KR100455419B1 - Device for reducing noise of scroll compressor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a noise reduction device of a scroll compressor, and the present invention forms a pair of compression pockets in which the volume decreases while being continuously engaged with the swinging scroll, and discharged in communication with the high pressure portion of the casing at the center of the compression pockets. A turning scroll which forms a ball and forms a bypass hole so as to bypass the high pressure portion of the fixed scroll to the low pressure portion, and forms an intermediate pressure hole so as to communicate with the bypass hole in the compression pocket; In the normal operation, the bypass hole is closed while being pushed by the refrigerant gas flowing through the intermediate pressure hole, while in the vacuum operation, the bypass hole is installed to close the intermediate hole and open the bypass hole. A scroll compressor comprising: a bypass valve assembly comprising: a first opening and closing portion for opening and closing a discharge hole of a fixed scroll by a pressure difference between a compression pocket and a high pressure portion, and for opening and closing the bypass hole in conjunction with the first opening and closing portion; By including a reed valve which integrally extends the second opening and closing the first opening and closing portion described above, the refrigerant of the high pressure portion is prevented from leaking to the low pressure portion through the bypass hole when the scroll compressor stops operating, so that the noise of the refrigerant gas is not delayed. To prevent it. In addition, it is possible to easily determine whether the sealing of the high and low pressure separation plate is correctly made when assembling the compressor can be a smooth process inspection, thereby preventing the efficiency degradation due to reverse leakage.

Description

Noise reduction device of scroll compressor {DEVICE FOR REDUCING NOISE OF SCROLL COMPRESSOR}

The present invention relates to a scroll compressor, and more particularly, a bypass valve assembly for bypassing a refrigerant from a high pressure portion to a low pressure portion during a vacuum operation of the scroll compressor to prevent noise from being caused by bypassing the refrigerant even when stopped. A bypass noise reduction device using a reed valve of a scroll compressor.

In the conventional scroll compressor 100, as shown in Figure 1 or 2, the upper frame 111 is fixed to the inner upper portion of the sealed container, the lower frame (not shown) is fixed to the lower, the upper frame An electric machine unit is installed between the 111 and the lower frame (not shown), and the upper half of the electric machine unit is developed by a rotating shaft 114 interlocking with a rotor (not shown) to develop and compress a refrigerant by compression. A mechanism part is provided. The sealed container 110 may be divided into a suction pressure side 160 in which the refrigerant gas sucked into the inside and a discharge pressure side 170 in which the sucked refrigerant gas is compressed before being discharged. The high and low pressure separation plate 117 is fixed.

The compression mechanism is composed of a fixed scroll 130 is fixed to the upper side of the upper frame 111, and the rotating scroll 120 is rotatably coupled between the fixed scroll 130 and the upper frame 111. .

An eccentric portion 116 formed to be eccentric to an upper end of the rotary shaft 114 is inserted into and coupled to an inner coupling hole of the boss portion 121 formed at the lower end of the turning scroll 120.

The fixed scroll wrap 131 and the rotating scroll are respectively formed on the bottom surface of the fixed scroll 130 and the upper surface of the rotating scroll 120 opposite to each other to form a pair of compression pockets P having a reduced volume while continuously moving inward. The wrap 121 is formed to be engaged, and a coolant inlet hole 118 is formed at one side of the fixed scroll 130 to guide the coolant to the compression pocket P. A compressed coolant is formed at the center of the fixed scroll 130. A discharge hole 132 is formed to penetrate the discharge hole. In addition, the compression mechanism is installed at the center of the upper surface of the fixed scroll 130 to prevent the high-pressure refrigerant gas discharged through the discharge hole 132 from flowing backward. It further includes a check valve assembly 140 to prevent, and a bypass valve assembly 150 installed radially toward the center from the outer peripheral surface of the fixed scroll 130 to prevent the compression pocket (P) from being vacuum compressed. .

The check valve assembly 140 includes a plate valve 141 for opening and closing the discharge hole 132 and a valve guide 142 for guiding the plate valve 141 from being separated. The valve 150 includes a valve housing 156 formed inside the upper hard plate portion of the fixed scroll 130, a piston valve 151 slidably inserted into the valve housing 156, and the piston valve 151. A spring elastic member 154 for supporting the spring, a spring guide 153 for guiding the spring elastic member 154, and the spring guide 153, which are formed integrally with the inside of the suction pressure side 160 It consists of a piston stopper 152 having a communicating hole 158. The valve housing 156 is a high-pressure, high-temperature refrigerant gas of the upper discharge pressure side 170 during the vacuum operation by pushing the piston valve 151 open. Mold inside the piston stopper 152 The bypass hole 157 is formed to flow from the discharge pressure side 170 to the suction pressure side 160 through the through hole 158, and the refrigerant compressed in the compression pocket P by the piston valve 151 in normal operation. An intermediate pressure through hole 159 is formed to push the piston valve 151 to close the bypass hole 156.

In the figure, reference numeral 112 denotes a refrigerant suction tube, 113 a refrigerant discharge tube, 115 an oil through hole, and 118 a refrigerant inlet hole.

The conventional scroll compressor as described above operates as follows. That is, when power is applied, the rotor (not shown) of the electric motor unit rotates, and the rotating shaft 114 rotates by the rotation of the rotor (not shown). And, the turning scroll 120 coupled to the upper end of the rotary shaft 114 is a pivoting movement with the eccentric distance which is the distance from the center of the rotary shaft 114 to the center of the eccentric portion 116 as the turning radius.

When the turning scroll 120 is turned, the turning scroll wrap 121 is engaged with the fixed scroll wrap 131 to make a turning movement. At this time, the refrigerant gas is low pressure of the sealed container 110 through the suction pipe 112. The refrigerant gas is introduced into the compression pocket P formed between the fixed scroll wrap 131 and the wrap of the swing scroll 120 through the refrigerant inlet hole 118 formed in the fixed scroll 130. The volume of the compression pocket P is reduced by the continuous rotation of the turning scroll 120 to compress the refrigerant gas and is discharged through the discharge hole 132 of the fixed scroll 130.

At this time, the plate valve 141 of the check valve is moved upward by the pressure of the compressed gas is opened to discharge the compressed gas through the discharge hole 132, the compressed gas discharged in such a state is separated by high and low pressure The discharge is discharged to the high pressure section partitioned by the plate 117 and discharged to the condenser of the refrigeration cycle apparatus through the discharge pipe 113.

Here, in the normal operation of the scroll compressor 100, the refrigerant gas compressed in the compression pocket P is pushed by the piston valve 151 inside the valve housing 156 through the intermediate pressure through hole 159 to the high pressure part 170. The bypass hole 157 is closed to prevent the discharge refrigerant gas from flowing into the low pressure unit 160. On the other hand, the condenser refrigerant when the air conditioner unit including the scroll compressor 100 is installed or dismantled is removed. In the vacuum operation in which the discharge valve (not shown) continues to be locked, the piston valve 151 of the bypass valve assembly 150 moves inwardly by the spring elastic member 154 due to the pressure drop in the compression mechanism. In addition, the discharge pressure side 170 refrigerant gas is discharged to the suction pressure side 160 through the bypass hole 157 and sucked back into the refrigerant inlet hole 118, or the high temperature and high pressure flowed out through the bypass hole 157. Refrigerant Pistons By operating the through holes 158 (not shown), a temperature sensing device of the bimetallic member provided around the buffer 152, and to prevent damage of the transmission mechanism by stopping the operation,

However, in the conventional scroll compressor as described above, when the compressor 100 is stopped, the piston valve 151 of the bypass valve assembly 150 has a pressure difference between the discharge pressure side 170 and the compression pocket P which is the intermediate pressure side. By the opening by the vacuum operation, even if not in the vacuum operation, the high-temperature, high-pressure refrigerant gas on the discharge pressure side 170 causes leakage noise due to the outflow to the suction pressure side 160, and the bypass hole during the reverse leakage inspection in the manufacturing process 157 Through the discharge pressure side 170, the high-temperature and high-pressure refrigerant gas is bypassed from the discharge pressure side 170 to the suction pressure side 160 through the bypass valve assembly 150, the high and low pressure leakage can not be confirmed, the high and low pressure separation plate 117 There is a problem that process control is difficult because the leaky part of the blocking conjunctiva cannot be found.

According to the present invention devised to solve the above problems, in the scroll compressor, the bypass valve assembly bypasses the refrigerant gas on the discharge pressure side to the suction pressure side even when the operation stops, causing noise, and it is difficult to check the back leakage of the manufacturing process. By forming an on / off valve for opening and closing the bypass hole to prevent leakage by stopping the bypass hole when the operation is stopped, thereby preventing leakage noise, and reed valve of the scroll compressor for high and low pressure reverse leakage inspection in the manufacturing process. The purpose is to reduce the bypass noise by using.

1 is a longitudinal sectional view of a conventional scroll compressor;

FIG. 2 is a partially enlarged cross-sectional view showing an operating state of a bypass valve assembly during vacuum operation of a conventional scroll compressor; FIG.

3 is a longitudinal sectional view of the scroll compressor of the present invention;

4 is a partially enlarged cross-sectional view showing the state of the reed valve assembly in the normal operation of the scroll compressor of the present invention;

5 is a plan view of the reed valve of the scroll compressor of the present invention,

6 is a plan view of a retainer of a scroll compressor of the present invention;

7 is a partially enlarged cross-sectional view showing a state of the reed valve assembly during the vacuum operation of the scroll compressor of the present invention;

8 is a cross-sectional view showing an operating state of the rib valve of the reed valve assembly when the scroll compressor of the present invention is stopped.

* Description of the main parts of the drawings *

1: scroll compressor 30: fixed scroll

32: discharge hole 40: discharge valve assembly

41: Retainer 42: Reed Valve

42a: first opening and closing portion 42b: second opening and closing portion

60: suction pressure side 70: discharge pressure side

An object of the present invention and the casing is divided into a high pressure portion and a low pressure portion; A swing scroll installed to allow a fixed swing movement inside the casing; A pair of compression pockets are formed in which the volume decreases while continuously moving in engagement with the turning scroll, and a discharge hole communicating with the high pressure part of the casing is formed in the center of the compression pocket, and bypasses from the high pressure part of the fixed scroll to the low pressure part. A fixed scroll which forms a pass hole and forms an intermediate pressure hole so as to communicate with the bypass hole in the compression pocket; In the normal operation, the bypass hole is closed while being pushed by the refrigerant gas flowing through the intermediate pressure hole, while in the vacuum operation, the bypass hole is installed to close the intermediate hole and open the bypass hole. A scroll compressor including a bypass valve assembly, comprising: a first opening and closing portion for opening and closing a discharge hole of a fixed scroll by a pressure difference between a compression pocket and a high pressure portion, and for opening and closing the bypass hole in conjunction with the first opening and closing portion; It is achieved by a noise reduction device of a scroll compressor including a reed valve which integrally extends the second opening and closing portion to the first opening and closing portion.

Hereinafter, the noise reduction device of the scroll compressor according to the present invention will be described in detail with reference to the embodiment shown in the accompanying drawings. FIG. 3 is a longitudinal sectional view of the scroll compressor of the present invention, and FIG. 4 is a scroll compressor of the present invention. Is a partially enlarged cross-sectional view showing a state of the reed valve assembly in the normal operation of FIG. 5, FIG. 5 is a plan view of the reed valve of the scroll compressor of the present invention, FIG. 6 is a plan view of the retainer of the scroll compressor of the present invention, and FIG. Partial enlarged cross-sectional view showing the state of the reed valve assembly during vacuum operation of the scroll compressor of the invention, Figure 8 is a cross-sectional view showing the operating state of the rib valve of the reed valve assembly during operation stop of the scroll compressor of the present invention. As shown in the drawing, the scroll compressor 1 according to the present invention includes a sealed container 10 partitioned into a high pressure part side 70 and a low pressure part side 60 by a high and low pressure separating plate 17. The upper frame 11 and the lower frame (not shown) is fixed to the portion, and the power mechanism is provided between the upper frame 11 and the lower frame 12, the upper side of the power mechanism portion of the rotating shaft in the transmission mechanism The rotating mechanism 20 is connected to the fixed scroll 30 is engaged with the fixed scroll (30) is provided with a compression mechanism to compress the refrigerant gas. The compression mechanism is a fixed scroll fixed to the upper side of the upper frame (11) ( 30 and a pivoting scroll 20 rotatably coupled between the fixed scroll 30 and the upper frame 11. The pivoting scroll 20 has an eccentric portion of the rotating shaft 14 at the center of its bottom surface. The boss portion 21 is formed so that the 16 is inserted and coupled thereto, and the pivoting scroll wrap 22 is formed on the upper surface thereof so as to form a plurality of pairs of compression pockets P in engagement with the fixed scroll wrap 31 to be described later. .

The fixed scroll (30) forms a fixed scroll wrap (31) on its bottom surface to be engaged with the swing scroll wrap (22), and the refrigerant flows into the compression pocket (P) outside the fixed scroll wrap (31). The refrigerant inlet hole 18 is formed so that the volume of the compression pocket P is reduced in the center of the fixed scroll 30, thereby compressing the refrigerant gas, and moving to the center portion to compress the refrigerant gas. The discharge hole 32 is formed to be discharged to.

A reed valve assembly 40 is installed on the upper surface of the fixed scroll 30 to prevent the high pressure refrigerant gas discharged to the upper side of the discharge hole 32, and is compressed on the outer circumferential surface of the fixed scroll 30. The bypass valve assembly 50 is installed to prevent the pocket P from being vacuum compressed. The reed valve assembly 40 has one end fixed to the upper surface of the fixed scroll 30 and the other end forming a free end. The lead valve 42 includes a reed valve 42 for opening and closing the discharge hole 32 and a retainer 41 having one end bent upward to support an open state of the reed valve 42. In addition, the fixed scroll 30 is fastened and fixed by the screw fastening member 43 on the upper side of the hard plate portion. The reed valve 42 includes a first opening and closing portion 42a for opening and closing the discharge hole 32, and a first opening. Extending integrally to the opening and closing portion 42a to open and close the bypass hole 57 to be described later. And a second opening / closing portion 42b. The fixed end of the reed valve 42 is positioned above the hard plate portion of the fixed scroll 30 in accordance with the retainer fastening hole 41b provided in the retainer 41. The valve fastening hole 42c is provided to be fastened by the screw fastening member 43 in the form of a cantilever beam.

The bypass valve assembly 50 includes a valve housing 56 formed inside the upper hard plate portion of the fixed scroll 30, a piston valve 51 slidably inserted into the valve housing 56, and A spring elastic member 54 holding the piston valve 51, a spring guide 53 for guiding the spring elastic member 54, and the spring guide 53, are integrally formed and sucked therein. It consists of a piston stopper 52 having a through hole 58 communicating with the pressure side 60.

The valve housing 56 is discharged through the through-hole 58 formed in the piston stopper 52 by opening the high-pressure high-temperature refrigerant gas of the upper discharge pressure side 70 by pushing the piston valve 51 during vacuum operation. The bypass hole 57 is formed so as to flow out from the pressure side 70 to the suction pressure side 60, and the refrigerant compressed in the compression pocket P may cause the piston valve 51 to operate in the normal operation of the piston valve 51. An intermediate pressure through hole 59 is formed to push to close the bypass hole 57.

In the drawings, reference numeral 12 denotes a refrigerant suction pipe, 13 a refrigerant discharge pipe, 15 an oil through hole, and 18 a refrigerant inlet hole.

The noise reduction device of the scroll compressor of the present invention as described above has the following effects. That is, when power is applied, the rotor (not shown) of the electric mechanism rotates, and the rotor (not shown) rotates. The rotating shaft 14 rotates, and the turning scroll 20 coupled to the upper end of the rotating shaft 14 is an eccentric distance which is a distance from the center of the rotating shaft 14 to the center of the eccentric portion 16 as the turning radius. To make a turn.

When the turning scroll 20 turns, while the turning scroll wrap 31 engages with the fixed scroll wrap 31 to rotate, the refrigerant gas passes through the refrigerant suction pipe 12 to the suction pressure side of the sealed container 10 ( 60), the refrigerant gas flows into the compression pocket (P) formed between the fixed scroll wrap (31) and the rotating scroll wrap (22) through the refrigerant inlet hole (18) of the fixed scroll (30). As it is moved to the center compression pocket P by the swinging motion of the revolving scroll 120, the revolving scroll 120 is continuously compressed and discharged to the discharge pressure side 70 through the discharge hole 32 of the fixed scroll 30.

Here, in the normal operation of the scroll compressor 100, even if the second opening / closing portion 42b linked with the first opening / closing portion 42a of the reed valve 42 opens or closes the bypass hole 57, the compression is an intermediate pressure portion. The refrigerant gas compressed in the pocket P causes the push-by-hole 57 of the piston valve 51 inside the valve housing 56 to be closed through the intermediate pressure through hole 59 so that the refrigerant of the discharge pressure side 70 is sucked in. It is not bypassed to the pressure side 60.

During the vacuum operation of the scroll compressor 1, the fine refrigerant gas of the compression pocket P is compressed by the swinging motion of the swinging scroll 20 to finely close the first opening / closing portion 42a of the reed valve 42. While repeatedly pushing and opening, the second opening / closing portion 42b of the reed valve 42 is interlocked to open so that the refrigerant gas of the discharge pressure side high pressure moves to the suction pressure side 60 through the bypass hole 57. Refrigerant gas is supplied to the compression pocket (P) to prevent high vacuum of the compression pocket.

On the other hand, when the scroll compressor 1 is stopped, the second opening / closing portion 42b of the reed valve 42 closes the bypass hole 57 of the bypass valve assembly 50 so that the discharge pressure side 70 is closed. By preventing the high-pressure refrigerant gas of the leakage to the suction pressure side 60, the refrigerant gas of the discharge pressure side 70 when the compressor is stopped is quickly exited to the suction pressure side 60 through the narrow bypass hole (57) Leakage noise can be prevented beforehand.

The noise reduction device of the scroll compressor of the present invention can prevent the refrigerant of the high pressure part from leaking to the low pressure part through the bypass hole when the scroll compressor stops operating, thereby preventing noise leakage of the refrigerant gas. In addition, it is possible to easily determine whether the sealing of the high and low pressure separation plate is correctly made when assembling the compressor can be a smooth process inspection, thereby preventing the efficiency degradation due to reverse leakage.

Claims (1)

A casing divided into a high pressure part and a low pressure part; A swing scroll installed to swing inside the casing; A pair of compression pockets are formed in which the volume is reduced while continuously moving in engagement with the turning scroll, a discharge hole communicating with the high pressure part of the casing is formed in the center of the compression pocket, and the bypass is communicated bypass from the high pressure part of the casing to the low pressure part. A fixed scroll which forms a hole and forms an intermediate pressure hole so as to communicate with the bypass hole in the compression pocket; In the normal operation, the bypass hole is closed while being pushed by the refrigerant gas flowing through the intermediate pressure hole, while in the vacuum operation, the bypass hole is installed to close the intermediate hole and open the bypass hole. In the scroll compressor comprising a bypass valve assembly, The first opening and closing portion for opening and closing the discharge hole of the fixed scroll by the pressure difference between the compression pocket and the high pressure portion, and the second opening and closing portion for opening and closing the bypass hole in conjunction with the first opening and closing portion integrally with the first opening and closing portion Noise reduction device for a scroll compressor including an extended reed valve.