KR102321486B1 - Scroll compressor and manufacturing method for the same - Google Patents

Abstract

The present invention relates to a scroll compressor and a method for manufacturing a scroll compressor, comprising: a housing; a fixed scroll fastened to the housing; an orbiting scroll forming a compression chamber together with the fixed scroll and rotating; and a cover member sealing between the housing and the fixed scroll and covering an externally exposed surface of the fixed scroll. Accordingly, it is possible to reduce the cost required to prevent refrigerant leakage, and to prevent noise and vibration generated in the compression chamber from being transmitted to the outside through the fixed scroll.

Description

SCROLL COMPRESSOR AND MANUFACTURING METHOD FOR THE SAME

The present invention relates to a scroll compressor and a method for manufacturing a scroll compressor, and more particularly, to a scroll compressor and manufacturing method of a scroll compressor capable of preventing leakage between a fixed scroll and a casing and reducing noise and vibration radiated through the fixed scroll it's about how

BACKGROUND ART In general, an air conditioning device (A/C) for heating and cooling an interior is installed in a vehicle. Such an air conditioner 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.

There are two types of compressors: a reciprocating type for compressing a refrigerant according to a reciprocating motion of a piston, and a rotary type for performing compression while rotating.

The reciprocating type includes a crank type that transmits to a plurality of pistons using a crank depending on the transmission method of the driving source, and a swash plate type that transmits to a rotating shaft with a swash plate installed.

The rotary type includes a vane rotary type using a rotating rotary shaft and vanes, and a scroll type using a revolving scroll and a fixed scroll.

Scroll compressors are widely used for refrigerant compression in air conditioners, etc. because of their advantages in that they can obtain a relatively high compression ratio compared to other types of compressors and obtain a stable torque by smoothly connecting refrigerant suction, compression, and discharge strokes.

1 is a cross-sectional view illustrating a conventional scroll compressor, and FIG. 2 is a perspective view illustrating a fixed scroll, a sealing member, and a sealing member fixing pin in the scroll compressor of FIG. 1 .

1 and 2, the conventional scroll compressor includes a center housing 120 in which a main frame 122 is formed, a front housing 110 coupled to the center housing 120, and the main frame ( The fixed scroll 210 is fastened to the center housing 120 on the opposite side of the front housing 110 with reference to 122 , and the orbiting scroll 220 is interposed between the main frame 122 and the fixed scroll 210 . ) and a rear housing 130 coupled to the fixed scroll 210 from the opposite side of the orbiting scroll 220 with respect to the fixed scroll 210 .

The center housing 120 and the front housing 110 form a space in which the motor 300 generating a rotational force is accommodated.

The motor 300 includes a stator 310 and a rotor 320 that is rotated by interaction with the stator 310 .

The stator 310 is fixed to at least one of the center housing 120 and the front housing 110 .

The rotor 320 is rotatably accommodated in the stator 310 and is coupled to a rotation shaft 400 for transmitting rotational force from the motor 300 to the orbiting scroll 220 .

The rotating shaft 400 passes through the main frame 122 and an eccentric portion 410 formed at an end of the rotating shaft 400 is fastened to the orbiting scroll 220 .

The orbiting scroll 220 forms a compression chamber C together with the fixed scroll 210 , and receives rotational force from the motor 300 through the rotation shaft 400 to orbit with respect to the fixed scroll 210 . Compress the refrigerant while exercising.

The refrigerant compressed in the compression chamber C is discharged to the outside of the compression chamber C through a discharge port 212d formed in the fixed scroll 210 .

The rear housing 130 includes a discharge space D in which the refrigerant discharged from the discharge port 212d is accommodated.

The discharge space D communicates with a discharge pipe (not shown) that guides the refrigerant to the outside of the scroll compressor.

Here, the fixed scroll 210 forms a part of a casing forming the exterior of the compressor. That is, the casing is formed of the front housing 110 , the center housing 120 , the fixed scroll 210 , and the rear housing 130 .

A first sealing member 510 is interposed between the fixed scroll 210 and the center housing 120 to prevent refrigerant from leaking through between the fixed scroll 210 and the center housing 120, A second sealing member 520 is interposed between the fixed scroll 210 and the rear housing 130 to prevent refrigerant from leaking through the space between the fixed scroll 210 and the rear housing 130 .

Meanwhile, the first sealing member 510 and the second sealing member 520 are formed with pins 610 and 620 before the fixed scroll 210 is fastened to the center housing 120 and the rear housing 130 . and pin holes 218a, 218b, 512 and 522 are fixed to the fixed scroll 210 in a predetermined position.

Specifically, the fixed scroll 210 is fastened to the center housing 120 and the rear housing 130 by bolts (not shown). To this end, the fixed scroll 210 is provided with the bolt (not shown). A penetrating fixed scroll through hole 217 is formed, and the first sealing member 710 through which the bolt (not shown) passes through each of the first sealing member 510 and the second sealing member 520 is also penetrated. A hole 514 and a second sealing part 720 material through hole 524 are formed.

However, if the first sealing member 510 is not fixed to the fixed scroll 210 at a predetermined position, the first sealing part 710 material through hole 514 is formed between the fixed scroll through hole 217 and the fixed scroll through hole 217 . The bolt (not shown) cannot pass through the first sealing part 710 material through hole 514 and the fixed scroll through hole 217 because it does not communicate.

Likewise, if the second sealing member 520 is not fixed to the fixed scroll 210 at a predetermined position, the second sealing unit 720 material through hole 524 is formed between the fixed scroll through hole 217 and the fixed scroll through hole 217 . The bolt (not shown) cannot pass through the second sealing part 720 material through hole 524 and the fixed scroll through hole 217 because it does not communicate.

In consideration of this, the first pin 610 and the second sealing member 520 for fixing the first sealing member 510 to the fixed scroll 210 at a predetermined position are attached to the fixed scroll 210 . The fixed scroll first pin hole 218a and the second pin are provided with a second pin 620 for fixing to a predetermined position in the fixed scroll 210 and into which the first pin 610 is inserted. A fixed scroll second pin hole 218b into which the 620 is inserted is formed, and the first sealing member 510 has a first sealing member 710 material first pin hole into which the first pin 610 is inserted. 512 is formed, and a second pin hole 522 is formed in the second sealing member 520 by a second sealing part 720 into which the second pin 620 is inserted.

Then, one end of the first pin 610 is inserted into the fixed scroll first pin hole 218a, and the other end of the first pin 610 is the first pin hole of the first sealing part 710 material. By being inserted into the 512 , the first sealing member 510 is fixed to the fixed scroll 210 at a predetermined position. Accordingly, the first sealing part 710 material through-hole 514 communicates with the fixed scroll through-hole 217 .

Then, one end of the second pin 620 is inserted into the fixed scroll second pin hole 218b, and the other end of the second pin 620 is the second pin hole of the second sealing portion 720 material. By being inserted into the 522 , the second sealing member 520 is fixed to the fixed scroll 210 at a predetermined position. Accordingly, the second sealing part 720 material through-hole 524 communicates with the fixed scroll through-hole 217 .

However, in the conventional scroll compressor and the method of manufacturing the scroll compressor, the first sealing member 510 and the second sealing member 520 must be separately provided, and the first pin 610 and the fixed scroll After forming a first pin hole 218a and a first pin hole 512 for the first sealing part 710, the first pin 610, the fixed scroll first pin hole 218a, and the first The first sealing member 510 should be fixed to the fixed scroll 210 at a predetermined position by using the first pin hole 512 of the sealing portion 710, and the second pin 620, the After forming the second pin hole 522 of the fixed scroll second pin hole 218b and the second sealing part 720, the second pin 620, the fixed scroll second pin hole 218b and the second pin hole 522 are formed. As the second sealing member 520 is fixed to the fixed scroll 210 at a predetermined position by using the second sealing member 720 and the second pin hole 522, the There was a problem in that the cost increased.

In addition, as the fixed scroll 210 is exposed to the outside of the scroll compressor, noise and vibration generated in the compression chamber C are transmitted to the outside through the fixed scroll 210, which is disadvantageous in terms of noise and vibration. there was.

Korean Patent Publication No. 10-2016-0005497

Accordingly, it is an object of the present invention to provide a scroll compressor and a method of manufacturing a scroll compressor capable of reducing the cost required to prevent refrigerant leakage.

Another object of the present invention is to provide a scroll compressor and a method for manufacturing a scroll compressor capable of preventing noise and vibration generated in a compression chamber from being transmitted to the outside through a fixed scroll.

The present invention, to achieve the object as described above, the housing; a fixed scroll fastened to the housing; an orbiting scroll forming a compression chamber together with the fixed scroll and rotating; and a cover member that seals between the housing and the fixed scroll and covers an externally exposed surface of the fixed scroll.

The fixed scroll may include: a disk-shaped fixed end plate having a base surface, an outer peripheral surface bent from the base surface, and an upper surface bent from the outer peripheral surface and forming a rear surface of the base surface; a fixing wrap protruding from the central portion of the base surface; and an annular wall protruding from the outer periphery of the base surface and accommodating the fixing wrap, wherein the cover member may include a soundproofing portion covering the outer circumferential surface of the fixed end plate and the outer circumferential surface of the annular wall.

The cover member may include at least one of a first sealing part covering the front end surface of the annular wall and a second sealing part covering the upper surface of the fixed head plate.

The housing may include a center housing coupled to the front end surface of the annular wall, and the first sealing part may be interposed between the front end surface of the annular wall and the center housing.

The housing may include a rear housing coupled to an upper surface of the fixed end plate, and the second sealing part may be interposed between the upper surface of the fixed end plate and the rear housing.

The soundproofing part, the first sealing part, and the second sealing part may be integrally formed.

Further, the present invention provides a method for manufacturing a scroll compressor for manufacturing the scroll compressor, comprising: forming a fixed scroll; and a cover member forming step of forming a cover member on the fixed scroll.

The cover member may be formed by injection into the fixed scroll.

The method of manufacturing the scroll compressor may further include a hole forming step of forming holes into which bolts are inserted in the fixed scroll and the cover member, and the hole forming step may follow the cover member forming step.

A scroll compressor and a method for manufacturing a scroll compressor according to the present invention include: a housing; a fixed scroll fastened to the housing; an orbiting scroll forming a compression chamber together with the fixed scroll and rotating; and a cover member that seals between the housing and the fixed scroll and covers an externally exposed surface of the fixed scroll, thereby fixing the sealing members to the fixed scroll at a predetermined position without separately providing the sealing members. As well as not forming a pin and a pin hole for this, it is possible to not fix the sealing members to a predetermined position on the fixed scroll, respectively. Accordingly, it is possible to reduce the cost required to prevent refrigerant leakage.

In addition, as the cover member prevents the fixed scroll from being exposed to the outside of the compressor, it is possible to prevent noise and vibration generated in the compression chamber from being transmitted to the outside through the fixed scroll.

1 is a cross-sectional view showing a conventional scroll compressor;
2 is a perspective view illustrating a fixed scroll, a sealing member, and a sealing member fixing pin in the scroll compressor of FIG. 1;
3 is a cross-sectional view illustrating a scroll compressor according to an embodiment of the present invention;
4 is a perspective view illustrating a fixed scroll and a cover member in the scroll compressor of FIG. 3;
5 is a cross-sectional view taken along line AA of FIG. 4 .

Hereinafter, a scroll compressor and a method of manufacturing a scroll compressor according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a cross-sectional view illustrating a scroll compressor according to an embodiment of the present invention, FIG. 4 is a perspective view illustrating a fixed scroll and a cover member in the scroll compressor of FIG. 3 , and FIG. 5 is a cross-sectional view taken along line A-A of FIG. 4 .

3 to 5 , in the scroll compressor according to an embodiment of the present invention, a center housing 120 in which a main frame 122 is formed, and a front housing 110 coupled to the center housing 120 . ), a fixed scroll 210 fastened to the center housing 120 from the opposite side of the front housing 110 with respect to the main frame 122 , and between the main frame 122 and the fixed scroll 210 . The rear housing 130 may include an interposed orbiting scroll 220 and a rear housing 130 coupled to the fixed scroll 210 from an opposite side of the orbiting scroll 220 with respect to the fixed scroll 210 .

The center housing 120 and the front housing 110 may form a space in which the motor 300 generating a rotational force is accommodated.

The motor 300 may include a stator 310 and a rotor 320 that is rotated by interaction with the stator 310 .

The stator 310 may be fixed to at least one of the center housing 120 and the front housing 110 .

The rotor 320 may be rotatably accommodated in the stator 310 , and may be coupled to a rotation shaft 400 for transmitting rotational force from the motor 300 to the orbiting scroll 220 .

The rotation shaft 400 may extend toward the fixed scroll 210 and the orbiting scroll 220 through the main frame 122 .

The fixed scroll 210 is a circle having a base surface 212a, an outer peripheral surface 212b bent from the base surface 212a, and an upper surface 212c bent from the outer peripheral surface 212b and forming a rear surface of the base surface 212a. A plate-shaped fixing end plate 212, a fixing wrap 214 protruding from the central portion of the base surface 212a, and an annular wall 216 protruding from the outer periphery of the base surface 212a and receiving the fixing wrap 214 can do.

Also, in the fixed scroll 210 , the annular wall 216 may be coupled to the center housing 120 , and the fixed head plate 212 may be coupled to the rear housing 130 .

The orbiting scroll 220 includes a turning head plate 222 opposite to the fixed end plate 212 and a turning wrap 224 protruding from the orbiting head plate 222 and meshing with the fixed wrap 214, A compression chamber C may be formed together with the fixed scroll 210 .

And, the orbiting scroll 220, the orbiting head plate 222 is engaged with the eccentric portion 410 formed at the end of the rotation shaft 400, the rotational force from the motor 300 through the rotation shaft 400 It is possible to compress the refrigerant while rotating with respect to the fixed scroll 210 by receiving the .

The refrigerant compressed in the compression chamber C may be discharged to the outside of the compression chamber C through a discharge port 212d formed in the fixed scroll 210 .

The rear housing 130 may include a discharge space D in which the refrigerant discharged from the discharge port 212d is accommodated.

The discharge space D may communicate with a discharge pipe (not shown) that guides the refrigerant to the outside of the compressor.

Here, the fixed scroll 210 may form a part of a casing forming the exterior of the compressor. That is, the casing may be formed of the front housing 110 , the center housing 120 , the fixed scroll 210 , and the rear housing 130 .

Accordingly, refrigerant may leak between the center housing 120 and the fixed scroll 210 (more precisely, the front end surface 216a of the annular wall), and the rear housing 130 and the fixed scroll 210 ) (more precisely, the refrigerant may leak between the upper surface 212c of the fixed head plate), and the fixed scroll 210 (more precisely, the outer circumferential surface 216b of the annular wall and the outer circumferential surface 212b of the fixed head plate) is the compressor The fixed scroll 210 may be damaged by exposure to the outside of the , and noise and vibration generated in the compression chamber C may be transmitted to the outside through the fixed scroll 210 .

Considering this, in the present embodiment, sealing between the center housing 120 and the fixed scroll 210 and sealing between the rear housing 130 and the fixed scroll 210, A cover member 700 covering the externally exposed surface may be formed on the surface of the fixed scroll 210 .

Specifically, the cover member 700 may include a soundproof part 730 covering the outer circumferential surface 212b of the fixed end plate and the outer circumferential surface 216b of the annular wall.

In addition, the cover member 700 includes a first sealing portion 710 covering the front end surface 216a of the annular wall and a second sealing portion 710 covering the upper surface 212c (more precisely, the outer periphery of the upper surface 212c) of the end plate. At least one of the sealing parts 720 may be included.

The soundproofing part 730 may be formed in an annular shape overlapping the outer circumferential surface 216b of the annular wall in the rotational radial direction of the rotation shaft 400 .

The first sealing part 710 may be bent from one front end of the soundproofing part 730 to have an annular shape overlapping the front end surface 216a of the annular wall in the axial direction of the rotation shaft 400 .

In addition, the first sealing part 710 may be interposed between the front end surface 216a of the annular wall and the center housing 120 .

The second sealing part 720 may be bent from the other front end of the soundproof part 730 to have an annular shape overlapping the upper surface 212c of the fixed head plate in the axial direction of the rotation shaft 400 .

In addition, the second sealing part 720 may be interposed between the upper surface 212c of the fixed end plate and the rear housing 130 .

The cover member 700 according to this configuration is the first sealing part 710, and the refrigerant is provided between the center housing 120 and the fixed scroll 210 (more precisely, the front end surface 216a of the annular wall). leakage can be prevented.

And, the cover member 700 prevents the refrigerant from leaking between the rear housing 130 and the fixed scroll 210 (more precisely, the upper surface 212c of the fixed head plate) through the second sealing part 720 . can be prevented

And, the cover member 700 is the soundproof part 730, so that the fixed scroll 210 (more precisely, the outer circumferential surface 216b of the annular wall and the outer circumferential surface 212b of the fixed head plate) is exposed to the outside of the compressor. can be prevented Accordingly, it is possible to prevent noise and vibration generated in the compression chamber C from being transmitted to the outside through the fixed scroll 210 . In addition, it is possible to prevent the fixed scroll 210 from being damaged.

Meanwhile, as the cover member 700 is integrally formed with the soundproof part 730 , the first sealing part 710 and the second sealing part 720 , the soundproof part 730 material and the sealing members Since it is not necessary to separately provide the 510 and 520, the manufacturing cost can be reduced.

Here, the cover member 700 is formed on the surface of the fixed scroll 210 by a so-called two-stage injection method, so that the soundproof part 730 , the first sealing part 710 , and the second sealing part 720 are formed. ) may be integrally formed. That is, after the fixed scroll 210 is formed, the surface of the fixed scroll 210 (more precisely, the front end face 216a of the annular wall, the outer circumferential surface 216b of the annular wall, the outer circumferential surface 212b of the fixed head plate and the fixed For example, an elastic material may be injected onto the upper surface 212c of the head plate to form the cover member 700 .

In addition, since the cover member 700 is formed by being injected into the fixed scroll 210 , there is no need to separately dispose the cover member 700 at a predetermined position on the fixed scroll 210 , and the conventional method Since it is not necessary to form the pins 610 and 620 and the pin holes 218a, 218b, 512, and 522, the manufacturing cost can be further reduced.

Here, the fixed scroll 210 is fastened to the center housing 120 and the rear housing 130 by bolts (not shown), and for this purpose, the bolt (not shown) passes through the fixed scroll 210 . a fixed scroll through hole 217 is formed, and a first sealing portion through hole 714 through which the bolt (not shown) passes through each of the first sealing portion 710 and the second sealing portion 720 , and A second sealing part through-hole 724 is formed. Even if the cover member 700 is not disposed in a predetermined position on the fixed scroll 210 , the fixed scroll through-hole 217 passes through the first sealing part. The cover member 700 is formed by injection into the fixed scroll 210 so as to communicate with the hole 714 and the second sealing part through-hole 724 , and then passes through the first sealing part by, for example, a drill. A hole 714 , the fixed scroll through-hole 217 , and the second sealing part through-hole 724 may be preferably formed.

120: center housing 130: rear housing
210: fixed scroll 212: fixed end plate
212a: basal surface 212b: outer peripheral surface
212c: top surface 214: fixing wrap
216: annular wall 217: fixed scroll through hole
220: orbiting scroll 700: cover member
710: first sealing part 714: first sealing part through-hole
720: second sealing part 724: second sealing part through-hole
730: soundproof unit

Claims (9)

housings 120 and 130;
a fixed scroll 210 coupled to the housings 120 and 130;
an orbiting scroll 220 forming a compression chamber (C) together with the fixed scroll 210 and rotating; and
and a cover member (700) sealing between the housings (120, 130) and the fixed scroll (210) and covering an externally exposed surface of the fixed scroll (210). According to claim 1,
The fixed scroll 210 is
a base surface 212a, an outer peripheral surface 212b bent from the base surface 212a, and an upper surface 212c bent from the outer peripheral surface 212b and forming a rear surface of the base surface 212a;
a fixing wrap 214 protruding from the central portion of the base surface 212a; and
an annular wall (216) protruding from the outer periphery of the base surface (212a) and receiving the fixing wrap (214);
and the cover member (700) includes a soundproof part (730) covering the outer circumferential surface (212b) of the fixed head plate and the outer circumferential surface (216b) of the annular wall. 3. The method of claim 2,
The cover member 700 is a scroll including at least one of a first sealing portion 710 covering the front end surface 216a of the annular wall and a second sealing portion 720 covering the upper surface 212c of the fixed end plate. compressor. 4. The method of claim 3,
The housings 120 and 130 include a center housing 120 fastened to the front end surface 216a of the annular wall,
The first sealing part (710) is interposed between the front end surface (216a) of the annular wall and the center housing (120). 4. The method of claim 3,
The housings 120 and 130 include a rear housing 130 fastened to the upper surface 212c of the fixed end plate,
The second sealing part 720 is interposed between the upper surface 212c of the fixed head plate and the rear housing 130 . 4. The method of claim 3,
The soundproofing part (730), the first sealing part (710), and the second sealing part (720) are integrally formed. A method for manufacturing a scroll compressor for manufacturing the scroll compressor according to any one of claims 1 to 6, comprising:
A fixed scroll forming step of forming a fixed scroll (210); and
and a cover member forming step of forming a cover member (700) on the fixed scroll (210). 8. The method of claim 7,
The method for manufacturing a scroll compressor in which the cover member 700 is formed by injection into the fixed scroll 210 . 8. The method of claim 7,
The method further includes a hole forming step of forming holes (217, 714, 724) into which bolts are inserted in the fixed scroll (210) and the cover member (700);
The method of claim 1, wherein the hole forming step is followed by the cover member forming step.

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