JP6497066B2 - Cooling device and air conditioner - Google Patents

Description

  The present invention relates to a cooling device and an air conditioner, and more specifically to a cooling device that cools an electrical component and an air conditioner including the cooling device.

  2. Description of the Related Art Conventionally, in an air conditioner using a vapor compression refrigeration cycle, a technique for cooling an electrical component typified by an inverter for a compressor using a refrigerant cooling circuit is known (for example, see Patent Document 1). . According to this technology, unlike a normal cooling method such as forced air cooling or water cooling, the inverter can be cooled at a temperature lower than the outside air temperature, and can be efficiently cooled when the inverter generates heat.

JP 2013-11392 A

  As described above, in the cooling method using the refrigerant cooling circuit of the air conditioner, efficient cooling is possible because the temperature difference between the inverter and the refrigerant is large, while cooling is performed at a temperature lower than the outside air temperature. Therefore, there is a problem that condensation occurs in the inverter. Therefore, an electrical short circuit path may be formed in the inverter.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a cooling device capable of suppressing the occurrence of dew condensation in cooling of electrical components, and an air conditioner including the cooling device. It is.

  The cooling device (4) which concerns on 1 aspect of this invention is a cooling device which cools an electrical component (5). The cooling device (4) includes a cooling member (21), a refrigerant pipe (10), and a housing member (11). The cooling member (21) includes a mounting surface (21A) on which the electrical component (5) is mounted, and has heat conductivity. The said refrigerant | coolant piping (10) is arrange | positioned inside the said cooling member (21), and comprises a refrigerant | coolant flow path (10A). The housing member (11) is attached to the cooling member (21), and constitutes an internal space (S) in which the electrical component (5) is housed together with the cooling member (21). Inside the cooling member (21), an air passage (30) for communicating the internal space (S) and the external space is formed.

  In the cooling device (4), heat is transferred from the electric component (5) mounted on the mounting surface (21A) to the refrigerant in the refrigerant pipe (10) through the cooling member (21), thereby the electric component ( 5) can be cooled. In the cooling device (4), air can be allowed to enter the internal space (S) from the external space via the air passage (30). Therefore, moisture in the air that has entered the air passage (30) is condensed by refrigerant cooling to condense on the pipe wall of the refrigerant pipe (10), and then the air whose moisture content has decreased is reduced to the internal space (S ). Therefore, according to the said cooling device (4), compared with the case where air penetrate | invades directly into the said interior space (S) without passing through the said ventilation path (30), generation | occurrence | production of dew condensation in the said interior space (S). Can be suppressed. “Heat transfer” means a property that allows heat transfer from the electric component (5) to the refrigerant in the refrigerant pipe (10) via the cooling member (21).

  In the cooling device (4), the refrigerant pipe (10) and the air passage (30) may extend along the inside of the cooling member (21).

  Thereby, the air that has entered the air passage (30) can be efficiently cooled by the refrigerant in the refrigerant passage (10A). As a result, the occurrence of condensation in the internal space (S) can be effectively suppressed.

  In the cooling device (4), the refrigerant pipe (10) and the air passage (30) may include straight portions (10B, 10D, 31). Moreover, the said linear part (10B) of the said refrigerant | coolant piping (10) and the said linear part (31) of the said ventilation path (30) may be arrange | positioned adjacently in parallel.

  Thereby, the air that has entered the air passage (30) can be more efficiently cooled by the refrigerant in the refrigerant passage (10A). As a result, it is possible to more effectively suppress the occurrence of condensation in the internal space (S).

  In the cooling device (4), the cooling member (21) may include a first end surface (21B) and a second end surface (21C) facing each other. A first opening (33) that opens to the external space side may be formed on the first end surface (21B). A second opening (34) that opens to the external space side may be formed on the second end face (21C). The mounting surface (21A) has a third opening (35) that opens toward the internal space (S) at an intermediate portion between the first end surface (21B) and the second end surface (21C). It may be formed. The air passage (30) extends from the first opening (33) and the second opening (34) to the third opening (35) through the inside of the cooling member (21). It may be formed as follows.

  This ensures a sufficient distance of the air passage (30) from the first opening (33) and the second opening (34) to the third opening (35). Can do. As a result, it is possible to sufficiently cool the refrigerant that has entered the air passage (30) before being released into the internal space (S). The “intermediate portion” includes not only a complete intermediate position between the first end surface (21B) and the second end surface (21C) but also a peripheral portion thereof.

  In the cooling device (4), the housing member (11) may be connected to the cooling member (21) via a seal member (40).

  Thereby, it can suppress that air penetrate | invades directly into the said internal space (S) from the clearance gap between the said accommodating member (11) and the said cooling member (21). As a result, since air that has not been cooled by refrigerant is prevented from directly entering the internal space (S), the occurrence of condensation in the internal space (S) can be more effectively suppressed.

  In the cooling device (4), the cooling member (21) may be made of a metal material.

  This enables efficient heat transfer from the electric component (5) to the refrigerant through the metal cooling member (21) having high heat transfer property, and air that has entered the air passage (30). Efficient heat transfer from the refrigerant to the refrigerant. As a result, it is possible to efficiently cool the electrical component (5) and efficiently cool the air that has entered the air passage (30).

  An air conditioner (1) according to one aspect of the present invention includes the cooling device (4) according to one aspect of the present invention. Therefore, according to the said air conditioning apparatus (1), generation | occurrence | production of dew condensation can be suppressed in cooling of the electrical component (5) using a refrigerant cooling circuit.

  ADVANTAGE OF THE INVENTION According to this invention, the cooling device which can suppress generation | occurrence | production of dew condensation in the cooling of an electrical component, and the air conditioning apparatus provided with the said cooling device can be provided.

It is the schematic which shows the structure of the air conditioning apparatus which concerns on embodiment of this invention. It is a schematic perspective view which shows the structure of the cooling device which concerns on embodiment of this invention. It is the schematic which shows the cross-section of the said cooling device. It is the schematic for demonstrating the structure of the refrigerant | coolant flow path and ventilation path in the said cooling device. It is the schematic which shows the structure of the modification of the said air conditioning apparatus.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<Configuration of air conditioner>
First, the structure of the air conditioning apparatus 1 which concerns on this embodiment is demonstrated. Referring to FIG. 1, an air conditioner 1 is an air conditioner that performs a cooling operation and a heating operation, and includes an outdoor unit 2 that is installed and used outdoors, and an indoor unit 3 that is installed and used indoors. And mainly. The outdoor unit 2 and the indoor unit 3 are connected to each other by a refrigerant pipe 10.

  The outdoor unit 2 includes a compressor 12, an oil separator 13, an outdoor heat exchanger 14, an outdoor fan 14 </ b> A, a first expansion valve 15, an accumulator 16, a four-way switching valve 17, and a cooling device 4. , Is mainly arranged. The compressor 12 has a refrigerant suction port 12A and a discharge port 12B, compresses the low-pressure refrigerant sucked from the suction port 12A, and discharges the compressed high-pressure refrigerant from the discharge port 12B. The compressor 12 has a scroll type or rotary type compression mechanism, and is driven by a compressor motor. The rotation speed of the compressor motor is controlled by an inverter.

  The oil separator 13 is for separating the lubricating oil from the refrigerant discharged from the discharge port 12B of the compressor 12. The refrigerant after the lubricating oil is separated is sent to the four-way switching valve 17 side, and the lubricating oil is returned to the compressor 12 side.

  The outdoor heat exchanger 14 is for performing heat exchange between the refrigerant and the outdoor air, and is a fin-and-tube heat exchanger. An outdoor fan 14A is installed in the vicinity of the outdoor heat exchanger 14, and outdoor air is sent to the outdoor heat exchanger 14 side by driving the outdoor fan 14A. The outdoor fan 14A has a fan motor and a propeller fan, and is driven by rotating the propeller fan by the fan motor.

  The first expansion valve 15 is for expanding and depressurizing the refrigerant flowing in from the refrigerant pipe 10, and is an electronic expansion valve having a variable opening. The accumulator 16 is for separating the refrigerant flowing from the refrigerant pipe 10 into gas and liquid, and is disposed between the suction port 12A of the compressor 12 and the four-way switching valve 17. The gas refrigerant separated in the accumulator 16 is sucked into the compressor 12 from the suction port 12A.

  The four-way switching valve 17 has first to fourth ports P1 to P4. The first port P1 is connected to the discharge port 12B side of the compressor 12. The second port P2 is connected to the suction port 12A side of the compressor 12. The third port P3 is connected to the outdoor heat exchanger 14 side. The fourth port P4 is connected to the indoor unit 3 side. The four-way switching valve 17 is in a state where the first port P1 and the third port P3 communicate with each other and the second port P2 and the fourth port P4 communicate with each other (first state: a state indicated by a solid line in FIG. 1). The first port P1 and the fourth port P4 communicate with each other, and the second port P2 and the third port P3 communicate with each other (second state: a state indicated by a broken line in FIG. 1). The four-way switching valve 17 is switched to the first state during the cooling operation of the air conditioner 1, and is switched to the second state during the heating operation.

  The cooling device 4 is a device that cools electrical components used for operation control of the air conditioner 1 such as an inverter that controls the rotation speed of the compressor motor, and is disposed in a part of the refrigerant pipe 10. The configuration of the cooling device 4 will be described in detail later.

  In the indoor unit 3, an indoor heat exchanger 18 and an indoor fan (not shown) are mainly arranged. The indoor heat exchanger 18 is for performing heat exchange between the refrigerant and the indoor air, and is a fin-and-tube heat exchanger. An indoor fan is installed in the vicinity of the indoor heat exchanger 18, and indoor air is sent to the indoor heat exchanger 18 side by driving the indoor fan.

  As described above, the air conditioner 1 includes a refrigerant cooling circuit including the compressor 12, the outdoor heat exchanger 14, the first expansion valve 15, the indoor heat exchanger 18, and the refrigerant pipe 10 that connects them to each other. Is formed. A vapor compression refrigeration cycle is performed by circulating the refrigerant in the refrigerant cooling circuit.

<Operation of air conditioner>
Next, the cooling operation and the heating operation which are main operations of the air conditioner 1 will be described.

(Cooling operation)
During the cooling operation, the four-way switching valve 17 is switched to the first state (solid line in FIG. 1). In the cooling operation, a refrigeration cycle is performed using the outdoor heat exchanger 14 as a condenser and the indoor heat exchanger 18 as an evaporator.

  First, the high-temperature and high-pressure refrigerant compressed in the compressor 12 is sent to the outdoor heat exchanger 14 side through the refrigerant pipe 10. Moreover, outdoor air is sent to the outdoor heat exchanger 14 side by driving the outdoor fan 14A. And in the outdoor heat exchanger 14, heat exchange between outdoor air and a refrigerant | coolant is performed, and a refrigerant | coolant condenses.

  The condensed refrigerant is decompressed by the first expansion valve 15 and then sent to the indoor heat exchanger 18 side. Moreover, indoor air is sent to the indoor heat exchanger 18 side by driving an indoor fan. The indoor heat exchanger 18 exchanges heat between the indoor air and the refrigerant. At this time, the refrigerant evaporates due to heat absorption from the room air, while the room air is cooled by the refrigerant. And the cooled air is sent out indoors from the blower outlet (not shown) provided in the indoor unit 3. FIG. The evaporated refrigerant is sent again to the outdoor unit 2 side, and is sucked into the compressor 12 from the suction port 12A. In this way, the cooling operation of the air conditioner 1 is performed.

(Heating operation)
During the heating operation, the four-way switching valve 17 is switched to the second state (broken line in FIG. 1). During the heating operation, the refrigeration cycle is performed using the outdoor heat exchanger 14 as an evaporator and the indoor heat exchanger 18 as a condenser.

  First, the high-temperature and high-pressure refrigerant compressed in the compressor 12 is sent to the indoor heat exchanger 18 side through the refrigerant pipe 10. Moreover, indoor air is sent to the indoor heat exchanger 18 side by driving an indoor fan. The indoor heat exchanger 18 exchanges heat between the indoor air and the refrigerant. At this time, the refrigerant is condensed by heat dissipation to the room air, while the room air is heated by the refrigerant. The heated air is sent out indoors from an outlet (not shown) provided in the indoor unit 3. The condensed refrigerant is depressurized by the first expansion valve 15 and then sent to the outdoor heat exchanger 14 side. Also, by driving the outdoor fan 14A, outdoor air is sent to the outdoor heat exchanger 14 side. Then, heat exchange between the refrigerant and the outdoor air is performed in the outdoor heat exchanger 14. At this time, the refrigerant evaporates due to heat absorption from the outdoor air, and is again sucked into the compressor 12 from the suction port 12A. Thus, the heating operation of the air conditioner 1 is performed.

<Configuration of cooling device>
Next, the configuration of the cooling device 4 will be described in detail with reference to FIGS. FIG. 2 is a perspective view schematically showing the overall configuration of the cooling device 4. FIG. 3 shows a cross-sectional structure of the cooling device 4. FIG. 4 shows the configuration of the refrigerant flow path 10 </ b> A and the ventilation path 30 provided in the refrigerant jacket 21 of the cooling device 4. 2 and 4, the illustration of the inverter 5 is omitted.

  Referring to FIGS. 2 and 3, cooling device 4 is a device that cools electrical components used for operation control of air conditioner 1, such as inverter 5 that controls the rotation speed of the compressor motor. The cooling device 4 includes a refrigerant jacket 21 (cooling member) including a flat mounting surface 21A on which the inverter 5 is mounted, a refrigerant pipe 10 disposed inside the refrigerant jacket 21, and the refrigerant jacket 21 on the mounting surface 21A. The lid member 11 (accommodating member) is mainly provided. The inverter 5 includes power devices 51, 52 mounted on the mounting surface 21A, a bus bar 53 connecting the power devices 51, 52, a capacitor 54 disposed on the bus bar 53, and a plurality of substrates 55, 56, 57.

  The refrigerant jacket 21 is made of a metal material having heat conductivity such as aluminum or copper. The refrigerant jacket 21 is a rectangular plate-like member composed of the mounting surface 21A and its opposite surface and four side surfaces including a first end surface 21B and a second end surface 21C facing each other. The refrigerant jacket 21 has a width W3 in the longitudinal direction and a width W2 in the short direction. The shape of the refrigerant jacket 21 is not limited to the above shape, and any shape can be adopted.

  The refrigerant jacket 21 is formed with a hole penetrating from the first end surface 21B toward the second end surface 21C inside a single plate-like member. And the refrigerant | coolant piping 10 is penetrated by the said hole. As another embodiment, the refrigerant jacket 21 is configured by combining two plate-like members in which grooves along the pipe shape of the refrigerant pipe 10 are formed, and the refrigerant pipe 10 is formed by the two plate-like members. A mode of being sandwiched can be exemplified.

  Referring to FIG. 4, the refrigerant pipe 10 is a copper pipe having a cylindrical shape, and constitutes a refrigerant flow path 10 </ b> A in an inner peripheral side region thereof. The refrigerant pipe 10 includes two straight portions 10B and 10D that extend linearly in a direction in which the first end surface 21B and the second end surface 21C face each other, and a connection portion 10C that connects the two straight portions 10B and 10D. And have. As shown in FIG. 4, the two straight portions 10 </ b> B and 10 </ b> D are arranged substantially in parallel with a predetermined interval. The connecting portion 10C is a pipe portion that is curved in a U shape and protrudes from the second end surface 21C on the second end surface 21C side. As indicated by the arrows in FIG. 4, the refrigerant in the refrigerant pipe 10 flows from the first end surface 21B toward the second end surface 21C in the straight portion 10B, then turns back at the connection portion 10C, and returns to the first portion in the straight portion 10D. By flowing from the second end face 21C toward the first end face 21B, it flows so as to reciprocate inside the refrigerant jacket 21.

  Referring to FIG. 3, the lid member 11 has a box shape including an opening end 11 </ b> A, and is disposed on the mounting surface 21 </ b> A with the opening end 11 </ b> A facing the refrigerant jacket 21 side. Thereby, as shown in FIG. 3, an internal space S surrounded by the inner surface of the lid member 11 and the mounting surface 21 </ b> A of the refrigerant jacket 21 is configured. The inverter 5 to be cooled is accommodated in the internal space S. The lid member 11 has a rectangular parallelepiped shape along the outer peripheral shape of the refrigerant jacket 21, and the size thereof is smaller than the mounting surface 21A (see FIG. 2). The depth D1 of the lid member 11 is larger than the height H1 of the inverter 5 (see FIG. 3). The lid member 11 has a width in the longitudinal direction and the short side direction, like the refrigerant jacket 21. The width W1 in the short direction of the lid member 11 is larger than the distance between the straight portions 10B and 10D of the refrigerant pipe 10 and smaller than the width W2 in the short direction of the refrigerant jacket 21 (see FIG. 4). . The lid member 11 is not limited to the above shape as long as it can form the internal space S for housing the inverter 5.

  The lid member 11 is connected to the refrigerant jacket 21 via a seal member 40 as shown in FIG. More specifically, the seal member 40 is disposed between the opening end 11 </ b> A of the lid member 11 and the refrigerant jacket 21, thereby sealing a gap between the lid member 11 and the refrigerant jacket 21. The sealing member 40 is preferably made of a material excellent in sealing performance such as rubber. The seal member 40 is not an essential component in the cooling device of the present invention, but by adopting this, the entry of outside air into the internal space S from the gap between the lid member 11 and the refrigerant jacket 21 can be suppressed. .

  With the above configuration, in the cooling device 4, the inverter 5 to be cooled is mounted on the mounting surface 21 </ b> A of the refrigerant jacket 21 and is accommodated in the internal space S. Further, the refrigerant flows through the refrigerant pipe 10 and into the refrigerant jacket 21. As a result, heat is transferred from the inverter 5 to the refrigerant through the refrigerant jacket 21, and the inverter 5 is cooled.

  Referring to FIG. 4, an air passage 30 that connects the internal space S and the external space is formed inside the refrigerant jacket 21. The air passage 30 includes a linear portion 31 that extends linearly in the direction in which the first end surface 21B and the second end surface 21C face each other inside the refrigerant jacket 21, and the first end surface 21B and the second end surface 21C. The intermediate portion has a branch portion 32 that branches from the straight portion 31 and extends in the direction orthogonal to the straight portion 31 toward the mounting surface 21A. The air passage 30 is formed so as to penetrate the inside of the refrigerant jacket 21 from the first end face 21B to the second end face 21C along the longitudinal direction of the refrigerant jacket 21.

  More specifically, the air passage 30 passes through the interior of the refrigerant jacket 21 from the first opening 33 formed on the first end surface 21B and the second opening 34 formed on the second end surface 21C. Thus, it is formed to reach the third opening 35 formed in the mounting surface 21A. The first and second openings 33 and 34 are open to the outer space side and are located at both ends of the linear portion 31. The third opening 35 opens to the inner space S side, and is formed on the mounting surface 21A at an intermediate portion between the first end surface 21B and the second end surface 21C. One end of the branch portion 32 is a third opening 35, and the other end communicates with the straight portion 31.

  The refrigerant pipe 10 and the air passage 30 extend along the direction in which the first end surface 21B and the second end surface 21C face each other inside the refrigerant jacket 21. More specifically, the straight line portion 10B of the refrigerant pipe 10 and the straight line portion 31 of the ventilation path 30 are arranged adjacent to each other in parallel with a predetermined interval. The interval between the refrigerant pipe 10 and the air passage 30 is not particularly limited, but the air in the air passage 30 is sufficiently cooled by the refrigerant in the refrigerant pipe 10 and the two are close enough to cause condensation in the air passage 30. Are preferably arranged.

  With the above configuration, the air that has entered the air passage 30 from the first and second openings 33 and 34 is cooled by the refrigerant flowing in the refrigerant flow path 10A, and as a result, dew condensation occurs on the inner wall surface of the air passage 30. . Then, the air whose water content has decreased due to the occurrence of condensation is discharged from the third opening 35 into the internal space S. Therefore, compared with the case where air directly enters the internal space S, the occurrence of condensation in the internal space S is suppressed.

  In order to cope with the occurrence of condensation in the air passage 30 as described above, the cooling device 4 is preferably used in a state where the extending direction of the air passage 30 is along the vertical direction with respect to the horizontal plane. Thereby, water droplets generated in the air passage 30 can be appropriately discharged out of the air passage 30 by gravity.

<Effect>
Next, the effect by the said cooling device 4 is demonstrated.

  In the cooling device 4, the inverter 5 can be cooled by transferring heat from the inverter 5 to the refrigerant flowing through the refrigerant pipe 10 through the refrigerant jacket 21. Thereby, compared with cooling methods, such as forced air cooling and water cooling, a cooling effect can be improved significantly.

  In the cooling device 4, for example, air can enter the internal space S from the external space via the air passage 30 when the temperature of the internal space S decreases. Therefore, moisture in the air that has entered the air passage 30 can be condensed by cooling the refrigerant and condensed on the pipe wall of the refrigerant pipe 10, and then the air having a reduced moisture content can enter the internal space S. Therefore, according to the cooling device 4, it is possible to suppress the occurrence of dew condensation in the internal space S as compared to the case where air directly enters the internal space S without passing through the air passage 30.

  As a measure for suppressing the occurrence of dew condensation when the inverter 5 is cooled, the inverter 5 is housed in a completely sealed case member to completely block the entry of air from the external space to the internal space. There are measures. However, in this case, there is a concern that the case member is damaged when the internal pressure of the case member fluctuates due to a temperature change. Further, when a vent is provided in the case member, air enters directly into the internal space from the vent, and therefore it is difficult to sufficiently suppress the occurrence of condensation. On the other hand, in the cooling device 4, since the internal space S and the external space are communicated with each other by the air passage 30 as described above, even if the pressure in the internal space S changes due to a temperature change, the lid member 11 and the refrigerant jacket 21 can be prevented from being damaged. Further, since the air after being cooled by the refrigerant in the air passage 30 enters the internal space S, the occurrence of condensation can be effectively suppressed as compared with the case where the air directly enters the internal space S.

  In the cooling device 4, the refrigerant pipe 10 and the air passage 30 extend along the inside of the refrigerant jacket 21. Moreover, the linear part 10B of the refrigerant | coolant piping 10 and the linear part 31 of the ventilation path 30 are arrange | positioned adjacently in parallel. As a result, the air that has entered the air passage 30 can be efficiently cooled by the refrigerant in the refrigerant pipe 10. As a result, the occurrence of condensation in the internal space S can be more effectively suppressed.

  In the cooling device 4, the air passage 30 passes through the inside of the refrigerant jacket 21 from the first opening 33 formed in the first end surface 21B and the second opening 34 formed in the second end surface 21C. The third opening 35 is formed. The third opening 35 is formed at an intermediate portion between the first end surface 21B and the second end surface 21C. Thereby, the length of the ventilation path 30 from the first opening 33 and the second opening 34 to the third opening 35 can be sufficiently secured, and the air that has entered the ventilation path 30 can be prevented. It can be sufficiently cooled by the refrigerant.

  In the cooling device 4, the lid member 11 is connected to the refrigerant jacket 21 via the seal member 40. Thereby, it can suppress that air penetrate | invades directly into the internal space S from the clearance gap between the cover member 11 and the refrigerant | coolant jacket 21. FIG. As a result, the occurrence of condensation in the internal space S can be further effectively suppressed.

  In the cooling device 4, the refrigerant jacket 21 is made of a metal material such as aluminum or copper. This enables efficient heat transfer from the inverter 5 to the refrigerant through the metal refrigerant jacket 21 having high heat transfer, and efficient heat transfer from the air that has entered the air passage 30 to the refrigerant. Is possible. As a result, efficient cooling of the inverter 5 and efficient cooling of the air that has entered the air passage 30 are possible.

<Modification>
Finally, a modification of the above embodiment will be described.

  In the above embodiment, the air passage 30 may be formed at an arbitrary position inside the refrigerant jacket 21, but the air in the air passage 30 is efficiently cooled by being formed along the refrigerant pipe 10. be able to. From this point of view, the air passage 30 is not limited to the case where the straight portion 31 is formed so as to be parallel to the straight portion 10B of the refrigerant pipe 10, and is formed so as to be parallel to the straight portion 10D. May be.

  In the said embodiment, the number in which the ventilation path 30 is formed is not specifically limited, Plural (two) may be formed so that it may adjoin in parallel with respect to both the linear part 10B of the refrigerant | coolant piping 10, and the linear part 10D. Good.

  In the said embodiment, as shown in FIG. 4, the refrigerant | coolant piping 10 is not limited to when reciprocating the inside of the refrigerant | coolant jacket 21 in a longitudinal direction once, You may reciprocate in the said longitudinal direction in multiple times.

  In the embodiment described above, the number of the third openings 35 that are opened to the inner space S side is not particularly limited, and a plurality of openings may be formed.

  In the said embodiment, the cooling device 4 is not limited to the case of cooling the electrical component used for operation control of the air conditioning apparatus 1 such as the inverter 5, but can be similarly applied to the cooling of other electrical components. .

  In the above embodiment, the cooling device 4 is provided in a part of the refrigerant cooling circuit constituted by the compressor 12, the outdoor heat exchanger 14, the first expansion valve 15, the indoor heat exchanger 18, and the refrigerant pipe 10 that connects them to each other. The cooling device 4 may be arranged in a part of the branch pipe 60 branched from the refrigerant pipe 10 constituting the refrigerant cooling circuit as shown in FIG. . In this case, the second expansion valve 61 is disposed upstream from the cooling device 4 during the cooling operation, and the third expansion valve 62 is disposed downstream.

  It should be thought that embodiment disclosed this time and its modification are illustrations in all the points, and are not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

DESCRIPTION OF SYMBOLS 1 Air conditioning apparatus, 4 Cooling apparatus, 5 Inverter (electric part), 10 Refrigerant piping, 10A Refrigerant flow path, 10B, 10D, 31 Straight part, 11 Lid member (accommodating member), 21 Refrigerant jacket (cooling member), 21A Mounting surface, 21B first end surface, 21C second end surface, 30 air passage, 33 first opening, 34 second opening, 35 third opening, 40 sealing member, S internal space.

Claims (7)

A cooling device (4) for cooling the electrical component (5),
A cooling member (21) including a mounting surface (21A) on which the electrical component (5) is mounted and having heat conductivity;
A refrigerant pipe (10) disposed inside the cooling member (21) and constituting a refrigerant flow path (10A);
A housing member (11) attached to the cooling member (21) and configured with the cooling member (21) in an internal space (S) in which the electrical component (5) is housed.
A cooling device (4) in which a ventilation path (30) for communicating the internal space (S) and the external space is formed inside the cooling member (21).   The cooling device (4) according to claim 1, wherein the refrigerant pipe (10) and the air passage (30) extend along the inside of the cooling member (21). The refrigerant pipe (10) and the vent path (30) include straight portions (10B, 10D, 31),
The cooling device according to claim 1 or 2, wherein the straight portion (10B) of the refrigerant pipe (10) and the straight portion (31) of the ventilation path (30) are arranged adjacent to each other in parallel. (4). The cooling member (21) includes a first end surface (21B) and a second end surface (21C) facing each other,
The first end surface (21B) is formed with a first opening (33) that opens to the external space side,
The second end face (21C) is formed with a second opening (34) that opens to the external space side,
The mounting surface (21A) has a third opening (35) that opens toward the internal space (S) at an intermediate portion between the first end surface (21B) and the second end surface (21C). Formed,
The air passage (30) extends from the first opening (33) and the second opening (34) to the third opening (35) through the inside of the cooling member (21). The cooling device (4) according to any one of claims 1 to 3, wherein the cooling device (4) is formed as described above.   The cooling device (4) according to any one of claims 1 to 4, wherein the housing member (11) is connected to the cooling member (21) via a seal member (40).   The cooling device (4) according to any one of claims 1 to 5, wherein the cooling member (21) is made of a metal material.   An air conditioner (1) comprising the cooling device (4) according to any one of claims 1 to 6.

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