KR100292508B1 - Refrigerant spreading device of linear compressor - Google Patents

Abstract

The present invention relates to a refrigerant gas discharge device of a linear compressor, and in the related art, the discharge valve seat and the discharge valve which are blocking the cylinder are supported by the head spring, and are in close contact with each other. There is a problem that the gap is generated without being in close contact with each other, and the discharge valve and the discharge valve seat continuously move relative to each other, causing abrasion between the two parts, causing leakage of compressed gas. It reduces the wear by reducing the relative movement between parts during discharging, which not only prevents the breakage of the parts, but also prevents the leakage of refrigerant gas, and alleviates the impact when the piston collides, and also reduces the precision machining area of the parts. It is to make it easier.

Description

Refrigerant Gas Discharge Device for Linear Compressor

The present invention relates to a refrigerant gas discharge device of a linear compressor, and in particular, the refrigerant gas of the linear compressor to minimize the leakage of the refrigerant gas and to mitigate the impact when the piston collides with the discharge valve during the compression of the refrigerant gas. It relates to a discharge device.

In general, the compressor constituting the refrigeration cycle device is to compress the refrigerant flowing from the evaporator to be discharged in a state of high temperature and high pressure. In one example of the compressor, a linear driving force of a motor is transmitted to a piston so that the piston sucks and compresses refrigerant gas while linearly reciprocating the inside of the cylinder.

As an example of the compressor, as shown in FIG. 1, the linear compressor includes a sealed container 1 having a suction port 1a formed on one side thereof and a discharge port (not shown) formed on the other side thereof, and an interior of the sealed container 1. Inner stator coupled to one side of the frame 10 and the cylinder 20 is inserted into the through-hole 11 formed through the multi-stage of the frame 10, the frame 10 is mounted to the frame 10 An outer stator assembly 31 coupled to the assembly 30 and its inner stator assembly 30 at predetermined intervals, and a magnet assembly inserted into a gap between the inner stator assembly 30 and the outer stator assembly 31. 32 and a piston 40 inserted into the cylinder 20 and connected to the magnet frame 33 coupled to the magnet assembly 32 and reciprocating by linear movement of the magnet assembly 32. And The inside of the piston 40 is formed with a through refrigerant path F through which refrigerant gas flows.

In addition, a cover 50 having a predetermined shape is duly coupled to one side of the frame 10, and positioned on both sides of the magnet frame 33 connected to the piston 40 to elastically move the piston 40. The main springs 51 which are supported by each are inserted.

The end of the piston 40 is coupled to the suction valve 41 is opened and closed in accordance with the suction of the gas, the lower portion of the frame 10 is equipped with an oil feeder 70 for supplying oil to the sliding parts.

One side of the cylinder 20 is provided with a discharge device for discharging the refrigerant gas compressed in the cylinder 20 in accordance with the linear reciprocating motion of the piston (40).

Reference numeral 34 is a coil assembly constituting the motor, 2 is a suction pipe.

The operation of the linear compressor as described above is as follows.

In the linear compressor, when the current is applied to the motor, the magnet assembly 32 linearly reciprocates, and the linear movement is transmitted to the piston 40 through the magnet frame 33 so that the piston 40 is inside the cylinder 20. Will reciprocate linearly. The refrigerant gas introduced into the sealed container 1 by the linear movement of the piston 40 is sucked into the cylinder 20 through the refrigerant flow path F formed in the piston 40, compressed and discharged through the discharge device. The process is repeated.

In the conventional discharging device for discharging the compressed refrigerant gas inside the cylinder 20, the discharge cover 60 formed in the form of a cap to cover the cylinder 20 coupled to the center of the frame 10 is one of the frame 10. A discharge valve seat 61 coupled to the side by a bolt 80 and having a predetermined thickness and a through hole formed therein is inserted into the discharge cover 60 to block one side of the cylinder 20, and has a predetermined thickness. A discharge valve 62 is inserted to contact the discharge valve seat 61, and a head spring 63 is inserted into the discharge cover 60 to support the discharge valve 62 and the discharge valve seat 61. It is configured to. The discharge valve seat 61 is caught and fixed by the locking groove 60a formed on the inner circumferential surface of the discharge cover 60, and the discharge valve 62 is formed smaller than the inner diameter of the discharge cover 60 to discharge the cover 60. The gas discharge hole 60a is formed at one side of the discharge cover 60. At the end of the piston 40, a screw 42 for fastening the suction valve 41 protrudes to a predetermined height.

In the conventional refrigerant gas discharge device as described above, as shown in Figs. 2 and 3, when the piston 40 moves from the bottom dead center to the top dead center, the refrigerant gas sucked into the cylinder 20 is compressed and the pressure is constant. In a state where the discharge valve 62 supported by the head spring 63 is opened, the compressed refrigerant gas is discharged. In addition, the head spring 63 is to mitigate the impact when the piston 40, when the piston 40 and the discharge valve 62 collide with the refrigerant gas.

However, the refrigerant gas discharge device of the conventional linear compressor as described above has a discharge valve seat 61 because the discharge valve seat 61 and the discharge valve 62 which are blocking the cylinder 20 are supported by the head spring 63 and are in close contact with each other. ) And the total processing accuracy of the discharge valve 62 is not precise, the gap is generated without close contact, and also the discharge valve 62 and the discharge valve seat 61 are continuously moved relative to each other and wear between the two parts This caused a problem that the leakage of the compressed gas occurs.

In addition, when designing to increase the discharge efficiency of the discharge valve 62, in consideration of the mechanical resonance of the head spring 63 and the discharge valve 62, the discharge valve seat 61 can not be designed to a predetermined thickness or more, so high pressure The discharge valve seat 61 and the discharge valve 62 may be broken during operation.

The object of the present invention devised in view of the above problems is to minimize the leakage of refrigerant gas and to reduce the shock when the piston collides with the discharge valve during the compression of the refrigerant gas. In providing a discharge device.

1 is a cross-sectional view showing a general linear compressor,

2 and 3 are cross-sectional views respectively illustrating a process in which the discharge device compresses the refrigerant gas in the linear compressor;

4 is a cross-sectional view showing a refrigerant gas discharge device of the linear compressor of the present invention;

5A and 5B are front and side cross-sectional views of a valve stopper constituting the refrigerant gas discharge device of the linear compressor of the present invention;

6 is a front view of a discharge valve seat constituting a refrigerant gas discharge device of the linear compressor of the present invention;

7 is a front view of a discharge valve constituting the refrigerant gas discharge device of the linear compressor of the present invention.

<Explanation of symbols for main parts of drawing>

10 frame 11 through hole

20: cylinder 90: discharge cover

100: guide bolt 110: buffer spring

120: discharge valve seat 121: discharge valve seat through hole

130: discharge valve 131: discharge valve annular portion

132: discharge valve opening and closing portion 140: valve stopper

141: valve stopper discharge hole 142: valve stopper disc portion

143: valve stopper support portion 150: gasket

In order to achieve the object of the present invention as described above, a discharge cover positioned to cover one side of the cylinder to one side of the frame to which the cylinder is coupled to the penetrating through hole, and penetrated and fixed to the frame while penetrating the discharge cover. A guide bolt, a buffer spring inserted into and supported by the guide bolt to closely contact the discharge cover by elastic force, a through-hole formed in the center thereof, and a discharge valve seat inserted into the discharge cover to block one side of the cylinder, and the discharge valve seat. A discharge valve in close contact with the discharge valve and a plurality of discharge holes for discharging the gas discharged into the through hole of the discharge valve seat by the operation of the discharge valve into the discharge cover, and the discharge valve seat and the discharge valve are located therein. In addition, the discharge valve seat and the discharge valve is fixed between the cylinder and the discharge cover Provided is a refrigerant gas discharge device for a linear compressor, comprising a fixed and supported valve stopper.

The valve stopper is formed in a circular shape having a predetermined thickness and has a disc shape having an insertion space formed therein by a disc portion having a plurality of discharge holes formed therein and a support portion extending in a needle shape at the edge of the disc portion. The discharge valve seat is formed in a disc shape having a predetermined thickness and a through-hole in the middle thereof, and the discharge valve is formed in an annular annular part having a predetermined thickness and is formed to extend in a predetermined shape inside the annular part. Comprising an opening and closing portion for opening and closing, the discharge valve seat and the discharge valve is provided with a refrigerant gas discharge device of the linear compressor, characterized in that inserted into the insertion space of the valve stopper.

Hereinafter, the refrigerant gas discharge device of the linear compressor according to the present invention will be described according to the embodiment shown in the accompanying drawings.

In the refrigerant gas discharge device of the linear compressor of the present invention, as shown in FIG. 4, the cylinder 20 is connected to one side of the frame 10 to which the cylinder 20 is coupled to the through hole 11 penetrated in the middle stage. A discharge cover 90 positioned to cover one side, a plurality of guide bolts 100 passing through the discharge cover 90 and fastened and fixed to the frame 10, and inserted into and supported by the guide bolt 100. And a spring spring 110 which is in close contact with the discharge cover 90 by elastic force, and a through hole 121 is formed in the middle thereof, and the discharge valve seat inserted into the discharge cover 90 to block one side of the cylinder 20. 120, the discharge valve 130 in close contact with the discharge valve seat 120, the discharge valve seat 120 and the discharge valve 130 is located inside the cylinder 20 and the discharge cover A valve stopper fixed between the 90 and fixedly supporting the discharge valve seat 120 and the discharge valve 130 ( 140).

The discharge cover 90 is formed in a cap shape similar to a conventional structure, and a through hole 91 through which the guide bolt 100 is inserted is formed at an edge thereof, and a gas discharge hole through which gas is discharged ( 92 is formed.

The screw hole 12 to which the guide bolt 100 is fastened is formed in the frame 10 to which the discharge cover 90 is in contact.

The guide bolt 100 passes through the through hole 91 of the discharge cover 90 in a state where the discharge cover 90 is in contact with the frame 10 and is fastened to the screw hole 12 of the frame and guide bolt 100. The shock absorbing spring 110 is inserted between the head of the guide bolt 100 and the discharge cover 90 to compress the discharge cover 90 to the frame 10.

5A and 5B, the valve stopper 140 is formed in a circular shape having a predetermined thickness and includes a disc portion 142 having a plurality of discharge holes 141 therein, and the disc portion 142. It is formed in the form of a cap is formed in the insertion space therein by the support portion 143 is bent in the form of a needle threaded on the edge of.

As shown in FIG. 6, the discharge valve seat 120 has a disc shape having a predetermined thickness and a through hole formed in the center thereof. And the discharge valve 130, as shown in Figure 7, the annular annular portion 131 having a predetermined thickness and extending in a predetermined shape inside the annular portion 131 is formed in the discharge valve seat ( The opening and closing portion 132 to open and close 120 is made.

The discharge valve seat 120 and the discharge valve 130 are in contact with the opening and closing portion 132 of the discharge valve 130 to block the through hole of the discharge valve seat 120 is inserted into the insertion space of the valve stopper 140. The valve stopper 140 into which the discharge valve seat 120 and the discharge valve 130 are inserted has one end of the cylinder 20 and the discharge cover 90 of which the support part 143 is coupled to the frame 10. The discharge valve seat 120 and the discharge valve 130 inserted into the valve stopper 140 and inserted between the side surfaces cover the cylinder 20.

A gasket for preventing the leakage of gas between one side of the valve stopper 140 and the cylinder 20 and the other side of the valve stopper 140 and the discharge cover 90 while supporting the valve stopper 140 ( 150 is inserted respectively.

The piston 40 is inserted into the cylinder 20 as in the related art, and the piston 40 is linearly reciprocated in the cylinder 20 by receiving a driving force of a motor mounted to the frame.

Hereinafter, the operational effects of the linear compressor refrigerant gas discharge device of the present invention will be described.

In the linear compressor refrigerant gas discharging device of the present invention, when the driving force of the motor is transmitted to the piston 40 and the piston 40 linearly reciprocates inside the cylinder 20, the sealed container is formed by linear reciprocating motion of the piston 40 ( 1) the refrigerant gas introduced into the cylinder 20 is sucked into the cylinder 20 through the refrigerant flow path F formed in the piston 40, compressed and discharged, and the refrigerant gas is discharged. When the 40 moves from the bottom dead center to the top dead center, when the refrigerant gas sucked into the cylinder 20 is compressed and is in a predetermined pressure state, the opening / closing portion 132 of the discharge valve 130 opens and the compressed refrigerant gas is discharged. It is discharged through the through hole 121 of the seat 120 and the discharge hole 141 of the valve stopper 140. The discharged refrigerant gas is discharged to the outside of the sealed container 1 through the gas discharge hole 92 of the discharge cover 90.

In addition, when the piston 40 collides with the discharge valve seat 120 while the piston 40 linearly reciprocates the inside of the cylinder 20 and sucks, compresses, and discharges the refrigerant gas, the shock is discharged from the cover 90. It is transmitted to the shock absorbing spring (110) supporting the relief.

In the present invention, when the refrigerant gas is discharged, only the opening and closing portion 132 of the discharge valve 130 moves and opens and closes the through hole 121 of the discharge valve seat 120, so that the valve stopper 140, the discharge valve 130, and the discharge valve are discharged. Relative movement of the seat 120 is reduced to reduce wear between the parts. In addition, precisely processing only the opening and closing portion 132 of the discharge valve and the through-hole 121 of the discharge valve seat 120 can prevent the leakage of compressed gas, so that the processing is easy and the gas is prevented from leaking.

In addition, the gasket 150 is inserted into both sides to which the valve stopper 140 is coupled to suppress the leakage of gas between the discharge cover 90, the valve stopper 140, and the valve stopper 140 and the cylinder 20.

As described above, the refrigerant gas discharge device of the linear compressor according to the present invention not only prevents breakage of the components but also prevents leakage of the refrigerant gas by reducing the relative movement between the components during the discharge of the refrigerant gas, thereby reducing wear. When the piston collides, the impact is alleviated, and the precision machining area of the part is reduced to facilitate the machining of the part.

Claims (3)

A discharge cover positioned to cover one side of the cylinder on one side of the frame to which the cylinder is coupled to the through hole, a guide bolt penetrating and fixed to the frame and penetrating the discharge cover; A cushioning spring for closely contacting the discharge cover, a discharge valve seat inserted into the discharge cover such that a through hole is formed in the center thereof to block one side of the cylinder, a discharge valve closely contacted with the discharge valve seat, and an operation of the discharge valve. And a plurality of discharge holes for discharging the gas discharged through the through-holes of the discharge valve seat into the discharge cover, and the discharge valve seat and the discharge valve are positioned therein and fixed between the cylinder and the discharge cover. And a valve stopper for holding and supporting the discharge valve seat and the discharge valve. Refrigerant gas discharge device of the linear compressor according to. The linear compressor according to claim 1, wherein a gasket for preventing the leakage of gas is inserted between one side of the valve stopper and the cylinder, which is in contact with the valve stopper, and the other side of the valve stopper and the discharge cover. Refrigerant gas discharge device. The method of claim 1, wherein the valve stopper is formed in a circular shape having a predetermined thickness and the insertion portion is formed therein by a disc portion formed with a plurality of discharge holes therein, and a support portion that is bent in the form of a needle on the edge of the disc portion It is made in the form of a cap, the discharge valve seat is made of a disk shape having a predetermined thickness and a through-hole in the middle, the discharge valve is formed in an annular annular portion having a predetermined thickness and extending in a predetermined shape inside the annular portion It is formed and the opening and closing portion for opening and closing the discharge valve seat, the refrigerant gas discharge device of the linear compressor, characterized in that the discharge valve seat and the discharge valve is inserted into the insertion space of the valve stopper.