KR102194807B1 - Compressor - Google Patents

Abstract

The present invention relates to a compressor, comprising: a casing; A driving motor provided in the inner space of the casing; A compression mechanism that is driven by the drive motor to compress a refrigerant; And an inverter for controlling the drive motor, wherein the casing includes an inverter cover covering the inverter, and a separation distance between the inverter cover and the inverter may form an insulating means between the inverter cover and the inverter. have. Accordingly, by securing insulation between the inverter and the inverter cover, it is possible to prevent damage to the inverter and suppress an increase in manufacturing cost due to the insulating means. In addition, by forming a rib in the inverter cover of the casing, the strength of the inverter cover may be improved, and noise and vibration transmitted to the outside through the inverter cover may be reduced.

Description

Compressor {COMPRESSOR}

The present invention relates to a compressor, and more particularly, to a compressor including a drive motor and an inverter for controlling the drive motor.

In general, a compressor is a device that compresses a fluid such as a refrigerant gas, and is applied to an air conditioning system of a building, an air conditioning system for a vehicle, and the like.

Referring to Korean Patent Laid-Open Publication No. 10-2013-0026291, a conventional compressor controls a drive motor that generates a driving force inside a casing, a compression mechanism that compresses a refrigerant by being driven by the drive motor, and the drive motor. It includes an inverter.

The casing includes a housing in which the drive motor, the compression mechanism, and the inverter are accommodated, and an inverter cover coupled to the housing and covering the inverter. Here, the inverter cover maintains the airtightness of the casing and protects the inverter.

1 is a perspective view showing an inverter cover in a conventional compressor.

Referring to FIG. 1, a conventional inverter cover 150 includes a partition plate 152 and a side plate portion 154 that is formed protruding from an outer circumference of the partition plate 152 and is coupled to the housing.

In addition, the conventional inverter cover 150 is a space formed by the partition plate 152 and the side plate 154 for insulation between the inverter cover 150 (more precisely, the partition plate 152) and the inverter. It includes an insulating paper 158 that is inserted and attached to the diaphragm portion 152.

Here, the partition plate part 152 is formed in a flat and thin plate shape for attaching the insulating paper 158, and the insulating paper 158 is attached to the partition plate part 152 with an adhesive.

However, in the conventional compressor, the strength of the inverter cover 150 is weak, and noise and vibration transmitted to the outside of the compressor through the inverter cover 150 have large problems. More specifically, as the partition plate portion 152 of the inverter cover 150 is formed in a flat and thin plate shape, the inverter cover 150 has a weak strength and thus the inverter cover 150 is easily damaged or damaged even with a small impact. And, the noise and vibration attenuation performance of the inverter cover 150 is poor, so that the noise and vibration generated by the operation of the driving motor and the compression mechanism cannot be sufficiently attenuated by the inverter cover 150 to the outside of the casing. There was a problem spreading.

In addition, as the expensive insulating paper 158 is formed to form an insulating means between the inverter and the inverter cover 150 (more precisely, the diaphragm 152), there is a problem that the manufacturing cost of the compressor is increased, and the insulating paper There is a problem that the inverter is damaged because 158 is separated from the diaphragm 152 by the vibration of the compressor, and insulation between the inverter and the inverter cover 150 is not made.

Korean Patent Publication No. 10-2013-0026291

Accordingly, an object of the present invention is to provide a compressor capable of improving the strength of an inverter cover and reducing noise and vibration transmitted to the outside through the inverter cover.

Another object of the present invention is to provide a compressor capable of preventing damage to the inverter by securing insulation between the inverter and the inverter cover, while suppressing an increase in manufacturing cost by the insulating means.

The present invention, in order to achieve the object as described above, the casing; A driving motor provided in the inner space of the casing; A compression mechanism that is driven by the drive motor to compress a refrigerant; And an inverter for controlling the driving motor, wherein the casing includes an inverter cover covering the inverter, and a separation distance between the inverter cover and the inverter forms an insulating means between the inverter cover and the inverter. Provides.

The inverter cover may be formed to be spaced apart from the inverter by a predetermined distance.

The casing includes a rear housing in which the inverter is accommodated, and the inverter cover includes a plate-shaped diaphragm; A side plate portion protruding from an outer peripheral portion of the partition plate portion, and coupled to the rear housing; And a rib protruding from the diaphragm part and accommodated in a space between the diaphragm part and the side plate part, wherein the rib is formed to be spaced apart from the inverter by a first distance, and the hard plate part It can be formed to be separated by 2 distances.

The first distance may be formed to be 2.89mm or more.

The second distance may be formed to be 5.5mm or more.

The first distance and the second distance may be adjusted by a protruding length of the side plate.

The protruding length of the side plate portion may be formed to be long within a range in which the partition plate portion is accommodated in a predetermined space.

The rib may be formed to cover a part of the diaphragm, so that a part of the inverter faces the rib, and the other part of the inverter may be formed to face the diaphragm.

The inverter, A plurality of elements for controlling the inverter; And a substrate on which the plurality of elements are mounted, and a predetermined element among the plurality of elements may be formed at a position facing the diaphragm.

The predetermined device may be at least one of a power pin and an ID pin.

The ribs are formed extending in a direction away from the center of the diaphragm from a portion spaced apart from the center of the diaphragm, and the ribs may be formed in plural, and the plurality of ribs may be radially formed with respect to the center of the diaphragm. .

The predetermined element may be formed at a position opposite to the center side of the partition plate.

The predetermined element may be formed at a position opposite to the space between the plurality of ribs.

The compressor according to the present invention may improve the strength of the inverter cover and reduce noise and vibration transmitted to the outside through the inverter cover by forming a rib on the partition plate of the inverter cover.

In addition, by forming an insulating means between the inverter and the inverter cover at a distance between the inverter and the inverter cover, it is possible to secure insulation between the inverter and the inverter cover to prevent damage to the inverter and to suppress an increase in manufacturing cost caused by the insulating means. .

1 is a perspective view showing an inverter cover in a conventional compressor,
2 is a cross-sectional view showing a compressor according to an embodiment of the present invention;
3 is an enlarged cross-sectional view of a rear housing, an inverter cover, and an inverter in the compressor of FIG. 2;
Figure 4 is a side view of Figure 3,
5 is a perspective view showing the inverter of FIG. 3;
6 is a perspective view showing the inverter cover of FIG. 3;
7 is a perspective view showing an inverter cover in a compressor according to another embodiment of the present invention.

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

FIG. 2 is a cross-sectional view showing a compressor according to an embodiment of the present invention, FIG. 3 is an enlarged cross-sectional view of a rear housing, an inverter cover, and an inverter in the compressor of FIG. 2, and FIG. 4 is a side view of FIG. FIG. 5 is a perspective view illustrating the inverter of FIG. 3, and FIG. 6 is a perspective view illustrating the inverter cover of FIG. 3.

2 to 6, the compressor according to an embodiment of the present invention includes a casing 100, a driving motor 200 provided in the inner space of the casing 100, and the driving motor 200. A compression mechanism unit 400 that is driven by and compresses the refrigerant and an inverter 500 that controls the driving motor 200 may be included.

The casing 100 is coupled to one side of the main housings 110 and 120 having a driving motor receiving space S1 in which the driving motor 200 is accommodated, and the compression mechanism unit 400 ), a front housing 130 having a compression mechanism receiving space S2, and a rear housing coupled to the other side of the main housings 110 and 120 and having an inverter receiving space S3 in which the inverter 500 is accommodated 140 and an inverter cover 150 coupled to the rear housing 140 and covering the inverter accommodation space S3.

Here, the direction in which the front housing 130 is located with respect to the main housings 110 and 120 is referred to as a front side (left direction in FIG. 2), and the rear housing with respect to the main housings 110 and 120 The direction in which 140 and the inverter cover 150 are located will be referred to as the rear side (right direction in FIG. 2).

The inverter cover 150 includes a disk-shaped partition plate 152 and an annular side plate portion 154 protruding from the outer circumferential portion of the partition plate 152 to the front side, and the front side is opened and the rear side is closed. It can be formed as Here, in the inverter cover 150, the side plate part 154 may be fastened to the rear housing 140, and the partition plate part 152 may cover the inverter accommodation space S3. That is, the inverter cover 150 may form the inverter accommodation space S3 together with the rear housing 140 by covering the opening of the rear housing 140.

Here, the partition plate portion 152 is formed as a flat and thin plate to reduce weight and cost, and accordingly, the strength of the partition plate portion 152 is weakened, and the partition plate portion 152 is easily damaged and damaged. Is generated, and noise and vibration transmitted to the outside of the compressor through the diaphragm portion 152 may cause a large problem. In consideration of this, the inverter cover 150 of the present embodiment is formed to protrude from the front surface of the partition plate portion 152, and is accommodated in the space formed by the partition plate portion 152 and the side plate portion 154 ( 156) may be further included.

The rib 156 may have an effect of substantially increasing the thickness of the diaphragm 152. Accordingly, since the strength of the inverter cover 150 is improved, damage or damage to the inverter cover 150 may be prevented. In addition, the noise and vibration damping performance of the inverter cover 150 is improved, so that noise and vibration generated by the operation of the drive motor 200 and the compression mechanism 400 are sufficiently attenuated by the inverter cover 150 As a result, propagation to the outside of the casing 100 can be prevented. That is, noise and vibration transmitted to the outside through the inverter cover 150 may be reduced.

Meanwhile, the rib 156 may be formed only on a part of the diaphragm 152 so as to minimize an increase in weight and cost due to the rib 156. That is, the rib 156 may be formed such that a part of the diaphragm 152 is covered by the rib 156, and the other part of the diaphragm 152 is not covered by the rib 156. .

More specifically, the ribs 156 may be formed to extend in a direction away from the center of the diaphragm 152 from a portion spaced from the center of the diaphragm 152.

Further, the ribs 156 may be formed in plural, and the plurality of ribs 156 may be formed in a radial shape based on the center of the diaphragm 152.

Here, the rib 156 may be extended to a fastening hole 154a formed in the side plate portion 154. The fastening hole 154a is a hole through which a fastening member (not shown) for fastening the inverter cover 150 and the rear housing 140 passes, and is arranged along the circumferential direction of the side plate part 154. It is formed with a plurality of holes, and each rib 156 may be formed to extend to each fastening hole (154a). In this way, the rib 156 extending to the fastening hole 154a may include a ring portion 156a surrounding the fastening hole 154a. The ring part 156a not only improves the strength of the area around the fastening hole 154a, but also noise transmitted from the rear housing 140 side to the inverter cover 150 through the fastening member (not shown). And can dampen vibration.

Further, the rib 156 may include flange portions 156b and 156c that increase the width of the rib 156 on at least one side of the rib 156. Here, the width of the rib 156 refers to a thickness in a direction perpendicular to the protruding direction and the extending direction of the rib 156. In this embodiment, the rib 156 is a first flange portion 156b formed at one end of the rib 156 positioned at the center of the diaphragm portion 152 and one end portion of the rib 156 And a second flange portion 156c formed between the other end (end connected to the fastening hole 154a) of the rib 156. The first flange portion 156b and the second flange portion 156c may be formed to protrude from the rib 156 in the width direction of the rib 156, respectively. The first flange portion 156b and the second flange portion 156c further enhance the strength of the inverter cover 150, respectively, and noise and vibration transmitted to the outside through the inverter cover 150 are further reduced. Can be reduced.

On the other hand, as the rib 156 is formed to cover a part of the diaphragm 152, a part of the inverter 500 faces the rib 156, and the other part of the inverter 500 Can be opposed to (152). At this time, as a predetermined element 510 of the elements 510 to be described later of the inverter 500 is formed at a position facing the partition plate 152 (a position not facing the rib 156), Insulation between the inverter 500 and the inverter cover 150 may be more effectively secured. This will be described later.

The driving motor 200 includes a stator 210 fixed inside the main housings 110 and 120 and a rotor 220 located inside the stator 210 and rotated by interaction with the stator 210. ) Can be included.

The rotor 220 may be coupled to the rotation shaft 300.

The compression mechanism unit 400 is coupled to the fixed scroll 410 fixed to the compression mechanism unit accommodation space S2 and the rotation shaft 300 to perform orbital motion, while compressing two pairs together with the fixed scroll 410 It may include an orbiting scroll 420 forming the thread (C).

The inverter 500 may include various elements 510 necessary for controlling the inverter 500 and a substrate 520 on which the elements 510 are mounted.

Here, in the inverter 500, when insulation between the inverter 500 (more precisely, the device 510) and the inverter cover 150 is not secured, the device 510 is damaged by a surge. As a result, a problem of stopping the drive of the compressor may occur. Therefore, insulation between the inverter 500 and the inverter cover 150 may be very important. In the conventional case, an insulating paper 158 is attached to the inverter cover 150 for insulation between the inverter 500 and the inverter cover 150 and is interposed between the inverter 500 and the inverter cover 150. , There is a problem in that the manufacturing cost of the compressor is increased by the insulating paper 158, and insulation between the inverter 500 and the inverter cover 150 is not achieved because the insulating paper 158 is separated from a predetermined position. In consideration of this, in the case of the present embodiment, in order to ensure insulation between the inverter 500 and the inverter cover 150 while minimizing an increase in manufacturing cost, the element 510 of the inverter 500 is not used without using an insulating paper 158. An insulating means may be formed between the inverter 500 and the inverter cover 150 with a separation distance between the inverter cover 150 and the inverter cover 150.

That is, the inverter cover 150 may be formed to be spaced apart from the inverter 500 (more precisely, the device 510) by a predetermined distance. More precisely, in the case of the present embodiment, as the rib 156 is formed, the separation distance between the element 510 of the inverter 500 and the inverter cover 150 is the element 510 of the inverter 500 and the It can be divided into a first distance (L1) between the front end (front surface) of the rib 156 and a second distance (L2) between the element 510 of the inverter 500 and the front surface of the partition plate 152. In addition, the first distance L1 and the second distance L2 may each have a predetermined value. The first distance L1 is formed to be a minimum insulation distance (for example, 2.89mm based on 275V), and the second distance L2 is the first distance L2 to secure additional insulation in consideration of the safety factor. It may be formed to a value larger than the distance L1 (eg, 5.5mm or more based on 275V). Here, the first distance (L1) and the second distance (L2) is the protruding length of the side plate portion 154, which is a distance between the front end surface of the side plate portion 154 and the front surface of the partition plate portion 152 Can be adjusted by That is, in a state in which the shape of the partition plate part 152 and the rib 156 is determined, the first distance L1 and the second distance L2 may be determined according to the protruding length of the side plate part 154. have. However, as the protruding length of the side plate portion 154 increases, the first distance L1 and the second distance L2 increase, which is advantageous in terms of insulation, but is disadvantageous in terms of size, weight and cost of the compressor. I can. In consideration of this, the protruding length (first distance L1 and second distance L2) of the side plate part 154 is to ensure insulation while minimizing the increase in size, weight and cost of the compressor, the partition plate part ( 152) may be formed to be long within a range accommodated in a predetermined space.

On the other hand, the inverter 500, so that the insulation between the inverter 500 and the inverter cover 150 is more effectively secured, the position where the element 510 of the inverter 500 faces the diaphragm 152 ( It may be formed at a position not facing the rib 156). That is, the element 510 of the inverter 500 may be disposed, for example, at the center side of the diaphragm 152 or may be disposed in a space between the plurality of ribs 156. In this case, as the separation distance between the element 510 and the inverter cover 150 is formed as the second distance L2 farther than the first distance L1, insulation may be improved. Here, it is preferable that all the elements 510 of the inverter 500 are formed at a position opposite to the diaphragm 152 (a position not opposite to the rib 156), but the circuit configuration of the inverter 500 It can be difficult. In this case, at least one of the elements 510 of the inverter 500, a relatively weak element 510 (for example, a power pin, an IGBT pin: Insulated Gate Bipolar Transistor Pin) Since it is formed at a position opposite to the portion 152 (a position not opposite to the rib 156), it is possible to secure maximum insulation within a range in which the circuit configuration of the inverter 500 is easily formed.

Hereinafter, the effect of the compressor according to the present embodiment will be described.

That is, when power is applied to the driving motor 200, the rotation shaft 300 rotates together with the rotor 220 and transmits a rotational force to the orbiting scroll 420. Then, the orbiting scroll 420 performs a orbiting motion by the rotational shaft 300, so that the compression chamber C may be continuously moved toward the center, thereby reducing the volume. Then, the refrigerant introduced into a suction pipe (not shown) communicated with the casing 100 and sucked into the compression chamber C is compressed while moving toward the center along the movement path of the compression chamber C, and the casing 100 ), a series of processes that are discharged to the outside of the compressor through a discharge pipe (not shown) communicated with each other are repeated. In this process, the driving motor 200 is controlled by the inverter 500, so that the cooling efficiency can be variably controlled.

Here, in the compressor according to the present exemplary embodiment, the ribs 156 are formed in the diaphragm 152 of the inverter cover 150, so that the strength of the inverter cover 150 may be improved. Accordingly, damage and breakage of the inverter cover 150 may be prevented. Further, the noise and vibration attenuation performance of the inverter cover 150 is improved, so that noise and vibration generated by the operation of the driving motor 200 and the compression mechanism 400 are sufficiently attenuated by the inverter cover 150 Then, noise and vibration transmitted to the outside through the inverter cover 150 may be reduced.

In addition, instead of the insulating paper 158, an insulating means is formed between the inverter 500 and the inverter cover 150 at a distance between the inverter 500 (more precisely, the device 510) and the inverter cover 150. , By securing insulation between the inverter 500 and the inverter cover 150, it is possible to prevent damage and damage to the inverter 500 and suppress an increase in manufacturing cost by the insulating means. At this time, as the first distance L1 between the element 510 of the inverter 500 and the rib 156 is formed to a predetermined value, the minimum insulation performance can be secured, and the element of the inverter 500 As the second distance L2 between the 510 and the partition plate 152 of the inverter cover 150 is formed to be greater than the first distance L1, additional insulation performance may be secured.

In addition, as the separation distance between the element 510 of the inverter 500 and the inverter cover 150 is formed long within a range in which the partition plate 152 of the inverter cover 150 is accommodated in a predetermined space, the compressor Insulation performance can be maximized while minimizing the increase in size, weight and cost.

In addition, in the inverter 500 and the inverter cover 150, a part of the inverter 500 is formed to face the rib 156 and the other portion of the inverter 500 is formed to face the hard plate, and the Since at least a predetermined element 510 among the various elements 510 of the inverter 500 is formed at a position opposite to the diaphragm 152, insulation performance can be effectively secured.

Meanwhile, in the case of the present embodiment, the rib 156 includes the ring portion 156a and the flange portions 156b and 156c, but as shown in FIG. 9, the strength of the inverter cover 150 is further increased. To improve, a connection part 156d for connecting the ribs 156 adjacent to each other among the plurality of ribs 156 may be further included. The connecting portion 156d may be formed in plural, and the plurality of connecting portions 156d may be arranged to overlap in a radial direction of the diaphragm 152 with respect to the center of the diaphragm 152.

Meanwhile, in the present embodiment, the compression mechanism unit 400 is formed of a scroll compressor having the fixed scroll 410 and the orbiting scroll 420, but may be formed of a reciprocating compressor, a rotary compressor, or the like.

100: casing 110, 120: main housing
130: front housing 140: rear housing
150: inverter cover 152: diaphragm
154: side plate portion 156: rib
200: drive motor 300: rotating shaft
400: compression mechanism 500: inverter
510: element 520: substrate
L1: first distance L2: second distance

Claims (13)

Casing 100;
A driving motor 200 provided in the inner space of the casing 100;
A compression mechanism unit 400 driven by the driving motor 200 to compress a refrigerant; And
Including; an inverter 500 for controlling the drive motor 200,
The casing 100 includes an inverter cover 150 covering the inverter 500,
The inverter 500 includes a plurality of elements 510 and a substrate 520 on which the plurality of elements 510 are mounted,
The inverter cover 150 includes a plate-shaped partition portion 152 and a rib 156 protruding from the partition plate portion 152 toward the plurality of elements 510,
The ribs 156 are formed to be spaced apart from the plurality of elements 510 by a first distance L1, and the diaphragm 152 is spaced apart from the plurality of elements 510 by a second distance L2. Is formed, the first distance (L1) and the second distance (L2) to form an insulating means between the inverter cover 150 and the inverter 500,
The rib 156 is formed to cover a part of the diaphragm 152 so that a part of the inverter 500 faces the rib 156, and the other part of the inverter faces the diaphragm 152. Is formed,
The plurality of devices 510 include at least one of a power pin and an ID pin,
At least a portion of the power pin and the ID pin is formed at a position opposite to the diaphragm portion (152). delete The method of claim 1,
The casing 100 includes a rear housing 140 in which the inverter 500 is accommodated,
The inverter cover 150 further includes a side plate portion 154 protruding from an outer peripheral portion of the partition plate portion 152 and coupled to the rear housing 140,
The rib 156 is a compressor that is accommodated in a space formed by the partition plate 152 and the side plate 154. The method of claim 1,
The first distance L1 is a compressor that is formed to be 2.89mm or more. The method of claim 1,
The second distance L2 is a compressor that is formed to be 5.5mm or more. The method of claim 3,
The first distance (L1) and the second distance (L2) is a compressor, characterized in that adjusted to the protruding length of the side plate (154). The method of claim 6,
The protruding length of the side plate portion 154 is formed to be long within a range in which the partition plate portion 152 is accommodated in a predetermined space. delete delete delete The method of claim 1,
The rib 156 is formed extending in a direction away from the center of the partition plate 152 from a portion spaced apart from the center of the partition plate 152,
The ribs 156 are formed in plural,
The plurality of ribs 156 are formed in a radial shape with respect to the center of the diaphragm portion 152. The method of claim 11,
At least a portion of the power pin and the ID pin is disposed at the center of the diaphragm portion (152). The method of claim 11,
At least some of the power pin and the ID pin are disposed in a space between the plurality of ribs (156).

Images