DE112009002720B4 - Electric compressor with integrated inverter - Google Patents

Abstract

An inverter integrated electric compressor having a built-in motor and having a motor drive circuit including an inverter installed in a containment space surrounded by a compressor case, characterized in that a crimping portion of a terminal of a lead wire connected to the inverter is combined with the inverter is molded in a resin introduced into the container space, and a gap that is open to the outside at the crimping portion is covered and sealed by a gap sealant in advance.

Description

TECHNICAL FIELD OF THE INVENTION

The present invention relates to an integrated inverter electric compressor in which a motor driver circuit including an inverter is mounted, and more particularly relates to an integrated inverter electric compressor in which the inverter section is covered with a urethane resin, etc. is shaped.

PRIOR ART OF THE INVENTION

As a structure of an integrated compressor electric compressor in which a motor driver circuit including an inverter is mounted, a structure is known in which a motor driver circuit is covered with a resin molding material for insulation so as to be embedded in the resin molding material (e.g., patent document 1). A lead wire for supplying high voltage to the inverter section in such a compressor is connected by a high voltage connector (an HV connector) having a solderless terminal, for example, by a screw connection on a circuit board for the inverter section.

Patent Document 2 shows a connector for an electric machine, the connector having terminals that are connected at one end to brushes of a motor. The connectors are crimped and soldered with supply wires to provide a tight connection between the connectors and the wires.

Patent Document 3 shows a connection structure between a thin wire and a connection on a carrier material, a metal plate being crimped onto the thin wire to enlarge the connection area, which is soldered to the connection.

PRIOR ART DOCUMENTS

Patent documents

• Patent document 1: JP 2002-70743 A
• Patent document 2: US 5,304,880 A
• Patent document 3: JP 2007-335260 A

SUMMARY OF THE INVENTION

Problems to be Solved by the Invention

In an electric compressor with an integrated inverter shown in Patent Document 1, a space for accommodating a motor driver circuit is filled with a molding material such as urethane resin, etc., to protect parts forming the inverter section, etc. from heat and vibration. However, when the molding material flows into a gap around a lead wire at a crimp portion of the HV connector during the filling operation because the molding material repeats expansion and contraction due to the temperature change of the HV connector, which accompanies a fluctuation in the operating condition of the compressor there is a fear that connection reliability of the crimp portion of the HV connector may be reduced.

Accordingly, it is an object of the present invention to provide an electric compressor with an integrated inverter in which an inverter section is molded by a urethane resin, etc., and which is excellent in connection reliability of an electrically connected section.

Means to solve the problems

In order to solve the problems described above, an integrated inverter electric compressor according to the present invention has a built-in motor and is provided with a motor driver circuit including an inverter installed in a container space surrounded by a compressor housing, and is characterized in that a crimp portion of a terminal of a lead wire connected to the inverter is molded together with the inverter in a resin that is introduced into the container space, and a gap that is open to the outside on the crimp portion by a gap sealant is covered and sealed in advance.

In the electric compressor with integrated inverter according to the present invention, the molding material is prevented from flowing into an inner gap of the crimp section, and therefore the connection reliability of the crimp section is secured because the crimp section together with the inverter in a state where a gap , which is open to the outside at the crimp section of the connection of the connecting wire connected to the inverter, is covered and sealed by a gap sealant. As the gap sealant described above, it is preferable to use a material whose degree of expansion or contraction caused by a temperature change of an HV connector is small. By using such a material, it becomes possible to obtain an adequate one Ensure connection reliability of the crimp section described above.

Further, it is preferable to effectively cover and seal the inside of the above-described open gap using the above-described gap sealant, such as using a material for the gap sealant that may temporarily show a liquefied state by heating, etc., and through Cooling, etc., can be solidified. Specifically, a gap sealant consisting of a solder can preferably be used. For example, by creating a state in which a solder is temporarily liquefied by a heated soldering iron and by introducing the solder in the state into the open gap, and by solidifying the solder by natural or forced cooling, covering and sealing the Gap that is open to the outside on the crimp portion can be effectively performed.

Further, in the present invention, although even the inside of the open gap is covered and sealed when a cross-sectional portion of a tip of the lead wire is exposed, there is a fear that a molding material adhering to an irregular part of the cross-sectional portion of the tip will expand and Contraction is repeated, whereby a voltage can be applied to the tip of the lead wire, and the connection reliability of the crimp portion can be reduced. Therefore, it is preferable that the cross-sectional portion of the tip of the lead wire is covered with the gap sealing material, so that the irregular part of the cross-sectional portion of the tip of the lead wire is smoothed.

The integrated inverter electric compressor according to the present invention can be applied to basically any type of compressor, and in particular, it may be suitable to be used as a compressor that is mounted in a vehicle that is often installed in a narrow space and the motor driver circuit is susceptible to being affected by heat and vibration.

Effect according to the invention

In the electric compressor with integrated inverter according to the present invention, since the container space surrounded by the compressor housing is together with the inverter in a state in which the gap that is at the crimp portion of the terminal of the lead wire connected to the inverter is increased is open on the outside, is covered in advance by the gap sealant, is molded, the molding material is prevented from flowing into the crimp portion of the terminal of the lead wire connected to the inverter, and therefore it is possible to ensure the connection stability and connection reliability of the crimp portion .

Figure list

• 1 FIG. 12 is a schematic vertical sectional view showing a basic configuration of an integrated inverter electric compressor according to an embodiment of the present invention.
• 2nd FIG. 12 is a diagram of a configuration that includes a control mechanism of an air conditioning system incorporating a 1 shown compressor from the perspective of the electrical circuit shows.
• 3rd FIG. 14 is a perspective view showing a state in which a motor driver circuit is installed in a container room separated from one in FIG 1 front housing shown is surrounded.
• 4th represents a crimp section that includes an HV connector and an in 3rd connects the lead wire shown, wherein (A) is a perspective view showing an uncovered state of the portion, and (B) is a perspective view showing an uncovered state of the portion.

EMBODIMENTS FOR CARRYING OUT THE INVENTION

Desired embodiments of the present invention are described below with reference to figures.

1 FIG. 12 shows an example of an electric compressor with an integrated inverter of a spiral type for a vehicle air conditioning system as a basic configuration of an electric compressor 1 with integrated inverter according to an embodiment of the present invention. In 1 shows symbol 2nd a compression mechanism that has a fixed spiral 3rd and a movable spiral 4th having. The moving spiral 4th becomes relative to the attached spiral 3rd in a state in which the rotation by a bobbin joint 5 is prevented from moving orbitally. An engine 7 is in a compressor housing 6 (central housing) added, and a main shaft 8th (Rotation axis) is due to the built-in motor 7 driven to be rotated. The rotation of the main shaft 8th is through an eccentric pin 9 that is at one end of the main shaft 9 is provided, and an eccentric socket 10th which is rotatably engaged therewith in an orbital movement of the movable spiral 4th transformed. In this embodiment there is a suction opening 11 that draws a refrigerant as a fluid to be compressed in a compressor housing 12th (front housing) is provided, and the refrigerant sucked in by a motor 7 arranged section to the compression mechanism 2nd passed, and the refrigerant through the compression mechanism 2nd has been compressed through a discharge hole 13 , an exhaust chamber 14 and an exhaust port 16 that are in the compressor housing 15 (rear housing) is provided to an external circuit.

A motor driver circuit 21 for the engine 7 is in the compressor housing 12th (front housing) is provided, and more precisely, the motor driver circuit 21 on the side of the outer surface of a partition 22 that are in the compressor housing 12th is formed to separate from the side of the refrigerant intake section. The motor driver circuit 21 delivers electrical energy via a sealed connection 23 (Output connection of the motor driver circuit 21 ) by the partition 22 is attached, and a connecting wire 24th to the engine 7 , and the side of the refrigerant suction path and the side of a section in which the motor driver circuit 21 are placed towards each other at a section that is the sealed connector 23 placed, separated from each other. By providing the motor driver circuit 21 on the side of the outer surface of the partition 22 can be at least part of the electrical parts including the motor driver circuit 21 Heat through the partition 22 exchange with the drawn-in refrigerant so as to be cooled by the drawn-in refrigerant.

The motor driver circuit 21 contains an IPM 25th (Intelligent Power Module), which has an inverter function and a control circuit 26 with electrical parts, such as a capacitor 27 , etc., is provided separately or connected in one piece. This motor driver circuit 21 is with an external power source (not shown) through a connector 28 connected as an input port. The side that faces the outside of the compressor housing 12th in which the electrical parts including the motor driver circuit 21 are mounted, is open, is by a cover element 29 covered in a sealed state, and these electrical parts are covered by the cover member 29 protected.

From the point of view of an electrical circuit, the configuration described above can, for example, as in 2nd shown. In 2nd is the electric compressor 1 with the motor driver circuit 21 provided, and by supplying an output of the motor driver circuit 21 through the sealed connection 23 and the connecting wire 24th to respective motor coils 47 of the built-in motor 7 becomes the engine 7 rotationally driven, and compression is achieved through the compression mechanism 2nd carried out. The motor driver circuit 21 has a high voltage circuit for a drive motor 30th and a low voltage circuit for a controller 45 using a motor control circuit 44 to control respective performance elements 43 (Switching elements) of the inverter 42 in the high voltage circuit for the drive motor 30th is provided, and this low voltage control circuit 45 is like in 1 shown in the control circuit 26 configured.

Energy from an external energy source 46 (eg a battery) is through a high voltage connector 47 to the high voltage circuit for the drive motor 30th delivered, and is through a noise filter 37 and a smoothing capacitor 27 to the inverter 42 delivered, and after the DC voltage from the energy source 46 through the inverter 42 is converted into a pseudo three-phase AC voltage, the energy becomes the motor 7 headed. The engine control circuit 44 is with low voltage energy, for example from an air conditioning control unit for vehicles 48 , through a connector for a control signal 49 provided. Although this connector for the control signal 49 and the connector for high voltage 47 in 2nd are shown at positions that are separate from each other, both of the connectors are actually within the same one, in 1 shown connector 28 Installed. A shielding plate 31 is on the control circuit 26 attached, and, as in 2nd shown is this shield plate 31 between the high voltage circuit for driving the motors 30th and the control circuit 26 that with the low voltage circuit for control 45 is provided, pushed, and covers the high voltage circuit for the drive motor 30th over a range that is as wide as possible to have an influence of noise from the high voltage circuit side for the drive motor 30th to the side of the low voltage control circuit 45 to suppress.

3rd is a perspective view showing the motor driver circuit 21 that are in a container room 60 by the compressor housing 12th (front housing) is surrounded, shows. An insert element 58 and the IPM 25th are in the container room 60 kept. There is also a connector for high voltage 47 , which consists of a solderless connection, with the tip of the connecting wire 24th connected by crimping. The connector for high voltage 47 is by a screw on the insert element 58 attached, and is electrical between the capacitor 27 and the noise filter 37 that on the rear surface of the insert element 58 are mounted, connected.

4th represents a crimp section which is the connector for high voltage 47 with the in 3rd shown connecting wire 24th connects, wherein (A) is a perspective view illustrating a state in which the crimp portion is not covered, and (B) is a perspective view illustrating a state in which the crimp portion is covered with the solder. In 4 (A) is the connector for high voltage 47 with the connecting wire 24th crimped connected. In the crimp section 61 form a plurality of connecting wires through a cover of the lead wire 24th are bundled, a gap to the outside 63 is open, and if a molding material consisting of urethane resin, etc., in this open gap 63 occurs, the connection reliability of the crimp section 61 reduced. Therefore, as in 4 (B) shown by shaping the container space 60 together with the inverter 42 through flowing solder 64 as a gap sealant in the open gap 63 and storing the molding material in the in 3rd shown container space 60 , the molding material can be prevented from entering the crimping section 61 to flow. In particular, it is as in 4 (B) shown by completely covering the cross-sectional portion of the tip of the lead wire 62 with the solder 64 possible, the connection reliability of the crimp section 61 ensure sufficiently, even if molding material adheres to this section.

INDUSTRIAL APPLICABILITY OF THE INVENTION

The electric compressor with integrated inverter according to the present invention can be applied to substantially all types of compressors, and is particularly suitable for a compressor that is mounted in a vehicle that is often installed in a narrow space and with one Motor driver circuit is provided, which is susceptible to being affected by heat and vibration.

Reference list

1:

electric compressor with integrated inverter

2:

Compression mechanism

3:

attached spiral

4:

movable spiral

5:

Lace connection

6:

Compressor housing (central housing)

7:

engine

8th:

Main shaft

9:

eccentric pen

10:

eccentric socket

11:

Suction opening

12:

Compressor housing (front housing)

13:

Ejection hole

14:

Discharge chamber

15:

Compressor housing (rear housing)

16:

Discharge opening

21:

Motor driver circuit

22:

partition wall

23:

sealed connection

24:

Connecting wire

25:

IPM

26:

Control circuit

27:

capacitor

28:

Interconnects

29:

Cover element

30:

High voltage circuit for drive motor

31:

Shielding plate

37:

Noise filter

41:

Motor coil

42:

Inverter

43:

Power element

44:

Motor control circuit

45:

Low voltage circuit for control

46:

external energy supply

47:

High voltage connector (HV connector)

48:

Air conditioning control unit

49:

Control signal connector

58:

Insert element

60:

Container space

61:

Crimp section

62:

Lead wire

63:

open gap

64:

Solder as a gap sealant

Claims (4)

An electric compressor with an integrated inverter that has a built-in motor and with a motor driver circuit that includes an inverter that is installed in a container space surrounded by a compressor housing, characterized in that a crimp portion of a terminal of a lead wire connected to the inverter is put together with the inverter is molded in a resin that is introduced into the container space, and a gap that is open to the outside at the crimp portion is covered and sealed in advance by a gap sealant. Electric compressor with integrated inverter according to Claim 1 wherein a cross-sectional portion of a tip of the lead wire is covered by the gap sealant. Electric compressor with integrated inverter according to Claim 1 or 2nd , wherein the gap sealant consists of a solder. Electric compressor with an integrated inverter according to one of the Claims 1 to 3rd , wherein the electric compressor with an integrated inverter is a compressor that is mounted in a vehicle.

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