JP2006294918A - Inverter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain an inverter which prevents oil components contained in a heat conductive grease from dropping down out of the inverter. <P>SOLUTION: The inverter has a power module 1a having power converting elements packaged with a mold resin, etc. , and a radiation fin 2a for radiating heat from the power module 1a. Heat conductive grease 3 is applied between the power module 1a and the fin 2a to efficiently conduct the heat generated by the power module 1a to the radiation fin 2a. The fin 2a for mounting the power module 1a has a recess 20 in the surface at a lower side position as seen when the inverter is installed. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an inverter device having a structure in which a power module is attached to a heat radiating fin coated with heat transfer grease.

In general, a semiconductor element module applied to an inverter device for controlling a motor has a base surface attached to a mounting surface of a mounting base such as a cooling fin to facilitate heat dissipation.
In order to improve the heat dissipation capability by eliminating the gap between the base surface of the semiconductor element module and the mounting surface of the cooling fin, a silicon compound with good thermal conductivity is applied to the mounting surface of the cooling fin, and then the semiconductor element module is mounted. It was.
When attaching the semiconductor element module to the cooling fin and the amount of silicon compound applied is large, the silicon compound protrudes from the side surface of the semiconductor element module or cooling fin when the semiconductor element module is attached to the cooling fin. However, there is a problem that it is necessary to remove the protruding silicon compound. In addition, when the amount of silicon compound applied is small, there is a problem in that the heat dissipation capability decreases.

  Patent document 1 is made in order to solve the said subject, and has described the mounting base of the semiconductor element module which formed the groove | channel in the mounting base which has a mounting surface which attaches the base surface of a semiconductor element module.

JP 2004-14991 A

  The mounting table of the semiconductor element module described in Patent Document 1 described above can prevent the silicon compound from protruding when the semiconductor element module is mounted on the mounting table, and can apply an appropriate amount of the silicon compound. In order to improve the workability and improve the workability, when the oil contained in the heat transfer grease is separated due to aging or temperature change, the oil drips from the inverter device, and the floor surface becomes dirty. .

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an inverter device that can prevent oil contained in the heat transfer grease from dripping from the inverter device. .

  An inverter device according to the present invention includes a power module in which an element for converting electric power is packaged in a mold resin or the like, and a heat radiation fin for radiating heat generated from the power module, and the power module generates heat. In the inverter device in which heat transfer grease is applied between the power module and the heat radiating fin in order to efficiently conduct to the heat radiating fin, when the inverter device is installed on the power module mounting surface of the heat radiating fin. A recess is provided at a lower position.

  In the inverter device according to the present invention, since the concave portion is provided at the lower side of the mounting surface of the power module of the radiating fin when the inverter device is installed, the oil component separated from the heat transfer grease is stored in the concave portion. It is possible to prevent the oil component separated from the heat transfer grease from dripping from the inverter device due to aging or temperature change.

Embodiment 1 FIG.
1 is a diagram showing a configuration of an inverter device according to Embodiment 1 of the present invention.
In FIG. 1, 1a is a power module in which a switching element for converting electric power is packaged in a mold resin or the like, 2a is a radiating fin for radiating heat generated from the power module 1a, and 3 is a radiating fin 2a for generating heat from the power module 1a. The heat transfer grease 4 for efficiently transferring heat to the power module 4 is a screw for attaching to the power module 1a and the radiation fin 2a, and 20 is a recess provided at a lower position when the inverter device is installed.

Normally, the inverter device is installed with the installation upper side up and the installation lower side down as shown in FIG. Usually, the heat transfer grease 3 is sandwiched between the power module 1b and the heat radiating fins 2b and is viscous and does not sag downward.
However, the oil contained in the heat transfer grease gradually separates due to aging and temperature changes, and in the case of a very small amount of separation, it does not fall down and is slightly lost due to capillarity on the side of the radiating fin or power module. No special problems occur. However, if the separated oil content increases to some extent, it collects and hangs down. In this case, conventionally, the heat is transmitted through the heat dissipating fins and the power module as they are, and finally gathers down, and finally falls off the inverter device.

  In the inverter device according to Embodiment 1 of the present invention, since the recess 20 is provided at the lower side when the inverter device is installed on the mounting surface of the power module of the radiating fin, the heat transfer grease 3 The separated oil can be stored in the recess, and the oil separated from the heat transfer grease 3 due to aging or temperature change can be prevented from dripping from the inverter device.

Embodiment 2. FIG.
FIG. 2 is a diagram showing a configuration of an inverter device according to Embodiment 2 of the present invention. FIG. 3 is a diagram showing a groove 6 provided on the power module 1b side in the inverter device according to Embodiment 1 of the present invention.
2 and 3, 1b is a power module in which a switching element for converting electric power is packaged in a mold resin or the like, 2b is a heat radiation fin for radiating heat generated from the power module 1b, and 3 is heat generated by the power module 1b. Heat transfer grease for efficiently conducting heat to the heat dissipating fins 2b, 4 is a screw for mounting to the power module 1b and the heat dissipating fins 2b, and 5 is a heat dissipating fin side to block oil separated from the heat transfer grease. A groove 6 is provided on the power module side to block oil separated from the heat transfer grease.

As described above, in the inverter device according to Embodiment 2 of the present invention, the grooves 5 that connect the both side surfaces of the radiation fin 2b are provided on the mounting surface of the radiation fin 2b with the power module. The oil component separated from the heat transfer grease 3 can be stored in this groove, and the oil component separated from the heat transfer grease 3 due to aging and temperature change can be prevented from dripping from the inverter device. Moreover, the oil component which oozes out on the both side surfaces of the radiation fin 2b can also be stored in the groove.
Further, since the groove 6 is provided on the mounting surface of the power module 1b with the cooling fin 2b so as to be aligned with the heat radiating fin 2b, the groove 5 on the heat radiating fin side and the groove 6 on the power module side can The separated oil can be efficiently damped and the oil can be prevented from dripping out of the inverter device.
Moreover, the capacity | capacitance which stores the oil component isolate | separated from the grease 3 for heat transfer can be increased by connecting the groove | channel 5 and the recessed part 20. FIG.

Embodiment 3 FIG.
4 is a diagram showing a configuration of an inverter apparatus according to Embodiment 3 of the present invention. In FIG. FIG. 5 shows a groove 8 provided on the power module 1c side in the inverter device according to Embodiment 3 of the present invention.
4 and 5, 1c is a power module in which a switching element for converting electric power is packaged in a mold resin or the like, 2c is a heat radiating fin for radiating heat generated from the power module 1c, and 3 is heat generated by the power module 1c. Heat transfer grease for efficiently conducting heat to the heat dissipating fins 2c, 4 is a screw for attaching to the power module 1c and the heat dissipating fins 2b, and 7 is a heat dissipating fin side to block oil separated from the heat transfer grease. The groove 8 is a groove that is cut at both ends diagonally, and 8 is a groove that is provided on the power module side to block oil separated from the heat transfer grease, and is a groove that is cut at both ends diagonally. is there.

As described above, in the inverter device according to the third embodiment of the present invention, the grooves 7 that connect the both side surfaces of the radiating fin to the mounting surface of the radiating fin with the power module are formed on the radiating fin when the inverter device is installed. Since the groove on both sides is cut at both ends diagonally so as to be higher than the central part, the oil separated from the heat transfer grease 3 can be stored in this groove 7, and the secular change and temperature change Thus, the oil component separated from the heat transfer grease 3 can be prevented from dripping from the inverter device. In addition, oil that has oozed out on both side surfaces of the heat radiating fin 2c can be easily stored in the groove inside the inverter device.
Further, by providing the groove 8 on the mounting surface of the power module 1c with the heat radiating fin 2c at the position where it is combined with the heat radiating fin 2c, the groove 7 on the heat radiating fin side and the groove 8 on the power module side The separated oil can be efficiently damped and the oil can be prevented from dripping out of the inverter device.
Moreover, the capacity | capacitance which stores the oil component isolate | separated from the grease 3 for heat transfer can be increased by connecting the groove | channel 7 and the recessed part 20. FIG.

Embodiment 4 FIG.
6 is a diagram showing a configuration of an inverter apparatus according to Embodiment 4 of the present invention. In FIG. FIG. 7 shows a groove 10 provided on the power module 1d side in the inverter device according to Embodiment 4 of the present invention.
6 and 7, 1d is a power module in which a switching element for converting electric power is packaged in a mold resin or the like, 2d is a radiation fin for radiating heat generated from the power module 1d, and 3 is the heat generated by the power module 1d. Heat transfer grease for efficiently conducting heat to the heat dissipating fins 2d, 4 is a screw for attaching to the power module 1d and the heat dissipating fins 2d, and 9 is a heat dissipating fin side to block oil separated from the heat transfer grease. A groove formed in the shape of a V-shaped groove and a groove 10 formed on the power module side to block the oil separated from the heat transfer grease and formed in a V-shaped shape.

As described above, in the inverter device according to Embodiment 4 of the present invention, the groove 9 connecting the both side surfaces of the radiation fin to the mounting surface of the radiation fin with the power module is V-shaped. Therefore, the oil component separated from the heat transfer grease 3 due to aging and temperature change can be prevented from dripping from the inverter device. In addition, oil that has oozed out on both side surfaces of the heat radiating fin 2d can be easily stored in the groove inside the inverter device.
Further, by providing the groove 10 at a position where the power module 1d is attached to the radiation fin 2d on the mounting surface of the radiation fin 2d, the groove 9 on the radiation fin side and the groove 10 on the power module side allow the heat transfer grease 3 to The separated oil can be efficiently damped and the oil can be prevented from dripping out of the inverter device.
Moreover, the capacity | capacitance which stores the oil part isolate | separated from the grease 3 for heat transfer can be increased by connecting the groove | channel 9 and the recessed part 20. FIG.

  The inverter device of the present invention can be used stably for a long period of time because the oil separated from the heat transfer grease can be prevented from dripping out of the inverter device.

It is a figure which shows the structure of the inverter apparatus which concerns on Embodiment 1 of this invention. It is a figure which shows the structure of the inverter apparatus which concerns on Embodiment 2 of this invention. It is a figure which shows the groove | channel 6 provided in the power module 1b side in the inverter apparatus which concerns on Embodiment 2 of this invention. It is a figure which shows the structure of the inverter apparatus which concerns on Embodiment 3 of this invention. It is a figure which shows the groove | channel 8 provided in the power module 1c side in the inverter apparatus which concerns on Embodiment 3 of this invention. It is a figure which shows the structure of the inverter apparatus which concerns on Embodiment 4 of this invention. It is a figure which shows the groove | channel 8 provided in the power module 1d side in the inverter apparatus which concerns on Embodiment 4 of this invention.

Explanation of symbols

  1a, 1b, 1c, 1d power module, 2a, 2b, 2c, 2d radiating fin, 3 heat module for heat transfer to efficiently conduct heat to the radiating fins 2a, 2b, 2c Grease, 4 Screws for mounting to the power module 1a and the heat radiating fin 2a, 5 Groove provided on the heat radiating fin side to block the oil separated from the heat transfer grease, 6 Damping the oil separated from the heat transfer grease 7 Grooves provided on the power module side, 7 Grooves provided on the radiating fin side to block the oil separated from the heat transfer grease, and grooves formed on both ends obliquely, 8 Separated from the heat transfer grease A groove provided on the side of the power module to block the oil that has been cut. A groove provided on the side of the heat radiation fin to block the oil content, a groove cut into a V shape, and a groove provided on the power module side to block the oil content separated from the grease for heat transfer. A groove having a shape cut into 20, and a recess.

Claims (6)

In order to efficiently conduct heat generated by the power module to the heat radiating fin, including a power module in which a power conversion element is packaged in a mold resin or the like and a heat radiating fin for radiating heat generated from the power module. In an inverter device in which heat transfer grease is applied between the power module and the heat radiating fin,
An inverter device, wherein a concave portion is provided on a lower side of the mounting surface of the power module of the heat radiating fin when the inverter device is installed. In order to efficiently conduct heat generated by the power module to the heat radiating fin, including a power module in which a power conversion element is packaged in a mold resin or the like and a heat radiating fin for radiating heat generated from the power module. In an inverter device in which heat transfer grease is applied between the power module and the heat radiating fin,
An inverter device characterized in that a groove connecting both side surfaces of the heat radiating fin is provided at a lower position when the inverter device is installed on a mounting surface of the power module of the heat radiating fin. The inverter device according to claim 1, wherein a groove connecting both side surfaces of the heat radiating fin provided on a mounting surface of the heat radiating fin with the power module is connected to the concave portion. The grooves that connect the both side surfaces of the heat radiation fin to the mounting surface of the heat radiation fin with the power module are arranged so that the positions of the grooves on both side surfaces of the heat radiation fin are higher than the center when the inverter device is installed. The inverter device according to claim 2, wherein the inverter device has a shape cut obliquely. 5. The inverter device according to claim 2, wherein a groove that connects both side surfaces of the heat radiating fin to a mounting surface of the heat radiating fin with the power module is V-shaped. The inverter device according to any one of claims 2 to 5, wherein a groove is provided on a mounting surface of the power module with the radiating fin at a position where the radiating fin is combined.

Images