JP2016199203A - Heat management system for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To progress the improvement of a heating capacity and the further power saving of heating by properly and combinedly using an outside-air heat absorption heating operation and an exhaust-heat absorption heating operation.SOLUTION: A heat management system for a vehicle comprises: a heat medium cooler 14 which performs cooling by making a low-temperature heat medium heat-exchange with a low-pressure side refrigerant of a refrigerator cycle 31; a heat medium outside-air heat exchanger 13 which makes the low-temperature heat medium absorb heat from outside air by making the low-temperature heat medium which is cooled by the heat medium cooler 14 heat-exchange with the outside air; a ventilation heat collection heat exchanger 18 which makes the low-temperature heat medium absorb heat from inside air by making the low-temperature heat medium which is cooled by the heat medium cooler 14 heat-exchange with the inside air; endothermic amount adjusting means 21, 22 and 30 which adjust an endothermic amount of the low-temperature heat medium in the heat medium outside-air heat exchanger 13; and control means 70 which controls operations of the endothermic amount adjusting means 21, 22 and 30 so that the endothermic amount of the low-temperature heat medium in the heat medium outside-air heat exchanger 13 is increased and decreased according to an increase and a decrease of the endothermic amount of the low-temperature heat medium in the ventilation heat collection heat exchanger 18.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a heat management system used in a vehicle.

  Conventionally, Patent Document 1 describes a vehicle air conditioner including a ventilation heat recovery evaporator that exchanges heat between air exhausted from the passenger compartment to the outside of the passenger compartment for ventilation and a refrigerant in the refrigeration cycle. ing.

  In this prior art, an outdoor heat exchanger that exchanges heat between air outside the passenger compartment and the refrigerant is provided, and switching between the outdoor heat absorption heating operation and the exhaust heat absorption heating operation can be performed. In the outdoor air heat absorption heating operation, the heat of the air outside the vehicle compartment is absorbed by the refrigerant by the outdoor heat exchanger. In the exhaust heat absorption heating operation, the heat of the exhaust air is absorbed by the refrigerant by the evaporator for recovering ventilation heat.

  That is, in the exhaust heat absorption heating operation, the heat of the air discharged from the passenger compartment to the outside of the passenger compartment can be recovered by the evaporator for recovery of ventilation heat and reused for heating, so that the power required for heating can be reduced.

  On the other hand, in Patent Document 2, heat is exchanged by a ventilation heat recovery heat exchanger that exchanges heat between air discharged from the vehicle interior to the outside of the vehicle for cooling and cooling water, and a ventilation heat recovery heat exchanger. In addition, a vehicle thermal management system including a cooling water cooler that exchanges heat between the cooling water and the refrigerant of the refrigeration cycle is described.

  In this prior art, the heat of the air discharged from the passenger compartment to the outside of the passenger compartment is absorbed by the refrigerant of the refrigeration cycle through the cooling water.

JP 2012-126280 A JP 2014-201224 A

  In the prior art described in Patent Document 1, the outdoor heat absorption heating operation and the exhaust heat absorption heating operation are alternatively switched. In other words, in the prior art described in Patent Document 1, the outdoor air endothermic heating operation and the exhaust endothermic heating operation cannot be used together depending on the situation. For this reason, it is difficult to improve the heating capacity and further reduce the power consumption of heating.

  In the above prior art, when the air is cooled below the freezing point by the ventilation heat recovery heat exchanger (ventilation heat recovery evaporator), the condensed water is frozen by the ventilation heat recovery heat exchanger and frost is formed. Occur. Therefore, a method for appropriately defrosting the ventilation heat recovery heat exchanger is required.

  In view of the above points, an object of the present invention is to improve the heating capacity and further reduce the power consumption of heating by appropriately using the outdoor heat absorption heating operation and the exhaust heat absorption heating operation together.

  In view of the above points, another object of the present invention is to appropriately defrost a ventilation heat recovery heat exchanger.

In order to achieve the above object, in the invention described in claim 1,
A compressor (32) for sucking and discharging refrigerant of the refrigeration cycle (31);
A blowing means (20) for blowing air into the passenger compartment;
Air heating means (15, 17, 60) for heating the air blown by the blowing means (20) using the heat of the high-pressure side refrigerant of the refrigeration cycle (31);
A heat medium cooler (14) that cools the low-temperature heat medium by exchanging heat with the low-pressure side refrigerant of the refrigeration cycle (31);
A heat medium outside air heat exchanger (13) that exchanges heat between the low temperature heat medium cooled by the heat medium cooler (14) and the outside air and absorbs heat from the outside air to the low temperature heat medium;
A ventilation heat recovery heat exchanger (18) for exchanging heat between the low temperature heat medium cooled by the heat medium cooler (14) and the inside air and absorbing heat from the inside air to the low temperature heat medium;
Endothermic amount adjusting means (21, 22, 30) for adjusting the endothermic amount of the low temperature heat medium in the heat medium outside air heat exchanger (13);
The endothermic amount adjusting means (21, 22) so that the endothermic amount of the low temperature heat medium in the heat medium outside air heat exchanger (13) increases or decreases in accordance with the increase or decrease of the endothermic amount of the low temperature heat medium in the ventilation heat recovery heat exchanger (18). , 30) and control means (70) for controlling the operation.

  According to this, when the amount of heat absorbed from the exhaust gas is small, the amount of heat absorbed from the outside air can be increased, so that the heating capacity can be improved. On the other hand, when the amount of heat absorbed from the exhaust gas is large, the amount of heat absorbed from the outside air can be reduced, so that excessive heating capacity can be suppressed to save power.

In order to achieve the other object, in the invention according to claim 13,
A compressor (32) for sucking and discharging refrigerant of the refrigeration cycle (31);
Air heating means (15, 17, 60) for heating the air blown into the passenger compartment using the heat of the high-pressure side refrigerant of the refrigeration cycle (31);
A heat medium cooler (14) that cools the low-temperature heat medium by exchanging heat with the low-pressure side refrigerant of the refrigeration cycle (31);
A heat medium outside air heat exchanger (13) that exchanges heat between the low temperature heat medium cooled by the heat medium cooler (14) and the outside air and absorbs heat from the outside air to the low temperature heat medium;
A ventilation heat recovery heat exchanger (18) for exchanging heat between the low temperature heat medium cooled by the heat medium cooler (14) and the inside air and absorbing heat from the inside air to the low temperature heat medium;
Switching between a state in which a low-temperature heat medium flows into the ventilation heat recovery heat exchanger (18) and a state in which a high-temperature heat medium higher in temperature than the low-temperature heat medium flows in, and a ventilation heat recovery heat exchanger (18) Switching means (21, 22) for performing at least one of the adjustment of the flow rate of the low-temperature heat medium or the high-temperature heat medium flowing into
When it is determined that frost is generated in the ventilation heat recovery heat exchanger (18) in a state where the low-temperature heat medium is flowing into the ventilation heat recovery heat exchanger (18), the ventilation heat recovery heat exchanger ( Switching means (21, 22) so that at least one of switching to a state in which the high-temperature heat medium flows into 18) and reducing the flow rate of the low-temperature heat medium flowing into the ventilation heat recovery heat exchanger (18) is performed. And a control means (70) for controlling the operation.

  According to this, when frost is generated in the ventilation heat recovery heat exchanger (18), the ventilation heat recovery heat exchanger (18) can be appropriately defrosted using the heat of the high-temperature cooling water or the heat of the inside 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.

1 is an overall configuration diagram of a vehicle thermal management system in a first embodiment. It is sectional drawing of the ventilation heat recovery unit in 1st Embodiment. It is a block diagram which shows the electrical machinery control part of the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of 1st heating mode in the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of 2nd heating mode in the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of 3rd heating mode in the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of 4th heating mode in the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of 5th heating mode in the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of 6th heating mode in the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of the 7th heating mode in the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of 1st air conditioning mode in the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of a 2nd air_conditioning | cooling mode in the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of 3rd air_conditioning | cooling mode in the thermal management system for vehicles in 1st Embodiment. It is a figure which shows the cooling water flow state of the 4th air conditioning mode in the thermal management system for vehicles in 1st Embodiment. It is a flowchart which shows the control processing which the control apparatus of the thermal management system for vehicles in 1st Embodiment performs. It is a flowchart which shows the control processing which the control apparatus of the thermal management system for vehicles in 1st Embodiment performs. It is sectional drawing which shows each operation mode of the ventilation heat recovery unit in 1st Embodiment. It is sectional drawing which shows each operation mode of the ventilation heat recovery unit in 1st Embodiment. It is sectional drawing of the ventilation heat recovery unit in 2nd Embodiment. It is a flowchart which shows the control processing which the control apparatus of the thermal management system for vehicles in 2nd Embodiment performs. It is a flowchart which shows the control processing which the control apparatus of the thermal management system for vehicles in 2nd Embodiment performs. It is a flowchart which shows the control processing which the control apparatus of the thermal management system for vehicles in 2nd Embodiment performs. It is a flowchart which shows the control processing which the control apparatus of the thermal management system for vehicles in 2nd Embodiment performs. It is sectional drawing which shows each operation mode of the ventilation heat recovery unit in 2nd Embodiment. It is sectional drawing which shows each operation mode of the ventilation heat recovery unit in 2nd Embodiment. It is sectional drawing which shows each operation mode of the ventilation heat recovery unit in 2nd Embodiment. It is sectional drawing which shows each operation mode of the ventilation heat recovery unit in 2nd Embodiment. It is sectional drawing of the ventilation heat recovery unit in 3rd Embodiment. It is a flowchart which shows the control processing which the control apparatus of the thermal management system for vehicles in 3rd Embodiment performs. It is a flowchart which shows the control processing which the control apparatus of the thermal management system for vehicles in 3rd Embodiment performs. It is a flowchart which shows the control processing which the control apparatus of the thermal management system for vehicles in 3rd Embodiment performs. It is a flowchart which shows the control processing which the control apparatus of the thermal management system for vehicles in 3rd Embodiment performs. It is sectional drawing which shows each operation mode of the ventilation heat recovery unit in 3rd Embodiment. It is sectional drawing which shows each operation mode of the ventilation heat recovery unit in 3rd Embodiment. It is sectional drawing which shows each operation mode of the ventilation heat recovery unit in 3rd Embodiment. It is sectional drawing which shows each operation mode of the ventilation heat recovery unit in 3rd Embodiment. It is a whole block diagram of the thermal management system for vehicles in other embodiment.

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

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

  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. And the electric power generated with the generator and the electric power supplied from the external power supply can be stored in the battery. The battery can also store electric power (regenerative energy) regenerated by the traveling electric motor during deceleration or downhill.

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

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

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

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

  As shown in FIG. 1, the vehicle thermal management system 10 includes a low temperature side pump 11, a high temperature side pump 12, a radiator 13, a cooling water cooler 14, a cooling water heater 15, a cooler core 16, a heater core 17, and ventilation heat recovery heat. An exchanger 18, a temperature adjustment target device 19, a distribution side switching valve 21 and a collecting side switching valve 22 are provided.

  The low temperature side pump 11 and the high temperature side 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 low temperature side pump 11 and the high temperature side pump 12 are flow rate adjusting means for adjusting the flow rate of the cooling water flowing through each cooling water circulation device.

  The radiator 13, the cooling water cooler 14, the cooling water heater 15, the cooler core 16, the heater core 17, the ventilation heat recovery heat exchanger 18, and the temperature adjustment target device 19 are cooling water circulation devices through which the cooling water flows.

  The radiator 13 is an outdoor heat exchanger (heat medium outdoor air heat exchanger) that performs heat exchange (sensible heat exchange) between cooling water and vehicle exterior air (hereinafter referred to as outdoor air). By flowing cooling water having a temperature equal to or higher than the outside air temperature to the radiator 13, heat can be radiated from the cooling water to the outside air. By flowing cooling water below the outside air temperature through the radiator 13, it is possible to absorb heat from the outside air to the cooling water. In other words, the radiator 13 can exhibit a function as a radiator that radiates heat from the cooling water to the outside air and a function as a heat absorber that absorbs heat from the outside air to the cooling water.

  The outside air blower 30 is an electric blower (outdoor blower) that blows outside air to the radiator 13. The outside air blower 30 is a flow rate adjusting unit that adjusts the flow rate of outside air flowing through the radiator 13.

  The radiator 13 and the outside air blower 30 are disposed in the foremost part of the vehicle. For this reason, the traveling wind can be applied to the radiator 13 when the vehicle is traveling.

  The cooling water cooler 14 (chiller) and the cooling water heater 15 (water cooling condenser) are temperature adjusting heat exchangers that adjust the temperature of the cooling water by exchanging heat of the cooling water.

  The cooling water cooler 14 is a heat exchanger (heat medium cooler) that cools the cooling water. The cooling water heater 15 is a heat exchanger (heat medium heater) that heats the cooling water.

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

  The refrigeration cycle 31 is a vapor compression refrigeration machine including a compressor 32, a cooling water heater 15, an expansion valve 33, and a cooling water cooler 14. In the refrigeration cycle 31 of the present embodiment, a chlorofluorocarbon refrigerant is used as the refrigerant, 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 32 is an electric compressor driven by electric power supplied from a battery, and sucks, compresses and discharges the refrigerant of the refrigeration cycle 31.

  The cooling water heater 15 is a condenser (high pressure side heat exchanger) that condenses (changes latent heat) the high pressure side refrigerant by exchanging heat between the high pressure side refrigerant discharged from the compressor 32 and the cooling water.

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

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

  The refrigeration cycle 31 is a cooling water cooling and heating means having a cooling water cooler 14 for cooling the cooling water and a cooling water heater 15 for heating the cooling water. In other words, the refrigeration cycle 31 is a low-temperature cooling water generating unit that generates low-temperature cooling water (low-temperature heat medium) with the cooling water cooler 14 and also generates high-temperature cooling water (high-temperature heat medium) with the cooling water heater 15. High temperature cooling water generating means.

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

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

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

  The cooler core 16 and the heater core 17 are accommodated in an indoor air conditioning unit (not shown). The indoor air conditioning unit is disposed inside the instrument panel (instrument panel) at the forefront of the vehicle interior.

  The indoor air conditioning unit has an inside / outside air blower 20 (blowing means) that introduces inside air (vehicle compartment air) and outside air (vehicle compartment outside air) and blows air. The inside / outside air blowing unit 20 includes an inside / outside air switching box that switches between the inside air and the outside air, and an indoor fan that blows the inside air and outside air introduced by the inside / outside air switching box toward the cooler core 16 and the heater core 17. Yes. The indoor blower is an electric blower that drives a centrifugal multiblade fan (sirocco fan) with an electric motor.

  The indoor air conditioning unit has a plurality of outlets that blow out the conditioned air heat-exchanged by the cooler core 16 and the heater core 17 toward a plurality of regions in the vehicle interior.

  The ventilation heat recovery heat exchanger 18 is a heat exchanger that recovers heat (cold heat or warm heat) discarded during ventilation. Specifically, the ventilation heat recovery heat exchanger 18 is an air cooling water heat exchanger that exchanges heat between air discharged from the passenger compartment to the outside of the passenger compartment for ventilation and cooling water. The ventilation heat recovery heat exchanger 18 recovers the heat that is thrown away during ventilation, thereby reducing the power required for air conditioning.

  The temperature adjustment target device 19 is a device whose temperature is adjusted (cooled or heated) by performing heat transfer with the cooling water. For example, the temperature adjustment target device 19 is a battery, an inverter, an electric motor for traveling, various engine devices, or the like.

  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.

  Examples of various engine devices include a turbocharger, an intercooler, an EGR cooler, a CVT warmer, and a CVT cooler.

  The turbocharger is a supercharger that supercharges engine intake air (intake). The intercooler is an intake air cooler (intake heat medium heat exchanger) that cools the supercharged intake air by exchanging heat between the supercharged intake air that has been compressed by the turbocharger and becomes high temperature and the cooling water.

  The EGR cooler is an exhaust cooling water heat exchanger (exhaust heat medium heat exchanger) that cools exhaust gas by exchanging heat between engine exhaust gas (exhaust gas) returned to the intake side of the engine and cooling water.

  CVT warmer is a lubricating oil cooling water heat exchanger (lubricating oil heat medium heat exchanger) that heats CVT oil by exchanging heat between lubricating oil (CVT oil) that lubricates CVT (continuously variable transmission) and cooling water. It is.

  The CVT cooler is a lubricating oil cooling water heat exchanger (lubricating oil heat medium heat exchanger) that heat-exchanges CVT oil and cooling water to cool the CVT oil.

  The temperature adjustment target device 19 is a heat generating device that generates heat when activated. The amount of heat generated by the temperature adjustment target device 19 changes according to the operating state. For example, the amount of heat generated by the temperature adjustment target device 19 changes in accordance with the traveling state of the vehicle, device efficiency, and the like.

  The low temperature side pump 11 is arrange | positioned in the flow path 41 for 1st pumps. A cooling water cooler 14 is disposed on the discharge side of the low temperature side pump 11 in the first pump flow path 41.

  The high temperature side pump 12 is disposed in the second pump flow path 42. A cooling water heater 15 is arranged on the discharge side of the high temperature side pump 12 in the second pump flow path 42.

  The radiator 13 is disposed in the radiator flow path 43. The cooler core 16 is disposed in the cooler core flow path 46. The heater core 17 is disposed in the heater core flow path 47.

  The ventilation heat recovery heat exchanger 18 is disposed in the ventilation heat recovery heat exchanger flow path 48. The temperature adjustment target device 19 is disposed in the temperature adjustment device flow path 49.

  1st pump flow path 41, 2nd pump flow path 42, radiator flow path 43, cooler core flow path 46, heater core flow path 47, ventilation heat recovery heat exchanger flow path 48 and temperature control apparatus flow path 49 is connected to the distribution side switching valve 21 and the collecting side switching valve 22.

  The distribution side switching valve 21 and the collecting side switching valve 22 are circulation switching means for switching the flow of cooling water (cooling water circulation state).

  The distribution-side switching valve 21 has a first inlet 21a and a second inlet 21b as cooling water inlets, and a first outlet 21c, a second outlet 21d, a third outlet 21e, a fourth outlet 21f and a cooling water outlet, It has a fifth outlet 21g.

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

  One end of a first pump flow path 41 is connected to the first inlet 21 a of the distribution side switching valve 21. In other words, the cooling water outlet side of the cooling water cooler 14 is connected to the first inlet 21 a of the distribution side switching valve 21.

  One end of a second pump flow path 42 is connected to the second inlet 21 b of the distribution side switching valve 21. In other words, the cooling water outlet side of the cooling water heater 15 is connected to the second inlet 21 b of the distribution side switching valve 21.

  One end of a radiator flow path 43 is connected to the first outlet 21 c of the distribution side switching valve 21. In other words, the cooling water inlet side of the radiator 13 is connected to the first outlet 21 c of the distribution side switching valve 21.

  One end of a cooler core channel 46 is connected to the second outlet 21 d of the distribution side switching valve 21. In other words, the cooling water inlet side of the cooler core 16 is connected to the second outlet 21 d of the distribution side switching valve 21.

  One end of a heater core channel 47 is connected to the third outlet 21 e of the distribution side switching valve 21. In other words, the cooling water inlet side of the heater core 17 is connected to the third outlet 21 e of the distribution side switching valve 21.

  One end of a ventilation heat recovery heat exchanger flow path 48 is connected to the fourth outlet 21 f of the distribution side switching valve 21. In other words, the cooling water inlet side of the ventilation heat recovery heat exchanger 18 is connected to the fourth outlet 21 f of the distribution side switching valve 21.

  One end of a temperature adjusting device channel 49 is connected to the fifth outlet 21 g of the distribution side switching valve 21. In other words, the cooling water inlet side of the temperature adjustment target device 19 is connected to the fifth outlet 21 g of the distribution side switching valve 21.

  The other end of the first pump flow path 41 is connected to the first outlet 22 a of the collecting side switching valve 22. In other words, the cooling water suction side of the low temperature side pump 11 is connected to the first outlet 22 a of the collecting side switching valve 22.

  The other end of the second pump flow path 42 is connected to the second outlet 22 b of the collecting side switching valve 22. In other words, the coolant outlet side of the high temperature side pump 12 is connected to the second outlet 22 b of the collecting side switching valve 22.

  The other end of the radiator flow path 43 is connected to the first inlet 22 c of the collecting side switching valve 22. In other words, the coolant outlet side of the radiator 13 is connected to the first inlet 22 c of the collecting side switching valve 22.

  The other end of the cooler core channel 46 is connected to the second inlet 22 d of the collecting side switching valve 22. In other words, the cooling water outlet side of the cooler core 16 is connected to the second inlet 22 d of the collecting side switching valve 22.

  The other end of the heater core flow path 47 is connected to the third inlet 22e of the collecting side switching valve 22. In other words, the cooling water outlet side of the heater core 17 is connected to the third inlet 22 e of the collecting side switching valve 22.

  The other end of the ventilation heat recovery heat exchanger flow path 48 is connected to the fourth inlet 22 f of the collecting side switching valve 22. In other words, the cooling water outlet side of the ventilation heat recovery heat exchanger 18 is connected to the fourth inlet 22 f of the collecting side switching valve 22.

  The other end of the temperature control device channel 49 is connected to the fifth inlet 22 g of the collecting side switching valve 22. In other words, the cooling water outlet side of the temperature adjustment target device 19 is connected to the fifth inlet 22 g of the collecting side switching valve 22.

  The distribution side switching valve 21 and the collecting side switching valve 22 have a structure that can arbitrarily or selectively switch the communication state between each inlet and each outlet.

  Specifically, the distribution side switching valve 21 receives the cooling water discharged from the low temperature side pump 11 for each of the radiator 13, the cooler core 16, the heater core 17, the ventilation heat recovery heat exchanger 18, and the temperature adjustment target device 19. A state where the cooling water discharged from the high temperature side pump 12 flows in, and a state where the cooling water discharged from the low temperature side pump 11 and the cooling water discharged from the high temperature side pump 12 do not flow.

  The collective side switching valve 22 includes a state in which cooling water flows out to the low temperature side pump 11 and the high temperature side pump 12 for each of the radiator 13, the cooler core 16, the heater core 17, the ventilation heat recovery heat exchanger 18 and the temperature adjustment target device 19. The state where the cooling water flows out and the state where the cooling water does not flow out to the low temperature side pump 11 and the high temperature side pump 12 are switched.

  The distribution side switching valve 21 and the collecting side switching valve 22 can adjust the valve opening. Thereby, the flow volume of the cooling water which flows through the radiator 13, the cooler core 16, the heater core 17, the ventilation heat recovery heat exchanger 18, and the temperature adjustment object apparatus 19 can be adjusted.

  That is, the distribution side switching valve 21 and the collecting side switching valve 22 are flow rates that adjust the flow rate of the cooling water for each of the radiator 13, the cooler core 16, the heater core 17, the ventilation heat recovery heat exchanger 18, and the temperature adjustment target device 19. Adjustment means.

  The distribution side switching valve 21 mixes the cooling water discharged from the low temperature side pump 11 and the cooling water discharged from the high temperature side pump 12 at an arbitrary flow rate ratio, and the radiator 13, the cooler core 16, the heater core 17, and the ventilation. It is possible to flow into the heat recovery heat exchanger 18 and the temperature adjustment target device 19.

  That is, the distribution side switching valve 21 and the collecting side switching valve 22 are cooled by the cooling water cooler 14 with respect to each of the radiator 13, the cooler core 16, the heater core 17, the ventilation heat recovery heat exchanger 18, and the temperature adjustment target device 19. The flow rate ratio adjusting means adjusts the flow rate ratio between the cooled cooling water and the cooling water heated by the cooling water heater 15.

  The distribution side switching valve 21 and the collecting side switching valve 22 may be formed integrally and share a valve drive source. The distribution side switching valve 21 and the collection side switching valve 22 may be configured by a combination of a number of valves.

  As shown in FIG. 2, the ventilation heat recovery heat exchanger 18 is accommodated in a case 51 of the ventilation heat recovery unit 50. The ventilation heat recovery unit 50 is disposed at the rear part of the vehicle interior.

  The case 51 forms an air passage through which the inside air flows, and is formed of a resin (for example, polypropylene) having a certain degree of elasticity and excellent in strength. An inlet 51a for introducing the inside air is formed at the most upstream part of the air flow of the case 51.

  In the case 51, a ventilation heat recovery blower 52 (blower) is disposed on the downstream side of the air flow of the introduction port 51a. The ventilation heat recovery blower 52 is a blower that sucks and blows in the inside air. The ventilation heat recovery blower 52 is an electric blower that drives a centrifugal multiblade fan (sirocco fan) with an electric motor.

  In the case 51, the ventilation heat recovery heat exchanger 18 is arranged on the downstream side of the air flow of the ventilation heat recovery fan 52. Inside the case 51, a ventilation heat recovery heat exchanger bypass passage 51b is formed. The ventilation heat recovery heat exchanger bypass passage 51 b is an air passage through which air blown by the ventilation heat recovery blower 52 flows around the ventilation heat recovery heat exchanger 18.

  Inside the case 51, an air path switching door 53 is arranged on the upstream side of the air flow of the ventilation heat recovery heat exchanger 18 and the ventilation heat recovery heat exchanger bypass passage 51b.

  The air path switching door 53 is an air volume ratio adjusting unit that continuously changes the air volume ratio between the air flowing into the ventilation heat recovery heat exchanger 18 and the air flowing into the ventilation heat recovery heat exchanger bypass passage 51b. The air path switching door 53 is a rotatable plate-like door, a slidable door or the like, and is driven by an electric actuator (not shown).

  A discharge port 51c for discharging the blown air to the outside of the passenger compartment is formed at the most downstream portion of the case 51 in the air flow.

  Next, the electric control part of the thermal management system 10 for vehicles is demonstrated based on FIG. The control device 70 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.

  The control target devices controlled by the control device 70 are the low temperature side pump 11, the high temperature side pump 12, the distribution side switching valve 21, the collecting side switching valve 22, the outside air blower 30, the compressor 32, the ventilation heat recovery blower 52, and the wind. An electric actuator or the like that drives the path switching door 53 is used.

  The configuration (hardware and software) for controlling the operation of various control target devices connected to the output side of the control device 70 constitutes a control unit (control means) for controlling the operation of each control target device. ing.

  The structure (hardware and software) which controls the operation | movement of the low temperature side pump 11 and the high temperature side pump 12 among the control apparatuses 70 is the pump control part 70a (pump control means). The pump control unit 70a is a flow rate control unit (flow rate control unit) that controls the flow rate of the cooling water flowing through each cooling water circulation device.

  The configuration (hardware and software) for controlling the operation of the distribution side switching valve 21 and the collecting side switching valve 22 in the control device 70 is a switching valve control unit 70b (switching valve control means). The switching control unit 70b is also a circulation switching control unit (circulation switching control means) that switches the cooling water circulation state. The switching control unit 70b is also a flow rate control unit (flow rate control unit) that adjusts the flow rate of the cooling water flowing through each cooling water circulation device.

  The structure (hardware and software) which controls the action | operation of the external air blower 30 among the control apparatuses 70 is the outdoor air blower control part 70c (outside air blower control means). The outdoor fan control unit 70c is a flow rate control unit (flow rate control unit) that controls the flow rate of the outside air flowing through the radiator 13.

  The configuration (hardware and software) for controlling the operation of the compressor 32 in the control device 70 is a compressor control unit 70d (compressor control means). The compressor control unit 70d is a refrigerant flow rate control unit (flow rate control unit) that controls the flow rate of the refrigerant discharged from the compressor 32.

  The structure (hardware and software) which controls the action | operation of the ventilation heat recovery fan 52 among the control apparatuses 70 is the heat recovery fan control part 70e (indoor fan control means). The heat recovery blower control means 70 e is an air volume control means for controlling the air volume of the air flowing through the ventilation heat recovery heat exchanger 18.

  The structure (hardware and software) which controls the operation | movement of the air path switching door 53 among the control apparatuses 70 is the air path switching control part 70f (air path switching control means). The air path switching control unit 70 f is an air volume control unit that controls the air volume of the air flowing through the ventilation heat recovery heat exchanger 18.

  Each control part 70a, 70b, 70c, 70d, 70e, 70f may be comprised separately with respect to the control apparatus 70. FIG.

  On the input side of the control device 70, an inside air temperature sensor 71, an outside air temperature sensor 73, a solar radiation sensor 74, a first water temperature sensor 75, a second water temperature sensor 76, a radiator water temperature sensor 77, cooler core temperature sensors 78A and 78B, a heater core temperature sensor. 79, detection signals of sensor groups such as the heat recovery temperature sensors 80A and 80B, the temperature control device temperature sensor 81, the suction refrigerant sensor 83, and the discharge refrigerant sensor 85 are input.

  The inside air temperature sensor 71 is detection means (inside air temperature detection means) for detecting the temperature of the inside air (vehicle compartment temperature). The room air humidity sensor 72 is detection means (room air humidity detection means) for detecting the humidity of the room air.

  The outside air temperature sensor 73 is detection means (outside air temperature detection means) that detects the temperature of the outside air (the temperature outside the passenger compartment). The solar radiation sensor 74 is detection means (solar radiation amount detection means) for detecting the amount of solar radiation in the passenger compartment.

  The first water temperature sensor 75 is detection means (first heat medium temperature detection means) for detecting the temperature of the cooling water flowing through the first pump flow path 41 (for example, the temperature of the cooling water sucked into the low temperature side pump 11). is there.

  The second water temperature sensor 76 is detection means (second heat medium temperature detection means) for detecting the temperature of the cooling water flowing through the second pump flow path 42 (for example, the temperature of the cooling water sucked into the high temperature side pump 12). is there.

  The radiator water temperature sensor 77 is detection means (equipment-side heat medium temperature detection means) that detects the temperature of the cooling water flowing through the radiator flow path 43 (for example, the temperature of the cooling water that has flowed out of the radiator 13).

  The cooler core temperature sensors 78A and 78B are detection means for detecting the temperature of the cooler core 16 (cooler core temperature detection means). The cooler core temperature sensors 78A and 78B detect the temperature of the fin thermistor 78A that detects the temperature of the heat exchange fins of the cooler core 16 and the temperature of the cooling water that flows through the cooler core flow path 46 (for example, the temperature of the cooling water that has flowed out of the cooler core 16). This is a water temperature sensor 78B.

  The heater core temperature sensor 79 is detection means (heater core temperature detection means) that detects the surface temperature of the heater core 17. The heater core temperature sensor 79 is a water temperature sensor that detects the temperature of the cooling water flowing through the heater core 17. The heater core temperature sensor 79 may be a fin thermistor that detects the temperature of the heat exchange fins of the heater core 17.

  The heat recovery temperature sensors 80A and 80B are detection means (heat recovery temperature detection means) for detecting the temperature of the ventilation heat recovery heat exchanger 18. The heat recovery temperature sensors 80A and 80B are a fin thermistor 80A that detects the temperature of the heat exchange fins of the ventilation heat recovery heat exchanger 18 and the temperature of the cooling water that flows through the ventilation heat recovery heat exchanger channel 48 (for example, ventilation heat recovery). This is a water temperature sensor 80B that detects the temperature of the cooling water that has flowed out of the heat exchanger 18.

  The temperature control device temperature sensor 81 detects a temperature of the cooling water flowing through the temperature control device channel 49 (for example, the temperature of the cooling water flowing out of the temperature adjustment target device 19) (device side heat medium temperature detection means). It is.

  The suction refrigerant sensor 83 is detection means for detecting the pressure and temperature of the refrigerant sucked into the compressor 32. The discharged refrigerant sensor 85 is detection means for detecting the pressure of the refrigerant discharged from the compressor 32.

  Operation signals from various air conditioning operation switches provided on the operation panel 89 are input to the input side of the control device 70. For example, the operation panel 89 is disposed near the instrument panel in the front part of the vehicle interior.

  Various air conditioning operation switches provided on the operation panel 89 are a defroster switch, an air conditioner switch, an auto switch, an air volume setting switch, an inside / outside air switching switch, a vehicle interior temperature setting switch, an air conditioning stop switch, and the like.

  Each switch may be a push switch in which electrical contacts are made conductive by being mechanically pressed, or may be a touch screen system that reacts by touching a predetermined area on the electrostatic panel.

  The defroster switch is a switch for setting or canceling the defroster mode. In the defroster mode, the air-conditioning air is blown out from the defroster outlet of the indoor air conditioning unit toward the inner surface of the front window glass to prevent fogging of the front window glass or to remove window fogging when the window is fogged It is.

  The air conditioner switch is a switch for switching on / off (on / off) of cooling or dehumidification. The auto switch is a switch for setting or canceling automatic control of air conditioning. The air volume setting switch is a switch for setting the air volume blown from the indoor fan of the inside / outside air blowing section 20.

  The inside / outside air changeover switch is a switch for switching between the inside air introduction mode, the outside air introduction mode, and the inside / outside air introduction mode. The inside / outside air changeover switch is an operating means for outputting, to the inside / outside air blowing unit 20, a command for setting the ratio of the inside air and the outside air introduced into the indoor air conditioning unit to a desired ratio when operated by a passenger.

  The vehicle interior temperature setting switch is target temperature setting means for setting the vehicle interior target temperature by the operation of the passenger. The air conditioning stop switch is a switch that stops air conditioning.

  The control device 70 determines the air conditioning mode based on the outside air temperature and the target blowing temperature TAO of the vehicle cabin blowing air. The target blowing temperature TAO is a value that is determined in order to quickly bring the inside air temperature Tr close to the occupant's desired target temperature Tset, and is calculated by the following formula F1.

TAO = Kset * Tset-Kr * Tr-Kam * Tam-Ks * Ts + C ... F1
In this equation, Tset is the target temperature in the vehicle interior set by the vehicle interior temperature setting switch, Tr is the internal air temperature detected by the internal air temperature sensor 71, and Tam is the external air temperature detected by the external air temperature sensor 73. Ts is the amount of solar radiation detected by the solar radiation sensor 74. Kset, Kr, Kam, Ks are control gains, and C is a correction constant.

  For example, when the target blowing temperature TAO is lower than the outside air temperature, the control device 70 determines the air conditioning mode as the cooling mode, and when the target blowing temperature TAO is higher than the outside air temperature, the control device 70 determines the air conditioning mode as the heating mode.

  The structure (hardware and software) which determines an air-conditioning mode among the control apparatuses 70 is an air-conditioning mode determination part (air-conditioning mode determination means). The air conditioning mode determination unit may be configured separately from the control device 70.

  Next, the operation in the above configuration will be described. The control device 70 controls the operation of the low temperature side pump 11, the high temperature side pump 12, the compressor 32, the distribution side switching valve 21, the collecting side switching valve 22, and the like, thereby switching to various operation modes.

  For example, the cooling water sucked and discharged by the low temperature side pump 11 is at least one of the cooling water cooler 14, the radiator 13, the cooler core 16, the heater core 17, the ventilation heat recovery heat exchanger 18, and the temperature adjustment target device 19. A low-temperature-side cooling water circuit (low-temperature-side heat medium circuit) that circulates between the two devices is formed, and the cooling water sucked and discharged by the high-temperature-side pump 12 is supplied to the cooling water heater 15, the radiator 13, and the cooler core. 16, a high temperature side cooling water circuit (high temperature side heat medium circuit) that circulates between at least one of the heater core 17, the ventilation heat recovery heat exchanger 18, and the temperature adjustment target device 19 is formed.

  For each of the radiator 13, the cooler core 16, the heater core 17, the ventilation heat recovery heat exchanger 18 and the temperature adjustment target device 19, a case where it is connected to a low temperature side cooling water circuit and a case where it is connected to a high temperature side cooling water circuit. By switching according to the situation, the radiator 13, the cooler core 16, the heater core 17, the ventilation heat recovery heat exchanger 18 and the temperature adjustment target device 19 can be adjusted to appropriate temperatures according to the situation.

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

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

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

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

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

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

  When the ventilation heat recovery heat exchanger 18 is connected to the low-temperature side cooling water circuit, the cooling water cooled by the cooling water cooler 14 flows through the ventilation heat recovery heat exchanger 18, so that the cooling water can absorb heat from the inside air. That is, since heat pump operation that pumps up the heat of ventilation can be realized, the heat can be recovered from the inside air.

  When the ventilation heat recovery heat exchanger 18 is connected to the high temperature side cooling water circuit, the cooling water heated by the cooling water heater 15 flows through the ventilation heat recovery heat exchanger 18, so that the cooling water can be cooled by the inside air. That is, cold heat can be recovered from the inside air.

  When the temperature adjustment target device 19 is connected to the low temperature side cooling water circuit, the cooling water cooled by the cooling water cooler 14 flows through the temperature adjustment target device 19, so that the temperature adjustment target device 19 can be cooled. In other words, it is possible to realize a heat pump operation that pumps up the waste heat of the temperature adjustment target device 19.

  When the temperature adjustment target device 19 is connected to the high-temperature side cooling water circuit, the cooling water heated by the cooling water heater 15 flows through the temperature adjustment target device 19, so that the temperature adjustment target device 19 can be heated (warmed up).

  In the first heating mode shown in FIG. 4, the ventilation heat recovery heat exchanger 18 and the heater core 17 are connected to the high temperature side cooling water circuit. Thereby, the ventilation heat recovered by the ventilation heat recovery heat exchanger 18 can be introduced into the heater core 17 for heating.

  In the second heating mode shown in FIG. 5, the ventilation heat recovery heat exchanger 18, the temperature adjustment target device 19, and the heater core 17 are connected to the high temperature side cooling water circuit. Thus, the ventilation heat recovered by the ventilation heat recovery heat exchanger 18 and the waste heat of the temperature adjustment target device 19 can be introduced into the heater core 17 and heated.

  In the third heating mode shown in FIG. 6, the ventilation heat recovery heat exchanger 18 and the heater core 17 are connected to the high temperature side cooling water circuit, and the temperature adjustment target device 19 is connected to the low temperature side cooling water circuit. Thereby, the ventilation heat recovered by the ventilation heat recovery heat exchanger 18 is introduced into the heater core 17, and the waste heat of the temperature adjustment target device 19 is transferred from the low temperature side cooling water circuit to the high temperature side cooling water by the heat pump operation of the refrigeration cycle 31. It can be heated by pumping into the circuit.

  In the fourth heating mode shown in FIG. 7, the ventilation heat recovery heat exchanger 18 is connected to the low temperature side cooling water circuit, and the heater core 17 is connected to the high temperature side cooling water circuit. As a result, the ventilation heat recovered by the ventilation heat recovery heat exchanger 18 can be heated by being pumped from the low-temperature side cooling water circuit to the high-temperature side cooling water circuit by the heat pump operation of the refrigeration cycle 31.

  In the fifth heating mode shown in FIG. 8, the ventilation heat recovery heat exchanger 18 and the radiator 13 are connected to the low temperature side cooling water circuit, and the heater core 17 is connected to the high temperature side cooling water circuit. Thereby, the ventilation heat recovered by the ventilation heat recovery heat exchanger 18 and the heat of the outside air are pumped from the low-temperature side cooling water circuit to the high-temperature side cooling water circuit by the heat pump operation of the refrigeration cycle 31 and can be heated.

  In the sixth heating mode shown in FIG. 9, the ventilation heat recovery heat exchanger 18 and the radiator 13 are connected to the low temperature side cooling water circuit, and the temperature adjustment target device 19 and the heater core 17 are connected to the high temperature side cooling water circuit. Thereby, the ventilation heat recovered by the ventilation heat recovery heat exchanger 18 and the heat of the outside air are pumped from the low-temperature side cooling water circuit to the high-temperature side cooling water circuit by the heat pump operation of the refrigeration cycle 31, and the temperature adjustment target device 19 Waste heat can be introduced into the heater core 17 for heating.

  In the seventh heating mode shown in FIG. 10, the ventilation heat recovery heat exchanger 18, the radiator 13, and the temperature adjustment target device 19 are connected to the low temperature side cooling water circuit, and the heater core 17 is connected to the high temperature side cooling water circuit. Thereby, the ventilation heat, the heat of the outside air collected by the ventilation heat recovery heat exchanger 18 and the waste heat of the temperature adjustment target device 19 are pumped from the low temperature side cooling water circuit to the high temperature side cooling water circuit by the heat pump operation of the refrigeration cycle 31. Can be heated.

  In the first cooling mode shown in FIG. 11, the ventilation heat recovery heat exchanger 18 is connected to the high temperature side cooling water circuit, and the cooler core 16 is connected to the low temperature side cooling water circuit. Thereby, the high-pressure side refrigerant of the refrigeration cycle 31 can be cooled and cooled by the ventilation cold heat collected by the heat recovery heat exchanger 18.

  In the second cooling mode shown in FIG. 12, the ventilation heat recovery heat exchanger 18 and the temperature adjustment target device 19 are connected to the high temperature side cooling water circuit, and the cooler core 16 is connected to the low temperature side cooling water circuit. Thereby, while cooling the high pressure side refrigerant | coolant of the refrigerating cycle 31 with the ventilation cold heat collect | recovered with the heat recovery heat exchanger 18, it can warm up the temperature adjustment object apparatus 19 with a high temperature cooling water.

  In the third cooling mode shown in FIG. 13, the ventilation heat recovery heat exchanger 18 and the cooler core 16 are connected to the low temperature side cooling water circuit. As a result, the cooling air collected by the ventilation heat recovery heat exchanger 18 can be introduced into the cooler core 16 to be cooled.

  In the fourth cooling mode shown in FIG. 14, the ventilation heat recovery heat exchanger 18, the temperature adjustment target device 19, and the cooler core 16 are connected to the low temperature side cooling water circuit. As a result, the cooling and cooling air recovered by the heat recovery heat exchanger 18 can be introduced into the cooler core 16 to be cooled, and the temperature adjustment target device 19 can be cooled with the low-temperature cooling water.

  The control device 70 switches the operation mode of the ventilation heat recovery unit 50 by executing the control processing shown in the flowcharts of FIGS. 15 and 16.

  First, in step S100 shown in FIG. 15, it is determined whether or not the heating mode is set. When it determines with it being heating mode in step S100, it progresses to step S110 and it is determined whether internal air has passed the ventilation heat recovery heat exchanger 18. FIG.

  When it determines with internal air having passed through the ventilation heat recovery heat exchanger 18 by step S110, it progresses to step S120 and it is determined whether the frost formation has generate | occur | produced in the ventilation heat recovery heat exchanger 18. FIG.

  When it determines with the frost formation having generate | occur | produced in the ventilation heat recovery heat exchanger 18 by step S120, it progresses to step S130 and switches to the warm air utilization defrost mode shown to Fig.17 (a).

  In the hot air defrosting mode, the switching valves 21 and 22 stop the water flow to the ventilation heat recovery heat exchanger 18, and the air path switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51b to ventilate heat. The recovered heat exchanger 18 is ventilated. Thereby, the ventilation heat recovery heat exchanger 18 is defrosted by the inside air (air above the freezing point).

  If it is determined in step S120 that frost is not generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S140, and it is determined whether the radiator 13 has insufficient heat dissipation capability. For example, based on the cooling water temperature difference before and after the radiator 13, it is determined whether or not the heat dissipation capability of the radiator 13 is insufficient.

  If it is determined in step S140 that the radiator 13 is not short of heat dissipation capability, the process proceeds to step S150, and the ventilation heat recovery mode shown in FIG.

  In the ventilation heat recovery mode, the switching valves 21 and 22 allow the low-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51b to recover the ventilation heat. The heat exchanger 18 is ventilated. Thereby, the ventilation heat recovery heat exchanger 18 causes the low-temperature cooling water to absorb the ventilation heat and recover the ventilation heat.

  If it is determined in step S140 that the heat dissipation capability of the radiator 13 is insufficient, the process proceeds to step S160 to switch to the heat dissipation assist mode illustrated in FIG.

  In the heat dissipation assist mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18 and the air passage switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51b to ventilate heat recovery heat. Ventilate the exchanger 18. As a result, the ventilation heat recovery heat exchanger 18 dissipates heat from the high-temperature cooling water to the air to make up for the shortage of the heat dissipation capability of the radiator 13.

  When it is determined in step S110 that the inside air has not passed through the ventilation heat recovery heat exchanger 18, the process proceeds to step S170, and it is determined whether or not frost is generated in the ventilation heat recovery heat exchanger 18.

  If it is determined in step S170 that frost is not generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S180, and the mode is switched to the outside air heating mode shown in FIG.

  In the outside air heating mode, the switching valves 21 and 22 stop the water flow to the ventilation heat recovery heat exchanger 18, and the air path switching door 53 stops the ventilation to the ventilation heat recovery heat exchanger 18. As a result, when the outside air is introduced and heated, the inside air discharged to the outside of the passenger compartment does not pass through the ventilation heat recovery heat exchanger 18, so that an increase in ventilation resistance can be avoided.

  When it determines with the frost formation having generate | occur | produced in the ventilation heat recovery heat exchanger 18 by step S170, it progresses to step S190 and switches to the warm water utilization defrost mode shown in FIG.17 (e).

  In the hot water defrosting mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 stops ventilation to the ventilation heat recovery heat exchanger 18. Thereby, the ventilation heat recovery heat exchanger 18 is defrosted by the high-temperature cooling water.

  When it determines with it not being heating mode by step S100, it progresses to step S200 shown in FIG. 16, and it is determined whether it is cooling mode.

  When it determines with it being the air_conditioning | cooling mode in step S200, it progresses to step S210 and it is determined whether internal air has passed the ventilation heat recovery heat exchanger 18. FIG.

  If it is determined in step S210 that the inside air has passed through the ventilation heat recovery heat exchanger 18, the process proceeds to step S220, and it is determined whether or not frost is generated in the ventilation heat recovery heat exchanger 18.

  If it is determined in step S220 that frost is generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S230, and the mode is switched to the hot air utilizing defrost mode shown in FIG.

  In the hot air defrosting mode, the switching valves 21 and 22 stop the water flow to the ventilation heat recovery heat exchanger 18, and the air path switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51b to ventilate heat. The recovered heat exchanger 18 is ventilated. Thereby, the ventilation heat recovery heat exchanger 18 is defrosted by the inside air (air above the freezing point).

  If it is determined in step S220 that frost is not generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S240 to switch to the heat radiation assist mode shown in FIG.

  In the heat dissipation assist mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18 and the air passage switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51b to ventilate heat recovery heat. Ventilate the exchanger 18.

  As a result, the ventilation heat recovery heat exchanger 18 dissipates heat from the high-temperature cooling water to the air to make up for the shortage of the heat dissipation capability of the radiator 13.

  When it is determined in step S210 that the inside air has not passed through the ventilation heat recovery heat exchanger 18, the process proceeds to step S250, and it is determined whether or not frost is generated in the ventilation heat recovery heat exchanger 18.

  If it is determined in step S250 that frost is not generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S260, and the outside air cooling mode shown in FIG.

  In the outside air cooling mode, the switching valves 21 and 22 stop the water flow to the ventilation heat recovery heat exchanger 18 and the air path switching door 53 stops the air flow to the ventilation heat recovery heat exchanger 18.

  As a result, when the outside air is introduced and cooled, the inside air discharged to the outside of the passenger compartment does not pass through the ventilation heat recovery heat exchanger 18, so that an increase in ventilation resistance can be avoided.

  If it is determined in step S250 that frost is generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S270, and the mode is switched to the hot-water defrosting mode illustrated in FIG.

  In the hot water defrosting mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 stops ventilation to the ventilation heat recovery heat exchanger 18. Thereby, the ventilation heat recovery heat exchanger 18 is defrosted by the high-temperature cooling water.

  Further, the control device 70 performs the following control.

  The control device 70 includes at least one of the switching valves 21 and 22 and the outside air blower 30 so that the heat absorption amount of the low-temperature cooling water in the radiator 13 increases or decreases in accordance with the increase or decrease in the heat absorption amount of the low-temperature cooling water in the ventilation heat recovery heat exchanger 18. Control one operation.

  According to this, when the amount of heat absorbed from the exhaust gas is small, the amount of heat absorbed from the outside air can be increased, so that the heating capacity can be improved. On the other hand, when the amount of heat absorbed from the exhaust gas is large, the amount of heat absorbed from the outside air can be reduced, so that excessive heating capacity can be suppressed to save power.

  The switching valves 21 and 22 and the outside air blower 30 are endothermic amount adjusting means for adjusting the endothermic amount of the low-temperature cooling water in the radiator 13.

  Specifically, the switching valves 21 and 22 adjust the heat absorption amount of the low-temperature cooling water in the radiator 13 by increasing or decreasing the flow rate of the low-temperature cooling water flowing through the radiator 13. The outside air blower 30 adjusts the amount of heat absorbed by the low-temperature cooling water in the radiator 13 by increasing or decreasing the flow rate of outside air flowing through the radiator 13.

  The control device 70 controls the operation of at least one of the switching valves 21 and 22 and the outside air blower 30 based on the detected temperature or estimated temperature of the inside air.

  When the control device 70 determines or estimates that the detected temperature or the estimated temperature of the low-temperature cooling water flowing into the radiator 13 is equal to or higher than the temperature of the outside air, the inflow of at least one of the low-temperature cooling water and the outside air to the radiator 13 is blocked. Thus, the operation of at least one of the switching valves 21 and 22 and the outside air blower 30 is controlled.

  According to this, when the temperature of the cooling water is higher than the temperature of the outside air, it can be suppressed that the cooling water radiates heat to the outside air by the radiator 13 and the heating capacity is impaired.

  In the state where the low-temperature cooling water is circulated between the ventilation heat recovery heat exchanger 18 and the radiator 13 and the cooling water cooler 14, the control device 70 sets the detected temperature or the estimated temperature of the low-temperature cooling water to the temperature of the outside air. When it is determined or estimated that the temperature is lower than the related outside air related temperature, the operation of at least one of the switching valves 21 and 22 and the outside air blower 30 is controlled so that the heat absorption amount of the low-temperature cooling water in the radiator 13 is increased. The outside air related temperature is, for example, a temperature that is 3 ° C. lower than the outside air temperature.

  According to this, when the heat recovery amount in the ventilation heat recovery heat exchanger 18 is insufficient, the heating capacity can be secured by increasing the heat absorption amount from the outside air. By performing heat recovery with the ventilation heat recovery heat exchanger 18, the temperature of the low-temperature cooling water can be increased. Therefore, it can suppress that frost formation generate | occur | produces with the radiator 13. FIG.

  The cooling water heater 15 and the heater core 17 are air heating means for heating the air blown by the indoor blower of the inside / outside air blowing unit 20 of the indoor air conditioning unit using the heat of the high-pressure side refrigerant of the refrigeration cycle 31.

  In the state in which the high-temperature cooling water is circulating between the temperature adjustment target device 19 and the ventilation heat recovery heat exchanger 18 and the cooling water heater 15, the control device 70 sets the temperature of the temperature adjustment target device 19 to a predetermined device temperature. When it is determined or estimated as above, the switching valves 21 and 22 are switched so that the low-temperature cooling water circulates between the temperature adjustment target device 19 and the ventilation heat recovery heat exchanger 18 and the cooling water cooler 14. Control the operation.

  According to this, when the temperature of the temperature adjustment object apparatus 19 rises excessively, the temperature adjustment object apparatus 19 can be cooled with the low-temperature cooling water. At this time, by interrupting the flow of the high-temperature cooling water to the temperature adjustment target device 19 and the ventilation heat recovery heat exchanger 18, the heat capacity on the high-temperature cooling water side can be reduced and the heat balance on the high-temperature cooling water side can be improved.

  The control device 70 may control the operation of the switching valves 21 and 22 so that both the temperature adjustment target device 19 and the ventilation heat recovery heat exchanger 18 are switched simultaneously, or the temperature adjustment target device 19 and the ventilation. You may control the action | operation of the switching valves 21 and 22 so that switching may be performed in order from either of the heat recovery heat exchangers 18.

  In the state in which the high-temperature cooling water is circulating between the temperature adjustment target device 19 and the ventilation heat recovery heat exchanger 18 and the cooling water heater 15, the control device 70 sets the temperature of the temperature adjustment target device 19 to a predetermined device temperature. When it is determined or estimated as above, the low-temperature cooling water circulates between the temperature adjustment target device 19 and the cooling water cooler 14 and the ventilation heat recovery heat exchanger 18 has a low temperature between the cooling water heater 15. The operation of the switching valves 21 and 22 is controlled so that the cooling water is switched to the circulating state.

  Thereby, when the temperature of the temperature adjustment object apparatus 19 rises excessively, the temperature adjustment object apparatus 19 can be cooled with the low-temperature cooling water. At this time, by interrupting the flow of the high-temperature cooling water to the ventilation heat recovery heat exchanger 18, the heat capacity on the high-temperature cooling water side can be reduced and the heat balance on the high-temperature cooling water side can be improved.

  When it is determined or estimated that the detected value or estimated value of the temperature difference between the inside air and the outside air is below a predetermined value, the control device 70 causes the ventilation heat recovery heat exchanger 18 and the radiator 13 to communicate with the cooling water cooler 14. The operation of the switching valves 21 and 22 is controlled so as to switch to a state in which the low-temperature cooling water circulates.

  According to this, when the temperature of the inside air is not sufficiently increased such as in the early stage of heating, the temperature of the inside air can be quickly raised by heating using both the ventilation heat recovery and the outside air heat absorption.

  The switching valves 21 and 22 and the ventilation heat recovery blower 52 increase or decrease the flow rate of at least one of the low temperature cooling water, the high temperature cooling water, and the inside air flowing through the ventilation heat recovery heat exchanger 18 to increase or decrease the ventilation heat recovery heat exchanger 18. It is a heat exchange capacity adjustment means for adjusting the heat exchange capacity of the.

  The controller 70 switches the switching valves 21 and 22 and the ventilation heat recovery so that the heat exchange capacity of the ventilation heat recovery heat exchanger 18 decreases when the ratio of the inside air introduced by the inside / outside air blower 20 of the indoor air conditioning unit increases. The operation of at least one of the blowers 52 is controlled.

  Thereby, during heating, when the ventilation amount decreases and the amount of heat that can be recovered by the ventilation heat recovery heat exchanger 18 decreases, the heat exchange capacity of the ventilation heat recovery heat exchanger 18 can also be decreased accordingly.

  The switching valves 21 and 22 are cooler core flow rate adjusting means for adjusting the flow rate of the low-temperature cooling water flowing through the cooler core 16.

  The controller 70 controls the operation of the switching valves 21 and 22 so that the flow rate of the low-temperature cooling water flowing through the cooler core 16 increases when the ratio of the inside air introduced by the inside / outside air blower 20 of the indoor air conditioning unit increases.

  According to this, in the case of cooling, when the ventilation amount decreases and the cooling heat amount recovered by the ventilation heat recovery heat exchanger 18 decreases, the cooling capability can be supplemented by improving the cooling capability of the cooler core 16.

  When the temperature of the low-temperature cooling water is less than a predetermined temperature in the state where the low-temperature cooling water is circulating between the ventilation heat recovery heat exchanger 18 and the radiator 13 and the cooling water cooler 14, the control device 70 The operation of the cooler core flow rate adjusting means 21, 22 is controlled so as to limit the flow rate of the low-temperature cooling water flowing through the cooler core 16, and the operation of the inside / outside air blower 20 of the indoor air conditioning unit is controlled so that the introduction ratio of the inside air is reduced. To do.

  According to this, it can suppress that frost formation generate | occur | produces in the cooler core 16 when low-temperature cooling water becomes low temperature. At this time, although the dehumidifying ability of the cooler core 16 is lowered, window fogging can be suppressed by introducing outside air.

  The switching valves 21 and 22 are cooling water flow rate adjusting means (heat medium flow rate adjusting means) for adjusting the flow rate of the low-temperature cooling water flowing through the ventilation heat recovery heat exchanger 18.

  When it is determined that frost is generated in the ventilation heat recovery heat exchanger 18, the control device 70 switches the switching valves 21 and 22 so that the flow rate of the low-temperature cooling water flowing through the ventilation heat recovery heat exchanger 18 decreases. And the operation of at least one of the switching valves 21 and 22 and the outside air blower 30 are controlled so that the heat absorption amount of the low-temperature cooling water in the radiator 13 is increased.

  Thereby, when frost is generated in the ventilation heat recovery heat exchanger 18, the ventilation heat recovery heat exchanger 18 can be appropriately defrosted using the heat of the inside air, and heating can be continued by heat absorption from the outside air.

  When the controller 70 determines or estimates that the defrosting of the ventilation heat recovery heat exchanger 18 has been completed, the control device 70 sets the switching valves 21 and 22 so that the flow rate of the low-temperature cooling water flowing through the ventilation heat recovery heat exchanger 18 increases. While controlling the operation, the operation of at least one of the switching valves 21 and 22 and the outside air blower 30 is controlled so that the heat absorption amount of the low-temperature cooling water in the radiator 13 is reduced.

  Thereby, after defrosting of the ventilation heat recovery heat exchanger 18 is completed, heating can be saved by ventilation heat recovery.

  When it is determined that frost is generated in the ventilation heat recovery heat exchanger 18 in a state where the low-temperature cooling water is flowing into the ventilation heat recovery heat exchanger 18, the control device 70 performs the ventilation heat recovery heat exchanger. The operation of the switching valves 21 and 22 is controlled so that at least one of the switching to the state in which the high-temperature cooling water flows into 18 and the flow rate of the low-temperature cooling water flowing into the ventilation heat recovery heat exchanger 18 are reduced. .

  Thereby, when frost is generated in the ventilation heat recovery heat exchanger 18, the ventilation heat recovery heat exchanger 18 can be appropriately defrosted using at least one of the heat of the high-temperature cooling water and the heat of the inside air.

  The ventilation heat recovery blower 52 and the air path switching door 53 are air volume adjusting means for adjusting the air volume of the inside air flowing into the ventilation heat recovery heat exchanger 18.

  When it is determined that frost is generated in the ventilation heat recovery heat exchanger 18, the control device 70 switches the switching valve 21 so that the flow rate of the low-temperature cooling water flowing into the ventilation heat recovery heat exchanger 18 decreases. 22 is controlled, and at least one of the ventilation heat recovery blower 52 and the air path switching door 53 is controlled so that the amount of the internal air flowing into the ventilation heat recovery heat exchanger 18 is increased.

  According to this, the ventilation heat recovery heat exchanger 18 can be defrosted early by actively utilizing the heat of the inside air.

  The control device 70 determines that frost is generated in the ventilation heat recovery heat exchanger 18 in a state where the low-temperature cooling water is circulating between the ventilation heat recovery heat exchanger 18 and the cooling water cooler 14. Alternatively, when estimated, the operation of the switching valves 21 and 22 is controlled so that the high temperature cooling water flows into the ventilation heat recovery heat exchanger 18, and the amount of the internal air flowing into the ventilation heat recovery heat exchanger 18 is controlled. The operation of at least one of the ventilation heat recovery blower 52 and the air path switching door 53 is controlled so as to decrease.

  According to this, when frost is generated in the ventilation heat recovery heat exchanger 18, the ventilation heat recovery heat exchanger 18 can be defrosted using the heat of the high-temperature cooling water. At this time, since the air volume of the inside air flowing into the ventilation heat recovery heat exchanger 18 is reduced, the ventilation resistance by the ventilation heat recovery heat exchanger 18 can be reduced, and thus the power consumption for blowing can be reduced.

  The air path switching door 53 is an air volume ratio adjusting means for controlling the air volume ratio between the air volume of the inside air flowing through the ventilation heat recovery heat exchanger 18 and the air volume of the inside air flowing through the bypass passage 51b.

  According to this, when the ventilation heat recovery by the ventilation heat recovery heat exchanger 18 is not necessary, the ventilation resistance can be reduced by preventing the inside air from passing through the ventilation heat recovery heat exchanger 18, so that power saving of the air blow is achieved. be able to.

  The control device 70 determines that frost is generated in the ventilation heat recovery heat exchanger 18 in a state where the low-temperature cooling water is circulating between the ventilation heat recovery heat exchanger 18 and the cooling water cooler 14. Or, when estimated, the operation of the switching valves 21 and 22 is controlled so that the high-temperature cooling water is switched between the ventilation heat recovery heat exchanger 18 and the cooling water heater 15, and the ventilation heat recovery heat exchange is performed. The operation of the air path switching door 53 is controlled so that the air volume of the inside air flowing through the vessel 18 decreases and the air volume of the inside air flowing through the bypass passage 51b increases.

  According to this, when frost is generated in the ventilation heat recovery heat exchanger 18, the ventilation heat recovery heat exchanger 18 can be defrosted using the heat of the high-temperature cooling water. At this time, since the air volume of the inside air that is humidified by the ventilation heat recovery heat exchanger 18 and blown into the vehicle interior is reduced, window fogging can be suppressed.

  The control device 70 controls the pressure of the low-pressure side refrigerant, the temperature of the low-temperature cooling water, the surface temperature of the ventilation heat recovery heat exchanger 18, the air volume of the ventilation heat recovery fan 52, and the air flow rate increase rate of the ventilation heat recovery fan 52. Based on at least one of the above, it is determined whether or not frost is generated in the ventilation heat recovery heat exchanger 18. Thereby, it can be determined appropriately whether frost is generated in the ventilation heat recovery heat exchanger 18 or not.

  That is, the control device 70 controls the ventilation heat recovery fan 52 so that the amount of the internal air passing through the ventilation heat recovery heat exchanger 18 increases as the temperature of the low-temperature cooling water flowing out from the ventilation heat recovery heat exchanger 18 increases. The operation is controlled. Therefore, it is possible to appropriately determine whether or not frost is generated in the ventilation heat recovery heat exchanger 18 based on at least one of the air flow rate and the air flow rate increase rate of the ventilation heat recovery fan 52.

  The control device 70 detects the temperature difference between the inside air flowing into the ventilation heat recovery heat exchanger 18 and the inside air flowing out from the ventilation heat recovery heat exchanger 18, the high-temperature cooling water flowing into the ventilation heat recovery heat exchanger 18, and the ventilation heat recovery. Based on at least one of the temperature difference with the high-temperature cooling water flowing out from the heat exchanger 18 and the time variation of the temperature of the inside air or high-temperature cooling water flowing out from the ventilation heat recovery heat exchanger 18, the ventilation heat recovery heat It is determined whether or not the defrosting of the exchanger 18 is completed. Thereby, it can be determined appropriately whether the defrosting of the ventilation heat recovery heat exchanger 18 has been completed.

  When the amount of heat that the low-temperature cooling water absorbs from the outside air in the radiator 13 is less than a predetermined amount of heat, the control device 70 changes the heat generation amount of the temperature adjustment target device 19 so that the temperature of the air heated by the heater core 17 approaches the target temperature. Control.

  According to this, when the amount of heat absorption from the outside air is insufficient, the heating capacity can be supplemented by using the waste heat of the temperature adjustment target device 19.

  When the temperature of the high-temperature cooling water is lower than the predetermined temperature, the control device 70 switches to a state where the low-temperature cooling water circulates between the temperature adjustment target device 19 and the cooling water cooler 14, and the temperature of the high-temperature cooling water is predetermined. When the temperature is equal to or higher than the temperature, the operation of the switching valves 21 and 22 is controlled so that the temperature adjustment target device 19 is switched to a state in which the high-temperature cooling water circulates between the device 19 and the cooling water heater 15.

  According to this, when the temperature of the high-temperature cooling water is not sufficiently increased, the temperature of the high-temperature cooling water is reduced by reducing the heat capacity on the high-temperature cooling water side so that the high-temperature cooling water is not circulated through the temperature adjustment target device 19. Can be raised early.

  When the temperature of the high-temperature cooling water sufficiently increases, the heating performance can be improved by circulating the high-temperature cooling water through the temperature adjustment target device 19 and using the waste heat of the temperature adjustment target device 19 for heating.

  When the controller 70 determines or estimates that the endothermic amount of the low-temperature cooling water in the radiator 13 is larger than the endothermic amount of the low-temperature cooling water in the ventilation heat recovery heat exchanger 18, the control air flows through the ventilation heat recovery heat exchanger 18. The operation of at least one of the ventilation heat recovery blower 52 and the air volume ratio adjusting means 53 is controlled so that the air volume of the air decreases.

  According to this, when the amount of heat that can be recovered by the ventilation heat recovery heat exchanger 18 decreases, the amount of the internal air flowing through the ventilation heat recovery heat exchanger 18 can be decreased to reduce the ventilation resistance. Power consumption can be reduced.

(Second Embodiment)
In the above embodiment, the exhaust port 51c for discharging the blown air to the outside of the passenger compartment is formed in the most downstream part of the air flow of the case 51 of the ventilation heat recovery unit 50. In this embodiment, as shown in FIG. In the most downstream portion of the air flow in the case 51 of the ventilation heat recovery unit 50, a discharge port 51c for discharging the blown air to the outside of the passenger compartment and a blower outlet 51d for blowing the blown air to the passenger compartment are formed.

  In the case 51, an air outlet switching door 54 that switches between the air outlet 51c and the air outlet 51d is disposed upstream of the air outlet 51c and the air outlet 51d.

  The blowout switching door 54 is a rotatable plate-like door, a slidable door, or the like, and is driven by an electric actuator (not shown). The operation of the electric actuator that drives the blowout switching door 54 is controlled by the control device 70.

  The blowout switching door 54 switches between the inside air mode, the semi-inside air mode, and the outside air mode. In the inside air mode, the outlet switching door 54 closes the outlet 51c and opens the outlet 51d. Thereby, the air which flowed through the ventilation heat recovery unit 50 is blown out into the vehicle interior without being discharged outside the vehicle.

  In the semi-inside air mode, the outlet switching door 54 opens the outlet 51c and the outlet 51d to the same extent. Thereby, a part of the air that has flowed through the ventilation heat recovery unit 50 is discharged outside the vehicle, and the remaining air is blown out into the vehicle interior.

  In the outside air mode, the outlet switching door 54 opens the outlet 51c and closes the outlet 51d. Thereby, the air that has flowed through the ventilation heat recovery unit 50 is discharged outside the vehicle without being blown into the vehicle interior.

  The control device 70 switches the operation mode of the ventilation heat recovery unit 50 by executing the control processing shown in the flowcharts of FIGS.

  First, in step S300 shown in FIG. 20, it is determined whether or not the heating mode is set. When it determines with it being heating mode by step S300, it progresses to step S310 and it is determined whether it is inside air mode or semi inside air mode.

  If it is determined in step S310 that the inside air mode or the semi-inside air mode is selected, the process proceeds to step S320, and it is determined whether or not the inside air has passed through the ventilation heat recovery heat exchanger 18.

  When it determines with internal air having passed through the ventilation heat recovery heat exchanger 18 by step S320, it progresses to step S330 and switches to the rear heater mode shown to Fig.24 (a).

  In the rear heater mode, the switching valves 21 and 22 cause the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51 b to ventilate heat recovery heat. Ventilate the exchanger 18.

  As a result, air is heated by the ventilation heat recovery heat exchanger 18 and blown out into the passenger compartment. Therefore, the ventilation heat recovery unit 50 performs heating.

  When it is determined in step S320 that the inside air has not passed through the ventilation heat recovery heat exchanger 18, the process proceeds to step S340, and it is determined whether or not frost is generated in the ventilation heat recovery heat exchanger 18.

  If it is determined in step S340 that frost is not generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S350, and the mode is switched to the inside air (semi-inside air) heating mode shown in FIG.

  In the inside air heating mode, the switching valves 21 and 22 stop the water flow to the ventilation heat recovery heat exchanger 18 and the air path switching door 53 stops the ventilation to the ventilation heat recovery heat exchanger 18. This avoids an increase in ventilation resistance in the ventilation heat recovery heat exchanger 18 when at least the inside air is introduced for heating.

  When it determines with the frost formation having generate | occur | produced in the ventilation heat recovery heat exchanger 18 by step S340, it progresses to step S360 and switches to the warm water utilization defrost mode shown in FIG.24 (c).

  In the hot water defrosting mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 stops ventilation to the ventilation heat recovery heat exchanger 18. Thereby, the ventilation heat recovery heat exchanger 18 is defrosted by the high-temperature cooling water.

  When it is determined in step S310 that the mode is not the inside air mode or the semi-inside air mode, the process proceeds to step S370 shown in FIG. 21, and it is determined whether or not the inside air has passed through the ventilation heat recovery heat exchanger 18.

  When it determines with internal air having passed through the ventilation heat recovery heat exchanger 18 by step S370, it progresses to step S380 and it is determined whether the frost formation has generate | occur | produced in the ventilation heat recovery heat exchanger 18. FIG.

  When it determines with the frost formation having generate | occur | produced in the ventilation heat recovery heat exchanger 18 by step S380, it progresses to step S390 and switches to the warm air utilization defrost mode shown to Fig.25 (a).

  In the hot air defrosting mode, the switching valves 21 and 22 stop the water flow to the ventilation heat recovery heat exchanger 18, and the air path switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51b to ventilate heat. The recovered heat exchanger 18 is ventilated. Thereby, the ventilation heat recovery heat exchanger 18 is defrosted by the inside air (air above the freezing point).

  If it is determined in step S380 that frost is not generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S400, and it is determined whether the radiator 13 has insufficient heat dissipation capability. For example, based on the cooling water temperature difference before and after the radiator 13, it is determined whether or not the heat dissipation capability of the radiator 13 is insufficient.

  If it is determined in step S400 that the radiator 13 has no shortage of heat dissipation capability, the process proceeds to step S410 to switch to the ventilation heat recovery mode shown in FIG.

  In the ventilation heat recovery mode, the switching valves 21 and 22 allow the low-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51b to recover the ventilation heat. The heat exchanger 18 is ventilated.

  Thereby, the ventilation heat recovery heat exchanger 18 causes the low-temperature cooling water to absorb the ventilation heat and recover the ventilation heat.

  If it is determined in step S400 that the heat dissipation capability of the radiator 13 is insufficient, the process proceeds to step S420 to switch to the heat dissipation assist mode shown in FIG.

  In the heat dissipation assist mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18 and the air passage switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51b to ventilate heat recovery heat. Ventilate the exchanger 18.

  As a result, the ventilation heat recovery heat exchanger 18 dissipates heat from the high-temperature cooling water to the air to make up for the shortage of the heat dissipation capability of the radiator 13.

  When it is determined in step S370 that the inside air has not passed through the ventilation heat recovery heat exchanger 18, the process proceeds to step S430, and it is determined whether or not frost is generated in the ventilation heat recovery heat exchanger 18.

  If it is determined in step S430 that frost is not generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S440, and the mode is switched to the outside air heating mode illustrated in FIG.

  In the outside air heating mode, the switching valves 21 and 22 stop the water flow to the ventilation heat recovery heat exchanger 18, and the air path switching door 53 stops the ventilation to the ventilation heat recovery heat exchanger 18.

  As a result, when the outside air is introduced and heated, the inside air discharged to the outside of the passenger compartment does not pass through the ventilation heat recovery heat exchanger 18, so that an increase in ventilation resistance can be avoided.

  When it determines with the frosting having generate | occur | produced in the ventilation heat recovery heat exchanger 18 by step S430, it progresses to step S450 and switches to the warm water utilization defrost mode shown in FIG.25 (e).

  In the hot water defrosting mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 stops ventilation to the ventilation heat recovery heat exchanger 18. Thereby, the ventilation heat recovery heat exchanger 18 is defrosted by the high-temperature cooling water.

  When it determines with it not being heating mode by step S300, it progresses to step S460 shown in FIG. 22, and it is determined whether it is cooling mode.

  If it is determined in step S460 that the cooling mode is set, the process proceeds to step S470, where it is determined whether the mode is the inside air mode or the semi-inside air mode.

  When it is determined in step S470 that the mode is the inside air mode or the semi-inside air mode, the process proceeds to step S480, and it is determined whether or not the inside air has passed through the ventilation heat recovery heat exchanger 18.

  If it is determined in step S480 that the inside air has passed through the ventilation heat recovery heat exchanger 18, the process proceeds to step S490, and the rear cooler mode shown in FIG.

  In the rear cooler mode, the switching valves 21 and 22 allow the low-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51b to ventilate heat recovery heat. Ventilate the exchanger 18.

  Thereby, the air is cooled by the ventilation heat recovery heat exchanger 18 and blown out into the passenger compartment. Therefore, the ventilation heat recovery unit 50 performs cooling.

  If it is determined in step S480 that the inside air has not passed through the ventilation heat recovery heat exchanger 18, the process proceeds to step S500, and it is determined whether or not frost is generated in the ventilation heat recovery heat exchanger 18.

  If it is determined in step S500 that frost is not generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S510 to switch to the inside air (semi-inside air) cooling mode shown in FIG.

  In the inside air (semi-inside air) cooling mode mode, the switching valves 21 and 22 stop the water flow to the ventilation heat recovery heat exchanger 18 and the air passage switching door 53 stops the ventilation to the ventilation heat recovery heat exchanger 18. Let

  As a result, at least when the inside air is introduced and cooled, the inside air does not pass through the ventilation heat recovery heat exchanger 18, so that an increase in ventilation resistance can be avoided.

  When it determines with the frosting having generate | occur | produced in the ventilation heat recovery heat exchanger 18 by step S500, it progresses to step S520 and switches to the warm water utilization defrost mode shown in FIG.26 (c).

  In the hot water defrosting mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 stops ventilation to the ventilation heat recovery heat exchanger 18. Thereby, the ventilation heat recovery heat exchanger 18 is defrosted by the high-temperature cooling water.

  If it is determined in step S470 that the mode is not the inside air mode or the semi-inside air mode, the process proceeds to step S530 shown in FIG. 23 to determine whether or not the inside air has passed through the ventilation heat recovery heat exchanger 18.

  When it determines with internal air having passed through the ventilation heat recovery heat exchanger 18 by step S530, it progresses to step S540 and switches to the radiation assistance mode shown to Fig.27 (a).

  In the heat dissipation assist mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18 and the air passage switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51b to ventilate heat recovery heat. Ventilate the exchanger 18.

  As a result, the ventilation heat recovery heat exchanger 18 dissipates heat from the high-temperature cooling water to the air to make up for the shortage of the heat dissipation capability of the radiator 13.

  If it is determined in step S530 that the inside air has not passed through the ventilation heat recovery heat exchanger 18, the process proceeds to step S550, and it is determined whether or not frost is generated in the ventilation heat recovery heat exchanger 18.

  If it is determined in step S550 that frost is not generated in the ventilation heat recovery heat exchanger 18, the process proceeds to step S560 to switch to the outside air cooling mode shown in FIG.

  In the outside air cooling mode, the switching valves 21 and 22 stop the water flow to the ventilation heat recovery heat exchanger 18 and the air path switching door 53 stops the air flow to the ventilation heat recovery heat exchanger 18.

  As a result, when the outside air is introduced and cooled, the inside air discharged to the outside of the passenger compartment does not pass through the ventilation heat recovery heat exchanger 18, so that an increase in ventilation resistance can be avoided.

  When it determines with the frost formation having generate | occur | produced in the ventilation heat recovery heat exchanger 18 by step S550, it progresses to step S570 and switches to the warm water utilization defrost mode shown in FIG.27 (c).

  In the hot water defrosting mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 stops ventilation to the ventilation heat recovery heat exchanger 18. Thereby, the ventilation heat recovery heat exchanger 18 is defrosted by the high-temperature cooling water.

  The blowout switching door 54 in the present embodiment is a discharge blowout air volume ratio adjusting unit that adjusts a ratio between the air volume of the inside air discharged from the discharge port 51c and the air volume of the inside air blown out from the air outlet 51d.

  According to this, the inside air heat-exchanged by the ventilation heat recovery heat exchanger 18 can be recirculated into the passenger compartment and used for air conditioning.

  For example, when the low-temperature cooling water or the high-temperature cooling water flows through the ventilation heat recovery heat exchanger 18, the control device 70 determines that the amount of the internal air blown from the outlet 51d is the amount of the internal air discharged from the outlet 51c. The operation of the blowout switching door 54 is controlled so as to be more than that.

  According to this, the passenger compartment can be air-conditioned by using the inside air heat-exchanged by the ventilation heat recovery heat exchanger 18.

(Third embodiment)
In the present embodiment, as shown in FIG. 28, a battery 55 is disposed on the downstream side of the air flow of the ventilation heat recovery heat exchanger 18 and the ventilation heat recovery heat exchanger bypass passage 51b in the case 51 of the second embodiment. Has been.

  A battery bypass passage 51 e is formed inside the case 51. The ventilation heat recovery heat exchanger bypass passage 51 b is an air passage through which air blown by the ventilation heat recovery blower 52 flows around the ventilation heat recovery heat exchanger 18.

  Inside the case 51, a battery air path switching door 56 is arranged on the upstream side of the air flow of the battery 55 and the battery bypass passage 51e.

  The battery air path switching door 56 is an air volume ratio adjusting means for continuously changing the air volume ratio between the air flowing into the air passage on the battery 55 side and the air flowing into the battery bypass passage 51e. The battery air path switching door 56 is a rotatable plate-like door, a slidable door, or the like, and is driven by an electric actuator (not shown).

  The battery air path switching door 56 is a rotatable plate-like door, a slidable door, or the like, and is driven by an electric actuator (not shown). The operation of the electric actuator that drives the battery air path switching door 56 is controlled by the control device 70.

  The control device 70 switches the operation mode of the ventilation heat recovery unit 50 by executing the control processing shown in the flowcharts of FIGS.

  First, in step S600 shown in FIG. 29, it is determined whether or not the heating mode is set. When it determines with it being heating mode in step S600, it progresses to step S610 and it is determined whether it is inside air mode or semi-inside air mode.

  If it is determined in step S610 that the mode is the inside air mode or the semi-inside air mode, the process proceeds to step S620, and it is determined whether or not the inside air has passed through the ventilation heat recovery heat exchanger 18.

  If it is determined in step S620 that the inside air has passed through the ventilation heat recovery heat exchanger 18, the process proceeds to step S630, where it is determined whether the ventilation heat recovery unit 50 needs to perform heating. In other words, it is determined whether or not the heating capacity of the heater core 17 is insufficient.

  If it is determined in step S630 that the ventilation heat recovery unit 50 does not need to perform heating, the process proceeds to step S640 to determine whether or not the battery 55 needs to be cooled.

  When it determines with there being no need to cool the battery 55 by step S640, it progresses to step S650 and switches to the 1st inside air heating mode shown to Fig.33 (a).

  In the first indoor air heating mode, the switching valves 21 and 22 stop the water flow to the ventilation heat recovery heat exchanger 18 and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to ventilate and switch the battery air path. The door 56 stops ventilation to the air passage on the battery 55 side.

  As a result, at least when the inside air is introduced and heated, the inside air does not pass through the battery 55 side, so that an increase in ventilation resistance can be avoided.

  If it is determined in step S640 that the battery 55 needs to be cooled, the process proceeds to step S660, and the mode is switched to the battery cooling mode shown in FIG.

  In the battery cooling mode, the switching valves 21 and 22 allow the low-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to ventilate and the battery air path switching door. 56 ventilates the air passage on the battery 55 side.

  Thereby, the battery 55 is cooled by the air cooled and dehumidified by the ventilation heat recovery heat exchanger 18, so that condensation of the battery 55 can be prevented.

  If it is determined in step S630 that the ventilation heat recovery unit 50 needs to perform heating, the process proceeds to step S670, and the rear heater mode shown in FIG.

  In the rear heater mode, the switching valves 21 and 22 cause the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 closes the ventilation heat recovery heat exchanger bypass passage 51 b to ventilate heat recovery heat. The exchanger 18 is ventilated, and the battery air path switching door 56 stops the ventilation to the air passage on the battery 55 side.

  As a result, air is heated by the ventilation heat recovery heat exchanger 18 and blown out into the passenger compartment. Therefore, the ventilation heat recovery unit 50 performs heating.

  When it determines with internal air not having passed through the ventilation heat recovery heat exchanger 18 by step S620, it progresses to step S680 and switches to the 2nd internal air heating mode shown in FIG.33 (d).

  In the second inside air heating mode, the switching valves 21 and 22 stop water flow to the ventilation heat recovery heat exchanger 18 and the battery air path switching door 56 stops air flow to the air passage on the battery 55 side.

  As a result, at least when the inside air is introduced and heated, the inside air does not pass through the battery 55 side, so that an increase in ventilation resistance can be avoided.

  When it is determined in step S610 that the mode is not the inside air mode or the semi-inside air mode, the process proceeds to step S690 shown in FIG. 30 and it is determined whether or not the inside air has passed through the ventilation heat recovery heat exchanger 18. In other words, it is determined whether or not ventilation is in progress.

  When it determines with internal air having passed through the ventilation heat recovery heat exchanger 18 by step S690, it progresses to step S700 and determines whether the water flow to the ventilation heat recovery heat exchanger 18 has stopped.

  When it determines with the water flow to the ventilation heat recovery heat exchanger 18 having stopped in step S700, it progresses to step S710 and it is determined whether it is necessary to warm up the battery 55. FIG.

  If it is determined in step S710 that the battery 55 needs to be warmed up, the process proceeds to step S720 to switch to the first battery warm-up mode shown in FIG.

  In the first battery warm-up mode, the battery air path switching door 56 ventilates the air passage on the battery 55 side. Thereby, the battery 55 is warmed up with the inside air.

  If it is determined in step S710 that the battery 55 does not need to be warmed up, the process proceeds to step S730 to switch to the first outdoor air heating mode shown in FIG.

  In the first outdoor air heating mode, the battery air path switching door 56 stops ventilation to the air passage on the battery 55 side. As a result, when the outside air is introduced and heated, the inside air does not pass through the battery 55 side, so that an increase in ventilation resistance can be avoided.

  If it is determined in step S700 that the water flow to the ventilation heat recovery heat exchanger 18 is not stopped, the process proceeds to step S740, and it is determined whether the ventilation heat needs to be recovered by the ventilation heat recovery heat exchanger 18. To do. In other words, it is determined whether or not the amount of heat absorbed from the outside air at the radiator 13 is insufficient.

  If it is determined in step S740 that the ventilation heat recovery heat exchanger 18 needs to recover the ventilation heat, the process proceeds to step S750, and it is determined whether or not the battery 55 needs to be cooled.

  If it is determined in step S750 that the battery 55 needs to be cooled, the process proceeds to step S760 to switch to the battery cooling mode shown in FIG.

  In the battery cooling mode, the switching valves 21 and 22 allow the low-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to ventilate and the battery air path switching door. 56 ventilates the air passage on the battery 55 side.

  Thereby, the battery 55 is cooled by the air cooled and dehumidified by the ventilation heat recovery heat exchanger 18, so that condensation of the battery 55 can be prevented.

  If it is determined in step S750 that it is not necessary to cool the battery 55, the process proceeds to step S770, and the mode is switched to the ventilation heat recovery mode shown in FIG.

  In the ventilation heat recovery mode, the switching valves 21 and 22 allow the low-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to ventilate and switch the battery air path. The door 56 stops ventilation to the air passage on the battery 55 side.

  Thereby, the ventilation heat recovery heat exchanger 18 causes the low-temperature cooling water to absorb the ventilation heat and recover the ventilation heat.

  If it is determined in step S740 that the ventilation heat recovery heat exchanger 18 does not need to recover the ventilation heat, the process proceeds to step S780, where it is determined whether the battery 55 needs to be warmed up.

  If it is determined in step S780 that the battery 55 needs to be warmed up, the process proceeds to step S790 to switch to the second battery warm-up mode shown in FIG.

  In the second battery warm-up mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to flow and The path switching door 56 ventilates the air passage on the battery 55 side. Thereby, the battery 55 is warmed up by the air heated by the ventilation heat recovery heat exchanger 18.

  If it is determined in step S780 that the battery 55 does not need to be warmed up, the process proceeds to step S800 to switch to the heat dissipation assist mode shown in FIG.

  In the heat radiation assist mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to ventilate and the battery air path switching door. 56 stops ventilation to the air passage on the battery 55 side.

  Thereby, the ventilation heat recovery heat exchanger 18 dissipates heat from the high-temperature cooling water to the air to supplement the heat dissipation capability of the radiator 13.

  If it is determined in step S690 that the inside air has not passed through the ventilation heat recovery heat exchanger 18, the process proceeds to step S810, where it is determined whether the battery 55 needs to be warmed up.

  If it is determined in step S810 that the battery 55 needs to be warmed up, the process proceeds to step S820 to switch to the third battery warm-up mode shown in FIG.

  In the third battery warm-up mode, the switching valves 21 and 22 stop water flow to the ventilation heat recovery heat exchanger 18 and the battery air path switching door 56 allows air to flow through the air passage on the battery 55 side. Thereby, the battery 55 is warmed up with the inside air.

  If it is determined in step S810 that the battery 55 does not need to be warmed up, the process proceeds to step S830 to switch to the second outdoor air heating mode shown in FIG.

  In the second outside air heating mode, the switching valves 21 and 22 stop water flow to the ventilation heat recovery heat exchanger 18 and the battery air path switching door 56 stops air flow to the air passage on the battery 55 side.

  As a result, when the outside air is introduced and heated, the inside air does not pass through the battery 55 side, so that an increase in ventilation resistance can be avoided.

  When it determines with it not being heating mode by step S600, it progresses to step S840 shown in FIG. 31, and it is determined whether it is cooling mode.

  If it is determined in step S840 that the cooling mode is set, the process proceeds to step S850, and it is determined whether the mode is the inside air mode or the semi-inside air mode.

  When it is determined in step S850 that the mode is the inside air mode or the semi-inside air mode, the process proceeds to step S860, and it is determined whether or not the inside air has passed through the ventilation heat recovery heat exchanger 18.

  When it determines with internal air having passed through the ventilation heat recovery heat exchanger 18 by step S860, it progresses to step S870 and it is determined whether the water flow to the ventilation heat recovery unit 50 has stopped.

  When it determines with the water flow to the ventilation heat recovery heat exchanger 18 having stopped in step S870, it progresses to step S880 and switches to the 1st inside air cooling mode shown to Fig.35 (a).

  In the first inside air cooling mode, the battery air path switching door 56 stops ventilation to the air passage on the battery 55 side. This avoids an increase in ventilation resistance in the battery 55 at least when introducing the inside air and cooling.

  If it is determined in step S870 that the water flow to the ventilation heat recovery heat exchanger 18 has not stopped, the process proceeds to step S890, where it is determined whether the battery 55 needs to be warmed up.

  If it is determined in step S890 that the battery 55 does not need to be warmed up, the process proceeds to step S900 to switch to the rear cooler mode shown in FIG.

  In the rear cooler mode, the switching valves 21 and 22 allow the low-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18 and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to ventilate and the battery air path switching door. 56 stops ventilation to the air passage on the battery 55 side.

  Thereby, the air is cooled by the ventilation heat recovery heat exchanger 18 and blown out into the passenger compartment. Therefore, the ventilation heat recovery unit 50 performs cooling.

  If it is determined in step S890 that the battery 55 needs to be warmed up, the process proceeds to step S910 to switch to the battery warm-up mode shown in FIG.

  In the battery warm-up mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18 and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to ventilate and switch the battery air path. The door 56 ventilates the air passage on the battery 55 side. Thereby, the battery 55 is warmed up by the air heated by the ventilation heat recovery heat exchanger 18.

  When it determines with internal air not having passed through the ventilation heat recovery heat exchanger 18 by step S860, it progresses to step S920 and switches to the 2nd internal air cooling mode shown in FIG.35 (d).

  In the second inside air cooling mode, the switching valves 21 and 22 stop water flow to the ventilation heat recovery heat exchanger 18, and the battery air path switching door 56 stops ventilation to the air passage on the battery 55 side. This avoids an increase in ventilation resistance in the battery 55 when at least the inside air is introduced for heating.

  When it is determined in step S850 that the mode is not the inside air mode or the semi-inside air mode, the process proceeds to step S930 shown in FIG. 32, and it is determined whether or not the inside air has passed through the ventilation heat recovery heat exchanger 18.

  When it determines with internal air having passed through the ventilation heat recovery heat exchanger 18 by step S930, it progresses to step S940 and it is determined whether the water flow to the ventilation heat recovery unit 50 has stopped.

  When it determines with the water flow to the ventilation heat recovery heat exchanger 18 having stopped in step S940, it progresses to step S950 and it is determined whether the battery 55 needs to be cooled.

  If it is determined in step S950 that the battery 55 needs to be cooled, the process proceeds to step S960 to switch to the first battery cooling mode shown in FIG.

  In the first battery cooling mode, the battery air path switching door 56 ventilates the air passage on the battery 55 side. Thereby, the battery 55 is cooled by inside air.

  If it is determined in step S950 that the battery 55 does not need to be warmed up, the process proceeds to step S970, and the mode is switched to the first outside air cooling mode shown in FIG.

  In the first outside air cooling mode, the battery air path switching door 56 stops ventilation to the air passage on the battery 55 side. As a result, when the outside air is introduced and cooled, the inside air does not pass through the battery 55, so that an increase in ventilation resistance can be avoided.

  When it determines with the water flow to the ventilation heat recovery heat exchanger 18 not having stopped in step S940, it progresses to step S980 and it is determined whether the battery 55 needs to be cooled.

  If it is determined in step S980 that the battery 55 needs to be cooled, the process proceeds to step S990 to switch to the second battery cooling mode shown in FIG.

  In the second battery cooling mode, the switching valves 21 and 22 allow the ventilation heat recovery heat exchanger 18 to pass the low-temperature cooling water, and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to pass through the battery air path. The switching door 56 ventilates the air passage on the battery 55 side.

  Thereby, the battery 55 is cooled by the air cooled and dehumidified by the ventilation heat recovery heat exchanger 18, so that condensation of the battery 55 can be prevented.

  If it is determined in step S980 that the battery 55 does not need to be cooled, the process proceeds to step S1000 to determine whether the battery 55 needs to be warmed up.

  If it is determined in step S1000 that the battery 55 needs to be warmed up, the process proceeds to step S1010 to switch to the battery warm-up mode shown in FIG.

  In the battery warm-up mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18 and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to ventilate and switch the battery air path. The door 56 ventilates the air passage on the battery 55 side. Thereby, the battery 55 is warmed up by the air heated by the ventilation heat recovery heat exchanger 18.

  If it is determined in step S1000 that the battery 55 does not need to be warmed up, the process proceeds to step S1020 to switch to the heat dissipation assist mode shown in FIG.

  In the heat radiation assist mode, the switching valves 21 and 22 allow the high-temperature cooling water to flow through the ventilation heat recovery heat exchanger 18, and the air path switching door 53 allows the ventilation heat recovery heat exchanger 18 to ventilate and the battery air path switching door. 56 stops ventilation to the air passage on the battery 55 side.

  Thereby, the ventilation heat recovery heat exchanger 18 dissipates heat from the high-temperature cooling water to the air to supplement the heat dissipation capability of the radiator 13.

  When it determines with internal air not having passed through the ventilation heat recovery heat exchanger 18 by step S930, it progresses to step S1030 and switches to the 3rd battery cooling mode shown in FIG.36 (f).

  In the third battery cooling mode, the switching valves 21 and 22 stop water flow to the ventilation heat recovery heat exchanger 18 and the battery air path switching door 56 allows air to flow to the air passage on the battery 55 side. Thereby, the battery 55 is warmed up with the inside air.

  In the present embodiment, the battery 55 is disposed in the case 51 on the downstream side of the inside air flow of the ventilation heat recovery heat exchanger 18. According to this, the temperature of the battery 55 can be adjusted using the inside air heat-exchanged by the ventilation heat recovery heat exchanger 18.

  The switching valves 21 and 22 are cooling water flow rate adjusting means for adjusting the flow rate of the high-temperature cooling water flowing through the ventilation heat recovery heat exchanger 18. The ventilation heat recovery blower 52 and the air path switching door 53 are air volume adjusting means for adjusting the air volume of the inside air flowing into the ventilation heat recovery heat exchanger 18.

  When the detected temperature or the estimated temperature of the battery 55 is equal to or higher than the predetermined battery temperature in a state where the high-temperature cooling water is flowing through the ventilation heat recovery heat exchanger 18, the control device 70 causes the high temperature to flow through the ventilation heat recovery heat exchanger 18. The operation of the switching valves 21 and 22 is controlled so that the flow rate of the cooling water decreases, or the ventilation heat recovery fan 52 and the air path switching door 53 so that the amount of the internal air flowing through the ventilation heat recovery heat exchanger 18 decreases. The operation of at least one of the above is controlled.

  Thereby, when the temperature of the battery 55 is high, it can suppress that the warm air heated with the ventilation heat recovery heat exchanger 18 hits the battery 55, and can improve the cooling performance of the battery 55.

  The battery air path switching door 56 is a battery air volume ratio adjusting unit that adjusts the air volume ratio between the air volume of the inside air flowing through the battery 55 and the air volume of the inside air flowing through the battery bypass passage 51e.

  Thereby, it is possible to switch between the case where the temperature of the battery 55 is adjusted using the inside air heat-exchanged by the ventilation heat recovery heat exchanger 18 and the case where the temperature is not adjusted.

  When the battery 55 needs to be cooled, the control device 70 switches the switching valves 21 and 22 so that the low-temperature cooling water is circulated between the ventilation heat recovery heat exchanger (18) and the cooling water cooler 14. And the operation of the battery air path switching door 56 is controlled so that the air volume of the inside air flowing through the battery 55 is increased.

  According to this, since the battery 55 can be cooled using the inside air cooled and dehumidified by the ventilation heat recovery heat exchanger 18, dew condensation of the cooled battery 55 can be prevented.

  At this time, if the operation of at least one of the ventilation heat recovery fan 52 and the air path switching door 53 is controlled so that the amount of the internal air flowing through the ventilation heat recovery heat exchanger 18 is increased, the cooling performance of the battery 55 is improved. it can.

  When it is necessary to warm up the battery 55, the controller 70 switches the switching valves 21 and 22 so that the high-temperature cooling water is switched between the ventilation heat recovery heat exchanger 18 and the cooling water heater 15. While controlling the operation, the operation of the battery air path switching door 56 is controlled so that the air volume of the inside air flowing through the battery 55 is increased.

  According to this, the battery 55 can be heated using the inside air heated by the ventilation heat recovery heat exchanger 18. Moreover, since the battery 55 can be heated using the inside air dehumidified by the cooler core 16, dew condensation of the heated battery 55 can be prevented.

  At this time, if the operation of at least one of the ventilation heat recovery blower 52 and the air path switching door 53 is controlled so that the amount of the internal air flowing through the ventilation heat recovery heat exchanger 18 is increased, the heating performance of the battery 55 is improved. it can.

(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 flow rate of the outside air flowing through the radiator 13 is adjusted by controlling the operation of the outside air blower 30, but the flow of the radiator 13 is controlled by controlling the operation of a radiator shutter (not shown). The flow rate of outside air may be adjusted. The radiator shutter is an outside air passage opening / closing means for opening and closing a passage through which outside air flows. Further, the flow rate of the outside air may be limited by rotating the fan of the outside air blower 30 in the reverse direction.

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

  A nanofluid may be used as the heat medium. A nanofluid is a fluid in which nanoparticles having a particle size of the order of nanometers are mixed. 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 32 is not operated by increasing the amount of cold storage heat, it is possible to control the temperature and temperature of the equipment using the cold storage heat for a certain amount of time. Motorization becomes possible.

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

  Nanoparticles containing any of Au, Ag, Cu and C can be used. Specifically, Au nanoparticle, Ag nanowire, CNT (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.

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

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

  (4) In each of the above embodiments, a low-temperature side cooling water circuit and a high-temperature side cooling water circuit are formed, but as shown in FIG. 37, the cooling water cooler 14 and the ventilation heat recovery heat exchange The low-temperature side cooling water circuit may be formed with the vessel 18, and the high-temperature side cooling water circuit may not be formed.

  In this embodiment, an indoor condenser 60 is provided instead of the cooling water heater 15 and the heater core 17 in the above embodiment. The indoor condenser 60 is a heat exchanger that condenses the high-pressure side refrigerant by heat-exchanging the high-pressure side refrigerant of the refrigeration cycle 31 and air and heats the air blown into the vehicle interior.

  The indoor condenser 60 is an air heating unit that heats the air blown into the vehicle interior using the heat of the high-pressure side refrigerant of the refrigeration cycle 31.

  (5) The cooling water heater 15 is separated into at least a region where the refrigerant has a degree of supercooling and at least a condensation region where the refrigerant has a degree of superheat. Water that has passed through the heat recovery heat exchanger 18 may be introduced. According to this, the cooling efficiency can be improved by increasing the degree of supercooling of the refrigerant.

13 Radiator (Heat medium outside air heat exchanger)
14 Cooling water cooler (heat medium cooler)
15 Cooling water heater (heat medium heater, air heating means)
16 Cooler core 17 Heater core (air heating means)
18 Ventilation heat recovery heat exchanger 20 Inside / outside air blowing section (blowing means)
21 1st switching valve (heat absorption amount adjustment means)
22 Second switching valve (heat absorption amount adjusting means)
30 Outside air blower (heat absorption amount adjusting means)
31 Refrigeration cycle 32 Compressor 70 Control device (control means)

Claims (29)

A compressor (32) for sucking and discharging refrigerant of the refrigeration cycle (31);
A blowing means (20) for blowing air into the passenger compartment;
Air heating means (15, 17, 60) for heating the air blown by the blowing means (20) using heat of the high-pressure side refrigerant of the refrigeration cycle (31);
A heat medium cooler (14) that cools the low-temperature heat medium by exchanging heat with the low-pressure side refrigerant of the refrigeration cycle (31);
A heat medium outside air heat exchanger (13) for heat-exchanging the low-temperature heat medium cooled by the heat medium cooler (14) and the outside air to absorb heat from the outside air to the low-temperature heat medium;
A ventilation heat recovery heat exchanger (18) for exchanging heat between the low temperature heat medium cooled by the heat medium cooler (14) and the inside air and absorbing heat from the inside air to the low temperature heat medium;
Endothermic amount adjusting means (21, 22, 30) for adjusting the endothermic amount of the low temperature heat medium in the heat medium outside air heat exchanger (13);
Adjusting the endothermic amount so that the endothermic amount of the low-temperature heat medium in the heat-medium outside air heat exchanger (13) increases or decreases according to the increase or decrease in the endothermic amount of the low-temperature heat medium in the ventilation heat recovery heat exchanger (18). The vehicle thermal management system comprising: control means (70) for controlling the operation of the means (21, 22, 30). The heat absorption amount adjusting means (21, 22, 30) is configured to increase or decrease the flow rate of at least one of the low temperature heat medium and the outside air flowing through the heat medium outside air heat exchanger (13), thereby increasing the heat medium outside air heat exchange. The heat absorption amount of the low-temperature heat medium in the vessel (13) is adjusted,
The vehicle heat according to claim 1, wherein the control means (70) controls the operation of the endothermic amount adjusting means (21, 22, 30) based on the detected temperature or estimated temperature of the inside air. Management system.   When the control means (70) determines or estimates that the detected temperature or the estimated temperature of the low temperature heat medium flowing into the heat medium outside air heat exchanger (13) is equal to or higher than the temperature of the outside air, the heat medium outside air The operation of the heat absorption amount adjusting means (21, 22, 30) is controlled so that at least one of the low-temperature heat medium and the outside air into the heat exchanger (13) is blocked. Item 3. The vehicle thermal management system according to Item 2.   The control means (70) is configured to circulate the low temperature heat medium between the ventilation heat recovery heat exchanger (18) and the heat medium outside air heat exchanger (13) and the heat medium cooler (14). When it is determined or estimated that the detected temperature or the estimated temperature of the low temperature heat medium is lower than the outside air related temperature related to the temperature of the outside air, the low temperature heat medium in the heat medium outside air heat exchanger (13) The vehicle thermal management system according to any one of claims 1 to 3, wherein the operation of the endothermic amount adjusting means (21, 22, 30) is controlled so that the endothermic amount increases. The air heating means includes
A heat medium heater (15) that heats a high-temperature heat medium having a temperature higher than that of the low-temperature heat medium by exchanging heat with the high-pressure refrigerant;
A heater core (17) that heats the air blown by the blowing means (20) by exchanging heat with the high-temperature heat medium;
A temperature adjustment target device (19) whose temperature is adjusted by performing heat transfer between the low-temperature heat medium or the high-temperature heat medium; and
A state in which the high-temperature heat medium circulates between the heat medium heater (15) for each of the temperature adjustment target device (19) and the ventilation heat recovery heat exchanger (18), and the heat medium Switching means (21, 22) for switching between a state in which the low-temperature heat medium circulates between the cooler (14) and
The control means (70) is in a state in which the high-temperature heat medium is circulated between the temperature adjustment target device (19), the ventilation heat recovery heat exchanger (18), and the heat medium heater (15). When the temperature adjustment target device (19) is determined or estimated to be equal to or higher than a predetermined device temperature, the temperature adjustment target device (19) and the ventilation heat recovery heat exchanger (18) 5. The operation of the switching means (21, 22) is controlled so as to switch to a state in which the low-temperature heat medium circulates between the cooler (14) and the container (14). Vehicle thermal management system. The air heating means includes
A heat medium heater (15) that heats the high-temperature heat medium by dissipating heat from the high-pressure side refrigerant to a high-temperature heat medium higher than the low-temperature heat medium;
A heater core (17) for heating the air by exchanging heat between the high-temperature heat medium and the air;
A temperature adjustment target device (19) whose temperature is adjusted by performing heat transfer between the low-temperature heat medium or the high-temperature heat medium; and
A state in which the high-temperature heat medium circulates between the heat medium heater (15) for each of the temperature adjustment target device (19) and the ventilation heat recovery heat exchanger (18), and the heat medium Switching means (21, 22) for switching between a state in which the low-temperature heat medium circulates between the cooler (14) and
The control means (70) is in a state in which the high-temperature heat medium is circulated between the temperature adjustment target device (19), the ventilation heat recovery heat exchanger (18), and the heat medium heater (15). , When it is determined or estimated that the temperature of the temperature adjustment target device (19) is equal to or higher than a predetermined device temperature, the temperature adjustment target device (19) is in contact with the heat medium cooler (14). Operation of the switching means (21, 22) so that the medium circulates and the ventilation heat recovery heat exchanger (18) switches to a state in which the low-temperature heat medium circulates between the heat medium heater (15). The vehicle thermal management system according to claim 1, wherein the vehicle thermal management system is controlled. The air heating means includes
A heat medium heater (15) that heats a high-temperature heat medium having a temperature higher than that of the low-temperature heat medium by exchanging heat with the high-pressure refrigerant;
A heater core (17) that heats the air blown by the blowing means (20) by exchanging heat with the high-temperature heat medium;
A state in which the high-temperature heat medium circulates between the heat medium heater (15) and the ventilation heat recovery heat exchanger (18) and the heat medium outside air heat exchanger (13), and Switching means (21, 22) for switching the state where the low-temperature heat medium circulates between the heat medium cooler (14),
When the control means (70) determines or estimates that the detected value or estimated value of the temperature difference between the inside air and the outside air is below a predetermined value, the ventilation heat recovery heat exchanger (18) and the heat The medium outside air heat exchanger (13) controls the operation of the switching means (21, 22) so as to switch to a state in which the low-temperature heat medium circulates between the heat medium cooler (14). The vehicle thermal management system according to any one of claims 1 to 4. Heat exchange capacity adjusting means (21, 22, 52) for adjusting the heat exchange capacity of the ventilation heat recovery heat exchanger (18),
The air blowing means (20) introduces the inside air and the outside air at an arbitrary ratio and blows air into the vehicle interior,
The control means (70) adjusts the heat exchange capacity adjustment means so that the heat exchange capacity of the ventilation heat recovery heat exchanger (18) decreases when the ratio of the inside air introduced by the blower means (20) increases. The thermal management system for a vehicle according to any one of claims 1 to 7, wherein the operation of (21, 22, 52) is controlled. A cooler core (16) for cooling the air blown by the blower means (20) by exchanging heat with the low-temperature heat medium;
Cooler core flow rate adjusting means (21, 22) for adjusting the flow rate of the low-temperature heat medium flowing through the cooler core (16),
The air blowing means (20) introduces the inside air and the outside air at an arbitrary ratio and blows air into the vehicle interior,
The control means (70) is configured to adjust the cooler core flow rate adjusting means (21) so that the flow rate of the low-temperature heat medium flowing through the cooler core (16) increases when the ratio of the inside air introduced by the blower means (20) increases. The thermal management system for a vehicle according to any one of claims 1 to 7, characterized in that the operation of (22) is controlled. A cooler core (16) for cooling the air blown by the blower means (20) by exchanging heat with the low-temperature heat medium;
Cooler core flow rate adjusting means (21, 22) for adjusting the flow rate of the low-temperature heat medium flowing through the cooler core (16),
The air blowing means (20) introduces the inside air and the outside air at an arbitrary ratio and blows air into the vehicle interior,
The control means (70) is configured to circulate the low temperature heat medium between the ventilation heat recovery heat exchanger (18) and the heat medium outside air heat exchanger (13) and the heat medium cooler (14). When the temperature of the low-temperature heat medium becomes lower than a predetermined temperature, the operation of the cooler core flow rate adjusting means (21, 22) is limited so as to limit the flow rate of the low-temperature heat medium flowing through the cooler core (16). The vehicle thermal management system according to any one of claims 1 to 8, wherein the operation of the blower means (20) is controlled so as to reduce the introduction ratio of the inside air. Heat medium flow rate adjusting means (21, 22) for adjusting the flow rate of the low temperature heat medium flowing through the ventilation heat recovery heat exchanger (18),
When it is determined that frost is generated in the ventilation heat recovery heat exchanger (18), the control means (70) has a flow rate of the low-temperature heat medium flowing through the ventilation heat recovery heat exchanger (18). Control of the heat medium flow rate adjusting means (21, 22) such that the heat absorption amount of the low temperature heat medium in the heat medium outside air heat exchanger (13) is increased. 11. The vehicle thermal management system according to claim 1, wherein the operation of the means (21, 22, 30) is controlled.   When the control means (70) determines or estimates that the defrosting of the ventilation heat recovery heat exchanger (18) is completed, the flow rate of the low-temperature heat medium flowing through the ventilation heat recovery heat exchanger (18) is The operation of the heat medium flow rate adjusting means (21, 22) is controlled so as to increase, and the heat absorption amount adjusting means so that the heat absorption amount of the low temperature heat medium in the heat medium outside air heat exchanger (13) is decreased. The vehicle thermal management system according to claim 11, wherein the operation of (21, 22, 30) is controlled. A compressor (32) for sucking and discharging refrigerant of the refrigeration cycle (31);
Air heating means (15, 17, 60) for heating the air blown into the passenger compartment using the heat of the high-pressure side refrigerant of the refrigeration cycle (31);
A heat medium cooler (14) that cools the low-temperature heat medium by exchanging heat with the low-pressure side refrigerant of the refrigeration cycle (31);
A heat medium outside air heat exchanger (13) for heat-exchanging the low-temperature heat medium cooled by the heat medium cooler (14) and the outside air to absorb heat from the outside air to the low-temperature heat medium;
A ventilation heat recovery heat exchanger (18) for exchanging heat between the low temperature heat medium cooled by the heat medium cooler (14) and the inside air and absorbing heat from the inside air to the low temperature heat medium;
Switching between the state in which the low-temperature heat medium flows into the ventilation heat recovery heat exchanger (18) and the state in which a high-temperature heat medium higher in temperature than the low-temperature heat medium flows in, and the ventilation heat recovery heat exchanger Switching means (21, 22) for performing at least one of the adjustment of the flow rate of the low-temperature heat medium flowing into (18);
When it is determined that frost is generated in the ventilation heat recovery heat exchanger (18) in a state where the low-temperature heat medium is flowing into the ventilation heat recovery heat exchanger (18), the ventilation heat recovery is performed. At least one of the switching to the state in which the high temperature heat medium flows into the heat exchanger (18) and the flow rate of the low temperature heat medium flowing into the ventilation heat recovery heat exchanger (18) are performed. The vehicle thermal management system comprising: a control means (70) for controlling the operation of the switching means (21, 22). An air volume adjusting means (52, 53) for adjusting the air volume of the inside air flowing into the ventilation heat recovery heat exchanger (18);
When it is determined that frost is generated in the ventilation heat recovery heat exchanger (18), the control means (70) controls the low temperature heat medium flowing into the ventilation heat recovery heat exchanger (18). The operation of the switching means (21, 22) is controlled so as to reduce the flow rate, and the air volume adjusting means (52, 22) so that the air volume of the inside air flowing into the ventilation heat recovery heat exchanger (18) is increased. 53. The vehicle thermal management system according to claim 13, wherein the operation of 53) is controlled. An air volume adjusting means (52, 53) for adjusting the air volume of the inside air flowing into the ventilation heat recovery heat exchanger (18);
In the state where the low-temperature heat medium circulates between the ventilation heat recovery heat exchanger (18) and the heat medium cooler (14), the control means (70) is configured to extract the ventilation heat recovery heat exchanger. When it is determined or estimated that frost is generated in (18), the switching means (21, 22) is switched so that the high-temperature heat medium flows into the ventilation heat recovery heat exchanger (18). The operation of the air volume adjusting means (52, 53) is controlled so that the air volume of the inside air flowing into the ventilation heat recovery heat exchanger (18) is reduced while controlling the operation. The vehicle thermal management system described in 1. An inlet (51a) for accommodating the ventilation heat recovery heat exchanger (18) and introducing the inside air; a bypass passage (51b) through which the inside air flows bypassing the ventilation heat recovery heat exchanger (18); A vent (51c) for exhausting the inside air that has passed through at least one of the ventilation heat recovery heat exchanger (18) and the bypass passage (51b) to the outside of the passenger compartment, and the ventilation heat recovery heat exchanger (18) And a case (51) that forms an outlet (51d) that blows out the inside air that has passed through at least one of the bypass passages (51b) into the vehicle interior,
An air volume ratio adjusting means (53) for controlling an air volume ratio between the air volume of the inside air flowing through the ventilation heat recovery heat exchanger (18) and the air volume of the inside air flowing through the bypass passage (51b);
The switching means (21, 22) includes a state in which the low temperature heat medium circulates between the ventilation heat recovery heat exchanger (18) and the heat medium cooler (14), and the heat medium heating. Switching between the state in which the high-temperature heat medium circulates with the vessel (15),
In the state where the low-temperature heat medium circulates between the ventilation heat recovery heat exchanger (18) and the heat medium cooler (14), the control means (70) is configured to extract the ventilation heat recovery heat exchanger. When it is determined or estimated that frost is generated in (18), the high-temperature heat medium circulates between the ventilation heat recovery heat exchanger (18) and the heat medium heater (15). The operation of the switching means (21, 22) is controlled so as to be switched, the air volume of the inside air flowing through the ventilation heat recovery heat exchanger (18) is reduced, and the air volume of the inside air flowing through the bypass passage (51b). 14. The vehicle thermal management system according to claim 13, wherein the operation of the air volume ratio adjusting means (53) is controlled so as to increase the air flow rate. A ventilation heat recovery blower (52) for blowing the inside air to the ventilation heat recovery heat exchanger (18);
The control means (70)
The ventilation heat recovery blower so that the amount of the internal air passing through the ventilation heat recovery heat exchanger (18) increases as the temperature of the low-temperature heat medium flowing out from the ventilation heat recovery heat exchanger (18) increases. Controlling the operation of (52),
The pressure of the low-pressure side refrigerant, the temperature of the low-temperature heat medium, the surface temperature of the ventilation heat recovery heat exchanger (18), the air flow rate of the ventilation heat recovery fan (52), and the ventilation heat recovery fan (52 17) Whether or not frost is generated in the ventilation heat recovery heat exchanger (18) is determined based on at least one of the increase rate of the blast volume). The vehicle thermal management system according to claim 1.   The control means (70) includes a temperature difference between the inside air flowing into the ventilation heat recovery heat exchanger (18) and the inside air flowing out from the ventilation heat recovery heat exchanger (18), and the ventilation heat recovery heat exchange. Temperature difference between the high temperature heat medium flowing into the heat exchanger (18) and the high temperature heat medium flowing out from the ventilation heat recovery heat exchanger (18), and the inside air flowing out from the ventilation heat recovery heat exchanger (18) Alternatively, it is determined whether or not the defrosting of the ventilation heat recovery heat exchanger (18) is completed based on at least one of the temporal changes in the temperature of the high-temperature heat medium. The thermal management system for vehicles as described in any one of thru | or 17. A case (51) that houses the ventilation heat recovery heat exchanger (18) and forms a passage through which the inside air flows;
A battery (55) arranged in the case (51) on the downstream side of the inside air flow of the ventilation heat recovery heat exchanger (18). Vehicle thermal management system. The air heating means includes
A heat medium heater (15) that heats a high-temperature heat medium having a temperature higher than that of the low-temperature heat medium by exchanging heat with the high-pressure refrigerant;
A heater core (17) that heats the air blown by the blowing means (20) by exchanging heat with the high-temperature heat medium;
Further, a case (51) for accommodating the ventilation heat recovery heat exchanger (18) and forming a passage through which the inside air flows,
A battery (55) disposed in the case (51) on the downstream side of the inside air flow of the ventilation heat recovery heat exchanger (18);
With respect to the ventilation heat recovery heat exchanger (18), the low temperature between the state where the high temperature heat medium circulates between the heat medium heater (15) and the heat medium cooler (14). Switching means (21, 22) for switching the state in which the heat medium circulates and adjusting the flow rate of the high-temperature heat medium flowing through the ventilation heat recovery heat exchanger (18);
Air volume adjusting means (52, 53) for adjusting the air volume of the inside air flowing into the ventilation heat recovery heat exchanger (18),
When the detected temperature or estimated temperature of the battery (55) is equal to or higher than a predetermined battery temperature in a state where the high-temperature heat medium is flowing in the ventilation heat recovery heat exchanger (18), the control means (70) The operation of the switching means (21, 22) is controlled so that the flow rate of the high-temperature heat medium flowing through the ventilation heat recovery heat exchanger (18) decreases, or the flow through the ventilation heat recovery heat exchanger (18). The vehicle thermal management system according to any one of claims 1 to 4, wherein the operation of the air volume adjusting means (52, 53) is controlled so that the air volume of the inside air decreases. The case (51) forms a battery bypass passage (51e) through which the inside air flows bypassing the battery (55),
A battery air volume ratio adjusting means (56) for adjusting an air volume ratio between the air volume flowing through the battery (55) and the air volume flowing through the battery bypass passage (51e) is provided. The vehicle thermal management system according to claim 19 or 20. The air heating means includes
A heat medium heater (15) that heats a high-temperature heat medium having a temperature higher than that of the low-temperature heat medium by exchanging heat with the high-pressure refrigerant;
A heater core (17) that heats the air blown by the blowing means (20) by exchanging heat with the high-temperature heat medium;
Further, a case (51) for accommodating the ventilation heat recovery heat exchanger (18) and forming a passage through which the inside air flows,
A battery (55) disposed in the case (51) on the downstream side of the inside air flow of the ventilation heat recovery heat exchanger (18),
The case (51) forms a battery bypass passage (51e) through which the inside air flows bypassing the battery (55),
A battery air volume ratio adjusting means (56) for adjusting an air volume ratio between the air volume flowing through the battery (55) and the air volume flowing through the battery bypass passage (51e);
With respect to the ventilation heat recovery heat exchanger (18), the low temperature between the state where the high temperature heat medium circulates between the heat medium heater (15) and the heat medium cooler (14). Switching means (21, 22) for switching between a state in which the heat medium circulates,
When it is necessary to cool the battery (55), the control means (70) circulates the low-temperature heat medium between the ventilation heat recovery heat exchanger (18) and the heat medium cooler (14). The operation of the switching means (21, 22) is controlled so as to switch to the state to be performed, and the operation of the battery air volume ratio adjusting means (56) is performed so that the air volume of the inside air flowing through the battery (55) increases. The vehicle thermal management system according to claim 1, wherein the vehicle thermal management system is controlled. The air heating means includes
A heat medium heater (15) that heats a high-temperature heat medium having a temperature higher than that of the low-temperature heat medium by exchanging heat with the high-pressure refrigerant;
A heater core (17) that heats the air blown by the blowing means (20) by exchanging heat with the high-temperature heat medium;
Further, a case (51) for accommodating the ventilation heat recovery heat exchanger (18) and forming a passage through which the inside air flows,
A battery (55) disposed in the case (51) on the downstream side of the inside air flow of the ventilation heat recovery heat exchanger (18),
The case (51) forms a battery bypass passage (51e) through which the inside air flows bypassing the battery (55),
A battery air volume ratio adjusting means (56) for adjusting an air volume ratio between the air volume flowing through the battery (55) and the air volume flowing through the battery bypass passage (51e);
With respect to the ventilation heat recovery heat exchanger (18), the low temperature between the state where the high temperature heat medium circulates between the heat medium heater (15) and the heat medium cooler (14). Switching means (21, 22) for switching between a state in which the heat medium circulates,
When the control means (70) needs to warm up the battery (55), the high temperature heat medium is transferred between the ventilation heat recovery heat exchanger (18) and the heat medium heater (15). The operation of the switching means (21, 22) is controlled so as to switch to a circulating state, and the operation of the battery air volume ratio adjusting means (56) so that the air volume of the inside air flowing through the battery (55) increases. The vehicle thermal management system according to claim 1, wherein the vehicle thermal management system is controlled. The air heating means (15, 17, 60)
A heat medium heater (15) for radiating heat from the high-pressure side refrigerant to the high-temperature heat medium to heat the high-temperature heat medium;
A heater core (17) for heating the air by exchanging heat between the high-temperature heat medium and the air;
The high-temperature heat medium circulates between the heat medium heater (15), and includes a heat generating device (19) whose calorific value changes according to the operating state,
When the amount of heat absorbed by the low-temperature heat medium from the outside air in the heat medium outside air heat exchanger (13) is less than a predetermined amount of heat in the heat medium outside air heat exchanger (13), the control means (70) is the temperature of the air heated by the heater core (17) The heat management system for a vehicle according to any one of claims 1 to 3, wherein the heat generation amount of the heat generating device (19) is controlled so that the temperature approaches a target temperature. The low temperature heat medium circulates between the heat medium heater (15) and the heat medium heater (15), and the high temperature heat medium circulates between the heat medium device (19) and the heat medium cooler (14). Switching means (21, 22) for switching between the states to be performed,
When the temperature of the high temperature heat medium is lower than a predetermined temperature, the control means (70) causes the low temperature heat medium to circulate between the heat generating device (19) and the heat medium cooler (14). When the temperature of the high temperature heat medium is switched to be equal to or higher than the predetermined temperature, the switching is performed so that the heat generating device (19) switches to a state in which the high temperature heat medium circulates between the heat medium heater (15). 25. The vehicle thermal management system according to claim 24, wherein the operation of the means (21, 22) is controlled. An inlet (51a) for accommodating the ventilation heat recovery heat exchanger (18) and introducing the inside air; a bypass passage (51b) through which the inside air flows bypassing the ventilation heat recovery heat exchanger (18); A case (51) that forms a discharge port (51c) for discharging the inside air that has passed through at least one of the ventilation heat recovery heat exchanger (18) and the bypass passage (51b) to the outside of the passenger compartment,
An air volume ratio adjusting means (53) for adjusting an air volume ratio between the air volume of the inside air flowing through the ventilation heat recovery heat exchanger (18) and the air volume of the inside air flowing through the bypass passage (51b) is provided. The thermal management system for vehicles according to any one of claims 1 to 13. A ventilation heat recovery blower (52) for blowing the inside air flowing through the ventilation heat recovery heat exchanger (18);
When the heat absorption amount of the low-temperature heat medium in the heat medium outside air heat exchanger (13) is larger than the heat absorption amount of the low-temperature heat medium in the ventilation heat recovery heat exchanger (18), the control means (70) If determined or estimated, at least one of the ventilation heat recovery blower (52) and the air volume ratio adjusting means (53) so as to reduce the air volume of the inside air flowing through the ventilation heat recovery heat exchanger (18). 27. The vehicle thermal management system according to claim 26, wherein the operation is controlled. The case (51) forms an outlet (51d) for blowing out the inside air into the vehicle interior,
Discharge air volume ratio adjusting means (54) for adjusting a ratio between the air volume of the inside air discharged from the discharge port (51c) and the air volume of the inside air discharged from the air outlet (51d) is provided. The vehicle thermal management system according to claim 26 or 27.   When the low-temperature heat medium or the high-temperature heat medium is flowing through the ventilation heat recovery heat exchanger (18), the control means (70) is configured such that the amount of the internal air blown out from the outlet (51d) is 29. The vehicle thermal management according to claim 28, wherein the operation of the exhaust air volume ratio adjusting means (54) is controlled so as to be larger than the air volume of the inside air discharged from the exhaust port (51c). system.

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