KR20220144012A - Scroll Compressor - Google Patents

Abstract

In accordance with the present invention, provided is a scroll compressor including: a main housing in which a rotary shaft and a motor installed on the rotary shaft are housed, and which has a suction port formed to suction a refrigerant; a rotary scroll disposed on an upper side of the main housing and having a rotary head to which the upper end of the rotary shaft is coupled; a main frame interposed between the main housing and the rotary scroll to have a back pressure chamber between itself and the rotary scroll to be supplied with oil; a fixing scroll installed on an upper side of the main frame with the rotary scroll laid therebetween, and having a compression chamber formed between itself and the rotary scroll to compress the refrigerant therein; and a cover housing installed on an upper side of the fixing scroll, and having an outlet formed between itself and the fixing scroll to discharge the refrigerant, wherein the rotary head has a rotary groove and a connection groove connected to the rotary groove, which are individually formed on a lower side. In accordance with the present invention, since the connection groove connected to the rotary groove is formed on the rotary head and an insertion groove into which the sealing member is inserted is formed on the outside in a radial direction of the connection groove, an accurate check about whether the sealing member is installed during a back pressure inspection can be possible. Therefore, in accordance with the present invention, since an accurate check about whether the sealing member is installed on the rotary head can be possible, the sealing member can be always installed to keep an intermediate pressure space between the main frame and the rotary scroll always in an intermediate pressure state, and cause the pressure to be quickly supplied into the insertion groove through the connection groove connected to the rotary groove, thereby improving a sealing force of the back pressure chamber, which can lead to an improvement in the durability of the scroll compressor.

Description

Scroll Compressor

The present invention relates to a scroll compressor, and more particularly, to a scroll compressor that sucks, compresses, and discharges refrigerant.

A scroll compressor for a vehicle used in an air conditioning system of a vehicle is a device that suctions, discharges, and compresses a refrigerant.

In general, a scroll compressor includes a main housing, a main frame, an orbiting scroll, a fixed scroll, and a cover housing. The external refrigerant flows into the inside through the main housing. Between the main housing and the main frame, a motor and a rotating shaft coupled to the motor are accommodated. An orbiting scroll is interposed between the main frame and the fixed scroll, and the orbiting scroll has a turning mirror plate for suction and discharge of refrigerant and oil, and a sealing member is installed between the orbiting mirror plate and the main frame, and the orbiting scroll As it rotates, the refrigerant is compressed between the spiral fixed wrap formed on the fixed scroll and the orbiting wrap formed on the orbiting scroll. The compressed refrigerant is discharged to the outside through the cover housing.

However, in the conventional scroll compressor, the presence or absence of the orbiting scroll sealing member is determined by injecting the pressure into the back pressure chamber where oil is supplied between the main frame and the orbiting scroll during back pressure inspection. Even if the sealing member is omitted due to viscosity, some of the orbiting scroll and main frame are closely attached to each other and pass the back pressure test. There are many cases in which parts are missing.

That is, since the sealing member installed on the orbiting mirror plate is omitted, the intermediate pressure between the main frame and the orbiting scroll cannot be constantly maintained.

Accordingly, the durability of the scroll compressor used in the vehicle air conditioning system is deteriorated and the performance is deteriorated.

The present invention relates to a scroll compressor, and an object of the present invention is to provide a scroll compressor capable of accurately confirming whether a sealing member installed on a turning mirror plate is installed during back pressure inspection.

The present invention includes a main housing in which a rotating shaft and a motor installed on the rotating shaft are accommodated therein, and a suction port through which a refrigerant is sucked is formed; an orbiting scroll disposed on the upper side of the main housing and having a pivot plate to which an upper end of the rotation shaft is coupled; a main frame interposed between the main housing and the orbiting scroll in which a back pressure chamber to which oil is supplied is formed between the main frame and the orbiting scroll; a sealing member installed on the revolving mirror plate; a fixed scroll installed on the upper side of the main frame with the orbiting scroll interposed therebetween and having a compression chamber in which a refrigerant is compressed between the orbiting scroll; It is installed on the upper side of the fixed scroll and includes a cover housing having a discharge port through which the refrigerant is discharged between the fixed scroll, wherein the orbiting mirror plate has a turning groove and a communication groove communicating with the orbiting groove on the lower surface, respectively. A formed scroll compressor is provided.

The communication groove is formed on the outside of the turning groove with respect to the radial direction of the turning mirror plate.

The orbital groove includes a plurality of first installation grooves disposed along a radial direction of the turning mirror plate, and a plurality of offset grooves disposed between the plurality of first installation grooves, wherein the communication groove includes the first It communicates with at least one of the installation groove and the offset groove.

The pivot groove includes a plurality of offset grooves disposed in a radial direction of the pivot plate and a plurality of second installation grooves disposed between the plurality of offset grooves, and the communication groove is in the second installation groove. communicate

The turning mirror plate is further formed with an insertion groove into which the sealing member is inserted on the radially outer side of the communication groove, and the communication groove communicates the turning groove and the insertion groove with each other.

The communication groove has a vertical width of 1 mm to 3 mm based on the lower surface of the inner wall surrounding the radially inner side of the insertion groove.

It further includes a first anti-rotation ring coupled to the first installation groove.

It further includes a second anti-rotation ring coupled to the second installation groove.

According to the scroll compressor according to the present invention, a communication groove communicating with the turning groove and an insertion groove into which the sealing member is inserted are formed in the turning mirror plate in the radial direction of the communication groove, so that it is accurate to check whether the sealing member is installed during the back pressure test. make it possible to check

Therefore, according to the scroll compressor according to the present invention, the sealing member is always installed in order to accurately check whether the sealing member installed on the orbiting mirror plate is installed, so that the intermediate pressure space between the main frame and the orbiting scroll is always constant. The durability of the scroll compressor is improved because the sealing force of the back pressure chamber is improved by allowing pressure to be quickly supplied to the insertion groove through the communication groove communicating with the orbiting groove.

1 is a cross-sectional view of a scroll compressor according to a first embodiment of the present invention.
FIG. 2 is an enlarged view of part A of FIG. 1 .
3 is an enlarged view of an insertion part of the revolving mirror plate.
FIG. 4 is a view showing a shape in which a communication groove is provided in a first installation groove at a lower side of the revolving mirror plate of FIG. 1 .
5 is a view showing a shape in which a communication groove is provided in an offset groove on the lower side of the revolving mirror plate according to the second embodiment of the present invention.
6 is a view showing a shape in which a communication groove is provided in a second installation groove on the lower side of the revolving mirror plate according to the third embodiment of the present invention.
7 is a view showing a shape in which a communication groove is provided in the first installation groove and the offset groove on the lower side of the revolving mirror plate according to the fourth embodiment of the present invention.
8 is a view showing a shape in which the first anti-rotation ring is provided in the first installation groove of the revolving mirror plate according to the fifth embodiment of the present invention.
9 is a view showing a shape in which a second anti-rotation ring is provided in the second installation groove of the revolving mirror plate according to the sixth embodiment of the present invention.

Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1 to 7 , the scroll compressor 100 according to the first embodiment of the present invention includes a main housing 110 , an orbiting scroll 120 , a main frame 130 , a fixed scroll 140 , and a cover housing. (150).

The main housing 110 is formed in a hollow cylindrical shape in which a rotating shaft 112 and a motor 111 installed on the rotating shaft 112 are accommodated therein, and a suction port (not shown) through which a refrigerant is sucked is formed.

Here, the refrigerant sucked through the suction port (not shown) flows into the suction chamber 113 which is a space inside the main housing 110 in which the motor 111 and the rotation shaft 112 are disposed.

The suction chamber 113 is filled with the refrigerant introduced through the suction port (not shown), and the refrigerant introduced into the suction chamber 113 comes into contact with the motor 111 and the rotating shaft 112 to contact the motor. 111 and the rotation shaft 112 are brought into contact to cool the motor 111 and the rotation shaft 112 .

The orbiting scroll 120 is disposed on the upper side of the main housing 110, the upper end of the rotating shaft 112 is coupled, and the orbiting scroll plate 121 revolves by the rotating shaft 112. 122) is formed and the rotation shaft 112 is coupled.

Here, the revolving mirror plate 121 is further provided with a sealing member 126 .

The main frame 130 is interposed between the main housing 110 and the orbiting scroll 120 to form a back pressure chamber 131 between the main frame and the orbiting scroll 120 .

At this time, the oil discharged from the back pressure chamber 131 is mixed with the refrigerant in the suction chamber 113 .

The fixed scroll 140 is seated on the upper side of the main frame 130, and a compression chamber 141 is formed in which refrigerant flows and is compressed from the suction chamber 113 between the orbital wrap 122. It has a fixing wrap (142).

The cover housing 150 is seated on the upper side of the fixed scroll 140 , and a discharge port 151 through which the compressed refrigerant is discharged is formed.

In addition, the cover housing 150 is a discharge chamber ( 152) is formed, and an oil separator (not shown) is provided.

Here, the refrigerant introduced into the discharge chamber 152 through the discharge hole 143 is separated into oil and refrigerant gas by the principle of centrifugation with the oil separator (not shown), and among them, the refrigerant gas is separated from the discharge port ( 151), and the oil flows into the back pressure chamber 131 through an oil passage (not shown).

On the other hand, the scroll compressor 100 of the present invention has a shape for checking whether the sealing member 126 is installed on the turning mirror plate 121 during a back pressure test. A communication groove 124 communicating with the 123 is formed, which will be described later.

Hereinafter, in the scroll compressor 100 according to the first embodiment of the present invention, a turning groove 123 in the turning mirror plate 121 and the communicating groove 124 communicating with the turning groove 123 are formed on the lower surface of the scroll compressor 100 according to the first embodiment of the present invention. It will be described in more detail about the shape that enables confirmation of whether the sealing member 126 is installed or not during the back pressure test.

The orbiting groove 123 includes a plurality of first installation grooves 123a disposed in a radial direction of the turning mirror plate 121 and a plurality of offsetting grooves disposed between the plurality of first installation grooves 123a. A groove 123b is provided.

Here, the communication groove 124 communicates with any one of the plurality of first installation grooves 123a.

On the other hand, the turning mirror plate 121 is further formed with an insertion groove 125 in which the sealing member 126 is inserted on the radially outer side of the communication groove 124 .

That is, the communication groove 124 communicating with any one of the first installation grooves 123a communicates the insertion grooves 125 with each other, and the lower surface of the inner wall surrounding the radially inner side of the insertion groove 125 is formed. Since it is provided to have an upper and lower width of 1 mm to 3 mm as a reference, it is possible to check whether the sealing member 126 installed in the insertion groove 125 is installed during the back pressure test of the scroll compressor 100 of the present invention. .

Due to this, in the scroll compressor 100 of the present invention, the intermediate pressure space between the main frame 130 and the orbiting scroll 120 always maintains a constant intermediate pressure state, so that abnormal behavior of the orbiting scroll 120 does not occur. It is possible to prevent leakage of compressed gas.

In addition, the communication groove 124 is a method of the present invention to increase the sealing force of the back pressure chamber 131 by rapidly supplying pressure to the insertion groove 125 into which the sealing member 126 is inserted. The performance of the scroll compressor 100 is improved.

Hereinafter, in the orbiting mirror plate 221 according to the second embodiment of the scroll compressor 100 of the present invention, a turning groove 223 and the communicating groove 224 communicating with the turning groove 223 are formed on the lower surface, respectively. A shape that is formed and enables confirmation of whether a sealing member (not shown) installed on the swivel mirror plate 221 is installed during the back pressure test will be described in more detail. is to be omitted.

The orbiting groove 223 includes a plurality of first installation grooves 223a disposed in a radial direction of the turning mirror plate 221 and a plurality of offsets disposed between the plurality of first pivoting grooves 223a. A groove 223b is provided.

Here, the communication groove 224 communicates with any one of the plurality of offset grooves 223b.

On the other hand, the turning mirror plate 221 is further formed with an insertion groove 225 into which the sealing member is inserted at the radially outer side of the communication groove 224 .

That is, the communication groove 224 communicating with any one of the offset grooves 223b communicates the offset groove 223b and the insertion groove 225 with each other, and the radial inner side of the insertion groove 225 is formed. Since it is provided to have an upper and lower width of 1 mm to 3 mm based on the lower surface of the surrounding inner wall, it is possible to check whether the sealing member inserted into the insertion groove 225 is installed during the back pressure test of the scroll compressor 100 of the present invention. will do

Due to this, in the scroll compressor 100 of the present invention, the intermediate pressure space between the main frame 130 and the orbiting scroll 120 always maintains a constant intermediate pressure state to prevent abnormal behavior of the orbiting scroll 120 from occurring. It is possible to prevent leakage of compressed gas.

In addition, in the communication groove 224 , pressure is quickly supplied to the insertion groove 225 into which the sealing member is inserted, so that the sealing force of the back pressure chamber 131 is increased.

Hereinafter, a turning groove 323 in the turning mirror plate 321 according to the third embodiment of the scroll compressor 100 of the present invention and the communicating groove 324 communicating with the turning groove 323 are formed on the lower surface of the scroll compressor 100 of the present invention. It is intended to describe in more detail a shape that enables confirmation of whether a sealing member (not shown) installed on the revolving mirror plate 321 is installed or not during the back pressure test, and in this case, the same shape as the first and second embodiments A description will be omitted.

The turning groove 323 includes a plurality of offset grooves 323a disposed along the radial direction of the turning mirror plate 321 and a plurality of second installation grooves disposed between the plurality of offset grooves 323a ( 323c).

Here, the communication groove 324 communicates with any one of the plurality of second installation grooves 323c.

In addition, the turning mirror plate 321 is further formed with an insertion groove 325 into which a sealing member (not shown) is inserted in the radial direction of the communication groove 324 .

That is, the communication groove 324 formed in any one of the second installation grooves 323c communicates the second installation groove 323c and the insertion groove 325 with each other, and Since it is provided to have an upper and lower width of 1 mm to 3 mm based on the lower surface of the inner wall surrounding the inner side in the radial direction, it is possible to check the sealing member inserted into the insertion groove 325 during the back pressure test of the scroll compressor 100 of the present invention. will do

Due to this, in the scroll compressor 100 of the present invention, the intermediate pressure space between the main frame and the orbiting scroll always maintains a constant intermediate pressure state to prevent abnormal behavior of the orbiting scroll, thereby preventing the leakage of compressed gas. do.

In addition, in the scroll compressor 100 of the present invention, in the communication groove 324 , pressure is quickly supplied to the insertion groove 325 into which the sealing member is inserted, so that it is possible to increase the sealing force of the back pressure chamber. .

Hereinafter, in the orbiting mirror plate 421 according to the fourth embodiment of the scroll compressor 100 of the present invention, a turning groove 423 and the communicating groove 424 communicating with the turning groove 423 are formed on the lower surface. A shape that enables confirmation of whether a sealing member (not shown) installed on the lower side of the revolving mirror plate 421 is installed during the back pressure test will be described in more detail.

The orbiting groove 423 includes a plurality of first installation grooves 423a disposed along the radial direction of the turning mirror plate 421 and a plurality of offsets disposed between the plurality of first pivoting grooves 423a. A groove 423b is provided.

Here, referring to FIG. 7 , the communication groove 424 communicates with at least one of the plurality of first installation grooves 423a and the offset grooves 423b.

On the other hand, the turning mirror plate 421, an insertion groove 425 into which the sealing member is inserted is further formed on the radially outer side of the communication groove 424 .

That is, at least one of the communication grooves 424 communicating with the first installation groove 423a communicates the insertion groove 425 with each other, and the lower surface of the inner wall surrounding the radially inner side of the insertion groove 425 . Since it is provided to have an upper and lower width of 1 mm to 3 mm based on the back pressure test of the scroll compressor 100 of the present invention, it is possible to check whether a sealing member (not shown) installed in the insertion groove 425 is possible. do.

For this reason, the scroll compressor 100 of the present invention maintains an intermediate pressure space between the main frame and the orbiting scroll to always maintain a constant intermediate pressure state to prevent abnormal behavior of the orbiting scroll and to prevent leakage of compressed gas. it is possible to do

In addition, the communication groove 424 improves the performance of the scroll compressor 100 of the present invention because pressure is quickly supplied to the insertion groove 425 into which the sealing member is inserted to increase the sealing force of the back pressure chamber. make it

Hereinafter, the shape in which the first anti-rotation ring 520 is provided on the orbiting mirror plate 521 according to the fifth embodiment of the scroll compressor 100 of the present invention will be described in more detail. A description of the same shape as that of the , 2 and 4 embodiments will be omitted.

Meanwhile, the turning groove 523 includes a plurality of first installation grooves 523a disposed along the radial direction of the turning mirror plate 521 and a plurality of first installation grooves 523a disposed between the plurality of first installation grooves 523a. A first anti-rotation ring ( 520).

That is, since the first anti-rotation ring 520 is disposed in the first installation groove 523a as described above, it is possible to prevent the orbiting scroll from rotating.

Hereinafter, the shape in which the second anti-rotation ring 620 is provided on the orbiting mirror plate 621 according to the sixth embodiment of the scroll compressor 100 of the present invention will be described in more detail. A description of the same shape as in the first and third embodiments will be omitted.

On the other hand, the turning groove 623, a plurality of offset grooves 623b disposed along the radial direction of the turning mirror plate 621 and a plurality of second installation grooves disposed between the plurality of offset grooves 623b 623c, wherein the scroll compressor of the present invention further includes a second anti-rotation ring 620 coupled to the second installation groove 623c disposed along the radial direction of the orbiting mirror plate 621. include

That is, since the second anti-rotation ring 620 is disposed in the second installation groove 623c as described above, it is possible to prevent the orbiting scroll from rotating.

However, in the conventional scroll compressor, since the turning mirror plate and the main frame are in excessive contact with each other, it is not possible to accurately check whether the sealing member installed on the turning mirror plate is installed during the back pressure test, and this often causes the sealing member to be omitted. got lost

That is, since the sealing member installed on the revolving mirror plate was omitted, the intermediate pressure between the main frame and the fixed scroll could not be constantly maintained.

Accordingly, the durability of the scroll compressor used in the vehicle air conditioning system is deteriorated and the performance is deteriorated.

However, according to the scroll compressor according to the present invention, a communication groove communicating with the turning groove and an insertion groove into which the sealing member is inserted are formed on the rotary mirror plate in the radial direction of the communication groove, so that it can be determined whether the sealing member is installed during back pressure inspection. It allows for accurate identification of

Therefore, according to the scroll compressor according to the present invention, the sealing member is always installed in order to accurately check whether the sealing member installed on the orbiting mirror plate is installed, so that the intermediate pressure space between the main frame and the orbiting scroll is always constant. The durability of the scroll compressor is improved because the sealing force of the back pressure chamber is improved by allowing pressure to be quickly supplied to the insertion groove through the communication groove communicating with the orbiting groove.

100: scroll compressor 110: main housing
111: motor 112: rotation shaft
113: suction chamber 120: orbiting scroll
121,221,321,421,521,621: swivel head plate 122: swivel wrap
123,223,323,423,523,623: swivel groove 123a,223a,423a,523a: first installation groove
123b,223b,323a,423b,523b, 623b: offset groove 124,224,324,424: communication groove
125,225,325,425: insertion groove 126: sealing member
130: main frame 131: back pressure chamber
140: fixed scroll 141: compression chamber
142: fixed wrap 143: discharge hole
150: cover housing 151: outlet
152: discharge chamber 323c, 623c: second installation groove
520: first anti-rotation ring 620: second anti-rotation ring

Claims (8)

a main housing in which a rotating shaft and a motor installed on the rotating shaft are accommodated therein, and a suction port through which refrigerant is sucked;
an orbiting scroll disposed on the upper side of the main housing and having a pivot plate to which an upper end of the rotating shaft is coupled;
a main frame interposed between the main housing and the orbiting scroll in which a back pressure chamber to which oil is supplied is formed between the main frame and the orbiting scroll;
a sealing member installed on the revolving mirror plate;
a fixed scroll installed on the upper side of the main frame with the orbiting scroll interposed therebetween and having a compression chamber in which a refrigerant is compressed between the orbiting scroll;
and a cover housing installed on the upper side of the fixed scroll and having a discharge port through which the refrigerant is discharged between the fixed scroll and the fixed scroll,
In the orbiting mirror plate, a turning groove and a communication groove communicating with the turning groove are formed on a lower surface of each of the scroll compressors. The method according to claim 1,
The communication groove is formed outside the orbiting groove with respect to a radial direction of the orbiting mirror plate. The method according to claim 1,
The orbital groove includes a plurality of first installation grooves disposed in a radial direction of the turning mirror plate, and a plurality of offset grooves disposed between the plurality of first installation grooves,
The communication groove is in communication with at least one of the first installation groove and the offset groove. The method according to claim 1,
The pivot groove includes a plurality of offset grooves disposed in a radial direction of the pivot mirror plate and a plurality of second installation grooves disposed between the plurality of offset grooves,
The communication groove is in communication with the second installation groove scroll compressor. The method according to claim 1,
The revolving mirror plate is further formed with an insertion groove into which the sealing member is inserted on the radially outer side of the communication groove,
The communication groove is a scroll compressor for communicating the orbiting groove and the insertion groove with each other. The method according to claim 1,
The communication groove may have a vertical width of 1 mm to 3 mm based on a lower surface of an inner wall surrounding a radially inner side of the insertion groove. 4. The method according to claim 3,
The scroll compressor further comprising a first anti-rotation ring coupled to the first installation groove. 5. The method according to claim 4,
The scroll compressor further comprising a second anti-rotation ring coupled to the second installation groove.

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