JP2008175069A - Electric compressor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric compressor with a built-in inverter enabling the efficient cooling of the inverter without increasing the size of a machine container and operable without impairing reliability and performance even under high temperatures and strong vibration with a direct-mounted engine or the like. <P>SOLUTION: This electric compressor comprises a casing body 3 incorporating a compression mechanism part 5 and a motor 4 driving the compression mechanism part 5; and an inverter case 22 incorporating the inverter 8 driving the motor 4 and made of a heat insulating material. A suction refrigerant is used as a main cooling means for cooling the heating part 19 of the inverter 8. The inner space of the inverter case 22 is cooled by the thermo-module 20 to suppress the promotion of the deterioration of the parts and circuits forming the inverter 8 by heat. Consequently, the performance and the reliability of the electric compressor can be enhanced. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electric compressor in which a compression mechanism unit and an electric motor that drives the compression mechanism unit are incorporated in a body container, and an inverter control device that controls driving (rotation) of the motor is provided in the body container. Is.

  As this type of electric compressor, there is known a structure in which a compressor unit including a compression mechanism unit and an electric motor and a storage unit of an inverter device for controlling the driving of the electric motor are partitioned in an airtight state and integrated as a single body container. (For example, refer to Patent Document 1).

  FIG. 4 is a longitudinal cross-sectional view of the electric compressor shown in Patent Document 1, in which the compression mechanism portion 113 is incorporated in a body container 112 that houses the electric motor 111, and further, the electric motor 111 is sandwiched between the compression mechanism portion 113. The lid body 115 that is located on the opposite side and accommodates the inverter control device 114 is provided so as to be partitioned from the airframe container 112 in an airtight state.

  The airframe container 112 and the lid body 115 are arranged coaxially and fastened with bolts or the like. Further, the inverter control device 114 is arranged such that the heat generating portion faces the compression mechanism portion 113.

  Therefore, the refrigerant sucked from the suction port 116 provided in the compression mechanism unit 113 is once guided to the passage 117 formed between the lid 115 and the compression mechanism unit 113, and the inverter device 114 After exchanging heat with the heat generating portion, the air is sucked into the compression mechanism portion 113.

Further, the refrigerant gas compressed by the compression mechanism unit 113 cools the electric motor 111 and is then discharged from the discharge port 118 provided in the body container 112.
JP 2004-183631 A

  However, since the structure described in Patent Document 1 is a structure that cools the highly heat-generating parts of the inverter control device 114 only by the sucked refrigerant, the compressor is operated at low speed, that is, when the refrigerant circulation amount is small, or the load When the intake refrigerant temperature becomes high due to fluctuations or the like, sufficient heat exchange cannot be performed, and the heat generating parts of the inverter control device 114 may be insufficiently cooled, which may greatly affect performance and reliability.

  Further, when the compressor is used as an air conditioner for an automobile and directly attached to the engine, the temperature inside the compressor rises abnormally due to heat conduction heating from the engine, and the compressor is stopped. Even in such a case, the inverter component is heated by the heat conduction from the engine, and the heating includes a factor that accelerates the deterioration of the component.

  As described above, the environment in which the compressor is mounted on the engine may exceed 100 ° C., and it is in a state where it is exposed to a considerably high temperature even in a parking state under hot weather.

  Further, even in an air conditioner for a living room such as an electric vehicle or a room air conditioner, the inverter control device 114 is exposed to the same environment and similarly includes a factor that accelerates deterioration of components due to heat.

  Therefore, the reliability conditions required for the inverter parts are considerably severe, and the cooling technique disclosed in Patent Document 1 has a limit in suppressing the deterioration of the inverter parts, and particularly in the case of a compressor mounted on a vehicle. However, because of the cooling of the inverter components, there are many restrictions on the mounting position and direction of the compressor, and some improvement measures such as increasing the degree of design freedom have been required.

  Furthermore, the cooling of the inverter control device 114 is required regardless of whether or not the engine is mounted because it has a characteristic of generating heat during operation.

  An object of the present invention is to provide an electric compressor that can efficiently cool an inverter control device without increasing the size of a fuselage container.

  In order to solve the above-mentioned conventional problems, the present invention cools an inverter control device by utilizing a cooling effect of a thermo module (also referred to as a Peltier element or a Peltier module).

  More specifically, an inverter case with a built-in inverter control device for driving and controlling the motor is assembled in a fuselage container containing a compression mechanism for sucking, compressing and discharging refrigerant and an electric motor for driving the compression mechanism. In the built-in electric compressor, as the cooling means for cooling the heat generating part (heat generating part) of the inverter control device, the heat transfer means for transmitting the intake refrigerant temperature to the heat generating part, and the thermo module for cooling the internal space of the inverter case Are arranged in the inverter case.

  Thereby, the heat generating part in the inverter control device can be cooled by a combination of cooling using the suction refrigerant temperature and cooling using the cooling action of the thermo module.

  Moreover, by comprising the said inverter case with a heat insulating material, it can also suppress that the temperature in an inverter case receives the influence of external heat, and can suppress the increase in the thermal load of the said thermomodule.

  In the electric compressor of the present invention, the inverter control device that controls the rotation and driving of the electric motor can be cooled (including suppression of temperature rise) by the temperature of the return refrigerant and the cooling action of the internal space of the inverter case by the thermo module. it can.

  Therefore, it is possible to increase the cooling efficiency of the inverter control device when the compressor is stopped or when the compressor is rotating at a low speed, and deterioration of the inverter components can be suppressed. In addition, when the electric compressor is directly mounted on an engine such as a hybrid vehicle, the electric compressor is exposed to a severe environment such as heating and vibration from the engine. Thus, the electric compressor can be operated without impairing the performance and reliability.

  In particular, by configuring the inverter case with a heat insulating material, heat transfer inside and outside the inverter case can be suppressed, and as a result, the cooling effect of the internal space of the inverter case can be affected by external heat. As a result, the thermo module can be operated efficiently.

  The invention according to claim 1 is formed of a compression mechanism section that sucks, compresses, and discharges refrigerant, a casing that includes the compression mechanism section and a motor that drives the compression mechanism section, and a heat insulating material. An inverter case having a built-in inverter control device for driving and an electric compressor using a suction refrigerant temperature as a cooling means for a heat generating part of the inverter control device, comprising a heat radiation surface and a heat absorption surface, and cooling the inside of the inverter case A thermo module is provided.

  With this configuration, the heat generating part in the inverter control device is cooled by using the cold heat of the suction refrigerant (return refrigerant) of the compression mechanism part, and in addition, the heat absorption action of the thermo module adds to the inside of the inverter case. Is cooled (including suppression of temperature rise), the inverter control device can be cooled, and acceleration of deterioration of the inverter components can be suppressed.

  Further, since the inverter case is made of a heat insulating material, heat transfer inside and outside the inverter case can be suppressed, and as a result, heat around the electric compressor or heat from the heat radiation surface of the thermo module can be suppressed. It is possible to suppress the conduction of heat from the inverter case to the space inside the inverter case and hinder the cooling action of the thermo module, and it is possible to suppress unnecessary heat exchange loss and reduce the cooling inside the inverter case. Efficiency can be increased.

  According to a second aspect of the present invention, the casing has an opening on one side, the casing main body containing the compression mechanism and the electric motor inside, the one side closed, and the refrigerant sucked in the compression mechanism at the time of closing. A structure comprising a lid made of a heat conductive material forming a passage, the heat generating portion of the inverter control device is attached to a surface cooled by the suction refrigerant in the lid, and the inverter case is mounted. And attached to at least one of the casing body or the lid.

  By adopting such a configuration, it is possible to perform dustproofing and waterproofing in the inverter case, and the heat generating part of the inverter control device exchanges heat with the sucked refrigerant through the wall surface of the lid body. The acceleration of deterioration of the inverter components can be suppressed by heat exchange (cooling action).

  According to a third aspect of the present invention, the heat dissipating surface of the thermo module faces the outside of the inverter case, and the heat absorbing surface of the thermo module faces the inside of the inverter case.

  With this configuration, the heat absorption action of the thermo module is performed in the space inside the inverter case, and the heat radiation action is performed in the external space of the inverter case. Therefore, the heat absorption action and the heat radiation action of the thermo module can be balanced, and the thermo module Can improve the operation efficiency.

  Furthermore, the inverter control device can be cooled by radiant cooling heat due to the endothermic action of the thermo module, and acceleration of deterioration of the inverter components can be suppressed.

  According to a fourth aspect of the present invention, an enlarged heat transfer surface forming means for enlarging a heat transfer area of the heat dissipation surface or the heat absorption surface is provided in close contact with at least one of the heat dissipation surface and the heat absorption surface of the thermo module. is there.

  By adopting such a configuration, it is possible to amplify the heat absorption effect or heat dissipation effect by the thermo module, and to increase the heat conversion efficiency of the thermo module.

  According to a fifth aspect of the present invention, the inverter case is provided with an elastic body that urges the enlarged heat transfer surface forming means in a direction to come into close contact with the thermo module by an elastic force.

  With this configuration, the thermo module can be fixed by the urging force of the elastic body. As a result, stress or thermal stress associated with vibration of the compressor acts on the inverter case or the thermo module itself. Further, the stress can be absorbed by the elastic force of the elastic body, and the thermo module can be prevented from being damaged.

  In addition, even if the inverter case is slightly distorted due to thermal expansion / contraction, etc., it is possible to maintain contact with the thermo module, and as a result, the heat absorption and heat dissipation of the thermo module can be maintained. Can be continued.

  According to a sixth aspect of the present invention, the thermo module is positioned above the inverter device.

  With this configuration, the cooling heat from the thermo module convects downward, and the inverter control device can be cooled by the cooling heat. Moreover, the thermomodule and the inverter control device can be cooled by radiant cooling heat from the thermomodule (enlarged heat transfer surface forming means) by adopting a positional relationship in which part of the projection surface overlaps.

  According to a seventh aspect of the present invention, the inverter case is provided with ventilation means for communicating the inside and outside of the inverter.

  By adopting such a configuration, it is possible to prevent heat accumulation in the inverter case, and to efficiently cool the inverter control device.

  According to an eighth aspect of the present invention, the ventilation means includes at least an intake port and an exhaust port provided in the inverter case, and a space in the inverter case.

  By setting it as this structure, the flow of the air in an inverter case can be formed and the heat accumulation in an inverter case can be suppressed.

  According to a ninth aspect of the present invention, at least one of the intake port and the exhaust port is provided at a position higher than the thermo module.

  By adopting such a configuration, high temperature warm air can be exhausted from a high place, hot air escapes smoothly in the inverter case, and relatively low temperature cooling air easily convects downward, The cooling action can be performed efficiently.

  According to a tenth aspect of the present invention, a through hole is provided in a wall surface of the inverter case, the thermo module is disposed in the through hole, and a fixture for fixing the thermo module to the inverter case is provided.

  By adopting such a configuration, the side surface of the thermo module is surrounded by a heat insulating material. As a result, a short circuit of heat transfer between the heat absorption side and the heat dissipation side of the thermo module can be prevented, and the thermo module is in a normal state. And can be operated efficiently.

  According to an eleventh aspect of the present invention, the elastic body is interposed between the heat sink and the fixture.

  With this configuration, the thermo module can be fixed by the fixing tool and the elastic body and the above-described stress protection can be performed, and the reliability of the cooling action can be improved.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 is a front view in which a part of the electric compressor in Embodiment 1 of the present invention is cut away. In the first embodiment, a case of a horizontal electric compressor installed sideways by a mounting leg 2 around a body portion of the electric compressor 1 is shown as an example. FIG. 2 is a cross-sectional perspective view of the mounting portion of the inverter control device 8 in the electric compressor 1.

  In FIG. 1, an electric compressor 1 is formed in a bottomed cylindrical shape having one end opened, and is made of a metal casing main body 3 provided with a plurality of mounting legs 2 at appropriate positions on the outer periphery, and the casing main body 3. An electric motor (DC brushless motor) 4 having a stator and a rotor, and a compression mechanism portion 5 fitted or press-fitted into the casing body 3 are main components. The rotating shaft 6 of the electric motor 4 is composed of the compression mechanism portion 5. A drive shaft is configured.

  And the opening edge part by the side of the compression mechanism part 5 in the casing main body 3 is obstruct | occluded with the cover body 7 made from metal (aluminum die-casting etc.), and is making the inside of the casing main body 3 into the sealing state.

  The electric motor 4 is driven and its rotational speed is controlled by an inverter control device (hereinafter referred to as an inverter) 8 incorporated in the lid body 7. In the electric compressor 1, the refrigerant to be handled is a gas refrigerant, and lubricating oil is employed as a liquid for lubrication of each sliding portion, sealing of the sliding portion in the compression mechanism portion 5, and lubrication.

  The compression mechanism unit 5 of the electric compressor 1 according to the first embodiment is of a scroll type and has a well-known configuration, and returns from an external cycle due to the volume change of the compression space 9 formed in the compression mechanism unit 5. The return refrigerant 10 is sucked into the suction side of the compression mechanism portion 5 from the suction port 11 provided in the lid body 7 and compressed in the compression space 9 as described above, and then from the discharge hole 12 located at the approximate center of the compression space 9. It discharges in the casing main body 3 via the channel | path 12a, and discharges to an external cycle (not shown) from the discharge outlet 13 provided in the casing main body 3.

  Since the above-described configuration of the compression mechanism 5 and the electric motor 4 in the casing body 3 may be a known configuration, a detailed description thereof will be omitted.

  On the other hand, the lid body 7 fitted with good sealing performance on the opening side of the casing body 3 via a sealing member 14 such as an O-ring is fixed to the casing body 3 by appropriate means (not shown) such as bolting. The compression mechanism 5 (fixed scroll) is in contact.

  Further, the lid body 7 is hermetically combined with the compression mechanism 5 (fixed end plate of the fixed scroll) by a partition member 7a provided on the inner surface thereof and a seal member 15 such as an O-ring provided on the tip thereof, and is connected to the suction port 11 A closed space leading to the suction side of the compression mechanism 5 is configured to form a suction passage 16.

  In addition, the space of the discharge hole 12 of the compression mechanism 5 is located in a part of the space of the suction passage 16 via the partition wall 17.

  The inverter 8 is disposed on the end wall 7b of the lid 7 on the opposite surface (outside) of the suction passage 16, and includes an electronic component such as a circuit board 18 and an electrolytic capacitor (not shown).

  The heat generating portion 19 of the inverter 8 is in contact with the end wall 7 b of the lid body 7 and also serves as a heat sink portion of the inverter 8. Here, the heat sink part is formed with the thickness of the end wall 7b, and is referred to in order to define the close contact position with the heat generating part 19 in the inverter 8, and is particularly thick in order to increase the heat capacity. Processing such as increasing the thickness is not performed.

  Furthermore, an inverter case 22 that closes the inverter 8, the circuit board 18, and the like is attached to the lid body 7 with bolts 23. The inverter case 22 is formed of a well-known material having heat insulation and heat resistance, preferably water resistance, such as ceramic resin, styrene resin, polyimide resin, and forms a dustproof / waterproof structure for the inverter 8 and the circuit board 18. To do.

  The inverter case 22 is formed in a dish shape, and a through hole (not shown) is provided in a surface corresponding to the bottom surface. A thermostat that cools the internal space 24 formed with the lid body 7 in the through hole. A module 20 is attached. Here, “cooling” will be described as meaning that, in addition to lowering the temperature of the internal space 24, it also means suppressing the temperature rise of the internal space 24.

  As is well known, the thermo module 20 is also referred to as a Peltier element or a Peltier module. For example, a thermoelectric element is formed on a substrate of an electrically insulating material having thermal conductivity, such as a substrate in which a thermally conductive material is mixed in a ceramic material. Are arranged such that current flows in series, and heat is generated on one surface and heat is absorbed on the other surface due to the Peltier effect by energization.

  The thermo module 20 is disposed such that the heat dissipation surface faces the outer surface of the inverter case 22 and the heat absorption surface faces the internal space 24.

  The heat absorbing surface and the heat radiating surface are made of aluminum metal or the like as is well known, and enlarged heat transfer surface forming means (hereinafter referred to as heat sinks) 25 and 28 for amplifying the heat absorbing action are provided in close contact with each other. . The heat sinks 25 and 28 are provided with fins 25a and 28a that increase the surface area.

  The thermo module 20 and the heat sinks 25 and 28 are fixed via elastic bodies 27 and 29 by a fixture 26 attached to the inner and outer surfaces of the inverter case 22 by appropriate means.

  Therefore, the thermo module 20 and the heat sink 25 are fixed in a state of being sandwiched between the opposing fixtures 26 by the urging force of the elastic bodies 27 and 29. In this configuration, if necessary, the close contact surfaces of the thermo module 20 and the heat sink 25 can be brought into close contact with each other through a heat conductive grease or the like.

  As described above, when the pressing and fixing of the thermo module 20 is taken into consideration, the elastic body 27 is not pressed by a point, but is pressed by a surface, for example, a shape along the peripheral shape of the heat sink 25 and the peripheral edge of the heat sink 25. It is preferable to use a coil-shaped spring material that presses down or an annular spring material that is formed in a corrugated shape so as to press the periphery of the heat sink 25. Further, if the influence (leakage etc.) on the thermo module 20 due to rain water or the like is taken into consideration, at least the elastic body 29 on the heat radiating surface side has a predetermined vibration absorbing function such as a heat-resistant rubber material, and a waterproof structure is easy to take. It is preferable to use a material.

  For example, in the case of an electric compressor mounted as a vehicle air conditioner, the pressing and fixing of the thermo module 20 by the elastic body 27 can absorb vibration from the vehicle, vibration from the engine, or the like by the elastic body 27. As a result, the thermomodule 20 is a particularly useful mounting structure as a vibration shock countermeasure for preventing damage due to vibration shock of an electrical insulator substrate mainly having a ceramic material and having thermal conductivity.

  Furthermore, since the side surface (surface between the heat absorption surface and the heat dissipation surface) of the thermo module 20 faces the plate pressure surface of the through hole in the inverter case 22, direct heat transfer is performed between the heat absorption surface and the heat dissipation surface of the thermo module 20. The thermo module 20 can be operated as rated or approached.

  Further, the thermo module 20 is arranged at a higher position than the inverter 8 so that the cooling heat (cooling air) from the thermo module 20 (heat sink 25) is lowered to cool the inverter 8 efficiently.

  Further, as shown in FIG. 1, the thermo module 20 and the inverter 8 are arranged so as to partially overlap in the projection direction (the axial direction of the compressor), so that the inverter is also generated by the radiant cooling heat from the thermo module 20 (heat sink 25). 8 can be cooled.

  Each heat sink 25, 28 is provided with a large number of radiating fins 25a, 28a so as to increase the surface area. This amplifies the heat exchange effects of heat absorption and heat dissipation in the thermo module 20 so that the heat absorption and heat dissipation balance of the thermo module 20 can be maintained as much as possible.

  Further, the inverter case 22 is provided with an intake port 30 and an exhaust port 31 communicating with the internal space 24 and the outside at different positions to form a ventilation passage in the inverter case 22 including the internal space 24. Here, the intake port 30 and the exhaust port 31 positioned higher than the intake port 30 are uniquely defined from the characteristics that cool air having a low temperature falls and hot air having a high temperature rises. For example, depending on changes in the surrounding environment in the electric compressor 1, such as when strong wind blows on the electric compressor 1, intake and exhaust may be performed in reverse. In addition, a known film body that allows air permeation and rejects moisture permeation may be provided in the intake port 30 and the exhaust port 31 as necessary.

  As shown in FIG. 2, the circuit board 18 is provided with a well-known IPM (intelligent power module) 18a including a switching element having a high heat generation, a control circuit unit 18b mainly composed of a microcomputer, and the like. Is configured. Furthermore, by fixing the circuit board 18 to the boss portion 7c provided at an appropriate location of the lid body 7 with the bolt 21, the heat generating portion (heat sink) 19 of the IPM 18a is in thermal contact with the end wall 7b. . If necessary, the close contact surface of the heat generating portion 19 with the end wall 7b can be brought into close contact with the heat conducting grease or the like in the same manner as the thermo module 20.

  In addition to the control circuit of the electric motor 4, a module control board 20 b provided with a circuit 20 a for controlling energization of the thermo module 20 is also provided on the circuit board 18 in parallel. Similar to the circuit board 18, the module control board 20 b is bolted to a boss portion (not shown) formed at an appropriate location of the lid body 7.

  The control circuit unit 18b and the module control board 20b mounted on the circuit board 18 may be heat resistant according to the environment where the electric compressor 1 is installed.

  Further, the lid body 7 is provided with a connection chamber 32 positioned alongside the suction passage 16 with the partition wall 7 a interposed therebetween. The connection chamber 32 is connected to the harness connector connected to the motor 4 and the inverter 8. A compressor terminal connection 33 is provided. Since the harness connector and the compressor terminal are electrically connected, the inverter 8 and the electric motor 4 are electrically connected via these.

  As is well known, the drive (rotation) control of the electric motor 4 by the inverter 8 is performed by monitoring loads such as the air-conditioning room temperature and the refrigerant temperature by a detection means (not shown), and by a load signal and a control signal based on the results, The rotation of the electric motor 4 is controlled at a frequency of. Since the specific control contents of the electric motor 4 are not directly related to the gist of the present invention, the description thereof is omitted here.

  Next, the operation of the electric compressor 1 having the above configuration will be described.

  When the electric motor 4 is rotated by the start control of the inverter 8, the rotation shaft (drive shaft) 6 is also rotated along with this, and the compression mechanism unit 5 is driven via the rotation shaft 6.

  Therefore, the compression mechanism unit 5 sucks the return refrigerant from the refrigeration cycle (not shown) having a known configuration through the suction port 11 provided in the lid body 7.

  The sucked low-temperature return refrigerant 10 cools the end wall 7b in the space of the intake refrigerant passage 16, and further exchanges heat with the heat generating part 19 of the inverter 8 that is in close contact with the end wall 7b. While cooling, it flows into the compression space 9 through a passage hole (not shown) of the compression mechanism 5.

  The refrigerant flowing into the compression space 9 is compressed by the volume reduction movement of the compression space 9 accompanying the circular orbit movement of the compression mechanism 5, and is discharged from the discharge hole 12 communicating with the final compression space.

  The refrigerant discharged from the discharge hole 12 enters the electric motor 4 side through the passage 12a provided in the outer peripheral portion of the compression mechanism 5, and is discharged from the discharge port 13 of the casing body 3 while cooling the electric motor 4, and the refrigeration cycle. It flows to.

  By continuing the flow of the refrigerant, the inverter 8 generates heat from the heat generating portion 19 along with the continuous rotation control of the electric motor 4. As described above, the heat generating portion is generated by heat exchange at the end wall 7 b by the return refrigerant 10. Since 19 is cooled, the temperature rise is suppressed.

  Further, the air in the internal space 24 of the inverter case 22 due to the heat generated by the inverter 8 is exhausted from the exhaust port 31 by its natural convection, as indicated by the arrow, because the exhaust port 31 is provided above, and the external air However, the air flows into the internal space 24 from the intake port 30, and the accumulation of hot air in the internal space 24 is suppressed by these flows.

  Although suppression of the temperature rise of the inverter 8 can be expected to have a certain effect in the rotation range of the electric compressor 1, the return refrigerant 10 is returned when the refrigerant circulation amount decreases in the low rotation range or when the refrigeration cycle load fluctuates. When the temperature rises, the effect cannot be expected only by the cooling action at the end wall 7b described above, and the inverter 8 may become unnecessarily high.

  In particular, if the electric compressor 1 is used for a vehicle, the compressor may be exposed to a temperature of 100 ° C. or higher due to high radiant heat from the engine immediately after the vehicle stops.

Since the heating of the inverter 8 due to the high temperature accelerates the deterioration of the related parts, in the first embodiment, the temperature of the internal space 24 in the inverter case 22 needs to be quickly reduced. It is also necessary to control so that the temperature does not reach such a high temperature.

  In the first embodiment, by controlling the energization of the thermo module 20, the temperature of the internal space 24 of the inverter case 22 is absorbed by the heat absorption surface and the heat sink 25, and the electric compressor 1 via the heat sink 28 is absorbed by the heat dissipation surface. The heat is dissipated to the outside and the temperature rise in the internal space 24 of the inverter case 22 is suppressed.

  That is, as is well known, the thermo module 20 can control the heat absorption amount and the heat generation amount in proportion to the energization amount (current amount). By controlling the energization amount to an optimum value, the temperature rise of the inverter 8 can be controlled. In addition to the cooling by the return refrigerant temperature through the end wall 7b, it can be suppressed by the combination with the cooling action of the internal space 24 by the thermo module 20.

  In other words, the cooling of the inverter 8 according to the first embodiment is performed by electric compression because the inverter case 22 is made of a heat insulating material and the temperature of the environment (internal space 24) in which the inverter 8 is installed is controlled. As compared with the configuration in which the inverter 8 is directly cooled, the circuit components on the circuit board 18 constituting the control circuit of the inverter 8 are also cooled to accelerate the deterioration of the inverter components. Can be suppressed.

  Further, the inverter case 22 provides a dustproof / waterproof structure for the thermo module 20, the inverter 8, the circuit board 18, and the like. By attaching the heat sinks 25 and 28 to each of the surfaces, the heat absorbing action and the heat releasing action can be well balanced across the inverter case 22, and the thermo module 20 can be operated with high efficiency. As a result, the inverter 8 can be efficiently cooled, and acceleration of deterioration of the inverter components can be suppressed.

  In particular, the heat sinks 25 and 28 provided in the thermo module 20 are provided with a plurality of heat dissipating fins 25a and 28a on the outer surface thereof to improve the heat dissipating ability, so that the heat absorbing and releasing action in the thermo module 20 is balanced, The thermal conversion efficiency operation of the thermo module 20 can be increased and stabilized.

  Further, since the thermo module 20 overlaps the inverter 8 on the projection surface, the radiant cooling heat from the heat sink 25 also acts on the inverter 8 and can effectively cool the inverter 8.

  Further, since the intake case 30 and the exhaust port 31 are provided in the inverter case 22, heat accumulation in the inverter case 22 can be suppressed using natural convection of cold air and warm air, and the exhaust port 31 can be connected to the intake port. Since it is provided at a position higher than 30, it is easy to supply and exhaust air by natural convection of cold air and warm air. I can expect.

  Moreover, since the cool air by the thermo module 20 or the heat sink 25 descends and cools so as to wrap the inverter 8, a further cooling effect can be expected.

  Further, since the thermo module 20 is configured to be fixed between the fixtures 26 in a sandwiched state by the urging forces of the elastic bodies 27 and 29, the heat sinks 25 and 28 follow the thermal expansion and thermal contraction of the inverter case 22. As a result, the heat transfer action of the thermo module 20 can be continuously performed, and the internal space 24 of the inverter case 22 can be cooled stably.

  In particular, fixing of the thermo module 20 by the urging force of the elastic bodies 27 and 29 is effective not only for impact such as thermal stress but also for impact such as vibration. Therefore, the electric compressor 1 is mounted on a vehicle. The thermomodule 20 is not dropped or damaged by vibration.

  Further, since the periphery of the side surface of the thermo module 20 is insulated by an inverter case 22 made of a heat insulating material so that there is no short circuit of heat conduction between the heat absorbing surface and the heat radiating surface of the thermo module 20, Or it can be set as the heat transfer by the operation state close | similar to it, and the obstruction of cooling efficiency maintenance can be reduced.

  The module control board 20b, which is a control control unit of the thermo module 20, is arranged in parallel with the circuit board 18 for driving the electric motor 4 in the inverter case 22, so that the rotation signal and energization of the electric motor 4 necessary for control are provided. The power source is shared with the circuit board 18. As a result, the circuit configuration can be simplified, and the electric circuit system can be assembled from the same direction all at once, and the assembly workability can be improved.

  As described above, according to the first embodiment, in the conventional electric compressor 1 with a built-in inverter, the size and weight of the electric compressor 1 are substantially maintained by the addition of the small and light component called the thermo module 20. Thus, the auxiliary cooling of the inverter 8 is possible, and even when the electric compressor 1 is used for vehicle mounting, the mounting property to the vehicle is not impaired.

(Embodiment 2)
FIG. 3 is a longitudinal sectional view of an electric compressor provided with different fixing structures for the inverter case and the thermo module.

  Therefore, only the parts different from the first embodiment will be described here, the same constituent elements as those of the first embodiment will be denoted by the same reference numerals, and the description of the same operations and the like will be omitted.

  In the same figure, the point which is greatly different from the first embodiment is that a flange 35 is provided at the periphery of the through hole of the inverter case 34 to form a recess 35, and the thermo module 20 is sandwiched in the recess 35. The heat sinks 25 and 28 and the elastic bodies 27 and 29 are accommodated, a fixing tool 26 is provided on the opposite side of the inverter case 34, and the thermo module 22 and the heat sinks 25 and 28 are elastic between the flange of the recess 35 and the fixing tool 26. It is a point attached via the bodies 27 and 29.

  Then, the thermo module 20 and the heat sink 25 are fixed by being pressed by the urging forces of the elastic bodies 27 and 29 in the same manner as in the first embodiment.

  In such a configuration, the fixture 26 can be reduced, and the lid body 7, the inverter 8, the circuit board 18, the inverter case 34, and the thermo module 20 can be attached from the same direction, which improves the assembly workability. It can be expected.

  In the first and second embodiments, various modifications can be made in details such as the mounting of the thermo module (for example, the depth of the recess or mounting without using the recess), and the shape and structure of the inverter case. However, even such a structure does not depart from the present invention.

As described above, the electric compressor according to the present invention can improve the reliability of the electronic component by providing the cooling means for the space in which the inverter device is stored, as compared with the conventional electric compressor with a built-in inverter device. In addition, the assembling workability of the cooling means is easy, and can be widely applied to vehicles such as environmental vehicles such as hybrid vehicles as well as refrigeration and air conditioning systems for living rooms, and further, as a refrigeration system for storing articles Widely applicable.

The longitudinal cross-sectional view of the electric compressor in Embodiment 1 of this invention Cross-sectional perspective view of the mounting portion of the inverter control device for the electric compressor in the first embodiment The longitudinal cross-sectional view of the electric compressor in Embodiment 2 of this invention Vertical section of an electric compressor showing a conventional example

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electric compressor 3 Casing main body 4 Electric motor 5 Compression mechanism part 7 Cover body 7b End part wall 8 Inverter (inverter control apparatus)
16 Suction passage 18 Circuit board 19 Heat generating part 20 Thermo module 22 Inverter case 24 Internal space 25 Heat sink (enlarged heat transfer surface forming means)
26 Fixing device 27 Elastic body 28 Heat sink (enlarged heat transfer surface forming means)
29 Elastic body 30 Intake port 31 Exhaust port 34 Inverter case 35 Recess

Claims (11)

A compressor mechanism for sucking, compressing and discharging refrigerant; a casing having an electric motor for driving the compression mechanism; an inverter case formed of a heat insulating material and having an inverter control device for driving the electric motor; and the inverter An electric compressor using an intake refrigerant temperature as a cooling means of a heat generating part of a control device, wherein the electric compressor has a heat radiation surface and a heat absorption surface, and is provided with a thermo module for cooling the inside of the inverter case. The casing is made of a casing body that is open on one side and that houses the compression mechanism and the electric motor, and a thermally conductive material that closes the one side and forms a passage for suction refrigerant in the compression mechanism when closed. A heat generating portion of the inverter control device is attached to a surface of the cover that is cooled by the suction refrigerant so that heat can be transferred, and the inverter case is attached to the casing body or the cover. The electric compressor according to claim 1 attached to at least one. The electric compressor according to claim 1 or 2, wherein the heat dissipating surface of the thermo module faces the outside of the inverter case, and the heat absorbing surface of the thermo module faces the inside of the inverter case. The expansion heat transfer surface forming means for expanding the heat transfer surface or the heat transfer area of the heat absorption surface is provided in close contact with at least one of the heat dissipation surface and the heat absorption surface of the thermo module. The electric compressor as described. 5. The electric compressor according to claim 4, wherein the inverter case is provided with an elastic body that urges the enlarged heat transfer surface forming unit in an intimate contact direction with the thermo module by an elastic force. The electric compressor according to any one of claims 1 to 5, wherein the thermo module is positioned above the inverter device. The electric compressor according to any one of claims 1 to 6, wherein the inverter case is provided with ventilation means for communicating the inside and outside of the inverter. The electric compressor according to claim 7, wherein the ventilation means includes at least an intake port and an exhaust port provided in the inverter case, and an inner space of the inverter case. The electric compressor according to claim 8, wherein at least one of the intake port and the exhaust port is provided at a position higher than the thermo module. The through hole is provided in the wall surface of the said inverter case, the said thermo module is arrange | positioned in the said through hole, and the fixing tool which fixes the said thermo module to the said inverter case is provided. Electric compressor. The electric compressor according to claim 10, wherein the elastic body is interposed between the heat sink and the fixture.

Images