KR20230136792A - Electric compressor - Google Patents

Abstract

The present invention relates to an electric compressor, comprising: a housing; a motor that generates power within the housing; an inverter that controls the motor; a rotating shaft rotated by the motor; a rotating scroll that rotates around the rotating shaft; and a fixed scroll engaged with the orbiting scroll, wherein the housing includes a motor housing accommodating the motor, an inverter housing accommodating the inverter, and is disposed between the motor housing and the inverter housing and is provided from the outside of the housing. By including an accumulator housing that collects liquid refrigerant among the incoming refrigerants, there is a problem in which the heating elements of the inverter are not sufficiently cooled due to the heat of the bearing supporting the rotating shaft, and the number of parts mounted on the vehicle increases due to the accumulator and connection piping is provided. This can prevent the problem of reduced space efficiency.

Description

Electric compressor{ELECTRIC COMPRESSOR}

The present invention relates to an electric compressor, and more specifically, to an electric compressor capable of compressing refrigerant with the driving force of a motor controlled by an inverter.

In general, a compressor is a device that compresses fluid such as refrigerant gas, and is applied to building air conditioning systems, vehicle air conditioning systems, etc.

Depending on the compression method, the compressor is classified into a reciprocating compressor that compresses the refrigerant through the reciprocating motion of the piston and a rotary compressor that performs compression while rotating. The reciprocating compressor uses a crank depending on the power transmission method to provide multiple It is classified into a crank-type compressor that transmits power through two pistons, a swash plate-type compressor that transmits power to a rotating shaft on which a swash plate is installed, and the rotary compressor is a vane rotary compressor that uses a rotating rotary shaft and vanes, and a rotating scroll and fixed compressor. It can be classified as a scroll compressor that uses scrolls.

Additionally, the compressor may be classified into a mechanical compressor using an engine and an electric compressor using a motor (hereinafter referred to as electric compressor) depending on the driving method.

Here, an inverter that controls the motor to control compression capacity is applied to the electric compressor, and a structure is applied to cool the heating element of the inverter.

Specifically, a conventional electric compressor includes a housing, a motor that generates power inside the housing, an inverter that controls the motor, a rotation shaft rotated by the motor, an orbiting scroll that rotates by the rotation shaft, and the orbiting scroll. It includes a fixed scroll that is engaged with and forms a compression chamber.

In addition, the housing includes a partition wall that partitions the motor accommodating space in which the motor is accommodated and the inverter accommodating space in which the inverter is accommodated, and a suction port that guides the refrigerant to the motor accommodating space.

Additionally, the inverter includes a heating element, and at least a portion of the heating element contacts the partition wall in the inverter accommodation space.

In a conventional electric compressor according to this configuration, when power is applied to the motor, refrigerant flows into the motor accommodation space through the suction port, and the refrigerant in the motor accommodation space flows into the compression chamber, is compressed, and then is compressed into the housing. is discharged to the outside of

In this process, the motor is controlled by the inverter, so that cooling efficiency is variably controlled, and the heat generated by the heating element is dissipated through the partition wall to the refrigerant in the motor accommodation space.

However, in such a conventional electric compressor, an annular boss portion into which a bearing supporting the rotating shaft is inserted is formed in the partition wall, so that the heat of the bearing is transmitted to the partition wall through the boss part, thereby sufficiently generating the heat generating element. There was a problem with cooling.

In addition, in the conventional case, an accumulator for separating liquid refrigerant and gaseous refrigerant is provided separately from the electric compressor and communicates with the suction port of the electric compressor through a connection pipe to supply gaseous refrigerant to the electric compressor, so that the accumulator is provided separately from the electric compressor. There were problems in that the number of installed parts increased, connecting pipes had to be provided, and space efficiency was reduced.

Republic of Korea Patent Publication No. 10-2010-0058659 Republic of Korea Patent Publication No. 10-2184051

Therefore, the purpose of the present invention is to provide an electric compressor that can prevent the problem of the heating element of the inverter not being sufficiently cooled due to the heat of the bearing supporting the rotating shaft.

Another object of the present invention is to provide an electric compressor that can prevent problems such as an increase in the number of parts mounted on a vehicle due to an accumulator, the need for connecting piping, and a decrease in space efficiency.

The present invention, in order to achieve the above-described object, includes a housing; a motor that generates power within the housing; an inverter that controls the motor; a rotating shaft rotated by the motor; a rotating scroll that rotates around the rotating shaft; and a fixed scroll engaged with the orbiting scroll, wherein the housing includes a motor housing accommodating the motor, an inverter housing accommodating the inverter, and is disposed between the motor housing and the inverter housing and is provided from the outside of the housing. An electric compressor including an accumulator housing that collects liquid refrigerant among incoming refrigerants is provided.

The accumulator housing may include a pin protection wall that surrounds the electrode pin connecting the motor and the inverter and shields it from the internal space of the accumulator housing.

The housing includes a first partition wall that partitions the inside of the accumulator housing and the inside of the inverter housing, the inverter includes a heat generating element, and the heat generating element may be in contact with the first partition wall.

The housing includes a second partition wall that partitions the inside of the accumulator housing and the inside of the motor housing, and the second partition wall supports the rotation shaft and an outlet that communicates the inside of the accumulator housing and the inside of the motor housing. It includes an annular boss portion into which a bearing is inserted, and the first partition wall may be spaced apart from the boss portion by the accumulator housing.

The fin protection wall extends from the first partition and contacts the second partition, and a sealing member may be disposed between the fin protection wall and the second partition.

The accumulator housing includes an outer wall extending along the outer periphery of the accumulator housing, an inlet penetrating the outer wall, and extending in the direction of gravity from a position opposite the inlet within the space formed by the outer wall, and then being turned and extending in the direction opposite to gravity. It may further include a first inner wall and a second inner wall extending at a distance from the first inner wall on an opposite side of the outer wall based on the first inner wall.

The first inner wall includes a first end of the first inner wall facing the inlet and a second end of the first inner wall located on an opposite side of the first end of the first inner wall in the extension direction of the first inner wall, and the second end of the first inner wall is located on the opposite side of the first end of the first inner wall. The inner wall has a first end of the second inner wall opposite the first end of the first inner wall and a second inner wall located on the opposite side of the first end of the second inner wall in the extension direction of the second inner wall and opposite to the second end of the first inner wall. 2 The inner wall may include a second end.

A first end of the first inner wall and a first end of the second inner wall may be connected to the outer wall.

The second end of the first inner wall and the second end of the second inner wall may be spaced apart from the outer wall.

The outlet may be formed between a first end of the first inner wall and a first end of the second inner wall.

The first inner wall further includes a first inner wall trap portion located in a direction of gravity closer to the first end of the first inner wall and the second end of the first inner wall, and the second inner wall includes a first end of the second inner wall and the second end of the first inner wall. It may further include a second inner wall trap portion located closer to the direction of gravity than the second end of the second inner wall.

The inlet and the outlet may be formed on a side opposite to gravity than the first inner wall trap part and the second inner wall trap part.

The fin protection wall may be formed between a first end of the second inner wall and a second end of the second inner wall.

The fin protection wall may be spaced apart from a first end of the second inner wall, a second end of the second inner wall, and the outer wall.

The pin protection wall may be formed on a side opposite to gravity than the second inner wall trap portion.

The electric compressor according to the present invention includes a housing; a motor that generates power within the housing; an inverter that controls the motor; a rotating shaft rotated by the motor; a rotating scroll that rotates around the rotating shaft; and a fixed scroll engaged with the orbiting scroll, wherein the housing includes a motor housing accommodating the motor, an inverter housing accommodating the inverter, and is disposed between the motor housing and the inverter housing and is provided from the outside of the housing. By including an accumulator housing that collects liquid refrigerant among the incoming refrigerants, there is a problem in which the heating elements of the inverter are not sufficiently cooled due to the heat of the bearing supporting the rotating shaft, and the number of parts mounted on the vehicle increases due to the accumulator and connection piping is provided. This can prevent the problem of reduced space efficiency.

1 is a front view showing an electric compressor according to an embodiment of the present invention;
Figure 2 is a cross-sectional view of portion A of Figure 1;
Figure 3 is a perspective view of part B of Figure 2;
FIG. 4 is a cross-sectional view taken along line I-I of FIG. 1.

Hereinafter, the electric compressor according to the present invention will be described in detail with reference to the attached drawings.

Figure 1 is a front view showing an electric compressor according to an embodiment of the present invention, Figure 2 is a cross-sectional view of part A of Figure 1, Figure 3 is a perspective view of part B of Figure 2, and Figure 4 is a perspective view of part B of Figure 1. This is a cross-sectional view along line Ⅰ-Ⅰ.

Referring to the attached FIGS. 1 to 4, the electric compressor according to an embodiment of the present invention includes a housing 100, a motor 200 that generates power inside the housing 100, and the motor 200. An inverter (not shown) that controls the It may include a fixed scroll (not shown) forming a compression chamber.

The housing 100 includes a center housing 110, a front housing 120 that is coupled to the center housing 110 and forms a motor accommodation space (Sm) in which the motor 200 is accommodated, and the center housing 110. A scroll accommodating space that is coupled to the center housing 110 on the opposite side of the front housing 120 and accommodates the orbiting scroll (not shown) and the fixed scroll (not shown), and the refrigerant discharged from the compression chamber. A rear housing 130 forming a discharge chamber accommodating the front housing 120 is coupled to the front housing 120 on the opposite side of the center housing 110 and flows in from the outside of the housing 100. It is coupled to the accumulator housing 140 on the opposite side of the front housing 120 with respect to the accumulator housing 140 and the accumulator housing 140, which forms an accumulation space (Sa) for collecting liquid refrigerant among the refrigerants. It may include an inverter housing 150 that forms an inverter accommodation space (not shown) in which an inverter (not shown) is accommodated.

Here, the accumulator housing 140 includes a first partition W1 dividing the accumulation space Sa and the inverter accommodation space (not shown), and an outer wall 142 extending along the outer periphery of the first partition W1. ), an inlet 143 penetrating the outer wall 142, extending in the direction of gravity from a position opposite the inlet 143 within the accumulation space Sa formed by the outer wall 142, and then being deflected to oppose gravity. An alphabet U-shaped first inner wall 144 extending in the direction, an alphabet U-shaped extending parallel to the first inner wall 144 on the opposite side of the outer wall 142 with respect to the first inner wall 144 It may include a second inner wall 146 and a pin protection wall 148 that surrounds the electrode pin 400 connecting the motor 200 and the inverter (not shown) and shields it from the storage space Sa. .

The first partition W1 has a first partition wall first surface W11 facing the accumulation space Sa and a first partition wall second surface W12 forming a rear surface of the first partition wall first surface W11. may include.

At this time, the outer wall 142, the first inner wall 144, the second inner wall 146, and the pin protection wall 148 protrude from the first partition wall first surface W11 toward the front housing 120. can be formed.

In addition, at least a portion of the heating elements (e.g., switching elements such as an insulated gate bipolar transistor (IGBT) and intelligent power module (IPM)) of the inverter (not shown) is disposed on the second surface of the first partition for heat dissipation ( W12) can be contacted.

Meanwhile, the first inner wall 144 has a first inner wall first end 144a opposite the inlet 143 and a first end 144a of the first inner wall 144a in the extension direction of the first inner wall 144. It may include a first inner wall second end 144c located on the opposite side and a first inner wall trap portion 144b located between the first inner wall first end 144a and the first inner wall second end 144c. You can.

The first end 144a of the first inner wall is connected to the outer wall 142 and may extend in the direction of gravity.

The second end 144c of the first inner wall may be spaced apart from the outer wall 142 at a position opposite the first end 144a of the first inner wall in the vertical direction of gravity and may extend in the direction of gravity.

The first inner wall trap portion 144b extends in the direction of gravity from the side of the first inner wall first end 144a and the second end 144c of the first inner wall in the direction of gravity, then is turned and extends in the direction opposite to gravity, It may be spaced apart from the outer wall 142.

The second inner wall 146 includes a second inner wall first end 146a opposite the first inner wall first end 144a, and a first end of the second inner wall in the extension direction of the second inner wall 146 ( A second inner wall second end 146c located on the opposite side of 146a) and opposite to the first inner wall second end 144c, and the second inner wall first end 146a and the second inner wall second end 146c. ) may include a second inner wall trap portion 146b located between.

The first end 146a of the second inner wall is connected to the outer wall 142 and may extend in the direction of gravity.

The second end 146c of the second inner wall may be spaced apart from the outer wall 142 at a position opposite to the first end 146a of the second inner wall in the vertical direction of gravity and may extend in the direction of gravity.

The second inner wall trap portion 146b may extend in the direction of gravity from the side of the gravity direction than the second inner wall first end 146a and the second inner wall second end 146c, and may be turned to extend in the direction opposite to gravity. there is.

Here, the accumulation space Sa is the first accumulation space Sa1, which is the space between the outer wall 142 and the first inner wall 144, and the space between the first inner wall 144 and the second inner wall 146. It may be divided into a second storage space (Sa2) and a third storage space (Sa3) composed of the second inner wall 146.

At this time, the inlet 143 opposite to the first end 144a of the first inner wall is located in a direction opposite to gravity than the first inner wall trap part 144b, and is located on one side (first side) of the first accumulation space Sa1. 1 It may be in communication with the upper part of the inner wall (side of the first end 144a).

The upper part of the other side (the side of the second end 144c of the first inner wall) of the first accumulation space Sa1 is the second accumulation space through the first gap between the second end 144c of the first inner wall and the outer wall 142. It may communicate with the upper part of one side (between the second end 144c of the first inner wall and the second end 146c of the second inner wall) of the space Sa2.

The other side of the second accumulation space Sa2 (between the first end 144a of the first inner wall and the first end 146a of the second inner wall) has an outlet 124 formed in the second partition W2, which will be described later. It communicates with the motor receiving space Sm through, and the outlet 124 is located between the first end 144a of the first inner wall and the first end 146a of the second inner wall, and the first inner wall trap part It may be located on a side opposite to gravity than the (144b) and the second inner wall trap portion (146b).

Meanwhile, the upper part of one side of the second accumulation space Sa2 may be in communication with the upper part of the third accumulation space Sa3 through a second gap between the second end 146c of the second inner wall and the outer wall 142. there is.

The pin protection wall 148 may be located at the top of the third storage space Sa3.

The pin protection wall 148 extends from the first partition W1 and may contact the second partition W2, more precisely, the electrode pin housing receiving portion W222, which will be described later.

In addition, the pin protection wall 148 is located between the first end 146a of the second inner wall and the second end 146c of the second inner wall and is located in a direction opposite to gravity than the second inner wall trap portion 146b. It can be.

And, the refrigerant flowing into the upper part of the third storage space Sa3 through the second gap flows to the lower part of the third storage space Sa3, and the refrigerant in the lower part of the third storage space Sa3 The fin protection wall 148 is connected to the second inner wall first end 146a, the second inner wall second end 146c, and the outer wall so that it flows into the second accumulation space Sa2 through the second gap. It may be formed to be spaced apart from (142).

Here, the upper part of the third accumulation space Sa3 may not communicate with the upper part of the other side of the second accumulation space Sa2 as the first end 146a of the second inner wall is connected to the outer wall 142. there is.

In addition, the upper part of the other side of the second accumulation space (Sa2) does not communicate with the upper part of the first accumulation space (Sa1) as the first end 144a of the first inner wall is connected to the outer wall 142. You can.

The front housing 120 may include a second partition W2 that partitions the motor accommodation space Sm and the storage space Sa.

The second partition W2 forms a first surface W21 of the second partition facing the motor accommodation space Sm and a rear surface of the first surface W21 of the second partition facing the storage space Sa. It may include a second side of the second partition W22.

The second partition wall first surface W21 includes an annular boss part 122 protruding from the center of the second partition wall first surface W21 toward the motor accommodation space Sm, and the boss part 122 ) A bearing 500 supporting the rotating shaft 300 may be inserted.

The second side of the second partition W22 corresponds to the outer wall 142, the first inner wall 144, the second inner wall 146, and the pin protection wall 148 of the accumulator housing 140. ) includes ribs protruding toward the side, and among the ribs, the rib corresponding to the pin protection wall 148 is the electrode pin housing 410 of the electrode pin 400, and three electrode pins are inserted into the electrode pin housing 410 to be fastened to the second partition wall. The electrode pin housing accommodating portion (W222) may be formed to receive the electrode pin housing accommodating portion (W222).

Here, the second partition W2 penetrates the second partition W2 from the second partition wall first surface W21 to the second partition wall second surface W22 to form the accumulation space Sa (further). To be precise, it may include the outlet 124 communicating with the second accumulation space (Sa2, the upper part of the other side) and the motor accommodation space (Sm).

And, the second partition W2 penetrates the second partition W2 from the second partition wall first surface W21 to the second partition wall second surface W22 to accommodate the electrode pin 400. It may further include a pin hole 126.

Hereinafter, the operational effects of the electric compressor according to this embodiment will be described.

That is, when power is applied to the motor 200, the rotation shaft 300 is rotated by the motor 200, and the orbiting scroll (not shown) may be rotated by the rotation shaft 300.

Accordingly, low-temperature, low-pressure refrigerant may flow into the accumulator housing 140 through the inlet 143, pass through the storage space Sa, and be separated into liquid refrigerant and gaseous refrigerant.

Specifically, the refrigerant that has passed through the inlet 143 passes through the first accumulation space (Sa1) from the upper part of one side of the first accumulation space (Sa1) to the upper part of the other side of the first accumulation space (Sa1), and in this process, Liquid refrigerant may be adsorbed on the wall forming the first accumulation space Sa1 and collected in the lower part of the first accumulation space Sa1 (between the first inner wall trap portion 144b and the outer wall 142).

Here, on the inner peripheral surface of the outer wall 142, a flange 142a for forming a bolting hole into which a bolt for fastening between housings is inserted is formed to protrude toward the first storage space Sa1, and the refrigerant collides with the flange 142a. It can be. Accordingly, the separation effect of the liquid refrigerant and the gaseous refrigerant can be increased. In addition, as the flanges 142a are formed in plurality, the separation effect of the refrigerant can be further increased, and as the plurality of flanges 142a are disposed in the lower part of the first accumulation space Sa1, the first storage space Sa1 has a plurality of flanges 142a. 1 The liquid refrigerant collected in the lower part of the storage space Sa1 may be prevented from flowing toward the second storage space Sa2.

A part of the refrigerant that has passed through the first accumulation space (Sa1) flows into the second accumulation space (Sa2) through the first gap, and the remainder is stored in the third accumulation space through the first gap and the second gap. It may flow into space (Sa3).

The liquid refrigerant contained in the refrigerant flowing into the third accumulation space (Sa3) is adsorbed on the wall forming the third accumulation space (Sa3) and is adsorbed on the lower part (second inner wall trap portion (second inner wall trap portion) of the third accumulation space (Sa3) 146b)) can be captured.

The refrigerant separated from the liquid refrigerant in the third storage space Sa3 may flow into the second storage space Sa2 through the second gap.

The refrigerant flowing into the second accumulation space (Sa2) passes through the second accumulation space (Sa2) from the upper part of one side of the second accumulation space (Sa2) to the upper part of the other side of the second accumulation space (Sa2), In the process, the liquid refrigerant is adsorbed on the wall forming the second storage space Sa2 and is stored in the lower part of the second storage space Sa2 (between the first inner wall trap portion 144b and the second inner wall trap portion 146b). can be captured.

The refrigerant that has passed through the second storage space (Sa2) may flow into the motor accommodation space (Sm) through the outlet 124.

Here, the gaseous refrigerant separated from the liquid refrigerant by the first storage space (Sa1), the third storage space (Sa3), and the second storage space (Sa2) passes through the outlet 124 and the motor receiving space ( Sm) can be introduced.

The refrigerant in the motor accommodation space Sm may flow into the compression chamber, be compressed at high temperature and high pressure, and then be discharged to the outside of the housing 100 through the discharge chamber.

In this process, the motor 200 is controlled by the inverter (not shown), so that the cooling efficiency is variably controlled, and the heat generated from the heating element is transmitted through the first partition W1 to the accumulation space ( Heat can be dissipated with refrigerant of Sa).

Here, in the electric compressor according to this embodiment, the accumulator housing 140 is provided between the motor housing, which is an assembly of the front housing 120 and the center housing 110, and the inverter housing 150, The heating element can be cooled smoothly. Specifically, as the first partition W1 is significantly spaced apart from the boss portion 122 in the axial direction by the accumulator housing 140, the heat of the bearing 500 flows through the boss portion 122. By preventing the heat from being transmitted to the first partition W1, the problem of the heating element not being sufficiently cooled due to the heat of the bearing 500 can be prevented. Additionally, as the first partition W1 comes into contact with the refrigerant of the accumulator housing 140, which has a lower temperature than the refrigerant of the motor housing, the heat of the heating element can be dissipated more smoothly.

In addition, as the low-temperature intake refrigerant stays in the center of the electric compressor where the heating element and the bearing are located for a longer time than before, the heating element and the bearing can be cooled more smoothly.

Also, as the accumulator housing 140 is provided, that is, as the housing 100 includes the accumulator housing 140, the number of parts mounted on the vehicle can be reduced.

In addition, as the accumulation space (Sa) communicates with the motor accommodating space (Sm) through the outlet 124, a connection pipe connecting the accumulation space (Sa) and the motor accommodating space (Sm) is provided separately. There is no need to be.

Accordingly, space utilization can also be increased.

And, as the inlet 143 is formed on a side opposite to gravity than the first inner wall trap portion 144b, the liquid refrigerant collected in the lower part of the first accumulation space Sa1 flows back into the inlet 143. It can be prevented from happening.

And, as the outlet 124 is formed on a side opposite to gravity than the first inner wall trap part 144b and the second inner wall trap part 146b, the water collected in the lower part of the second accumulation space Sa2 Liquid refrigerant can be prevented from flowing into the outlet 124.

In addition, as the first end 144a of the first inner wall is connected to the outer wall 142, the refrigerant passing through the inlet 143 is prevented from flowing directly into the upper part of the other side of the second accumulation space Sa2. It can be.

And, as the first end 146a of the second inner wall is connected to the outer wall 142, the refrigerant flowing into the third storage space Sa3 is directly directed to the upper part of the other side of the second storage space Sa2. Inflow can be prevented, and the gaseous refrigerant on the other side of the second storage space Sa2 can be prevented from flowing out into the third storage space Sa3.

In addition, as the fin protection wall 148 is formed, the electrode fin 400 can be prevented from being exposed to the coolant in the storage space Sa.

In particular, as the fin protective wall 148 is formed on the side opposite to gravity than the second inner wall trap portion 146b, the electrode fin 400 collects the liquid refrigerant in the lower part of the third accumulation space Sa3. Exposure to can be prevented.

Here, although not separately shown, for sealing, it is preferable that a sealing member is provided between the accumulator housing 140 and the motor housing, and the sealing member is connected to the front end surface of the pin protection wall 148 and the electrode pin housing. It may be more desirable to form a seal between the receiving portions W222.

In this way, the electrode pin 400 is sealed by the pin protection wall 148 and the sealing member and directly penetrates the accumulator housing 140 to be connected to the inverter and the motor 200. A safe electrical connection between the motors 200 is guaranteed, and there is no need to form a separate electrode connection structure outside the compressor.

Meanwhile, in the case of this embodiment, the first partition W1 for dividing the inverter accommodation space (not shown) and the accumulation space Sa is included in the accumulator housing 140, and the accumulation space Sa and the second partition W2 for dividing the motor accommodation space Sm are included in the motor housing, but are not limited thereto. That is, for example, the first partition W1 may be included in the inverter housing 150 or the second partition W2 may be included in the accumulator housing 140 .

100: housing
110, 120: motor housing
122: Boss Department
124: outlet
140: Accumulator housing
142: Exterior wall
143: inlet
144: first inner wall
144a: first end of first inner wall
144b: First inner wall trap portion
144c: second end of first inner wall
146: Second inner wall
146a: first end of second inner wall
146b: Second inner wall trap portion
146c: second end of second inner wall
148: pin protection wall
150: Inverter housing
200: motor
300: rotation axis
400: electrode pin
500: Bearing
W1: first bulkhead
W2: Second bulkhead

Claims (15)

housing;
a motor that generates power within the housing;
an inverter that controls the motor;
a rotating shaft rotated by the motor;
a rotating scroll that rotates around the rotating shaft; and
It includes a fixed scroll engaged with the orbiting scroll,
The housing includes a motor housing accommodating the motor, an inverter housing accommodating the inverter, and an accumulator housing disposed between the motor housing and the inverter housing and collecting liquid refrigerant from the refrigerant flowing from the outside of the housing. Electric compressor. According to paragraph 1,
The accumulator housing includes a pin protection wall that surrounds the electrode pin connecting the motor and the inverter and shields it from the internal space of the accumulator housing. According to paragraph 2,
The housing includes a first partition dividing the interior of the accumulator housing and the interior of the inverter housing,
The inverter includes a heating element,
The electric compressor wherein the heating element is in contact with the first partition. According to paragraph 3,
The housing includes a second partition wall dividing the interior of the accumulator housing and the interior of the motor housing,
The second partition includes an outlet connecting the inside of the accumulator housing and the inside of the motor housing, and an annular boss portion into which a bearing supporting the rotation shaft is inserted,
The first partition wall is axially spaced apart from the boss portion by the accumulator housing. According to paragraph 4,
The fin protection wall extends from the first partition and is in contact with the second partition,
An electric compressor in which a sealing member is disposed between the fin protective wall and the second partition wall. According to paragraph 4,
The accumulator housing includes an outer wall extending along the outer periphery of the accumulator housing, an inlet penetrating the outer wall, and extending in the direction of gravity from a position opposite the inlet within the space formed by the outer wall, and then being turned and extending in the direction opposite to gravity. An electric compressor further comprising a first inner wall and a second inner wall extending on an opposite side of the outer wall with respect to the first inner wall and being spaced apart from the first inner wall. According to clause 6,
The first inner wall includes a first end of the first inner wall facing the inlet and a second end of the first inner wall located on the opposite side of the first end of the first inner wall in the extension direction of the first inner wall,
The second inner wall has a first end of the second inner wall opposite to the first end of the first inner wall and is located on the opposite side of the first end of the second inner wall in the extension direction of the second inner wall and is located at the second end of the first inner wall. An electric compressor comprising an opposing second inner wall second end. In clause 7,
A first end of the first inner wall and a first end of the second inner wall are connected to the outer wall. According to clause 8,
The electric compressor wherein the first inner wall second end and the second inner wall second end are spaced apart from the outer wall. According to clause 9,
The electric compressor wherein the outlet is formed between a first end of the first inner wall and a first end of the second inner wall. According to clause 10,
The first inner wall further includes a first inner wall trap portion located in a direction of gravity closer to the first end of the first inner wall and the second end of the first inner wall,
The second inner wall further includes a first end of the second inner wall and a second inner wall trap portion located in a direction of gravity closer to the second end of the second inner wall. According to clause 11,
The electric compressor wherein the inlet and the outlet are formed on a side opposite to gravity than the first inner wall trap portion and the second inner wall trap portion. In clause 7,
The electric compressor wherein the fin protective wall is formed between a first end of the second inner wall and a second end of the second inner wall. According to clause 13,
The pin protection wall is spaced apart from a first end of the second inner wall, a second end of the second inner wall, and the outer wall. According to clause 11,
The pin protection wall is formed on a side opposite to gravity than the second inner wall trap portion.

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