KR102379938B1 - Electric Compressor capacitor housing assembly - Google Patents

Abstract

The present invention relates to a capacitor housing assembly for an electric compressor, and includes a mounting part 110 having a shape corresponding to an outer circumferential surface of the capacitor 3 so that a plurality of capacitors 3 are respectively inserted in a spaced apart state, and the mounting part 110 ) divided into a separate space in communication with the capacitor housing 100 including an electrolyte storage unit 120 in which the electrolyte ejected from the capacitor 3 is stored; and an upper housing 200 coupled to the upper surface of the capacitor housing 100 after the capacitor 3 is seated on the mounting part 110 .

Description

Electric Compressor capacitor housing assembly

The present invention relates to a capacitor housing assembly, and more particularly, to a motor-driven compressor for stable operation of a motor-driven compressor by preventing failure or damage in advance of a high-voltage converter due to electrolyte ejected from a capacitor provided in an inverter housing of the motor-compressor It relates to a capacitor housing assembly.

Cars are equipped with an air conditioning system (Air Conditioning System) for heating and cooling indoors. Such an air conditioning system includes a compressor that compresses a low-temperature and low-pressure gaseous refrigerant introduced from an evaporator into a high-temperature and high-pressure gaseous refrigerant and sends it to a condenser as a configuration of a cooling system. Such a compressor includes a mechanical type that performs compression by rotating an engine as a driving source, and an electric type that uses a motor as a driving source.

1 to 2, it is very important for the electric compressor to be stably supplied with a constant voltage for the stable driving of the inverter. To this end, the capacitor housing 4 in which the capacitor 3 is mounted on one surface of the printed circuit board 2 is mounted on the motor-compressor inverter housing.

The capacitor housing 4 is formed in an L-shape, and a plurality of capacitors are mounted as shown in the drawings. As the capacitor 3, an electrolytic capacitor is mainly used and is used to reduce a DC input voltage ripple.

To reduce this thickness, an inverter in which various circuit elements including an Insulated Gate Bipolar Transistor (IGBT) and a capacitor 3 are mounted on a printed circuit board 2 is installed in the inverter housing.

The switching element and capacitor 3 of the inverter generate a lot of heat and require heat dissipation. In particular, the capacitor 3 has the largest size among the electronic components of the inverter and is greatly affected by the surrounding environment compared to other components. Therefore, it is one of the biggest factors that determine the lifespan of an inverter.

When a normal voltage is not applied to the inverter and an overvoltage is applied or a reverse voltage is applied to the inverter high voltage line due to the carelessness of the operator, the inverter may be damaged, and the element with the lowest withstand voltage among the elements on the high voltage circuit is damaged first This happens.

Due to this, if the electrolyte inside the capacitor is ejected in the direction of the arrow shown at position A, the electrolyte may contact the pins of various electrical elements located in the inverter circuit or damage the surrounding connection circuits, thereby causing a short circuit. This caused an urgent need for countermeasures.

Republic of Korea Patent Publication 10-2014-0101181 (published on August 19, 2014)

The present invention has been devised to solve the above problems. A capacitor housing assembly is installed on a printed circuit board of an electric compressor to mount a plurality of capacitors, and even when electrolyte is ejected from the capacitor, the printed circuit An object of the present invention is to provide a capacitor housing assembly for an electric compressor capable of stably blocking the ejection of electrolyte to a substrate.

The present invention for achieving the above object is a capacitor housing assembly (1) in which a capacitor (3) mounted on a printed circuit board (2) of an electric compressor is accommodated, wherein the capacitor housing assembly (1) includes a plurality of capacitors. A mounting part 110 having a shape corresponding to the outer circumferential surface of the capacitor 3 so as to be inserted in a spaced state from 3 is divided into a separate space in communication with the mounting part 110, and the capacitor 3 ) a capacitor housing 100 including an electrolyte storage unit 120 in which the ejected electrolyte is stored; and an upper housing 200 coupled to the upper surface of the capacitor housing 100 after the capacitor 3 is seated on the mounting part 110 .

The capacitor housing 100 further includes an auxiliary storage unit 130 formed below the mounting unit 110 and primarily storing the electrolyte ejected from the capacitor 3 .

In the auxiliary storage unit 130 , when the capacitor housing 100 and the upper housing 200 are coupled to each other, an enclosed space is formed, and the auxiliary storage unit ( In 130), it further includes a passage 132 that is opened toward the electrolyte storage unit 120.

The electrolyte storage unit 120 includes a first electrolyte storage unit 122 extending in a longitudinal direction on one side of the capacitor housing 100 ; and a second electrolyte storage unit 124 that communicates with the first electrolyte storage unit 122 and extends along one side of the capacitor housing 100 in a horizontal direction.

The first electrolyte storage unit 122 and the second electrolyte storage unit 124 communicate with each other, characterized in that the movement of the electrolyte is made.

The second electrolyte storage unit 124 is characterized in that it extends relatively longer than the first electrolyte storage unit (122).

After the capacitor housing 100 is installed, the electrolyte moved to the first electrolyte storage unit 122 is first moved to the second electrolyte storage unit 124 .

The electrolyte storage unit 120 has a U-shaped cross section and extends upward to a predetermined height in order to prevent the electrolyte from flowing out when the electrolyte is introduced.

The upper housing 200 further includes an auxiliary cover 220 in close contact with the upper surface of the auxiliary storage unit 130 to maintain a sealed state.

The upper housing 200 is provided with a coupling portion 210 extending toward the capacitor housing 100 and having an insertion groove 212 formed in a longitudinal direction, and the capacitor housing 100 includes the coupling portion 210 and It is characterized in that a protrusion 140 inserted into the insertion groove 212 is provided at a position facing each other.

The upper housing 200 further includes a groove portion 202 having a shape corresponding to a position corresponding to the electrolyte storage unit 120 .

According to the present invention, even when electrolyte is ejected from the capacitor provided in the inverter housing of the electric compressor, the malfunction of the electric compressor or the damage of expensive electronic components is prevented through the electrolyte storage unit that can stably store it. Stable operation of the electric compressor can be promoted.

In the embodiments of the present invention, when the electrolyte is ejected while the capacitor is mounted in the capacitor housing, it can be stably stored regardless of the location, so that it can be used regardless of the installation direction of the electric compressor.

1 is a perspective view showing a capacitor mounted on a printed circuit board of a conventional electric compressor.
2 is a perspective view illustrating a state in which an electrolyte is ejected from a conventional capacitor;
3 is an exploded perspective view of a capacitor housing assembly for an electric compressor according to an embodiment of the present invention;
4 is an exploded perspective view illustrating the capacitor housing assembly for an electric compressor according to an embodiment of the present invention from another angle;
5 is a combined perspective view of a capacitor housing assembly for an electric compressor according to an embodiment of the present invention;
6 is a state diagram of a capacitor housing assembly for an electric compressor according to an embodiment of the present invention.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention. The thickness of lines or the size of components shown in the accompanying drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or precedent of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. 3 is an exploded perspective view of a capacitor housing assembly for an electric compressor according to an embodiment of the present invention, and FIG. 4 is a combined perspective view of the capacitor housing assembly for an electric compressor according to an embodiment of the present invention.

3 to 4, the capacitor housing assembly 1 for an electric compressor according to the present embodiment is a capacitor housing assembly 1 in which the capacitor 3 mounted on the printed circuit board 2 of the electric compressor is accommodated. The capacitors are divided into a mounting unit 110 having a shape corresponding to the outer circumferential surface of the capacitor 3 so that a plurality of capacitors are respectively inserted in a spaced apart state, and a separate space in communication with the mounting unit 110 . a capacitor housing 100 including an electrolyte storage unit 120 in which the electrolyte ejected in (3) is stored; and an upper housing 200 coupled to the upper surface of the capacitor housing 100 after the capacitor 3 is seated on the mounting part 110 .

The printed circuit board 2 is used to safely protect the electrolyte from being ejected from the capacitor 3 toward the position A where the high voltage converter (not shown) is disposed. In the case of the high voltage connector, the power supplied from the battery is provided to convert power in the inverter element and supply it to the motor of the electric compressor.

The capacitor 3 has the largest size among the electronic components of the inverter and is greatly influenced by the surrounding environment compared to other components, so it is one of the biggest factors determining the lifespan of the inverter.

That is, since the electric compressor is mainly mounted in the engine room of the vehicle, when the temperature of the engine room rises to a high temperature, heat dissipation is not stably performed, thereby shortening the life of the capacitor 3 .

In addition, when the amount of current applied to the capacitor 3 is greater than the allowable value, the life of the capacitor 3 is shortened or the electrolyte is ejected to the outside.

The capacitor 3 together with the high voltage connector is inserted into the mounting unit 110 provided in the capacitor housing 100 . Since the capacitor 3 is formed in a cylindrical shape, the mounting unit 110 also corresponds to the capacitor 3 . made in a shape that becomes

For example, the capacitor housing 100 is formed in an L-shape, and two capacitors 3 are mounted on the mounting unit 110 in a vertical direction, and two capacitors 3 are mounted on the mounting unit 110 in a horizontal direction. .

In particular, in the case of an electric compressor, a plurality of capacitors 3 are mounted, and electrolyte may be ejected from the plurality of capacitors 3 . To prevent this, the capacitor housing 100 further includes an auxiliary storage unit 130 in which the electrolyte ejected from the capacitor 3 is primarily stored in an independent space below the mounting unit 110 .

The auxiliary storage unit 130 maintains the state in which the electrolyte ejected from the capacitor 3 is primarily stored, so that direct leakage of the high voltage converter does not occur.

The auxiliary storage unit 130 does not provide a space to store a large amount of electrolyte, but provides a space to store it at the initial stage when the electrolyte is rapidly ejected, thereby preventing the electrolyte from moving to the location where the high voltage converter is installed. .

In the auxiliary storage unit 130 , when the capacitor housing 100 and the upper housing 200 are coupled to each other, an enclosed space is formed, and the auxiliary storage unit ( In 130), it further includes a passage 132 that is opened toward the electrolyte storage unit 120.

Since the passages 132 are respectively opened toward the electrolyte storage unit 120 based on the state in which the capacitor housing 100 is mounted on the printed circuit board 2 , the capacitor 3 is located at any position in the capacitor housing 100 . Even when is mounted, the electrolyte ejected toward the electrolyte storage unit 120 is stored and moved in a specific direction.

Therefore, even when a large amount of electrolyte is ejected from the capacitor 3 , the phenomenon of ejecting to the outside of the electrolyte storage unit 120 is blocked, thereby preventing damage to the printed circuit board 2 .

Since the passage 132 is opened toward the electrolyte storage unit 120 located on the right side when the capacitor 3 is mounted in the vertical direction of the capacitor housing 100 , the electrolyte ejected in the direction of the arrow flows through the passage 132 . It is moved to the storage unit 120 .

In addition, when the capacitor 3 is mounted in the horizontal direction of the capacitor housing 100 , the passage 132 is opened toward the electrolyte storage unit 120 located at the upper portion, so after the electrolyte is ejected from the capacitor 3 . It is stably moved toward the electrolyte storage unit 120 .

The electrolyte storage unit 120 includes a first electrolyte storage unit 122 extending in a longitudinal direction on one side of the capacitor housing 100 , and communicates with the first electrolyte storage unit 122 , and includes one side of the capacitor housing 100 . It includes a second electrolyte storage unit 124 extending along the horizontal direction.

Since the first electrolyte storage unit 122 and the second electrolyte storage unit 124 communicate with each other, the movement of the electrolyte may be facilitated.

The second electrolyte storage unit 124 extends relatively longer than the first electrolyte storage unit 122. The reason for such extension is that when the electrolyte is ejected from the capacitor 3, the first electrolyte storage unit ( This is because after moving to 122), it is moved to the second electrolyte storage unit 124 .

Since the capacitor housing 100 is mounted in an L-shape maintained when it is mounted on the printed circuit board 2 , when the electrolyte moves to the first electrolyte storage unit 122 , the second electrolyte storage unit ( 124), so that the length of the second electrolyte storage unit 120 is extended to provide a space in which more electrolyte can be stored.

Therefore, even when the electrolyte is simultaneously ejected from the plurality of capacitors 3 , the electrolyte can be stably stored by the electrolyte storage unit 120 , thereby preventing malfunction and failure of the electric compressor in advance.

The electrolyte storage unit 120 has a U-shaped cross section and extends upward to a predetermined height, and the upper portion is opened. The phenomenon does not occur and is stored stably. Therefore, even when the electric compressor is used in a high temperature condition, it is possible to prevent damage to the high voltage connector due to the electrolyte ejected from the capacitor 3 .

The upper housing 200 further includes an auxiliary cover 220 that is in close contact with the upper surface of the auxiliary storage unit 130 to maintain a sealed state, the auxiliary cover 220 is the opening of the mounting portion 110 described above. By covering the upper part, the electrolyte ejected from the capacitor 3 is prevented from being ejected to the outside of the upper housing 200 . Therefore, even when the electrolyte is ejected from the capacitor 3 , it is not ejected to the outside of the upper housing 200 , thereby preventing damage to the electronic components mounted on the printed circuit board 2 .

The upper housing 200 further includes a groove portion 202 having a shape corresponding to a position corresponding to the electrolyte storage unit 120 . When the groove portion 202 is in close contact with the upper surface of the electrolyte storage unit 120 , a circular or polygonal closed space is formed, so that external leakage of the ejected electrolyte is blocked.

Accordingly, damage to the printed circuit board 2 is prevented even when a large amount of the electrolyte is ejected to the electrolyte storage unit 120 at a predetermined pressure.

In order to assemble the capacitor housing 100 and the upper housing 200 to each other, the upper housing 200 includes a coupling part 210 extending toward the capacitor housing 100 and having an insertion groove 212 formed in the longitudinal direction. The capacitor housing 100 includes a protrusion 140 at a position facing the coupling portion 210 , into which the insertion groove 212 is inserted.

When an operator assembles the upper housing 200 to couple it to the capacitor housing 100 , the coupling part 210 is assembled to the protrusion 140 , and the protrusion 140 is inserted into the insertion groove 212 to make the The capacitor housing 100 and the upper housing 200 are assembled with each other.

A plurality of the coupling parts 210 are provided for stable fixing, and the installation positions are also spaced apart from each other at regular intervals.

As described above, the present invention has been described with reference to the embodiment shown in the drawings, but this is merely exemplary, and those of ordinary skill in the art can make various modifications and equivalent other embodiments therefrom. You will understand that it is possible. Accordingly, the true technical protection scope of the present invention should be defined by the following claims.

1: Capacitor housing assembly
2: printed circuit board
3: capacitor
100: capacitor housing
110: mounting part
120: electrolyte storage unit
122: first electrolyte storage unit
124: second electrolyte storage unit
130: auxiliary storage unit
132: passage
140: protrusion
200: upper housing
210: coupling part
212: insert groove

Claims (11)

A capacitor housing assembly (1) in which a capacitor (3) mounted on a printed circuit board (2) of an electric compressor is accommodated,
The capacitor housing assembly (1),
A mounting part 110 having a shape corresponding to the outer circumferential surface of the capacitor 3 so that a plurality of capacitors 3 are respectively inserted in a spaced apart state, and a separate space in communication with the mounting part 110, a capacitor housing 100 including an electrolyte storage unit 120 in which the electrolyte ejected from the capacitor 3 is stored; and
an upper housing 200 coupled to the upper surface of the capacitor housing 100 after the capacitor 3 is seated on the mounting unit 110;
The capacitor housing 100 further includes an auxiliary storage unit 130 that is formed below the mounting unit 110 and primarily stores the electrolytes ejected from the plurality of capacitors 3 independently, respectively,
The electrolyte storage unit 120 communicates with a first electrolyte storage unit 122 extending along one side longitudinal direction of the capacitor housing 100 and the first electrolyte storage unit 122 and includes the capacitor housing 100 . Includes a second electrolyte storage unit 124 extending along one side of the transverse direction,
The first and second electrolyte storage units 122 and 124 extend in different directions while facing a position at which the high voltage converter of the printed circuit board 2 is disposed. delete According to claim 1,
The auxiliary storage unit 130,
When the capacitor housing 100 and the upper housing 200 are coupled to each other, an enclosed space is formed,
The capacitor housing assembly for an electric compressor further comprising a passage 132 opened from the auxiliary storage 130 toward the electrolyte storage 120 to move the electrolyte to the electrolyte storage 120 . delete According to claim 1,
The first electrolyte storage unit 122 and the second electrolyte storage unit 124 communicate with each other so that the electrolyte moves. According to claim 1,
The second electrolyte storage unit 124,
The capacitor housing assembly for an electric compressor, characterized in that it extends relatively longer than the first electrolyte storage unit (122). According to claim 1,
After the capacitor housing (100) is installed, the electrolyte moved to the first electrolyte storage unit (122) is first moved to the second electrolyte storage unit (124). According to claim 1,
The electrolyte storage unit 120,
A capacitor housing assembly for an electric compressor, characterized in that it has a U-shaped cross section and extends upward to a predetermined height in order to prevent the electrolyte from flowing out when introduced. According to claim 1,
The upper housing 200,
The capacitor housing assembly for an electric compressor further comprising an auxiliary cover 220 that is in close contact with the upper surface of the auxiliary storage unit 130 to maintain a sealed state. According to claim 1,
In the upper housing 200,
A coupling portion 210 extending toward the capacitor housing 100 and having an insertion groove 212 formed in a vertical direction is provided;
The capacitor housing assembly for an electric compressor, characterized in that the capacitor housing (100) is provided with a protrusion (140) inserted into the insertion groove (212) at a position facing the coupling portion (210). According to claim 1,
The upper housing 200,
The capacitor housing assembly for an electric compressor further comprising a groove portion 202 having a shape corresponding to a position corresponding to the electrolyte storage portion 120 .

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