduced by the inside / outside air switching box 52.

  Specifically, the case 51 is designed such that the ventilation resistance of the path for discharging air is larger than the ventilation resistance of the path for introducing outside air.

  As a result, it is possible to suppress a decrease in the pressure in the passenger compartment when the air is exhausted to the outside of the passenger compartment, and thus it is possible to suppress the outside air from entering the passenger compartment through a minute gap existing in the passenger compartment constituent member. .

  In the ventilation heat recovery heating mode, when the heat necessary for heating is sufficient only by the heat recovered from the air exhausted outside the vehicle for ventilation, the second switching valve 19 bypasses the radiator 13 and bypasses the cooling water. You may make it flow through the path 38. Thereby, it is possible to heat only the heat recovered from the air discharged outside the vehicle for ventilation without pumping up the heat of the outside air.

  In the defrost heating mode, as shown in FIG. 12, the inside / outside air switching door 53 closes the inside air suction port 52a and opens the outside air suction port 52b, the inside air door 70 closes the second inside air suction port 52c, and the first air mix. The door 56A opens the first heater core passage 51c to close the heater core bypass passage 51e, the second air mix door 56B closes the second heater core passage 51d, and the bypass door 57 opens the bypass passage 51a to open the first heater core passage 51c and the heater core. The bypass passage 51e is partitioned from the cooler core 16, the communication door 58 connects the first heater core passage 51c and the second heater core passage 51d, the defroster door 59A opens the defroster outlet 51f, and the face door 59B is the face outlet 51g. , Foot door 59C opens foot outlet 51h and discharges Closed door 72 opens the air discharge port 51k.

  Thereby, a part of the air blown into the vehicle interior passes through the cooler core 16 and is discharged from the air discharge port 51k to the outside of the vehicle, and the air blown into the vehicle interior that flows by bypassing the cooler core 16 is It is heated by the heater core 17 and blown out from the defroster outlet 51f. Therefore, the vehicle interior can be heated.

  In the defrost heating mode, since the frost is melted by the cooler core 16, the air that has passed through the cooler core 16 contains a lot of water vapor evaporated from the surface of the cooler core 16. On the other hand, the air that flows by bypassing the cooler core 16 does not include water vapor evaporated from the surface of the cooler core 16.

  The air that has passed through the cooler core 16 is discharged from the air outlet 51k to the outside of the vehicle, and the air that has bypassed the cooler core 16 is blown out from the defroster outlet 51f. Therefore, it is possible to prevent the air containing a large amount of water vapor evaporated from the surface of the cooler core 16 from being blown out into the passenger compartment, and thus to suppress the window glass from being fogged.

  In the present embodiment, in the ventilation heat recovery heating mode, the radiator 13, the cooling water cooler 14, and the cooler core 16 absorb heat from the inside air discharged to the outside of the passenger compartment to the low-pressure side refrigerant of the refrigeration cycle 21, and from outside air to the low-pressure side refrigerant. The cooling water heater 15 constitutes a cooling water heating means for heating the cooling water by exchanging heat between the high-pressure side refrigerant of the refrigeration cycle 21 and the cooling water, and the heater core 17 is composed of cooling water. Using the heat of the cooling water heated by the heater 15, air heating means for heating the air blown into the passenger compartment is configured.

  Therefore, the air blown into the vehicle interior can be heated using both the heat recovered from the inside air discharged to the outside of the vehicle interior and the heat absorbed from the outside air.

  In the present embodiment, the cooling water discharge side of the first pump 11, the cooling water discharge side of the second pump 12, and the cooler core 16 are connected to the first switching valve 18, and the first switching valve 18 is the first pump for the cooler core 16. 11 is switched between a state in which the cooling water discharged from 11 flows in and a state in which the cooling water discharged from the second pump 12 flows in, the cooling water discharge side of the first pump 11, the cooling water discharge side of the second pump 12, The cooler core 16 is connected to the second switching valve 19, and the second switching valve 19 switches between a state in which the cooling water flows out to the first pump 11 and a state in which the cooling water flows out to the second pump 12 with respect to the cooler core 16. Thereby, the structure for switching the cooling water which flows into the cooler core 16 can be simplified.

  In the present embodiment, as in the defrosting heating mode, the first switching valve 18 and the second switching valve 19 include one of the first pump 11 and the second pump 12, the cooling water heater 15, and the cooler core 16. It is possible to switch to a state in which cooling water circulates between the two.

  According to this, the cooling water heated by the cooling water heater 15 can be flowed to the cooler core 16. For this reason, when frost adheres to the cooler core 16, the frost attached to the cooler core 16 can be melted using the heat of the cooling water heated by the cooling water heater 15.

  In the present embodiment, the heater core 17 is connected to the first switching valve 18 and the second switching valve 19, and the first switching valve 18 is in a state in which cooling water discharged from the first pump 11 flows into the heater core 17. And the state where the cooling water discharged from the second pump 12 flows in, the second switching valve 19 causes the cooling water to flow out to the second pump 12 and the state where the cooling water flows out to the first pump 11 with respect to the heater core 17. Switch the state to be performed. Thereby, the structure for switching the cooling water which flows into the heater core 17 can be simplified.

  In the present embodiment, the cooler core 16 is disposed inside the case 51 so that the inside air and outside air introduced by the inside / outside air switching box 52 pass through, and the heater core 17 is the inside air and outside air introduced by the inside / outside air switching box 52. The case 51 is disposed inside the case 51, and the case 51 includes air outlets 51f, 51g, 51h for blowing air that has passed through at least one of the cooler core 16 and the heater core 17 into the vehicle interior, and a cooler core. A discharge port 51k for discharging the air that has passed through the vehicle 16 to the outside of the vehicle compartment is formed, and the air that has passed through the cooler core 16 is blown into the vehicle compartment through the air outlets 51f, 51g, 51h. The state and the state where the air that has passed through the cooler core 16 is discharged out of the passenger compartment through the discharge port 51k are switched.

  According to this, the cooler core 16 can fulfill both the function of absorbing heat from the air discharged outside the vehicle compartment and the function of cooling the air blown out into the vehicle compartment. Therefore, a structure can be simplified compared with the case where the heat exchanger which absorbs heat from the air discharged to the outside of the passenger compartment and the heat exchanger which cools the air blown into the passenger compartment are separately provided.

  In the present embodiment, the case 51 has a structure in which the volume of air discharged outside the passenger compartment through the discharge port 51k is equal to or less than the volume of outside air introduced by the inside / outside air switching box 52.

  As a result, it is possible to suppress a decrease in the pressure in the passenger compartment when the air is exhausted to the outside of the passenger compartment, and thus it is possible to suppress the outside air from entering the passenger compartment through a minute gap existing in the passenger compartment constituent member. .

(Third embodiment)
In the present embodiment, as shown in FIGS. 13 and 14, a second bypass passage 51 m is formed on the side of the cooler core 16 inside the case 51 of the indoor air conditioning unit 50.

  The second bypass passage 51m is an air passage (bypass passage) through which air flows by bypassing the cooler core 16. The inlet of the second bypass passage 51m communicates with the second passage 51j. The outlet portion of the second bypass passage 51m communicates with the second heater core passage 51d.

  A second bypass door 73 is disposed in the second bypass passage 51m. The second bypass door 73 is a rotatable plate-like door and is driven by an electric actuator (not shown). The second bypass door 73 is bypass passage opening / closing means for opening and closing the second bypass passage 51m. The operation of the electric actuator that drives the second bypass door 73 is controlled by the control device 60.

  In the present embodiment, the configuration (hardware and software) for controlling the operation of the electric actuator for the second bypass door 73 is the bypass passage opening / closing control means 60e (shown in FIG. 2). The bypass passage opening / closing control means 60e may be configured separately from the control device 60.

  A second discharge opening / closing door 74 is disposed in a portion between the cooler core 16 and the heater core 17 inside the case 51. The second discharge opening / closing door 74 can open and close the air discharge passage 51l and the second heater core passage 51d.

  The second discharge opening / closing door 74 is a rotatable plate-like door, and is driven by an electric actuator (not shown). The operation of the electric actuator for the second discharge opening / closing door 74 is controlled by the control device 60.

  The indoor air conditioning unit 50 is switched to the cooling mode, the dehumidifying heating mode, the ventilation heat recovery heating mode, and the defrosting heating mode, as in the second embodiment.

  In the cooling mode, as shown in FIG. 13, the inside / outside air switching door 53 opens the inside air suction port 52a and closes the outside air suction port 52b, the inside air door 70 opens the second inside air suction port 52c, and the first air mix door 56A. Closes the first heater core passage 51c and opens the heater core bypass passage 51e, the second air mix door 56B closes the second heater core passage 51d, the bypass door 57 closes the bypass passage 51a, and the communication door 58 connects the first heater core passage 51c. And the second heater core passage 51d, the defroster door 59A closes the defroster outlet 51f, the face door 59B opens the face outlet 51g, the foot door 59C closes the foot outlet 51h, and the discharge opening / closing door 72 The outlet 51k is closed, and the second discharge opening / closing door 74 closes the air discharge passage 51l. As shown in FIG. 14, the second bypass door 73 closes the second bypass passage 51m.

  As a result, the inside air blown by the first fan 54c and the second fan 54d of the indoor blower 54 is cooled by the cooler core 16 and blown out from the face outlet 51g without being heated by the heater core 17. Therefore, the passenger compartment can be cooled.

  In the dehumidifying heating mode, as shown in FIG. 15, the inside / outside air switching door 53 closes the inside air suction port 52a and opens the outside air suction port 52b, the inside air door 70 opens the second inside air suction port 52c, and the first air mix door 56A opens the first heater core passage 51c and closes the heater core bypass passage 51e, and the second air mix door 56B opens the second heater core passage 51d to partition the first heater core passage 51c and the second heater core passage 51d, thereby bypassing the door 57. Closes the bypass passage 51a, the communication door 58 partitions the first heater core passage 51c and the second heater core passage 51d, the defroster door 59A opens the defroster outlet 51f, the face door 59B closes the face outlet 51g, and the foot door 59C Opens the foot outlet 51h, and the discharge opening / closing door 72 is the air outlet 51k. Closed, the second discharge door 74 closes the air discharge passage 51l. As shown in FIG. 14, the second bypass door 73 closes the second bypass passage 51m.

  Thereby, the outside air blown by the first fan 54c of the indoor blower 54 is heated by the heater core 17 and blown out from the defroster outlet 51f, and the inside air blown by the second fan 54d of the indoor blower 54 is heated by the heater core 17. It is heated and blown out from the foot outlet 51h. Therefore, the vehicle interior can be heated.

  In the dehumidifying and heating mode, at least one of the first switching valve 18 and the second switching valve 19 may block the flow of the cooling water to the cooler core 16. In this case, dehumidification is not performed by the cooler core 16, but the air blown out from the defroster outlet 51f is air that has heated a relatively dry outside air, and the air that has heated the relatively humid inside air is a foot outlet 51h. Since it blows out from, it can suppress that a window glass fogs.

  In the ventilation heat recovery heating mode, as shown in FIG. 16, the inside / outside air switching door 53 closes the inside air suction port 52a and opens the outside air suction port 52b, the inside air door 70 opens the second inside air suction port 52c, and the first air The mix door 56A opens the first heater core passage 51c and closes the heater core bypass passage 51e, and the second air mix door 56B opens the second heater core passage 51d to partition the first heater core passage 51c and the second heater core passage 51d and bypass them. The door 57 opens the bypass passage 51a to partition the first heater core passage 51c and the heater core bypass passage 51e from the cooler core 16, the communication door 58 partitions the first heater core passage 51c and the second heater core passage 51d, and the defroster door 59A Open defroster outlet 51f and face door 59B The mouth 51g is closed, the foot door 59C opens the foot outlet 51h, the discharge opening / closing door 72 opens the air discharge port 51k, the second discharge opening / closing door 74 opens the air discharge passage 51l and the second heater core passage 51d through the air discharge passage. Partition against 51l. As shown in FIG. 17, the second bypass door 73 opens the second bypass passage 51m.

  Thereby, the outside air blown by the first fan 54c of the indoor blower 54 is heated by the heater core 17 and blown out from the defroster outlet 51f, and the inside air blown by the second fan 54d of the indoor blower 54 is cooled by the cooler core 16. Heat is absorbed and discharged from the air outlet 51k to the outside of the vehicle. Therefore, the heat of the air discharged outside the vehicle for ventilation can be recovered and used for heating the vehicle interior.

  In the defrost heating mode, the indoor air conditioning unit 50 is switched similarly to the ventilation heat recovery heating mode shown in FIG.

  Thereby, the outside air blown by the first fan 54c of the indoor blower 54 flows by bypassing the cooler core 16, is heated by the heater core 17, and blown from the defroster outlet 51f, and blown by the second fan 54d of the indoor blower 54. The inside air thus passed passes through the cooler core 16 and is discharged from the air discharge port 51k to the outside of the vehicle. Therefore, the vehicle interior can be heated.

  In the defrost heating mode, since the frost is melted by the cooler core 16, the air that has passed through the cooler core 16 contains a lot of water vapor evaporated from the surface of the cooler core 16. On the other hand, the air that flows by bypassing the cooler core 16 does not include water vapor evaporated from the surface of the cooler core 16.

  The air that has passed through the cooler core 16 is discharged from the air outlet 51k to the outside of the vehicle, and the air that has bypassed the cooler core 16 is blown out from the defroster outlet 51f. Therefore, it is possible to prevent the air containing a large amount of water vapor evaporated from the surface of the cooler core 16 from being blown out into the passenger compartment, and thus to suppress the window glass from being fogged.

  In the present embodiment, the heater core 17 is arranged in the case 51 on the downstream side of the air flow from the cooler core 16, and the case 51 is configured such that the inside air introduced by the inside / outside air switching box 52 bypasses the cooler core 16 and the heater core. The first switching valve 18 and the second switching valve 19 are in a state where the cooling water absorbed by the cooling water cooler 14 flows into the cooler core 16 and the cooler core 16. Switching between the state where the cooling water heated by the cooling water heater 15 flows, the second bypass door 73 opens and closes the second bypass passage 51m, and the control device 60 (bypass passage opening / closing control means 60e) cools the cooler core 16. When cooling water heated by the water heater 15 is flowing, the operation of the second bypass door 73 is controlled so as to open the second bypass passage 51m. To.

  As a result, when the cooling water heated by the cooling water heater 15 is caused to flow through the cooler core 16 to melt the frost adhering to the surface of the cooler core 16, air that does not contain water vapor evaporated from the surface of the cooler core 16 is removed from the heater core. It can be heated at 17 and blown into the passenger compartment.

(Fourth embodiment)
In the present embodiment, as shown in FIG. 18, the arrangement of the radiator 13, the cooling water cooler 14, and the cooling water heater 15 is changed with respect to the first embodiment, and the cooler core flow path 36 and the heater core are changed. The connection destination of the flow path 37 is changed.

  The radiator 13 is disposed in the radiator flow path 33. One end of the radiator flow path 33 is connected to the first switching valve 18, and the other end is connected to the second switching valve 19.

  The cooling water cooler 14 is disposed in a portion between the second pump 12 and the first switching valve 18 in the second pump flow path 32. The cooling water heater 15 is disposed in a portion between the first pump 11 and the first switching valve 18 in the first pump flow path 31.

  One end of the cooler core flow path 36 is connected to the first switching valve 18, and the other end is connected to a portion of the second pump flow path 32 between the second switching valve 19 and the second pump 12. Yes.

  One end of the heater core flow path 37 is connected to a portion of the first pump flow path 31 between the first switching valve 18 and the second pump 12, and the other end is connected to the second switching valve 19. Yes.

  The temperature adjustment target device 40 is disposed in the device channel 41. One end of the device flow path 41 is connected to the first switching valve 18, and the other end is connected to the second switching valve 19.

  Specifically, the temperature adjustment target device 40 is an intake air cooler, an exhaust gas cooler, a battery cooler, an inverter motor cooler, a CVT warmer, or the like.

  The intake air cooler is a heat exchanger that cools the intake air by exchanging heat between the intake air that has been compressed by the engine supercharger and becomes high temperature and the cooling water. The intake air is preferably cooled to about 30 ° C. The exhaust gas cooler is a heat exchanger that cools engine exhaust gas with cooling water.

  The battery cooler is a device that has a cooling water flow path and cools the battery by applying heat of the battery to the cooling water. The battery is preferably maintained at a temperature of about 10 to 40 ° C. for reasons such as a decrease in output, a decrease in charge / discharge efficiency, and prevention of deterioration.

  The inverter motor cooler is a device that has a cooling water flow path and cools the inverter traveling electric motor by applying heat to the cooling water from the inverter and the traveling electric motor. 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 preferably maintained at a temperature of 65 ° C. or lower for reasons such as preventing deterioration.

  The CVT warmer is a heat exchanger that heats CVT oil by exchanging heat between CVT oil (lubricating oil) used in a CVT (continuously variable transmission) and cooling water.

  In the cooling mode, as shown in FIG. 18, the first switching valve 18 and the second switching valve 19 connect the first pump flow path 31 to the radiator flow path 33 and the heater core flow path 37, and the second pump The working channel 32 is connected to the cooler core channel 36 and the device channel 41.

  Thereby, the 1st pump 11, the cooling water heater 15, the radiator 13, and the heater core 17 comprise the 1st cooling water circuit C1 (1st heat medium circuit), and the 2nd pump 12, the cooling water cooler 14, and the cooler core 16 are comprised. And the 2nd cooling water circuit C2 (2nd heat medium circuit) is comprised by the apparatus 40 for temperature adjustment.

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 flows through the cooling water heater 15, the radiator 13, and the heater core 17 and is sucked into the first pump 11 as shown by a thick solid arrow in FIG. Is done.

  In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water cooler 14, the cooler core 16, and the temperature adjustment target device 40 as shown by the thick dashed line arrow in FIG. It is sucked into the pump 12.

  In the first cooling water circuit C <b> 1, the cooling water heated by the cooling water heater 15 flows through the radiator 13, so that the heat of the cooling water heated by the cooling water heater 15 is radiated to the outside air by the radiator 13.

  In the second cooling water circuit C2, since the cooling water cooled by the cooling water cooler 14 flows through the cooler core 16 and the temperature adjustment target device 40, the cooling water cools the air blown into the vehicle interior by the cooler core 16, and the temperature The adjustment target device 40 is cooled with cooling water.

  In the dehumidifying heating mode and the ventilation heat recovery heating mode, as shown in FIG. 19, the first switching valve 18 and the second switching valve 19 connect the first pump flow path 31 to the heater core flow path 37, and The pump flow path 32 is connected to the cooler core flow path 36, the equipment flow path 41 and the radiator flow path 33.

  Thus, the first pump 11, the cooling water heater 15, and the heater core 17 constitute a first cooling water circuit C1 (first heat medium circuit), and the second pump 12, the cooling water cooler 14, the cooler core 16, and the temperature adjustment. The target device 40 and the radiator 13 constitute a second cooling water circuit C2 (second heat medium circuit).

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 flows through the cooling water heater 15 and the heater core 17 and is sucked into the first pump 11 as indicated by a thick solid arrow in FIG.

  In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water cooler 14, the cooler core 16, the temperature adjustment target device 40, and the radiator 13, as indicated by a thick dotted line arrow in FIG. And sucked into the second pump 12.

  In the first cooling water circuit C1, since the cooling water heated by the cooling water heater 15 flows through the heater core 17, the cooling water heats the air blown into the vehicle interior by the heater core 17.

  In the second cooling water circuit C2, the cooling water cooled by the cooling water cooler 14 flows through the radiator 13, the cooler core 16, and the temperature adjustment target device 40. Therefore, the cooling water cooled by the cooling water cooler 14 is generated by the radiator 13. While absorbing heat from the outside air, the cooler core 16 cools the air blown into the vehicle interior, and the temperature adjustment target device 40 is cooled by the cooling water.

  That is, in the dehumidifying heating mode and the ventilation heat recovery heating mode, the refrigerant of the refrigeration cycle 21 absorbs heat from the outside air by the cooling water cooler 14 and becomes the cooling water of the second cooling water circuit C2 by the cooling water heater 15. Dissipate heat. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

  In the defrost heating mode, as shown in FIG. 20, the first switching valve 18 and the second switching valve 19, the first pump flow path 31 and the second pump flow path 32, the cooler core flow path 36 and the heater core flow It connects with the flow path 37.

  Thereby, the 1st pump 11, the 2nd pump 12, the cooling water cooler 14, the cooling water heater 15, the cooler core 16, and the heater core 17 comprise the cooling water circuit C1 (heat medium circuit).

  In the cooling water circuit C1, as indicated by a thick solid arrow in FIG. 20, the cooling water discharged from the first pump 11 and flowing through the cooling water heater 15 and the cooling water discharged from the second pump 12 and the cooling water cooler 14 The cooling water that has flown through the cooler core 16 and the heater core 17 is sucked into the first pump 11 and the second pump 12.

  In the cooling water circuit C1, the cooling water heated by the cooling water heater 15 flows through the cooling water cooler 14 and is absorbed by the refrigerant. Thereby, the heat of the work of the compressor 22 can be thrown into the cooling water of a cooling water circuit, and the temperature of the cooling water of the cooling water circuit C1 can be raised.

  In the cooling water circuit C1, since the cooling water heated by the heat of the work of the compressor 22 flows through the cooler core 16 and the heater core 17, the cooling water melts frost in the cooler core 16, and the cooling water is heated in the passenger compartment by the heater core 17. Heat the blown air to.

(Fifth embodiment)
In the present embodiment, as shown in FIG. 21, a bypass cooling water flow path 42 is added to the second embodiment, and the connection destination of the cooler core flow path 36 and the heater core flow path 37 is changed. doing.

  The bypass cooling water flow path 42 is a bypass means for bypassing the radiator 13, the cooler core 16, the heater core 17, and the temperature adjustment target device 40 and flowing cooling water. The bypass cooling water flow path 42 has one end connected to the first switching valve 18 and the other end connected to the second switching valve 19.

  One end of the cooler core flow path 36 is connected to the first switching valve 18, and the other end is connected to the second switching valve 19. One end of the heater core flow path 37 is connected to the first switching valve 18, and the other end is connected to the second switching valve 19.

  In the cooling mode, as shown in FIG. 21, the first switching valve 18 and the second switching valve 19 connect the first pump flow path 31 to the radiator flow path 33 and the heater core flow path 37, so that the second pump The working channel 32 is connected to the cooler core channel 36 and the device channel 41.

  Thereby, the 1st pump 11, the cooling water heater 15, the radiator 13, and the heater core 17 comprise the 1st cooling water circuit C1 (1st heat medium circuit), and the 2nd pump 12, the cooling water cooler 14, and the cooler core 16 are comprised. And the 2nd cooling water circuit C2 (2nd heat medium circuit) is comprised by the apparatus 40 for temperature regulation.

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 flows through the cooling water heater 15, the radiator 13, and the heater core 17 and is sucked into the first pump 11 as indicated by the thick solid arrows in FIG. Is done.

  In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water cooler 14, the cooler core 16, and the temperature adjustment target device 40 as shown by the thick dashed line arrow in FIG. It is sucked into the pump 12.

  In the first cooling water circuit C <b> 1, the cooling water heated by the cooling water heater 15 flows through the radiator 13, so that the heat of the cooling water heated by the cooling water heater 15 is radiated to the outside air by the radiator 13.

  In the second cooling water circuit C2, since the cooling water cooled by the cooling water cooler 14 flows through the cooler core 16 and the temperature adjustment target device 40, the cooling water cools the air blown into the vehicle interior by the cooler core 16, and the temperature The adjustment target device 40 is cooled with cooling water.

  In the dehumidifying heating mode and the ventilation heat recovery heating mode, as shown in FIG. 22, the first switching valve 18 and the second switching valve 19 connect the first pump flow path 31 to the heater core flow path 37, and The pump flow path 32 is connected to the cooler core flow path 36, the equipment flow path 41 and the radiator flow path 33.

  Thus, the first pump 11, the cooling water heater 15, and the heater core 17 constitute a first cooling water circuit C1 (first heat medium circuit), and the second pump 12, the cooling water cooler 14, the cooler core 16, and the temperature adjustment. The target device 40 and the radiator 13 constitute a second cooling water circuit C2 (second heat medium circuit).

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 flows through the cooling water heater 15 and the heater core 17 and is sucked into the first pump 11 as indicated by a thick solid arrow in FIG.

  In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water cooler 14, the cooler core 16, the temperature adjustment target device 40, and the radiator 13, as indicated by a thick dotted line arrow in FIG. And sucked into the second pump 12.

  In the first cooling water circuit C1, since the cooling water heated by the cooling water heater 15 flows through the heater core 17, the cooling water heats the air blown into the vehicle interior by the heater core 17.

  In the second cooling water circuit C2, the cooling water cooled by the cooling water cooler 14 flows through the radiator 13, the cooler core 16, and the temperature adjustment target device 40. Therefore, the cooling water cooled by the cooling water cooler 14 is generated by the radiator 13. While absorbing heat from the outside air, the cooler core 16 cools the air blown into the vehicle interior, and the temperature adjustment target device 40 is cooled by the cooling water.

  That is, in the dehumidifying heating mode and the ventilation heat recovery heating mode, the refrigerant of the refrigeration cycle 21 absorbs heat from the outside air by the cooling water cooler 14 and becomes the cooling water of the second cooling water circuit C2 by the cooling water heater 15. Dissipate heat. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

  In the ventilation heat recovery heating mode, when the heat necessary for heating is sufficient only by the heat recovered from the air exhausted outside the vehicle for ventilation, the first switching valve 18 and the second switching valve 19 are used for the second pump flow. The path 32 may be connected to the bypass cooling water flow path 42 and not connected to the radiator flow path 33. Thereby, it is possible to heat only the heat recovered from the air discharged outside the vehicle for ventilation without pumping up the heat of the outside air.

  In the defrost heating mode, as shown in FIG. 23, the first switching valve 18 and the second switching valve 19 use the first pump flow path 31 as the cooler core flow path 36, the equipment flow path 41, and the heater core flow path. 37 and the second pump flow path 32 is connected to the radiator flow path 33.

  Accordingly, the first pump 11, the cooling water heater 15, the cooler core 16, the temperature adjustment target device 40, and the heater core 17 constitute a first cooling water circuit (first heat medium circuit), and the second pump 12, cooling water cooling A second cooling water circuit (second heat medium circuit) is configured by the vessel 14 and the radiator 13.

  In the first cooling water circuit, the cooling water discharged from the first pump 11 flows through the cooling water heater 15, the cooler core 16, the temperature adjustment target device 40, and the heater core 17 as indicated by the thick solid arrows in FIG. The cooling water sucked into the first pump 11 and discharged from the second pump 12 flows through the cooling water cooler 14 and the radiator 13 and is sucked into the second pump 12.

  In the first cooling water circuit C1, the cooling water heated by the cooling water heater 15 flows through the cooler core 16 and the heater core 17, so that the cooling water melts frost in the cooler core 16 and the cooling water flows into the vehicle interior in the heater core 17. The blast air is heated.

  In the second cooling water circuit C2, the cooling water cooled by the cooling water cooler 14 flows through the radiator 13, so that the cooling water cooled by the cooling water cooler 14 absorbs heat from the outside air by the radiator 13.

  That is, in the defrost heating mode, as in the dehumidification heating mode and the ventilation heat recovery heating mode, the refrigerant of the refrigeration cycle 21 absorbs heat from the outside air by the cooling water cooler 14 and is secondly discharged by the cooling water heater 15. Heat is radiated to the cooling water in the cooling water circuit C2. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

(Sixth embodiment)
In the present embodiment, as shown in FIG. 24, a cooling water / cooling water heat exchanger 43 is provided instead of the heater core 17 as compared with the first embodiment. The cooling water cooling water heat exchanger 43 is disposed in the cooling water cooling water heat exchanger channel 44. One end of the cooling water / cooling water heat exchanger channel 44 is connected to the first switching valve 18, and the other end is connected to the second switching valve 19.

  The cooling water cooling water heat exchanger 43 exchanges heat between the cooling water discharged from the first pump 11 or the second pump 12 and the engine cooling water (second heat medium) circulating in the engine cooling circuit 80. It is an exchanger (heat medium heat medium heat exchanger).

  The engine cooling circuit 80 is a cooling water circuit (heat medium circuit) having a circulation passage 81 through which engine cooling water circulates. The circulation channel 81 constitutes the main channel of the engine cooling circuit 80. In this embodiment, a liquid containing at least ethylene glycol, dimethylpolysiloxane, or nanofluid is used as the engine cooling water.

  In the circulation channel 81, the third pump 82, the engine 83, the cooling water / cooling water heat exchanger 43, the heater core 84, and the CVT warmer 85 are arranged in this order in series. The engine 83 is a heat generating device that generates heat as it operates.

  The third pump 82 is an electric pump that sucks and discharges engine coolant. The cooling water cooling water heat exchanger 43 exchanges heat between the engine cooling water circulating in the engine cooling circuit 80 and the cooling water circulated by the first pump 11 or the second pump 12 (heat medium heat). Medium heat exchanger).

  The heater core 84 is a 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 CVT warmer 85 is a heat exchanger that heats the CVT oil by exchanging heat between CVT oil (lubricating oil) used in the CVT (continuously variable transmission) and cooling water.

  One end of an engine radiator flow path 86 is connected to a portion of the circulation flow path 81 on the coolant outlet side of the engine 83. The other end of the engine radiator flow path 86 is connected to a portion of the circulation flow path 81 on the suction side of the third pump 82.

  An engine radiator 87 is disposed in the engine radiator flow path 86. The engine radiator 87 is an engine radiator that dissipates heat from the cooling water to the outside air by exchanging heat between the cooling water and outside air (hereinafter referred to as outside air). It is.

  The outside air blower 21 blows outside air to the engine radiator 87. Although not shown, the engine radiator 87 is disposed downstream of the radiator 13 in the outside air flow direction at the foremost part of the vehicle.

  A thermostat 88 is disposed at a connection portion between the other end of the engine radiator flow path 86 and the circulation flow path 81. The thermostat 88 is a cooling water temperature responsive valve configured by a mechanical mechanism that opens and closes the cooling water flow path by displacing the valve body with a thermo wax (temperature sensitive member) that changes in volume according to temperature.

  Specifically, when the temperature of the cooling water is lower than a predetermined temperature (for example, less than 80 ° C.), the thermostat 88 closes the engine radiator flow path 86 and the temperature of the cooling water is higher than the predetermined temperature ( For example, the engine radiator passage 86 is opened.

  In the cooling mode, as shown in FIG. 24, the first switching valve 18 and the second switching valve 19 use the first pump flow path 31 as the cooling water heater flow path 35, the equipment flow path 41, and the cooling water cooling water. The second pump flow path 32 is connected to the cooling water cooler flow path 34 and the cooler core flow path 36 by being connected to the heat exchanger flow path 44.

  Thus, the first cooling water circuit C1 (first heat medium circuit) is configured by the first pump 11, the cooling water heater 15, the temperature adjustment target device 40, the cooling water cooling water heat exchanger 43, and the radiator 13, and the first The second pump 12, the cooling water cooler 14, and the cooler core 16 constitute a second cooling water circuit C2 (second heat medium circuit).

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 is the cooling water heater 15, the temperature adjustment target device 40, and the cooling water cooling water heat exchanger 43, as indicated by the thick solid arrows in FIG. And it flows through the radiator 13 and is sucked into the first pump 11.

  In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water cooler 14 and the cooler core 16 and is sucked into the second pump 12 as indicated by a thick dashed line arrow in FIG. .

  In the first cooling water circuit C <b> 1, the cooling water heated by the cooling water heater 15 flows through the radiator 13, so that the heat of the cooling water heated by the cooling water heater 15 is radiated to the outside air by the radiator 13.

  In the second cooling water circuit C2, since the cooling water cooled by the cooling water cooler 14 flows through the cooler core 16, the cooling water cools the air blown into the vehicle interior by the cooler core 16.

  In the dehumidifying heating mode and the ventilation heat recovery heating mode, as shown in FIG. 25, the first switching valve 18 and the second switching valve 19 use the first pump flow path 31 as the cooling water cooler flow path 34, the equipment flow path. The channel 41 and the cooler core channel 36 are connected, and the second pump channel 32 is connected to the cooling water heater channel 35 and the cooling water cooling water heat exchanger channel 44.

  Thus, the first cooling water circuit C1 (first heat medium circuit) is configured by the first pump 11, the cooling water cooler 14, the temperature adjustment target device 40, the cooler core 16, and the radiator 13, and the second pump 12, cooling water The heater 15 and the coolant cooling water heat exchanger 43 constitute a second coolant circuit C2 (second heat medium circuit).

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 flows through the cooling water cooler 14, the temperature adjustment target device 40, the cooler core 16 and the radiator 13 as shown by the thick solid arrows in FIG. It is sucked into the first pump 11. In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water heater 15 and the cooling water cooling water heat exchanger 43 as shown by the thick dashed line arrow in FIG. It is sucked into the pump 12.

In the first cooling water circuit C 1, the cooling water cooled by the cooling water cooler 14 flows through the cooler core 16, the temperature adjustment target device 40 and the radiator 13, so that the cooling water cooled by the cooling water cooler 14 is the cooler core 16. Cooling water heated by the cooling water heater 15 is cooled in the second cooling water circuit C2 that cools the air blown into the passenger compartment and the temperature adjustment target device 40 is cooled by the cooling water and absorbs heat from the outside air by the radiator 13. Flows through the cooling water cooling water heat exchanger 43, the engine cooling water is heated by the cooling water cooling water heat exchanger 43, and the engine cooling water heats the air blown into the vehicle compartment by the heater core 84.

  That is, in the dehumidifying heating mode and the ventilation heat recovery heating mode, the refrigerant of the refrigeration cycle 21 absorbs heat from the outside air by the cooling water cooler 14 and becomes the cooling water of the second cooling water circuit C2 by the cooling water heater 15. Dissipate heat. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

  In the defrost heating mode, as shown in FIG. 26, the first switching valve 18 and the second switching valve 19 connect the first pump flow path 31 to the cooling water cooler flow path 34 and the equipment flow path 41. The second pump flow path 32 is connected to the cooling water heater flow path 35, the cooler core flow path 36, and the cooling water cooling water heat exchanger flow path 44.

  Thereby, the 1st cooling water circuit (1st heat medium circuit) is comprised by the 1st pump 11, the cooling water cooler 14, the temperature adjustment object apparatus 40, and the radiator 13, and the 2nd pump 12, the cooling water heater 15, The cooler core 16 and the cooling water cooling water heat exchanger 43 constitute a second cooling water circuit (second heat medium circuit).

  In the first cooling water circuit, as shown by the thick solid line arrow in FIG. 26, the cooling water discharged from the first pump 11 flows through the cooling water cooler 14, the temperature adjustment target device 40, and the radiator 13 to pass through the first pump. 11, the cooling water discharged from the second pump 12 flows through the cooling water heater 15, the cooler core 16, and the cooling water cooling water heat exchanger 43 and is sucked into the second pump 12.

  In the first cooling water circuit C1, the cooling water cooled by the cooling water cooler 14 flows through the radiator 13, so that the cooling water cooled by the cooling water cooler 14 absorbs heat from the outside air by the radiator 13.

  In the second cooling water circuit C2, since the cooling water heated by the cooling water heater 15 flows through the cooler core 16 and the cooling water cooling water heat exchanger 43, the cooling water melts frost and cools the cooling water in the cooler core 16. The engine cooling water is heated by the water heat exchanger 43, and the engine cooling water heats the air blown into the passenger compartment by the heater core 84.

  That is, in the defrost heating mode, as in the dehumidification heating mode and the ventilation heat recovery heating mode, the refrigerant of the refrigeration cycle 21 absorbs heat from the outside air by the cooling water cooler 14 and is secondly discharged by the cooling water heater 15. Heat is radiated to the cooling water in the cooling water circuit C2. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

  In this embodiment, the cooling water cooling water heat exchanger 43 and the heater core 84 use air heating means for heating the air blown into the vehicle interior using the heat of the cooling water heated by the cooling water heater 15. It is composed. Therefore, the same operational effects as those of the above embodiment can be obtained.

  In the present embodiment, the cooling water cooling water heat exchanger 43 is connected to the first switching valve 18 and the second switching valve 19, and the first switching valve 18 is the first for the cooling water cooling water heat exchanger 43. The state where the cooling water discharged from the pump 11 flows in and the state where the cooling water discharged from the second pump 12 flows in are switched, and the second switching valve 19 switches the first pump with respect to the cooling water cooling water heat exchanger 43. The state where the cooling water flows out to 11 and the state where the cooling water flows out to the second pump 12 are switched. Thereby, the structure for switching the cooling water which flows into the cooling water cooling water heat exchanger 43 can be simplified.

(Seventh embodiment)
In the present embodiment, as shown in FIG. 27, the arrangement of the radiator 13, the cooling water cooler 14, and the cooling water heater 15 is changed with respect to the sixth embodiment.

  The radiator 13 is disposed in the radiator flow path 33. The cooling water cooler 14 is disposed on the cooling water discharge side of the second pump 12 in the second pump flow path 32. The cooling water heater 15 is disposed on the cooling water discharge side of the first pump 11 in the first pump flow path 31.

  The battery cooler 45 is disposed in the battery cooler flow path 47. The inverter motor cooler 46 is disposed on the downstream side of the cooling water flow of the battery cooler 45 in the battery cooler flow path 47.

  The engine bypass flow path 90 allows the engine coolant that has flowed out of the coolant coolant heat exchanger 43 and the heater core 84 to bypass the CVT warmer 85 and the engine 83 in the engine cooling circuit 80. It is a flow path.

  One end of the engine bypass passage 90 is connected to a portion of the circulation passage 81 of the engine cooling circuit 80 between the heater core 84 and the CVT warmer 85. The other end of the engine bypass passage 90 is connected to a portion of the circulation passage 81 of the engine cooling circuit 80 between the engine 83 and the cooling water / cooling water heat exchanger 43.

  The sub pump 91 is an electric pump that sucks and discharges engine cooling water, and is disposed in the engine bypass flow path 90. The sub pump 91 is disposed in the engine bypass flow path 90 so as to suck in engine cooling water flowing out from the heater core 84 and discharge the engine cooling water toward the cooling water cooling water heat exchanger 43 side.

  In the three-way valve 92, the engine cooling water circulates in the circulation passage 81 without flowing through the engine bypass passage 90, and the engine cooling water bypasses the CVT warmer 85 and the engine 83 and flows in the engine bypass passage 90. And is disposed at a connection portion between the engine bypass flow path 90 and the circulation flow path 81.

  In the cooling mode, as shown in FIG. 27, the first switching valve 18 and the second switching valve 19 connect the first pump flow path 31 to the radiator flow path 33 and the battery cooler flow path 47, and The pump flow path 32 is connected to the cooler core flow path 36.

  Thus, the first pump 11, the cooling water heater 15, the radiator 13, and the battery cooler 45 constitute a first cooling water circuit C1 (first heat medium circuit), and the second pump 12, the cooling water cooler 14, and The cooler core 16 constitutes a second cooling water circuit C2 (second heat medium circuit).

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 flows through the cooling water heater 15, the radiator 13, and the battery cooler 45 as shown by the thick solid arrows in FIG. Inhaled. In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water cooler 14 and the cooler core 16 and is sucked into the second pump 12 as indicated by a thick dashed line arrow in FIG. .

  In the first cooling water circuit C <b> 1, the cooling water heated by the cooling water heater 15 flows through the radiator 13, so that the heat of the cooling water heated by the cooling water heater 15 is radiated to the outside air by the radiator 13.

  In the second cooling water circuit C2, since the cooling water cooled by the cooling water cooler 14 flows through the cooler core 16, the cooling water cools the air blown into the vehicle interior by the cooler core 16.

  In the dehumidifying heating mode and the ventilation heat recovery heating mode, as shown in FIG. 28, the first switching valve 18 and the second switching valve 19 connect the first pump flow path 31 to the cooling water / cooling water heat exchanger flow path 44. The second pump flow path 32 is connected to the cooler core flow path 36, the radiator flow path 33, and the battery cooler flow path 47.

  Thereby, the 1st cooling water circuit C1 (1st heat medium circuit) is comprised by the 1st pump 11, the cooling water heater 15, and the cooling water cooling water heat exchanger 43, and the 2nd pump 12, the cooling water cooler 14 is comprised. The cooler core 16, the radiator 13, the battery cooler 45, and the inverter motor cooler 46 constitute a second coolant circuit C2 (second heat medium circuit).

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 flows through the cooling water heater 15 and the cooling water cooling water heat exchanger 43 as shown by a thick solid arrow in FIG. 11 is inhaled. In the second cooling water circuit C2, the cooling water discharged from the second pump 12 is the cooling water cooler 14, the cooler core 16, the radiator 13, the battery cooler 45, and the inverter motor, as indicated by the thick dashed line arrows in FIG. It flows through the cooler 46 and is sucked into the second pump 12.

  In the first cooling water circuit C1, since the cooling water heated by the cooling water heater 15 flows through the cooling water cooling water heat exchanger 43, the engine cooling water is heated by the cooling water cooling water heat exchanger 43 and the heater core 84 is heated. The engine cooling water heats the air blown into the passenger compartment.

  In the second cooling water circuit C2, the cooling water cooled by the cooling water cooler 14 flows through the cooler core 16, the radiator 13, the battery cooler 45, and the inverter motor cooler 46. Therefore, the cooling cooled by the cooling water cooler 14 is performed. Water cools the air blown into the passenger compartment by the cooler core 16 and absorbs heat from the outside air by the radiator 13, and the battery cooler 45 and the inverter motor cooler 46 are cooled by the cooling water.

  That is, in the dehumidifying heating mode and the ventilation heat recovery heating mode, the refrigerant of the refrigeration cycle 21 absorbs heat from the outside air by the cooling water cooler 14 and becomes the cooling water of the second cooling water circuit C2 by the cooling water heater 15. Dissipate heat. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

  In the ventilation heat recovery heating mode, when the heat necessary for heating is sufficient only by the heat recovered from the air exhausted outside the vehicle for ventilation, the first switching valve 18 and the second switching valve 19 are used for the second pump flow. The path 32 may not be connected to the radiator flow path 33. Thereby, it is possible to heat only the heat recovered from the air discharged outside the vehicle for ventilation without pumping up the heat of the outside air.

  In the defrost heating mode, as shown in FIG. 29, the first switching valve 18 and the second switching valve 19 use the first pump flow path 31 as the cooler core flow path 36 and the cooling water / cooling water heat exchanger flow path 44. And the second pump flow path 32 is connected to the radiator flow path 33 and the battery cooler flow path 47.

  Thereby, the 1st pump 11, cooling water heater 15, cooler core 16, and cooling water cooling water heat exchanger 43 constitute a 1st cooling water circuit (1st heat medium circuit), and 2nd pump 12, cooling water cooling The second cooling water circuit (second heat medium circuit) is configured by the cooler 14, the radiator 13, the battery cooler 45, and the inverter motor cooler 46.

  In the first cooling water circuit, the cooling water discharged from the first pump 11 flows through the cooling water heater 15, the cooler core 16, and the cooling water cooling water heat exchanger 43 as shown by the thick solid arrows in FIG. The cooling water sucked into the first pump 11 and discharged from the second pump 12 flows through the cooling water cooler 14, the radiator 13, the battery cooler 45 and the inverter motor cooler 46 and is sucked into the second pump 12.

  In the first cooling water circuit C1, since the cooling water heated by the cooling water heater 15 flows through the cooler core 16 and the cooling water cooling water heat exchanger 43, the cooling water melts frost and cools the cooling water in the cooler core 16. The engine cooling water is heated by the water heat exchanger 43, and the engine cooling water heats the air blown into the passenger compartment by the heater core 84.

  In the second cooling water circuit C2, the cooling water cooled by the cooling water cooler 14 flows through the radiator 13, so that the cooling water cooled by the cooling water cooler 14 absorbs heat from the outside air by the radiator 13.

  That is, in the defrost heating mode, as in the dehumidification heating mode and the ventilation heat recovery heating mode, the refrigerant of the refrigeration cycle 21 absorbs heat from the outside air by the cooling water cooler 14 and is secondly discharged by the cooling water heater 15. Heat is radiated to the cooling water in the cooling water circuit C2. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

(Eighth embodiment)
In the eighth embodiment, as shown in FIG. 30, an evaporator 25 is provided instead of the cooler core 16 in the seventh embodiment.

  The refrigeration cycle 22 includes an evaporator expansion valve 26 and a solenoid valve 27. The evaporator expansion valve 26 and the evaporator 25 are arranged in parallel with the expansion valve 24 and the cooling water cooler 14 in the refrigeration cycle 22.

  The electromagnetic valve 27 opens and closes the refrigerant flow path from the cooling water heater 15 to the expansion valve 24. Therefore, the electromagnetic valve 27 intermittently switches the refrigerant flow to the expansion valve 24 and the cooling water cooler 14.

  Although not shown, the evaporator 25 is disposed inside the case 51 on the upstream side of the air flow of the heater core 84.

  The inverter motor cooler 46 is disposed in the inverter motor cooler flow path 48. One end of the inverter motor cooler flow path 48 is connected to the first switching valve 18, and the other end is connected to the second switching valve 19. The heater core 17 is disposed in the heater core flow path 37.

  In the cooling mode, as shown in FIG. 30, the first switching valve 18 and the second switching valve 19 use the first pump flow path 31 as the radiator flow path 33, the heater core flow path 37, the inverter motor cooler flow path. 48 and the cooling water / cooling water heat exchanger channel 44, and the second pump channel 32 is connected to the battery cooler channel 47.

  Thereby, the 1st cooling water circuit C1 (1st heat medium circuit) is comprised by the 1st pump 11, the cooling water heater 15, the radiator 13, the heater core 17, the inverter motor cooler 46, and the cooling water cooling water heat exchanger 43. The second pump 12, the cooling water cooler 14, and the battery cooler 45 constitute a second cooling water circuit C2 (second heat medium circuit).

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 is the cooling water heater 15, the radiator 13, the heater core 17, the inverter motor cooler 46, and the cooling water as shown by the thick solid arrows in FIG. It flows through the cooling water heat exchanger 43 and is sucked into the first pump 11.

  In the second cooling water circuit C2, the cooling water discharged from the second pump 12 flows through the cooling water cooler 14 and the battery cooler 45 and is sucked into the second pump 12 as indicated by a thick dashed line arrow in FIG. Is done.

  In the first cooling water circuit C <b> 1, the cooling water heated by the cooling water heater 15 flows through the radiator 13, so that the heat of the cooling water heated by the cooling water heater 15 is radiated to the outside air by the radiator 13.

  In the second cooling water circuit C2, since the cooling water cooled by the cooling water cooler 14 flows through the battery cooler 45, the battery cooler 45 is cooled by the cooling water.

  In the evaporator 25, the low-pressure side refrigerant of the refrigeration cycle 22 cools the air blown into the passenger compartment.

  In the dehumidifying heating mode and the ventilation heat recovery heating mode, as shown in FIG. 31, the first switching valve 18 and the second switching valve 19 use the first pump flow path 31 as the heater core flow path 37 and the cooling water cooling water heat. The second pump flow path 32 is connected to the radiator flow path 33, the battery cooler flow path 47, and the inverter motor cooler flow path 48.

  Thus, the first pump 11, the cooling water heater 15, the heater core 17, and the cooling water cooling water heat exchanger 43 constitute a first cooling water circuit C1 (first heat medium circuit), and the second pump 12, cooling water The cooler 14, the radiator 13, the inverter motor cooler 46, and the battery cooler 45 constitute a second coolant circuit C2 (second heat medium circuit).

  In the first cooling water circuit C1, the cooling water discharged from the first pump 11 flows through the cooling water heater 15, the heater core 17, and the cooling water cooling water heat exchanger 43 as shown by the thick solid arrows in FIG. It is sucked into the first pump 11. In the second cooling water circuit C2, the cooling water discharged from the second pump 12 is supplied from the cooling water cooler 14, the radiator 13, the inverter motor cooler 46, and the battery cooler 45, as indicated by a thick dotted line arrow in FIG. And is sucked into the second pump 12.

  In the first cooling water circuit C1, since the cooling water heated by the cooling water heater 15 flows through the heater core 17, the cooling water heats the air blown into the vehicle interior by the heater core 17.

  In the second cooling water circuit C2, since the cooling water cooled by the cooling water cooler 14 flows through the radiator 13, the inverter motor cooler 46, and the battery cooler 45, the cooling water cooled by the cooling water cooler 14 is the radiator. 13 absorbs heat from the outside air, and the inverter motor cooler 46 and the battery cooler 45 are cooled with cooling water.

  That is, in the dehumidifying heating mode and the ventilation heat recovery heating mode, the refrigerant of the refrigeration cycle 21 absorbs heat from the outside air by the cooling water cooler 14 and becomes the cooling water of the second cooling water circuit C2 by the cooling water heater 15. Dissipate heat. Therefore, it is possible to realize a heat pump operation that pumps up the heat of the outside air.

  In the evaporator 25, the low-pressure side refrigerant of the refrigeration cycle 22 cools the air blown into the passenger compartment. In other words, in the evaporator 25, the low-pressure side refrigerant of the refrigeration cycle 22 absorbs heat from the air blown into the vehicle interior.

  In the present embodiment, the evaporator 25 constitutes heat absorption means that absorbs heat from the inside air discharged to the outside of the passenger compartment to the low-pressure side refrigerant of the refrigeration cycle 21 and absorbs heat from the outside air to the low-pressure side refrigerant. Therefore, the same operational effects as those of the above embodiment can be obtained.

  In the present embodiment, the evaporator 25 is arranged inside the case 51 so that the inside air and outside air introduced by the inside / outside air switching box 52 pass, and the heater core 17 has the inside air and outside air introduced by the inside / outside air switching box 52. The case 51 is disposed inside the case 51, and the case 51 includes air outlets 51f, 51g, 51h for blowing air that has passed through at least one of the evaporator 25 and the heater core 17 into the vehicle interior, and an evaporator. A discharge port 51k for discharging the air that has passed through the vehicle 25 to the outside of the vehicle compartment is formed, and the discharge opening / closing door 72 blows the air that has passed through the evaporator 25 into the vehicle compartment through the air outlets 51f, 51g, 51h. Between the state and the state in which the air that has passed through the evaporator 25 is discharged out of the passenger compartment through the discharge port 51k

  According to this, the evaporator 25 can perform both the function of absorbing heat from the air discharged outside the vehicle compartment and the function of cooling the air blown out into the vehicle compartment. Therefore, a structure can be simplified compared with the case where the heat exchanger which absorbs heat from the air discharged to the outside of the passenger compartment and the heat exchanger which cools the air blown into the passenger compartment are separately provided.

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

  (1) In the above embodiment, the cooling water cooler 14 that cools the cooling water with the low-pressure refrigerant of the refrigeration cycle 21 is used as the cooling means for cooling the cooling water to a temperature lower than the temperature of the outside air. It may be used as a cooling means.

  (2) In each of the above embodiments, instead of the engine 83, various heat generating devices (for example, fuel cells) that generate heat in accordance with operation may be provided.

  (3) 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. In addition to the effect of lowering the freezing point as in the case of cooling water using ethylene glycol (so-called antifreeze liquid), the following effects can be obtained by mixing the nanoparticles with the heat medium.

  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 heat stored in the heat medium itself (cold heat stored by sensible heat) can be increased.

  Even if the compressor 22 is not operated by increasing the amount of cold storage heat, it is possible to control the temperature of the equipment using the cold storage heat and heating for a certain amount of time. Can be realized.

  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 (carbon nanotube), graphene, graphite core-shell nanoparticle (a structure such as a carbon nanotube surrounding the above atom is included as a constituent atom of the nanoparticle. Particles), Au nanoparticle-containing CNTs, and the like can be used.

  (4) In the refrigeration cycle 21 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 21 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.

  (5) In each of the above embodiments, an example in which the heat management system 10 and the vehicle air conditioner are applied to a hybrid vehicle has been described. Alternatively, the heat management system 10 and the vehicle air conditioner may be applied.

11 First pump 12 Second pump 13 Radiator (external air heat absorber, heat absorption means)
14 Cooling water cooler (heat absorber for heat medium, heat absorption means)
15 Cooling water heater (heat medium heater)
16 Cooler core (heat absorber for inside air, heat absorption means)
17 Heater core (air heater, air heating means)
18 First switching valve 19 Second switching valve 21 Refrigeration cycle

Claims (13)

Endothermic means (13, 14, 16, 25) for absorbing heat from the inside air discharged outside the passenger compartment to the low-pressure side refrigerant of the refrigeration cycle (21), and absorbing heat from the outside air to the low-pressure side refrigerant;
A heat medium heater (15) for heating the heat medium by exchanging heat between the high-pressure side refrigerant of the refrigeration cycle (21) and the heat medium;
Air heating means (17, 43, 84) for heating the air blown into the passenger compartment using the heat of the heat medium heated by the heat medium heater (15),
The heat absorption means includes a heat medium heat absorber (14) for exchanging heat between the low pressure side refrigerant and the heat medium to absorb heat from the heat medium to the low pressure side refrigerant, and a heat medium heat absorber (14). An air conditioner for a vehicle, comprising: a heat absorber (13) for outside air that exchanges heat between the heat medium that has absorbed heat and the outside air to absorb heat from the outside air to the low-pressure side refrigerant.   The heat absorption means includes an internal air heat absorber (16) for exchanging heat between the heat medium absorbed by the heat medium heat absorber (14) and the internal air to absorb heat from the internal air to the heat medium. The vehicle air conditioner according to claim 1, wherein   The said heat absorption means has an inside air heat absorber (25) which heat-exchanges the said inside air and the said low voltage | pressure side refrigerant | coolant, and absorbs heat from the said inside air to the said low voltage | pressure side refrigerant | coolant. Vehicle air conditioner. A first pump (11) and a second pump (12) for sucking and discharging the heat medium;
The heat medium discharge side of the first pump (11), the heat medium discharge side of the second pump (12), and the internal air heat absorber (16) are connected, and the internal air heat absorber (16) is A first switching valve (18) for switching between a state in which the heat medium discharged from one pump (11) flows in and a state in which the heat medium discharged from the second pump (12) flows;
The heat medium discharge side of the first pump (11), the heat medium discharge side of the second pump (12), and the internal air heat absorber (16) are connected, and the internal air heat absorber (16) is A second switching valve (19) for switching between a state in which the heat medium flows out to one pump (11) and a state in which the heat medium flows out to the second pump (12) is provided. The vehicle air conditioner described in 1.   The first switching valve (18) and the second switching valve (19) include one of the first pump (11) and the second pump (12), the heat medium heater (15), and the The vehicle air conditioner according to claim 4, wherein the heat medium can be switched to a state in which the heat medium circulates with the inside air heat absorber (16).   The air heating means includes an air heater (17) that heats the air by exchanging heat between the heat medium heated by the heat medium heater (15) and the air. The vehicle air conditioner according to any one of claims 1 to 5. The air heating means includes an air heater (17) that heats the air by exchanging heat between the heat medium heated by the heat medium heater (15) and the air,
The air heater (17) is connected to the first switching valve (18) and the second switching valve (19),
The first switching valve (18) is in a state where the heat medium discharged from the first pump (11) flows into the air heater (17) and the heat discharged from the second pump (12). Switch between the state where the medium flows in,
The second switching valve (19) includes a state in which the heat medium flows out to the first pump (11) and a state in which the heat medium flows out to the second pump (12) with respect to the air heater (17). The vehicle air conditioner according to claim 4 or 5, wherein the air conditioner is switched. A heat medium circuit (80) in which the second heat medium heated by the heat generating device (83) that generates heat circulates;
The air heating means includes a heat medium heat medium heat exchanger (43) for exchanging heat between the heat medium heated by the heat medium heater (15) and the second heat medium, and the heat medium heat medium heat. The air heater (84) that heats the air by exchanging heat between the second heat medium exchanged by the exchanger (43) and the air. The vehicle air conditioner according to any one of 5. A heat medium circuit (80) in which the second heat medium heated by the heat generating device (83) that generates heat circulates;
The air heating means includes a heat medium heat medium heat exchanger (43) for exchanging heat between the heat medium heated by the heat medium heater (15) and the second heat medium, and the heat medium heat medium heat. An air heater (84) for exchanging heat between the second heat medium exchanged with the exchanger (43) and the air to heat the air,
The heat medium heat medium heat exchanger (43) is connected to the first switching valve (18) and the second switching valve (19),
The first switching valve (18) discharges from the second pump (12) when the heat medium discharged from the first pump (11) flows into the heat medium heat medium heat exchanger (43). Switching the state where the heat medium that has been flown,
The second switching valve (19) includes a state in which the heat medium flows out to the first pump (11) with respect to the heat medium heat medium heat exchanger (43) and the heat medium to the second pump (12). The vehicle air conditioner according to claim 4 or 5, wherein the state of flowing out is switched. A case (51) forming an air passage through which air flows;
Inside and outside air introduction means (52) for introducing inside air and outside air into the case (51),
The inside air heat absorber (16, 25) is arranged inside the case (51) so that the inside air and outside air introduced by the inside / outside air introduction means (52) pass therethrough,
The air heating means (17, 43, 84) is an air heater (17, 84) disposed inside the case (51) so as to heat the inside air and the outside air introduced by the inside / outside air introduction means (52). )
The case (51) has an air outlet (51f, 51g) for blowing out air that has passed through at least one of the inside air heat absorber (16, 25) and the air heater (17, 84) into the vehicle interior. 51h) and a discharge port (51k) for discharging the air that has passed through the inside air heat absorber (16, 25) out of the passenger compartment,
Furthermore, the state where the air that has passed through the inside air heat absorber (16, 25) is blown out into the vehicle interior through the air outlets (51f, 51g, 51h) and the inside air heat absorber (16, 25). 6. The vehicle according to claim 2, further comprising an air flow switching unit that switches between a state in which the discharged air is discharged out of the passenger compartment through the discharge port. Air conditioner.   The case (51) has a structure in which the volume of air discharged outside the vehicle compartment through the discharge port (51k) is equal to or less than the volume of outside air introduced by the inside / outside air introduction means (52). The vehicle air conditioner according to any one of Claims 10 to 10. The air heater (17, 84) is arranged in the air flow downstream of the inside air heat absorber (16, 25) inside the case (51),
The case (51) has a bypass passage (51m) through which the inside air introduced by the inside / outside air introduction means (52) bypasses the inside air heat absorber (16, 25) and is guided to the air heater (17). Formed,
Further, the heat medium absorbed by the heat medium heat absorber (14) flows to the inside air heat absorber (16), and the heat medium heater (15) to the inside air heat absorber (16). ) Heat medium flow switching means (18, 19) for switching between the state in which the heat medium heated in (1) flows;
Bypass passage opening and closing means (73) for opening and closing the bypass passage (51m);
When the heat medium heated by the heat medium heater (15) flows through the internal air heat absorber (16), the bypass passage opening / closing means (73) opens the bypass passage (51m). The vehicle air conditioner according to claim 10 or 11, further comprising bypass passage opening / closing control means (60e) for controlling the operation. Temperature detecting means (65) for detecting a temperature related to the surface temperature of the internal air heat absorber (16);
Based on the temperature detected by the temperature detection means (65), it is determined whether or not there is a possibility that frost may adhere to the surface of the internal air heat absorber (16), and the internal air heat absorber (16) When it is determined that there is a possibility that frost may adhere to the surface, at least one of the air flowing through the inside air heat absorber (16) and the heat medium so that the surface temperature of the inside air heat absorber (16) increases. The vehicle air conditioner according to claim 2, further comprising flow rate control means (60c, 60d) for controlling one flow rate.

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