KR102522649B1 - Scroll compressor - Google Patents

Abstract

The present invention, a main housing having a suction chamber into which a refrigerant is introduced, accommodating a motor and a rotating shaft coupled to the motor into the suction chamber; Main frame installed on the upper side of the main housing; a fixed scroll installed on the upper side of the main frame; a rotating scroll installed between the main frame and the fixed scroll, coupled to the rotating shaft, having a back pressure chamber formed between the rotating scroll and the main frame, and having a compression chamber formed between the rotating scroll and the fixed scroll; a cover housing installed above the fixed scroll and having a discharge chamber through which refrigerant is discharged to the outside; and a gasket installed between the fixed scroll and the cover housing; The gasket provides a scroll compressor in which an inner bead and an outer bead disposed radially outside of the inner bead are formed.

Description

Scroll compressor {Scroll compressor}

The present invention relates to a scroll compressor, and more particularly, to a scroll type compressor that sucks in refrigerant from the outside using rotational force of a motor, compresses it, and then discharges it to the outside.

In general, a compressor means a device that sucks in gas, compresses it, and then discharges it to the outside. Compressors are classified into electric type, mechanical type, etc. according to the type of power source, and also classified into swash plate type, scroll type, screw type, etc. according to the driving principle.

Among them, the electric scroll compressor refers to a device that sucks in and compresses refrigerant from the outside through relative rotation of two scrolls, and then supplies it to another target space or mechanical part. In addition, in such an electric scroll compressor, a motor installed inside generates rotational force by receiving electricity from the outside, and sucks, compresses, and discharges refrigerant through this rotational force.

The scroll compressor includes a main housing, a main frame, a rotating 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. A rotary scroll is interposed between the main frame and the fixed scroll. As the rotating scroll rotates, the refrigerant is compressed between the spiral blade formed on the fixed scroll and the spiral blade formed on the rotating scroll. The compressed refrigerant is discharged to the outside through the cover housing.

According to the conventional scroll compressor, a gasket is interposed between the cover housing and the fixed scroll to form the discharge pressure to maintain airtightness of the compressor. Here, the higher the discharge pressure, the larger the pressure difference with the air. Therefore, in order to maintain the airtightness of the gasket, much consideration is required when designing the gasket material, bead, and bolt tightening torque. Even small problems in the manufacturing process can cause refrigerant leakage Compressor reliability problems may result.

The present invention was developed to solve the above problems, and an object of the present invention is to improve compressor reliability by reducing the pressure acting on the gasket to facilitate airtightness.

The present invention, a main housing having a suction chamber into which a refrigerant is introduced, accommodating a motor and a rotating shaft coupled to the motor into the suction chamber; Main frame installed on the upper side of the main housing; a fixed scroll installed on the upper side of the main frame; a rotating scroll installed between the main frame and the fixed scroll, coupled to the rotating shaft, having a back pressure chamber formed between the rotating scroll and the main frame, and having a compression chamber formed between the rotating scroll and the fixed scroll; a cover housing installed above the fixed scroll and having a discharge chamber through which refrigerant is discharged to the outside; and a gasket installed between the fixed scroll and the cover housing; The gasket provides a scroll compressor in which an inner bead and an outer bead disposed radially outside of the inner bead are formed.

In the cover housing, a back pressure chamber communication passage for supplying oil separated from the refrigerant through an oil separator installed in the discharge chamber to the back pressure chamber is formed at a portion in contact with the gasket, and the inner bead is formed in the back pressure chamber communication passage. and a first inner bead disposed radially inside, and the outer bead includes a first outer bead disposed radially outside of the back pressure chamber communication passage.

In the cover housing, a compression chamber communication passage is formed at a portion in contact with the gasket to supply oil flowing from the back pressure chamber to the upper side of the fixed scroll to the compression chamber, and the inner bead is formed in the compression chamber communication passage. A second inner bead is disposed radially inside, and the outer bead includes a second outer bead disposed radially outside the compression chamber communication passage.

In the fixed scroll, a back pressure chamber communication passage for supplying the oil separated from the refrigerant through the oil separator installed in the discharge chamber to the back pressure chamber is formed at a portion in contact with the gasket, and the inner bead is formed in the back pressure chamber communication passage and a first inner bead disposed radially inside, and the outer bead includes a first outer bead disposed radially outside of the back pressure chamber communication passage.

In the fixed scroll, a compression chamber communication passage is formed at a portion in contact with the gasket to supply oil introduced from the back pressure chamber to the upper side of the fixed scroll to the compression chamber, and the inner bead is formed in the compression chamber communication passage. A second inner bead is disposed radially inside, and the outer bead includes a second outer bead disposed radially outside the compression chamber communication passage.

The inner bead and the outer bead each protrude upward from the gasket.

The inner bead and the outer bead protrude downward from the gasket, respectively.

According to the scroll compressor according to the present invention, the gasket has a double inner bead and an outer bead protruding along the axial direction and extending in the circumferential direction, and a discharge chamber in which a high pressure discharge pressure acts in the center of the cover housing. By forming a pressure distribution having an intermediate value between the pressure of the atmosphere and the pressure of the refrigerant in the discharge chamber between the inner bead and the outer bead, the pressure difference between the suction chamber and the atmosphere can be reduced. can improve performance. In addition, according to the present invention, since the leakage of refrigerant in the high-pressure discharge chamber is at the suction pressure and the intermediate pressure and leads to internal leakage, leakage of the refrigerant to the outside of the compressor can be prevented.

1 is a cross-sectional view of a scroll compressor according to the present invention.
2 is a view showing a gasket and a cover housing of a scroll compressor according to a first embodiment of the present invention.
3 is a view showing a gasket and a fixed scroll of a scroll compressor according to a second embodiment of the present invention.

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

Referring to FIG. 1, the scroll compressor 100 according to the present invention sucks in and compresses the refrigerant and discharges it to the outside, and the main housing 110, the main frame 120, the fixed scroll 130, and the rotation It includes a scroll 140, a cover housing 150, and gaskets 160, 160a, and 160b.

In the main housing 110, a suction chamber 111 into which refrigerant flows is formed therein. The suction chamber 111 accommodates a motor 112 and a rotating shaft 113 coupled to the motor 112 and rotating. The main frame 120 is installed above the main housing 110 . The fixed scroll (130) is installed on the upper side of the main frame (120). The rotary scroll 140 is installed between the main frame 120 and the fixed scroll 130, and is coupled to the rotary shaft 113 to rotate.

A back pressure chamber 141 is formed between the rotary scroll 140 and the main frame 120, and a compression chamber 131 is formed between the rotary scroll 140 and the fixed scroll 130. The compression chamber 131 is a space in which the refrigerant introduced from the suction chamber 111 is compressed by rotation of the rotary scroll 140 . The back pressure chamber 141 is a space where oil exists, and the oil present in the back pressure chamber 141 presses the rotary scroll 140 upward, so that the rotary scroll 140 is the main frame 120. ) and prevents friction from occurring between them.

The cover housing 150 is installed above the fixed scroll 130 and has a discharge chamber 153 through which refrigerant is discharged to the outside. The gaskets 160, 160a, and 160b are installed between the fixed scroll 130 and the cover housing 150, and seal the discharge chamber 153 from the outside. Accordingly, the gaskets 160, 160a, and 160b prevent the refrigerant present in the discharge chamber 153 from leaking to the outside.

Referring to FIG. 2 or 3 , inner beads 161 and 162 and outer beads 163 and 164 protrude from the gaskets 160 , 160a and 160b. The inner beads 161 and 162 protrude from the gaskets 160, 160a and 160b along the axial direction of the rotating shaft 113, and are formed in a shape extending along the circumferential direction of the gaskets 160, 160a and 160b. . The outer beads 163 and 164 are disposed outside the inner beads 161 and 162 based on the radial direction of the gaskets 160 , 160a and 160b.

Between the cover housing 150 and the fixed scroll 130, a back pressure chamber communication passage 151 and a compression chamber communication passage 152 are formed. The back pressure chamber communication passage 151 serves to supply the oil separated from the refrigerant through the oil separator installed in the discharge chamber 153 to the back pressure chamber 141 . The compression chamber communication passage 152 supplies the oil introduced from the back pressure chamber 141 to the upper side of the fixed scroll 130 to the compression chamber 131 .

The inner beads 161 and 162 include a first inner bead 161 and a second inner bead 162 . The outer beads 163 and 164 include a first outer bead 163 and a second outer bead 164 .

The first inner bead 161 and the first outer bead 163 are disposed inside and outside the back pressure chamber communication passage 151 in a radial direction, respectively, and surround the back pressure chamber communication passage 151 . Accordingly, the first inner bead 161 and the first outer bead 163 separate the back pressure chamber communication passage 151 from the outside and the discharge chamber 141, and the back pressure chamber communication passage 151 The oil flowing through is prevented from being exposed to the outside or to the discharge chamber 141.

The second inner bead 162 and the second outer bead 164 are disposed inside and outside the compression chamber communication passage 152 in a radial direction, respectively, and surround the compression chamber communication passage 152 . Accordingly, the second inner bead 162 and the second outer bead 164 separate the compression chamber communication passage 152 from the outside and the discharge chamber 141, and the compression chamber communication passage 152 The oil flowing through is prevented from being exposed to the outside or to the discharge chamber 141.

According to the scroll compressor 100 according to the present invention, the intermediate pressure defined by the inner beads 161 and 162 and the outer beads 163 and 164 between the discharge chamber 153 and the outside of the scroll compressor 100 ( By additionally forming a space of middle pressure, a buffer space may be formed between the discharge chamber 153 and the outside of the scroll compressor 100. Therefore, according to the present invention, sealing performance by the gaskets 160 , 160a and 160b can be improved, and leakage of the refrigerant from the discharge chamber 153 to the outside can be more effectively prevented.

Referring to FIG. 2 , in the first embodiment of the present invention, the back pressure chamber communication passage 151 and the compression chamber communication passage 152 are in contact with the gasket 160a of the cover housing 150, respectively. can be formed at the site. At this time, the inner beads 161 and 162 and the outer beads 163 and 164 protrude upward from the gasket 160a, respectively, and are disposed to be in contact with a portion of the cover housing 150 in contact with the gasket 160a, They may be arranged to surround the back pressure chamber communication passage 151 and the compression chamber communication passage 152, respectively.

Contrary to this, referring to FIG. 3 , in the second embodiment of the present invention, the back pressure chamber communication passage 151 and the compression chamber communication passage 152 are the gasket 160b of the fixed scroll 130, respectively. ) may be formed at the site in contact with At this time, the inner beads 161 and 162 and the outer beads 163 and 164 protrude downward from the gasket 160b, respectively, and are disposed to be in contact with a portion of the fixed scroll 130 in contact with the gasket 160b, They may be arranged to surround the back pressure chamber communication passage 151 and the compression chamber communication passage 152, respectively.

However, this is only one of several embodiments related to the present invention, and either of the back pressure chamber communication passage 151 and the compression chamber communication passage 152 is the gasket 160 and the cover housing 150. One may be formed at a portion in contact with the fixed scroll 130, and the other may be formed at a portion in contact with the gasket 160. In addition, the inner beads 161 and 162 and the outer beads 163 and 164 protrude upward or downward from the gasket 160, corresponding to positions where the back pressure chamber communication passage 151 and the compression chamber communication passage 152 are formed. It can be.

According to the scroll compressor according to the present invention, the gasket has a double inner bead and an outer bead that protrude along the axial direction and extend in the circumferential direction, and the high pressure discharge pressure acts on the central portion of the cover housing The discharge chamber is formed, and a pressure distribution having an intermediate value between the atmospheric pressure and the refrigerant pressure in the discharge chamber is formed between the inner bead and the outer bead, thereby reducing the pressure difference between the suction chamber and the atmosphere. confidentiality can be improved. In addition, according to the present invention, since the leakage of refrigerant in the high-pressure discharge chamber is at the suction pressure and the intermediate pressure and leads to internal leakage, leakage of the refrigerant to the outside of the compressor can be prevented.

100: scroll compressor 110: main housing
120: main frame 130: fixed scroll
140: rotary scroll 150: cover housing
160, 160a, 160b: gasket

Claims (7)

a main housing having a suction chamber into which a refrigerant flows, and accommodating a motor and a rotating shaft coupled to the motor into the suction chamber;
Main frame installed on the upper side of the main housing;
a fixed scroll installed on the upper side of the main frame;
a rotating scroll installed between the main frame and the fixed scroll, coupled to the rotating shaft, a back pressure chamber formed between the rotating scroll and the main frame, and a compression chamber formed between the rotating scroll and the fixed scroll;
a cover housing installed above the fixed scroll and having a discharge chamber through which refrigerant is discharged to the outside; and
including a gasket installed between the fixed scroll and the cover housing;
The gasket is formed with an inner bead and an outer bead disposed radially outside the inner bead,
The fixed scroll or the cover housing,
Including a compression chamber communication passage and a back pressure chamber communication passage,
The compression chamber communication passage and the back pressure chamber communication passage are disposed facing each other,
The inner bead is formed radially inside the compression chamber communication passage and the back pressure chamber communication passage,
The outer bead is formed radially outside the compression chamber communication passage and the back pressure chamber communication passage,
An intermediate pressure space is formed as a buffer space between the inner bead and the outer bead,
The inner bead and the outer bead extend while maintaining a predetermined width from the compression chamber communication passage and the back pressure chamber communication passage to define the intermediate pressure space. The method of claim 1,
In the cover housing, a back pressure chamber communication passage is formed at a portion in contact with the gasket to supply oil separated from the refrigerant to the back pressure chamber through an oil separator installed in the discharge chamber.
The inner bead includes a first inner bead disposed radially inside the communication passage of the back pressure chamber;
The outer bead includes a first outer bead disposed radially outside the communication passage of the back pressure chamber. The method of claim 1,
In the cover housing, the compression chamber communication passage is formed at a portion in contact with the gasket to supply oil introduced from the back pressure chamber to the upper side of the fixed scroll to the compression chamber,
The inner bead includes a second inner bead disposed radially inside the compression chamber communication passage,
The outer bead includes a second outer bead disposed radially outside the compression chamber communication passage. The method of claim 1,
In the fixed scroll, the back pressure chamber communication passage is formed at a portion in contact with the gasket to supply the oil separated from the refrigerant through the oil separator installed in the discharge chamber to the back pressure chamber,
The inner bead includes a first inner bead disposed radially inside the communication passage of the back pressure chamber;
The outer bead includes a first outer bead disposed radially outside the communication passage of the back pressure chamber. The method of claim 1,
In the fixed scroll, the compression chamber communication passage is formed at a portion in contact with the gasket to supply oil introduced from the back pressure chamber to the upper side of the fixed scroll to the compression chamber,
The inner bead includes a second inner bead disposed radially inside the compression chamber communication passage,
The outer bead includes a second outer bead disposed radially outside the compression chamber communication passage. According to claim 2 or claim 3,
The inner bead and the outer bead each protrude upward from the gasket. According to claim 4 or claim 5,
The inner bead and the outer bead each protrude downward from the gasket.

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