JP2015223063A - Cooling apparatus for power conversion device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cooling apparatus for a power conversion device, whose development is desired, capable of efficiently cooling and protecting the power conversion device.SOLUTION: The cooling apparatus includes: a cooling water channel (120) through which cooling water flows to cool a power conversion device; a coolant channel (110) which configures a refrigeration cycle for air conditioning and through which a coolant flows; and heat exchangers (80, 80B) connected to the cooling water channel and the coolant channel. The heat exchanger has such a structure that the cooling water channel contacts to the outside of the coolant channel so that heat exchange can be made between the cooling water channel and the coolant channel. Also, the heat exchanger is disposed at a place exposed in air flow which is generated by a fan for supplying wind to an evaporator (50) of the refrigeration cycle.

Description

    The present invention relates to a cooling device for a power converter.

  Hybrid cars that run using an engine and motor together, electric vehicles that run using only a motor, and fuel cell vehicles are equipped with power conversion devices such as inverters that control the battery power to a predetermined voltage. Yes.

Here, the power conversion device is a device that receives a DC voltage from, for example, a fuel cell or a battery, converts the DC voltage into an AC voltage, and supplies the AC voltage as a drive voltage.
In addition, when an energy regeneration system is mounted, for example, an AC voltage generated by a regeneration motor or the like during deceleration can be converted into a DC voltage to charge the battery.

  In the process of such power conversion, it is known that a part of electric energy is converted into heat, and the power conversion device generates heat and becomes high temperature. Therefore, it is desired to develop a cooling device for a vehicle, in particular, a cooling device that can efficiently cool a power conversion device.

  Patent Document 1 discloses a heat exchanger that cools cooling water of a power unit with an air conditioner refrigerant. According to this document, it is shown that the cooling water of the power unit can be efficiently cooled by exchanging heat between the cooling water of the power unit and the air conditioner refrigerant as compared with the case of exchanging heat with the outside air.

  In Patent Document 2, a water-cooled radiator for cooling a compressed refrigerant of a refrigeration system has a double pipe structure, a cooling water channel on the inside, a refrigerant channel on the outside, and one on the outer periphery of the outer channel pipe. What is provided with the air cooling fin of this is disclosed. According to this document, when the outside air temperature is low, it is indicated that the cooling water flow path can be stopped and the radiator can be air-cooled.

Japanese Patent Laying-Open No. 2005-012890 (paragraph 0057, FIG. 3, etc.) Japanese Unexamined Patent Publication No. 2008-051370 (paragraph 0049, FIG. 2, etc.)

  However, in the apparatus described in Patent Document 1, in order to cool the cooling water of the power unit, the air conditioner is driven each time to lower the temperature of the air conditioner refrigerant. For this reason, power consumption is required and energy-saving efficiency will fall.

  The device described in Patent Document 2 enables so-called hybrid cooling of the refrigerant of the refrigeration system by combining the air cooling method and the water cooling method and exchanging heat with the refrigerant of the refrigeration system.

  However, this is not a technique for cooling the cooling water of the power unit with an air conditioning refrigerant for vehicles. For this reason, there is no description or suggestion on how to coordinate with the vehicle air conditioner (air conditioner).

  Then, this invention makes it a subject to provide the cooling device of the power converter device which improved the cooling efficiency further.

  In order to solve the above-described problems, the present invention provides a cooling water flow path through which cooling water for cooling a power converter flows, and a refrigerant flow path through which a refrigerant flows while constituting a refrigeration cycle for air conditioning. And a heat exchanger connected to the cooling water flow path and the refrigerant flow path, and the heat exchanger includes the refrigerant flow so that the cooling water flow path and the refrigerant flow path can exchange heat. It has a structure in which the cooling water flow path is in contact with the outside of the path, and is arranged in a place where an air flow generated by a fan that supplies air to the evaporator of the refrigeration cycle hits.

  ADVANTAGE OF THE INVENTION According to this invention, the cooling device of the power converter device which improved the cooling efficiency further can be provided.

It is the schematic regarding the cooling device of the power converter device which concerns on 1st Embodiment, (a) is the case where the evaporator in the heat exchange cycle of an air conditioner and the heat exchanger in the cooling circuit of a power converter device are connected in series. FIG. (B) is sectional drawing which shows typically the internal structure of the heat exchanger in the cooling circuit of a power converter device. It is the schematic regarding the modification of the cooling device of the power converter device which concerns on 1st Embodiment, and the figure at the time of connecting the evaporator in the heat exchange cycle of an air conditioner, and the heat exchanger in the cooling circuit of a power converter device in parallel. It is. It is explanatory drawing at the time of incorporating the heat exchanger in the cooling circuit of a power converter into HVAC. It is a figure explaining the example of the operation | movement built in to HVAC (the 1). It is a figure explaining the example of the operation | movement built in to HVAC (the 2). It is a figure explaining the example of the operation | movement built in to HVAC (the 3). It is a figure explaining the example of integration operation (the 4) to HVAC. It is a figure explaining the example of the operation | movement built in to HVAC (the 5). It is a figure explaining the example of the operation | movement built in to HVAC (the 6). It is a figure explaining the operation | movement at the time of incorporating the heat exchanger in the cooling circuit of the power converter device which concerns on 1st Embodiment in the evaporator of HVAC. It is a block diagram explaining the structure of a control mechanism regarding the cooling device of the power converter device which concerns on 1st Embodiment. It is a figure explaining the control flow for cooling the cooling water for power converters about the cooling device of the power converter concerning a 1st embodiment. It is a figure explaining the operation | movement at the time of incorporating the heat exchanger in the cooling circuit of the power converter device which concerns on 2nd Embodiment in the evaporator of HVAC.

Hereinafter, the cooling device of the power converter according to the present embodiment will be described with reference to FIGS. 1 to 13.
In the following description, a case of cooling a power conversion device (hereinafter referred to as “PCU: Power Control Unit”), which is a power control unit for automobiles, will be described as an example, but the present invention is not limited to this. The present invention can also be applied to the case of cooling a PCU of equipment other than an automobile, such as an industrial machine. Similarly, the cooling object is not limited to the PCU. The present invention can be applied to any heat generating device that is desired to be cooled.

  In the following description, the case where the air conditioner is operated by cooling will be described as an example, but the present invention is not limited thereto. Each embodiment of the present invention can be similarly applied even in an environment where an air conditioner is operated by heating.

  Moreover, in each figure, the same code | symbol is attached | subjected to the same apparatus and the overlapping description shall be abbreviate | omitted.

(First embodiment)
FIG. 1 is a schematic diagram related to a cooling device for a power conversion device according to the first embodiment. FIG. 1A shows an evaporator in a heat exchange cycle of an air conditioner and a heat exchanger in a cooling circuit for the power conversion device in series. It is a figure at the time of connecting. (B) is sectional drawing which shows typically the internal structure of the heat exchanger in the cooling circuit of a power converter device.

  As shown in FIG. 1 (a), in the PCU cooling device according to the present embodiment, the PCU cooling water flow path 120 that is a PCU cooling system and the air conditioner refrigerant that is a heat exchange cycle system of a known air conditioner flow. The air conditioner refrigerant flow path 110 is configured to be combined.

  An air conditioner refrigerant flow path 110, which is a known heat exchange cycle system of an air conditioner, includes a compressor 10, a filter dryer 20, a condenser 30, an expansion valve 40, and an evaporator 50, and is configured to be connected in an annular shape in this order. The

  Here, the outside of the vehicle compartment is arranged in this order including the compressor 10, the filter dryer 20, and the condenser 30, and the inside of the vehicle compartment is arranged in this order including the expansion valve 40 and the evaporator 50.

  The compressor 10 is a compressor, and compresses the air-conditioner refrigerant flowing from the suction side and discharges it from the discharge side.

  A filter dryer 20 is disposed in the flow path on the discharge side of the compressor 10. The filter dryer 20 removes foreign matters and the like contained in the circulating air-conditioner refrigerant, and particularly protects the compressor 10 and the expansion valve 40.

  The condenser 30 is a heat exchanger provided outside the passenger compartment and is also called a condenser. The refrigerant that has been compressed by the compressor 10 to a high temperature and high pressure and the outside air that is ventilated by the blower 60 are heat-exchanged by the condenser 30, and the refrigerant is condensed to a medium temperature and high pressure.

  The expansion valve 40 is a valve that adiabatically expands by depressurizing the medium-temperature and high-pressure refrigerant. In the adiabatic expansion process, the temperature decreases. As a result, the refrigerant becomes a low-temperature and low-pressure cold refrigerant and is supplied to the evaporator 50. The expansion valve 40 is provided on the vehicle interior side.

  The evaporator 50 is a heat exchanger provided on the vehicle interior side, and is also called an evaporator. The evaporator 50 has a structure in which thin refrigerant pipes are folded several times in order to promote heat exchange.

  In the evaporator 50, heat exchange is performed between the low-temperature and low-pressure cooled refrigerant that has passed through the expansion valve 40 and the outside air or the inside air that is ventilated by the blower fan 415. Here, whether to exchange heat with the outside air or the inside air depends on whether the setting of the air conditioner by the user is set to the outside air introduction or the inside air circulation.

  At this time, the warm air sucked by the blower fan 415 absorbs the heat of the cooled refrigerant, becomes cold air, and is supplied indoors (cooling operation). Moreover, the cold refrigerant absorbs the heat of warm air, vaporizes, and evaporates.

  The vaporized high-temperature and low-pressure refrigerant is led out of the passenger compartment and supplied again to the inlet side of the compressor 10, that is, the suction side.

  Next, the PCU cooling water flow path 120 which is a PCU cooling system includes an electric water pump 90 and a PCU 100 on the outside of the vehicle interior, and a heat exchanger 80 for cooling the PCU cooling water on the vehicle interior side, and is connected in this order. .

  The PCU 100 accommodates a power conversion device such as an inverter. The PCU 100 is a heat generating device that is desired to be cooled, and is a cooling target in the present embodiment.

  The electric water pump 90 for PCU cooling water is a water pump for circulating PCU cooling water. In addition, you may use LLC (long life coolant) of the antifreeze used for the PCU cooling water in this embodiment, for example as a cooling fluid for cooling an internal combustion engine.

  As illustrated in FIG. 1B, the PCU cooling water cooling heat exchanger 80 is provided with the PCU cooling water flow channel 120 so as to be in contact with, for example, the periphery of the piping of the air conditioning refrigerant flow channel 110. That is, the air conditioner refrigerant flow path 110 and the PCU cooling water flow path 120 have a double pipe structure. Further, air cooling fins 85 are provided on the exterior of the PCU cooling water flow channel 120 on the side opposite to the air conditioner refrigerant flow channel 110.

  That is, the image of the heat exchanger 80 for cooling the PCU cooling water has, for example, a double-pipe structure in which the air conditioner refrigerant flow path 110 and the PCU cooling water flow path 120 are overlapped. It is a fin-and-tube heat exchanger processed from 85.

  In this example, the PCU cooling water cooling heat exchanger 80 is provided on the downstream side of the air flow created by the blower fan 415. More preferably, it arrange | positions so that it may become the downstream of the evaporator 50. FIG. In this case, the air sent to the evaporator 50 by the blower fan 415 becomes heat-exchanged and becomes cold air, hits the air-cooling fins 85, and cooling of the PCU cooling water cooling heat exchanger 80 is further promoted. Or you may make it equip some evaporators 50 with the heat exchanger 80 for PCU cooling water cooling so that it may mention later.

  Thus, the heat exchange efficiency between PCU cooling water and an air-conditioner refrigerant | coolant can be improved by setting it as the structure which makes the PCU cooling-water flow path 120 and the air-conditioner refrigerant | coolant flow path 110 contact | abut.

  In addition, the PCU cooling water flow path 120 is provided outside the air conditioner refrigerant flow path 110 with a double pipe structure, and an air cooling fin 85 is provided on the outer periphery of the PCU cooling water flow path 120 so as to be disposed downstream of the blower fan 415. The PCU cooling water is cooled from both sides so as to be sandwiched between the air-cooling fins 85 and the air-conditioner refrigerant flow path 110, and cold air can be captured by the air-cooling fins 85, so that the cooling efficiency can be further improved.

(Modification of heat exchanger 80 for cooling PCU cooling water)
Note that the PCU cooling water cooling heat exchanger 80 may be arranged such that the pipings of the PCU cooling water channels 120 and 120 are in contact with both sides of the piping of the air conditioning refrigerant channel 110, for example (sandwich structure). ). Further, air cooling fins 85, 85 may be provided on the exterior of the PCU cooling water passages 120, 120 on the side opposite to the air conditioner refrigerant passage 110.

  That is, the PCU cooling water flow path 120 is provided outside the air conditioner refrigerant flow path 110, and the air cooling fins 85 are provided on the outer periphery thereof, and are arranged downstream of the blower fan 415. Thus, the PCU cooling water is cooled from both sides so as to be sandwiched between the air-cooling fins 85 and the air-conditioner refrigerant flow path 110, and cold air is captured by the air-cooling fins 85. Even if comprised in this way, cooling efficiency can be improved.

  A plurality of air cooling fins 85 are usually provided. Further, the direction of the fins may be installed so as to be parallel to the longitudinal direction of the PCU cooling water cooling heat exchanger 80, or the direction orthogonal to the longitudinal direction of the PCU cooling water cooling heat exchanger 80. You may install in.

  In the present embodiment, the evaporator 50 and the PCU cooling water cooling heat exchanger 80 are connected in series.

In addition to a known air conditioner system such as an auto air conditioner, for example, a controller for controlling the water temperature of the PCU cooling water, a fin temperature sensor 270, And a PCU cooling water temperature sensor 280.
Note that control lines and communication lines are omitted as appropriate in order to avoid complications in the figure.

  In the following description, the control device for controlling the water temperature of the PCU cooling water in the present embodiment will be described as an integral component with the air conditioner ECU 300, but the present invention is not limited to this. That is, a separate control device may be provided so as to be separate from the air conditioner ECU 300.

  The air conditioner ECU 300 in the present embodiment acquires data including temperature data of the fin temperature sensor 270 and the PCU cooling water temperature sensor 280 as temperature detecting means by always sensing even while the automatic air conditioner is stopped. It is configured to be able to control opening and closing of a door (detailed later) provided in a known air conditioner system and communicating with the vehicle interior.

  The fin temperature sensor 270 is provided, for example, at the tip portion of the air cooling fin 85 provided in the most downstream position of the air-conditioner refrigerant flow path 110 in the PCU cooling water cooling heat exchanger 80.

  The fin temperature sensor 270 measures the temperature of the portion of the PCU cooling water cooling heat exchanger 80 where the temperature of the air conditioning refrigerant flow path 110 is highest.

  Further, the PCU cooling water temperature sensor 280 is installed, for example, in the vicinity of the outlet of the PCU 100 in the PCU cooling water channel 120. The PCU cooling water temperature sensor 280 is installed in a portion where the PCU cooling water absorbs the exhaust heat of the PCU 100 and has the highest temperature, and measures the water temperature of the PCU cooling water.

  Both the fin temperature sensor 270 and the PCU cooling water temperature sensor 280 may use a temperature sensor such as a thermistor. For example, regarding the fin temperature sensor 270, a temperature sensor that is brought into contact with the tip portion of the air cooling fin 85 can be used. As for the PCU cooling water temperature sensor 280, a temperature sensor that is brought into contact with the pipe surface may be used. Moreover, a temperature sensor is not limited to a thermistor, for example, You may use the apparatus which can directly measure the refrigerant gas temperature of an air-conditioner, or the cooling water temperature of PCU cooling water.

The blower 60 is for exchanging heat between the air-conditioning refrigerant flowing in the refrigerant pipe of the capacitor 30 and the air. The blower fan 415 is for exchanging heat between the air-conditioning refrigerant flowing in the refrigerant pipe of the evaporator 50 and the air (airflow).
At the same time, the blower fan 415 includes air cooling fins 85 in which the heat of the PCU cooling water flow channel 120 is conducted in the PCU cooling water cooling heat exchanger 80 placed downstream of the evaporator 50 as viewed from the air flow. This is for exchanging heat with air (airflow).

(Modification of FIG. 1A)
Next, a modification according to the present embodiment will be described with reference to FIG. In addition, in the structure similar to Fig.1 (a), the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.
FIG. 2 is a schematic diagram relating to another cooling device of the power conversion device according to the first embodiment, in which an evaporator in a heat exchange cycle of an air conditioner and a heat exchanger in a cooling circuit of a PCU are connected in parallel. FIG.

  In FIG. 1 described above, the evaporator 50 in the heat exchange cycle of the air conditioner and the PCU cooling water cooling heat exchanger 80 are connected in series. In this modification, these portions are connected so as to have a parallel positional relationship. Furthermore, the air conditioning refrigerant flow path 110 on the PCU cooling water cooling heat exchanger 80 side in parallel with the evaporator 50 is provided with a valve 45 for adjusting the flow rate.

  The valve 45 is for adjusting the flow rate of the air conditioner refrigerant flowing into the PCU cooling water cooling heat exchanger 80 side, and is, for example, an electric valve. By providing this valve, for example, the amount of flow of the air-conditioner refrigerant into the PCU cooling water cooling heat exchanger 80 side can be adjusted, for example, or fully opened. Therefore, there is a merit that it becomes easy to manage the temperature of the heat exchange in the heat exchanger 80 for cooling the PCU cooling water.

(Continued from the first embodiment)
Next, referring to FIG. 3, an example of incorporating the heat exchanger 80 for cooling the PCU cooling water according to the present embodiment (see FIGS. 1 and 2) into the HVAC constituting a known in-vehicle air conditioner system. explain.
FIG. 3 is an explanatory diagram when the PCU cooling water cooling heat exchanger 80 provided on the PCU cooling water flow path 120 is incorporated into the HVAC. Incidentally, in the example of FIG. 3, the PCU cooling water cooling heat exchanger 80 is incorporated in the evaporator 50 as an example.

  In general, a vehicle air conditioner has a surplus capacity as compared with a home air conditioner. In this embodiment, the surplus is used.

  Here, HVAC is an abbreviation for Heating, Ventilation, and Air Conditioning. Here, an outline of a general HVAC will be described. First, by switching the rotation angle θ1 of the ventilation switching door 425 by the ventilation switching door motor 420, it is determined whether to introduce outside air or take in inside air.

  Next, by operating the blower fan motor 410, the blower fan 415 rotates, and the inside air or the outside air is sucked and discharged toward the evaporator 50.

Next, in the evaporator 50, the air-conditioner refrigerant and air are heat-exchanged to become cold air. Thereafter, the rotation angle θ3 of the air mix door 445 is adjusted by the air mix door motor 440 so as to reach the set temperature, and a part of the cool air is taken into the heater core 130.
Hereinafter, for convenience of explanation, a flow path from the blower fan 415 to the air mix door 445 is referred to as a first flow path.

  In the heater core 130, for example, an automobile having an internal combustion engine guides the combustion heat of the internal combustion engine, and in the case of an electric automobile, a heat source is supplied by an appropriate method such as providing an electric heater or the like. Therefore, the taken-in cold air is heated by exchanging heat with the heat source of the heater core 130.

  The cool air that has passed through the evaporator 50 is mixed with the warm air that has passed through the heater core 130, adjusted to a desired temperature, and supplied to the vehicle interior via appropriate ducts such as the defroster duct 457, the face duct 467, and the foot duct 477. .

  At this time, for example, when venting to the defroster duct 457, the rotation angle θ4 may be adjusted so that the defroster door motor 450 is operated and the defroster door 455 is opened.

  Further, for example, when ventilation is performed to the face duct 467, the rotation angle θ5 may be adjusted so that the face door motor 460 is operated and the face door 465 is opened.

  For example, when ventilating to the foot duct 477, the foot door motor 470 may be operated to adjust the rotation angle θ6 so as to open the foot door 475.

  Hereinafter, for convenience of explanation, the flow path from the air mix door 445 to the defroster door 455 or the air mix door 445 to the face door 465 is the second flow path, and the flow path from the heater core 130 to the foot door 475 is the third flow path. Call it.

  In such a known HVAC, in this embodiment, the PCU cooling water cooling heat exchanger 80 in FIGS. 1 and 2 is incorporated into, for example, the evaporator 50, and both devices are integrated. .

  However, this is only an example, and the heat exchanger 80 for cooling the PCU cooling water is arranged separately in the vicinity of the downstream side of the evaporator 50 when viewed from the air flow by the blower fan 415, for example. You can also.

  When the heat exchanger 80 for cooling the PCU cooling water is incorporated in the evaporator 50 and both the devices are integrated, the space for installing the heat exchanger 80 for cooling the PCU cooling water is omitted, and the entire device is reduced in size. Can be

  At this time, the installation position of the heat exchanger 80 for cooling the PCU cooling water into the evaporator 50 is located as far as possible from the PCU 100, that is, at the uppermost part (on the paper surface) of the evaporator 50 and closer to the downstream as viewed from the air flow. It is desirable to set the position (right side of the page).

  This is because if the uppermost position (on the paper surface) of the evaporator 50 is set, the distance until the PCU cooling water passes through the evaporator 50 and reaches the heat exchanger 80 for cooling the PCU cooling water is increased. This is because the cooling is further promoted by the heat exchange of the PCU cooling water with the cold air generated by the evaporator 50 to dissipate heat.

  In addition, when the PCU cooling water cooling heat exchanger 80 is installed at the uppermost part (on the paper surface) of the evaporator 50 and closer to the downstream side (right side of the paper surface), it is in the immediate vicinity of the heat exchanger 80 for cooling the PCU cooling water. In addition, by providing a forced exhaust duct 437 communicating with the outside air at a position downstream from the air flow, the air that has passed through the heat exchanger 80 for cooling the PCU cooling water is forcibly and efficiently exhausted to the outside air. To be able to.

  At this time, for example, the forced exhaust door motor 430 may be operated to adjust the rotation angle θ2 so that the forced exhaust door 435 is opened.

  Compared with the case where the heat exchanger 80 for cooling the PCU cooling water is incorporated at the uppermost part of the evaporator 50 (on the paper surface) and upstream of the air flow, that is, the air flow (left of the paper surface), If it is incorporated in the position on the right side of the drawing, the air is cooled by the evaporator 50 before reaching the PCU cooling water cooling heat exchanger 80, and the cooled air reaches the PCU cooling water cooling heat exchanger 80. Therefore, it is more preferable.

4 to 9 briefly introduce an example of the operation of the HVAC in the case of such a configuration.
In addition, the same code | symbol is attached | subjected about the structure similar to FIG. Moreover, the arrow which shows the flow of air typically shows that an air flow actually exists in the case of a solid line. Moreover, in the case of a broken line, it shows schematically that there is actually no air flow.

First, referring to FIG. 4, an example of an operation for incorporating into HVAC (part 1) will be introduced.
In this example of operation, the ventilation switching door 425 is in the outside air introduction, the forced exhaust door 435 is opened, the air mix door 445 is closed, the defroster door 455 is closed, the face door 465 is opened, and the foot door 475 is closed. .

  When the blower fan 415 is operated in this state, the outside air is sucked in by the negative pressure accompanying the rotation of the fan, and this outside air is discharged toward the evaporator 50 (first flow path).

  Then, when the air flow, that is, a part of the air flow passes through the PCU cooling water cooling heat exchanger 80, heat exchange is performed with the air cooling fins 85 provided in the PCU cooling water cooling heat exchanger 80, Cool the PCU cooling water.

  Further, the PCU cooling water is cooled by directly exchanging heat with the air conditioner refrigerant as described above when flowing through the inside of the PCU cooling water cooling heat exchanger 80. This is because, for example, if the PCU cooling water cooling heat exchanger 80 has the double pipe structure, the PCU cooling water flows outside and the air conditioner refrigerant flows inside.

  The PCU cooling water cooled in this way flows through the PCU cooling water flow path 120 and is supplied to the PCU 100, so that the PCU 100 can be cooled.

  Further, when passing through the heat exchanger 80 for cooling the PCU cooling water, the air that exchanges heat with the air cooling fins 85 and absorbs the heat of the PCU cooling water, for example, passes through the forced exhaust door 435 and is forced exhaust duct. It is possible to completely exhaust the air from outside 437 into the outside air and to have no influence on the air conditioning of the air conditioner in the passenger compartment.

  Further, the remaining cold air that has passed through the first flow path flows into the second flow path, and is supplied from the face duct 467 to the vehicle interior via the face door 465 that is open.

  This case is an operation example in the case where the outside of the vehicle is hot and the inside of the vehicle is cool, such as in a vehicle in summer when the air conditioner is effective. Thus, this embodiment may be applied and the PCU 100 may be cooled.

Next, with reference to FIG. 5, an example of the operation of incorporating into HVAC (part 2) will be introduced.
In this operation example, the ventilation switching door 425 is in the inside air circulation, the forced exhaust door 435 is closed, the air mix door 445 is closed, the defroster door 455 is closed, the face door 465 is opened, and the foot door 475 is closed. .

  When the blower fan 415 is operated in this state, the inside air in the passenger compartment is sucked in by the negative pressure accompanying the turning of the fan through the open ventilation switching door 425, and this inside air is discharged toward the evaporator 50 (first). Flow path).

  And when a part passes the heat exchanger 80 for cooling a PCU cooling water, it heat-exchanges with the air cooling fin 85 with which the heat exchanger 80 for PCU cooling water cooling was equipped, and cools PCU cooling water .

  Similarly to the operation example (No. 1), the PCU cooling water is cooled by directly exchanging heat with the air conditioner refrigerant as described above when flowing through the heat exchanger 80 for cooling the PCU cooling water.

  The PCU cooling water cooled in this way flows through the PCU cooling water flow path 120 and is supplied to the PCU 100, so that the PCU 100 can be cooled.

  Further, when passing through the PCU cooling water cooling heat exchanger 80, the air that has exchanged heat with the air cooling fins 85 and absorbed the heat of the PCU cooling water and the remaining cold air that has passed through the first flow path are mixed. The air flows into the second flow path and is supplied from the face duct 467 to the vehicle interior via the face door 465 which is in the open state.

  This case is an operation example in the case where the outside of the vehicle is hotter than the conditions shown in FIG. Thus, this embodiment may be applied and the PCU 100 may be cooled.

Next, with reference to FIG. 6, an example of an operation for incorporating into HVAC (part 3) will be introduced.
In this example of operation, the ventilation switching door 425 is in the open position, the forced exhaust door 435 is closed, the air mix door 445 is open, the defroster door 455 is closed, the face door 465 is open, and the foot door 475 is open. .

  When the blower fan 415 is operated in this state, the outside air is sucked in by the negative pressure accompanying the rotation of the fan, and this outside air is discharged toward the evaporator 50 (first flow path).

  Then, when the air flow, that is, a part of the air flow passes through the PCU cooling water cooling heat exchanger 80, heat exchange is performed with the air cooling fins 85 provided in the PCU cooling water cooling heat exchanger 80, Cool the PCU cooling water.

  Similarly to the operation example (No. 1), the PCU cooling water is cooled by directly exchanging heat with the air conditioner refrigerant as described above when flowing through the heat exchanger 80 for cooling the PCU cooling water. By the way, when the day with little solar radiation from autumn to winter is assumed as will be described later, the flow of the air conditioner refrigerant may be stopped.

  The PCU cooling water cooled in this way flows through the PCU cooling water flow path 120 and is supplied to the PCU 100, so that the PCU 100 can be cooled.

  Further, when passing through the heat exchanger 80 for cooling the PCU cooling water, the air that has exchanged heat with the air cooling fins 85 and absorbed the heat of the PCU cooling water proceeds through the second flow path and is in an open state. The vehicle can be supplied from the face duct 467 to the vehicle interior via the door 465.

  Further, the warm air from the first flow path through the heater core 130 and the air that has flowed into the third flow path are supplied from the foot duct 477 to the vehicle interior via the foot door 475 that is open.

  This case is an operation example in the case of a day when there is little solar radiation from autumn to winter, for example. Thus, this embodiment may be applied and the PCU 100 may be cooled.

Next, with reference to FIG. 7, an example of an operation for incorporating into HVAC (part 4) will be introduced.
In this operation example, the ventilation switching door 425 is in the inside air circulation, the forced exhaust door 435 is closed, the air mix door 445 is opened, the defroster door 455 is closed, the face door 465 is opened, and the foot door 475 is opened. .

  In this operation example, the ventilation switching door 425 of the operation example (No. 3) in FIG. 6 is changed from the introduction of the outside air to the position of the circulation of the inside air. Is omitted.

  This case is an operation example in the case where the temperature is lower than the condition shown in FIG. 6, for example, on a day with little solar radiation from autumn to winter. Thus, this embodiment may be applied and the PCU 100 may be cooled.

Next, with reference to FIG. 8, an example of an operation for incorporating into HVAC (part 5) will be introduced.
In this example of operation, the ventilation switching door 425 is in the open position, the forced exhaust door 435 is closed, the air mix door 445 is fully open, the defroster door 455 is closed, the face door 465 is open, and the foot door 475 is open. .

  When the blower fan 415 is operated in this state, the outside air is sucked in by the negative pressure accompanying the rotation of the fan, and this outside air is discharged toward the evaporator 50 (first flow path).

  And when a part passes the heat exchanger 80 for cooling a PCU cooling water, it heat-exchanges with the air cooling fin 85 with which the heat exchanger 80 for PCU cooling water cooling was equipped, and cools PCU cooling water .

  Further, the PCU cooling water is cooled by directly exchanging heat with the air conditioner refrigerant as described above when flowing through the inside of the PCU cooling water cooling heat exchanger 80 as described above. Note that air-conditioning refrigerant may have stopped because it is a cold day in winter.

  The PCU cooling water cooled in this way flows through the PCU cooling water flow path 120 and is supplied to the PCU 100, so that the PCU 100 can be cooled.

  Further, when passing through the heat exchanger 80 for cooling the PCU cooling water, the air that has exchanged heat with the air cooling fins 85 and absorbed the heat of the PCU cooling water and the remaining air that has passed through the first flow path are air mixed. All flows into the heater core 130 via the door 445.

  Then, the air that has passed through the heater core 130 and has been warmed passes through the third flow path, and is supplied from the foot duct 477 to the vehicle interior via the open foot door 475.

  This case is an operation example when the temperature in winter is low, for example. Thus, this embodiment may be applied and the PCU 100 may be cooled.

Next, with reference to FIG. 9, an example of an operation for incorporating into HVAC (part 6) will be introduced.
In this operation example, the ventilation switching door 425 is in the inside air circulation, the forced exhaust door 435 is closed, the air mix door 445 is fully opened, the defroster door 455 is closed, the face door 465 is open, and the foot door 475 is open. .

  In this operation example, the ventilation switching door 425 in the operation example (No. 5) in FIG. 8 is changed from the introduction of the outside air to the position of the inside air circulation. To do. In addition, unlike the example of FIG. 8, since it is internal air circulation, possibility that the air-conditioner compressor 10 is moving is higher than the example of FIG.

  This case is an operation example when the temperature in winter is low, for example. Thus, this embodiment may be applied and the PCU 100 may be cooled.

  Next, a characteristic operation when the PCU cooling water cooling heat exchanger 80 according to the present embodiment is incorporated into the evaporator 50 of the HVAC will be described with reference to FIG.

  In this embodiment, the ventilation switching door 425 is in the position of introducing outside air, the forced exhaust door 435 is opened, the air mix door 445 is closed, the defroster door 455 is closed, the face door 465 is closed, and the foot door 475 is closed. .

  That is, the forced exhaust door 435 is the only open door that communicates with the external space inside the HVAC. That is, the defroster door 455, the face door 465, and the foot door 475, which are communication doors to the vehicle interior side, are all closed. That is, no air flow is generated in the second flow path and the third flow path. Further, in the season when heating is not used, the air mix door 445 responsible for adjusting the air flow rate to the heater core 130 is closed.

  When the blower fan 415 is operated in this state, the outside air is sucked in by the negative pressure accompanying the rotation of the fan, and this outside air is discharged toward the evaporator 50 (first flow path).

  And when a part passes the heat exchanger 80 for cooling a PCU cooling water, it heat-exchanges with the air cooling fin 85 with which the heat exchanger 80 for PCU cooling water cooling was equipped, and cools PCU cooling water .

  Further, the PCU cooling water is cooled by directly exchanging heat with the air conditioner refrigerant as described above when flowing through the inside of the PCU cooling water cooling heat exchanger 80. If the compressor 10 of the air conditioner is operating, it is for cooling the PCU cooling water.

  The PCU cooling water cooled in this way flows through the PCU cooling water flow path 120 and is supplied to the PCU 100, so that the PCU 100 can be cooled.

  In addition, when passing through the heat exchanger 80 for cooling the PCU cooling water, heat exchanged with the air cooling fins 85 and the air that has been warmed by absorbing the heat of the PCU cooling water all pass through the forced exhaust door 435. Then, the air is exhausted from the forced exhaust duct 437 into the outside air.

  In the present embodiment, for example, even when the user is running with the air conditioner turned off, the blower fan 415 is operated with all the doors 455, 465, and 475 on the vehicle interior side closed, thereby The air conditioner OFF state can be maintained as seen from the passengers inside. Therefore, the cooling of the PCU 100 can be performed without causing the passenger to feel uncomfortable.

Next, the configuration of the control mechanism of the cooling device for the PCU 100 according to the first embodiment will be described with reference to FIG.
In the present embodiment, the air conditioner ECU 300 includes a cooling condition determination unit 310, a drive command unit 320, and a display unit 330.

  The cooling condition determination unit 310 determines, for example, how the PCU cooling water is cooled, which door of the HVAC is opened / closed based on input information such as the measured temperature.

  Further, drive command unit 320 transmits a drive command to each control element according to the content determined by cooling condition determination unit 310.

  The display unit 330 accepts the user's selection such as the set temperature of the air conditioner and causes the display device 400 to display information related to the operating state related to the air conditioner in a form that the user can visually recognize regardless of whether or not the user selects.

Hereinafter, the input side connected device will be described.
The cooling condition determination unit 310 of the air conditioner ECU 300 includes, for example, an outside air temperature sensor 210, an inside air temperature sensor 220, a solar radiation sensor 230, an evaporator temperature sensor 240, a heater temperature sensor 250, a humidity sensor 260 (reference numerals 210 to 210) attached to a known air conditioner system. Since 260 is a known sensor, none of which is detected in FIGS. 1 to 10), in addition to detection from a fin temperature sensor 270, a PCU cooling water temperature sensor 280 (see FIGS. 1 and 2), etc. A signal is input.

  These are not limited to one each. Each of these may be configured to sense a predetermined location using a plurality of measuring devices.

  In addition, information selected by the user is input to the display unit 330 via a control panel 200 attached to a known air conditioner system. This is, for example, detection information regarding ON / OFF of the air conditioner itself, detection information regarding a desired set temperature, detection information regarding an operation mode such as air conditioning or dehumidification, a wind direction, an air volume, or the like. The control panel 200 may be, for example, a touch panel, a knob-like switch, or the like.

Next, the output side connected device will be described.
The drive command unit 320 of the air conditioner ECU 300 includes, for example, a blower fan motor 410, a ventilation switching door motor 420, a forced exhaust door motor 430, an air mix door motor 440, a defroster door motor 450, a face door motor 460, a foot door as output side devices. A motor 470 and an electric water pump motor 95 for PCU cooling water are connected.

  Here, the blower fan motor 410 is a motor that drives the blower fan 415. The ventilation switching door motor 420 is a motor that drives the ventilation switching door 425. The forced exhaust door motor 430 is a motor that drives the forced exhaust door 435. The air mix door motor 440 is a motor that drives the air mix door 445.

  The defroster door motor 450 is a motor that drives the defroster door 455. The face door motor 460 is a motor that drives the face door 465. The foot door motor 470 is a motor that drives the foot door 475. The electric water pump motor 95 for PCU cooling water is a motor that drives an electric water pump 90 for circulating PCU cooling water in the PCU cooling water flow path 120.

  Further, a display device 400 is connected to the display unit 330 of the air conditioner ECU 300 as an output-side device.

  Next, a control flow for cooling the PCU cooling water according to the present embodiment will be described with reference to FIG.

  In step S10, the air conditioner ECU 300 according to the present embodiment controls the output of the PCU cooling water electric water pump motor 95 so that the PCU cooling water is constantly output regardless of the operation state of the air conditioner. Perform flow control.

Next, in step S20, the cooling condition determination unit 310 of the air conditioner ECU 300 determines whether or not the automatic air conditioner is in operation. If YES in step S20, that is, if it is determined that the auto air conditioner is in operation, the process proceeds to step S90. On the other hand, if it is determined No in step S20, that is, if it is determined that the auto air conditioner is not in operation, the process proceeds to step S30.
In addition, when step S20 is No, the passenger has no awareness that the air conditioner is operating. Therefore, although details will be described later, in step S70, all the doors are closed to prevent the passenger from feeling uncomfortable.

In step S30, the cooling condition determination unit 310 determines whether the PCU cooling water temperature is higher than the air conditioner refrigerant temperature.
For the air conditioner refrigerant temperature, for example, a measured value of an evaporator temperature sensor 240 (not shown) attached to a known air conditioner system or each temperature detecting means of the fin temperature sensor 270 is used, or one value is set to the other value. What is necessary is just to estimate an air-conditioner refrigerant | coolant temperature by correct | amending.
Moreover, what is necessary is just to make it refer to the value measured with the water temperature sensor 280 for PCU cooling water, for example, for the temperature of PCU cooling water.

If YES in step S30, that is, if it is determined that the PCU cooling water temperature is higher than the air conditioning refrigerant temperature, heat is released from the PCU cooling water to the air conditioning refrigerant in the PCU cooling water cooling heat exchanger 80. This is a state where the PCU cooling water is naturally cooled.
Therefore, in this case, it is determined that there is no cooling failure even if it is left as it is, and the process proceeds to step S90.

  In step S30, No, that is, when it is determined that the temperature of the air-conditioner refrigerant is higher than the temperature of the PCU cooling water, heat is dissipated from the air-conditioner refrigerant toward the PCU cooling water in the PCU cooling water cooling heat exchanger 80. In this state, it is considered that the PCU cooling water absorbs heat and gradually rises in temperature. Therefore, in order to determine whether or not the heat of the PCU cooling water can be radiated to the outside air through the air cooling fins 85, the process proceeds to step S40.

  In step S40, the cooling condition determination unit 310 determines whether the PCU cooling water temperature is higher than the outside air temperature. Here, for the outside air temperature, for example, a value of an outside air temperature sensor 210 (not shown) attached to a known air conditioner system may be referred to. For the temperature of the PCU cooling water, for example, a value measured by the PCU cooling water temperature sensor 280 is referred to.

  If YES in step S40, that is, if it is determined that the outside air temperature is lower than the PCU cooling water temperature, it is considered that the heat of the PCU cooling water can be radiated to the outside air via the air cooling fins 85.

  Therefore, in step S50, the drive command unit 320 of the air conditioner ECU 300 sends a command to the ventilation switching door motor 420 to change the rotation angle θ1 of the ventilation switching door 425 to the outside air introduction position and control to introduce outside air. To do.

  Next, in step S60, the drive command unit 320 sends a command to the forced exhaust door motor 430 to change the rotation angle θ2 of the forced exhaust door 435 to the open position so that the forced exhaust duct is opened. To control.

  Next, in step S70, the drive command unit 320 sends a command to each door motor so that the defroster duct 457, the face duct 467, and the foot duct 477, which are ducts communicating with the vehicle interior side, are all closed. . This is to prevent the passenger from feeling uncomfortable. In addition, since it is No in step S30, that is, the season when the temperature of the air-conditioner refrigerant increases, the air mix door 445 is also closed for the purpose of reducing the air flow rate to the heater core 130.

  Specifically, in order to close the defroster duct 457, the drive command unit 320 causes the defroster door motor 450 to change the rotation angle θ4 so that the defroster door 455 is closed.

  Similarly, in order to close the face duct 467, the drive command unit 320 causes the face door motor 460 to change the rotation angle θ5 so that the face door 465 is closed.

  Similarly, in order to close the foot duct 477, the drive command unit 320 causes the foot door motor 470 to change the rotation angle θ6 so that the foot door 475 is closed.

  Similarly, in order to close the air mix door 445, the drive command unit 320 causes the air mix door motor 440 to change the rotation angle θ3 so that the air mix door 445 is closed.

  Next, the process proceeds to step S80, and the drive command unit 320 sends a command to the blower fan motor 410 so as to rotate the blower fan 415, and then proceeds to step S90.

Note that the processing from step S50 to step S80 may be performed continuously in this order, or may be performed simultaneously at the same time regardless of the order.
By doing in this way, the open / closed state of each door and the cooled state of the PCU 100 are realized, similar to the operation diagram of the HVAC described in FIG.

Here, the reason why the defroster door 455, the face door 465, and the foot door 475 are simultaneously closed in step S70 is as follows.
Step S70 is No in step S20, that is, a step performed in an environment where the automatic air conditioner is stopped.
For this reason, when any one of the defroster duct 457, the face duct 467, and the foot duct 477 communicating with the vehicle interior is opened when the blower fan 415 is rotated in step S80, The air blown from the air will blow out, and the occupant may feel uncomfortable. In other words, although the automatic air conditioner is stopped in step S20, air may blow out from the open duct, causing the passenger to feel uncomfortable.
Therefore, in order to avoid such a situation, in step S70, the drive command unit 320 closes all the ducts communicating with the vehicle interior side, specifically, the defroster duct 457, the face duct 467, and the foot duct 477. Then, a command is sent to each door motor.

  If it is determined in step S40 that No, that is, the outside air temperature is higher than the PCU cooling water temperature, it is considered that the heat of the PCU cooling water cannot be radiated to the outside air via the air cooling fins 85.

  Therefore, in this case, the process proceeds to step S90 in order to cool the PCU cooling water by forcibly operating the compressor 10 of the air conditioner and forcibly cooling the air conditioner refrigerant.

  In step S90, the cooling condition determination unit 310 detects the overheat protection temperature in the PCU 100. Here, the overheat protection temperature of the PCU 100 is a temperature that exceeds the operation guarantee of the PCU 100.

  The temperature of the PCU 100 may directly measure the chip temperature of the PCU 100 using, for example, a temperature detection unit such as a temperature sensor (not shown), or the water temperature sensor 280 for the PCU cooling water may be measured. It may be.

  If YES in step S90, that is, the overheat protection temperature of the PCU 100, that is, a temperature exceeding the operation guarantee of the PCU 100 is detected, the process proceeds to step S100.

  In step S100, the drive command unit 320 sends a command to the compressor 10 of the air conditioner to forcibly operate the compressor 10. This is a step for forcibly operating even if the user turns off the air conditioner. By doing so, the air conditioner refrigerant is rapidly cooled, and the PCU cooling water can be forcibly cooled in the PCU cooling water cooling heat exchanger 80. Then, the process returns to step S10.

  In step S90, if no temperature is detected, that is, the overheating protection temperature of the PCU 100, that is, the temperature exceeding the operation guarantee of the PCU 100 is not detected, an emergency such as taking some action particularly with respect to the PCU cooling water temperature. Therefore, the process returns to step S10, which is the first part of this flow.

  As described above, efficient cooling of the PCU 100 is realized.

(Action / Effect)
The actions and effects of this embodiment are summarized as follows.
In the present embodiment, the PCU cooling water cooling heat exchanger 80 is configured, for example, integrally with the evaporator 50 or as a separate body.

  Here, the heat exchanger 80 for cooling the PCU cooling water sandwiches the piping of the PCU cooling water passage 120 so that the piping of the air-conditioner refrigerant passage 110 comes into contact with the outside, and further, on the outer periphery of the piping of the PCU cooling water passage 120. The air cooling fin 85 is provided. That is, it has a double tube + air cooling fin structure.

When such a PCU cooling water cooling heat exchanger 80 is integrated with the evaporator 50 and incorporated therein, a space for separately providing the PCU cooling water cooling heat exchanger 80 can be saved. .
With this space saving, it is possible to increase the degree of design freedom such as the layout of other equipment arrangements.

  Further, when the PCU cooling water cooling heat exchanger 80 is arranged separately from the evaporator 50, the cold air that has passed through the evaporator 50 can be obtained by arranging it in the vicinity of the evaporator 50 as viewed from the air flow. It can catch with the air-cooling fin 85, and can further improve heat exchange efficiency.

  Further, the HVAC is provided with a forced exhaust duct 437, a forced exhaust door 435, and a forced exhaust door motor 430 in order to exhaust the air heat-exchanged by the air cooling fins 85 of the PCU cooling water cooling heat exchanger 80.

  By configuring in this way, for example, even in an environment where the air conditioner is OFF and the air conditioner refrigerant temperature is higher than the PCU cooling water temperature, the outside air temperature and the PCU cooling water temperature are set. In comparison, when the PCU cooling water temperature is higher, the duct communicating with the interior side of the HVAC cabin is maintained in a fully closed state, the outside air is introduced, the blower fan 415 is turned, and the air cooling fin 85 is passed through. It is possible to exchange heat with the outside air and exhaust it to the outside as it is (Yes in Step S40 to Step S80).

  By doing in this way, PCU cooling water can be cooled efficiently, without giving a feeling of strangeness to a crew member. Moreover, since the compressor 10 of the air conditioner is not operated at this time, it is possible to improve quietness and secure a more comfortable living space for the occupant. In addition, by enhancing the energy saving effect, it is possible to contribute to an improvement in fuel consumption or electricity costs and an increase in cruising distance.

  In other environments, for example, when the PCU cooling water temperature is lower than the outside air temperature, or when the air conditioner refrigerant temperature is lower than the PCU cooling water temperature, the overheat protection temperature of the PCU 100 is detected. When the overheat protection temperature is detected, the air conditioner compressor 10 is forcibly operated, the air conditioner refrigerant is rapidly cooled, and the PCU cooling water is exchanged with the PCU cooling water. Allow the cooling water to cool.

  With this configuration, so-called hybrid cooling of the PCU cooling water is possible by cooling with the air-cooling fins 85 and cooling with the air-conditioning refrigerant in consideration of the outside air temperature. Thereby, there is an effect that the PCU 100 can be more reliably and efficiently thermally protected and cooled.

(Second Embodiment)
Next, the operation when the heat exchanger in the cooling circuit of the power conversion device according to the second embodiment is incorporated into the evaporator of the HVAC will be described with reference to FIG.
FIG. 13 is a diagram in which the PCU cooling water cooling heat exchangers 80 and 80B are incorporated in an evaporator of the HVAC.
In addition, about the structure similar to 1st Embodiment, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.

  In the first embodiment, the PCU cooling water cooling heat exchanger incorporated in the evaporator 50 is only one heat exchanger represented by reference numeral 80. In this embodiment, reference numeral 80B is further added to form a two-unit system. The configuration of reference numeral 80B may be exactly the same as that of reference numeral 80, or may be different. In the present embodiment, it is assumed that they are the same.

  The PCU cooling water cooling heat exchangers 80 and 80B are connected in series with each other as shown in FIG. In addition, each is connected and incorporated in series with the evaporator 50. All other configurations are the same as in the first embodiment.

  Even if comprised in this way, there can exist an effect similar to 1st Embodiment. Rather, if constituted in this way, the PCU cooling water is equivalent to one round along the PCU cooling water flow path 120, for example, the PCU cooling water electric water pump 90 → PCU 100 → the evaporator 50 → PCU cooling water cooling heat exchanger 80. → PCU cooling water cooling heat exchanger 80B → PCU100, while circulating through the loop, the PCU cooling water cooling heat exchangers 80 and 80B are each cooled once, for a total of twice. It can be said that it is more efficient and more suitable than the first embodiment.

  The PCU cooling water cooling heat exchangers 80 and 80B may be connected to each other so as to be connected in parallel. Similarly, each connection relationship with respect to the evaporator 50 may be connected in a parallel connection relationship as shown in FIG.

  Further, each of the PCU cooling water cooling heat exchangers 80 and 80B is not incorporated in the evaporator 50, but is installed in the vicinity of the downstream side of the evaporator 50 as viewed from the air flow and separately from the evaporator 50. There may be.

  The above-described embodiment has been described in detail for easy understanding of the present invention, and is not necessarily limited to the one having all the described configurations.

  In addition, control lines, information lines, and power supply lines are those that are considered necessary for the description, and not all control lines, information lines, and power supply lines are necessarily shown. Actually, it may be considered that almost all the components are connected to each other.

  In addition, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and a part or all of the configuration of another embodiment can be added to the configuration of one embodiment. It is.

  In addition, it is possible to add, delete, and replace other configurations for a part of the configuration of each embodiment.

  Specifically, for example, the above embodiments have been described by taking cooling of a power conversion device mounted on an automobile as an example, but the present invention is not limited to this. The present invention can be applied to anything that uses a high-voltage device.

  Specifically, for example, it may be applied to industrial machines such as trains and electric general-purpose machines, electric power shovels, highly electronic ships and aircraft, and the mounted equipment may be cooled.

  Moreover, although the said embodiment gave and demonstrated the example at the time of air_conditioning | cooling operation of an air-conditioner, it is applicable similarly also at the time of heating operation.

  Specifically, during the heating operation, for example, the forced exhaust door 435 and the air mix door 445 are opened to the extent that they are in contact with each other, thereby blocking the flow of air from the first flow path to the second flow path. Then, a configuration may be adopted in which almost all the air in the first flow path is led to the third flow path, and heat is exchanged by the heater core 130 to which heat from a heat source such as an internal combustion engine is supplied to obtain warm air.

  In other words, the process from the intake of outside air or inside air to the blower fan 415 and the evaporator 50 is the same regardless of the cooling / heating operation state of the air conditioner, so that the discussion during cooling can be applied as it is during heating. .

DESCRIPTION OF SYMBOLS 10 Compressor 20 Filter dryer 30 Capacitor 40 Expansion valve 45 Valve 50 Evaporator 60 Blower 80, 80B Heat exchanger for cooling PCU cooling water (heat exchanger)
85 Air-cooled fins 90 Electric water pump for PCU cooling water 95 Electric water pump motor for PCU cooling water 100 PCU (power converter)
110 Air conditioner refrigerant flow path (refrigerant flow path)
120 PCU cooling water flow path (cooling water flow path)
130 heater core 200 control panel 210 outside air temperature sensor (temperature detecting means)
220 Inside air temperature sensor (temperature detection means)
230 Solar radiation sensor 240 Evaporator temperature sensor (temperature detection means)
250 Heater temperature sensor (temperature detection means)
260 Humidity sensor 270 Fin temperature sensor (temperature detection means)
280 Water temperature sensor for PCU cooling water (temperature detection means)
300 Air conditioner ECU (control device)
310 Cooling Condition Determination Unit 320 Drive Command Unit 330 Display Unit 400 Display Device 410 Blower Fan Motor 415 Blower Fan 420 Ventilation Switching Door Motor 425 Ventilation Switching Door 430 Forced Exhaust Door Motor 435 Forced Exhaust Door 437 Forced Exhaust Duct (Duct)
440 Air mix door motor 445 Air mix door 450 Defroster door motor 455 Defroster door 457 Defroster duct (duct)
460 Face door motor 465 Face door 467 Face duct (duct)
470 Foot door motor 475 Foot door 477 Foot duct (duct)
θ1, θ2, θ3, θ4, θ5, θ6 Rotation angle

Claims (7)

A cooling water flow path through which cooling water for cooling the power conversion device flows;
A refrigerant flow path through which a refrigerant flows while constituting a refrigeration cycle for air conditioning,
A heat exchanger connected to the cooling water flow path and the refrigerant flow path,
The heat exchanger has a structure in which the cooling water channel is in contact with the outside of the refrigerant channel so that heat can be exchanged between the cooling channel and the refrigerant channel, and the evaporator of the refrigeration cycle A cooling device for a power conversion device, wherein the cooling device is disposed in a place where an air flow generated by a fan supplying air to the air hits.   2. The cooling device for a power conversion device according to claim 1, wherein the heat exchanger has a double-pipe structure in which the cooling water passage is in contact with the outside of the refrigerant passage. The cooling apparatus for a power converter according to claim 1, wherein the heat exchanger is incorporated in the evaporator. Temperature detection means for detecting the temperature of the outside air;
Temperature detecting means for detecting the temperature of the refrigerant;
Temperature detecting means for detecting the temperature of the cooling water;
A duct for exhausting air heat-exchanged by the evaporator or the heat exchanger;
A control device for controlling the air conditioning,
The controller is
Based on the magnitude comparison of the temperatures detected by the temperature detection means, all the ducts communicating with the indoor side are closed, the outside air is sucked and the heat exchanger exchanges heat with the cooling water, and the ducts The cooling device for a power conversion device according to claim 1, wherein control for exhausting the air to the outside air is performed. The controller is
Comparing the temperature of the refrigerant and the temperature of the cooling water, if the temperature of the refrigerant is lower than the temperature of the cooling water, heat exchange between the refrigerant and the cooling water, otherwise, Comparing the temperature of the outside air and the temperature of the cooling water, and controlling the heat exchange between the outside air and the cooling water when the temperature of the outside air is lower than the temperature of the cooling water. The cooling device for a power conversion device according to claim 4. The controller is
5. The power conversion according to claim 4, wherein when the overheat protection temperature of the power conversion device is detected via the temperature detection means, control is performed to forcibly operate the compressor of the refrigeration cycle. 6. Equipment cooling device. The cooling device for a power converter according to any one of claims 1 to 6, wherein air-cooling fins are provided on an outer periphery of the heat exchanger.

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