KR19980076018A - Reciprocating compressor - Google Patents

Abstract

The present invention relates to a reciprocating compressor, and an object of the present invention is to change the shape of the stopper valve supporting the discharge valve when opening the discharge valve to ensure the reliability of the operation of the discharge valve, and also to prevent breakage of the stopper valve. It is to provide a homogeneous compressor.

The valve plate 15 provided with the discharge port 17 of the compressed refrigerant in the compression chamber 21 is coupled with a discharge valve 12 formed by drawing a circular arc on one side in a plate shape, and the discharge valve 12 is connected to the valve plate 15. A stopper valve 13 is provided to be pressed and supported, and one end of the stopper valve 13 is supported by contact with the surface of the cylinder head 7 and the other end is fixedly supported by the support groove 7a of the cylinder head 7. Therefore, when the compressed refrigerant is discharged, the rotating part 12a of the discharge valve 12 which opens the discharge port 17 is supported in surface contact with the rotating support part 13a formed by the inclined surface of the stopper valve 13 so that the stopper valve ( The breakage of 13) is prevented and the opening position of the discharge valve 12 is made constant to improve discharge performance.

Description

Reciprocating Compressor

The present invention relates to a reciprocating compressor, and more particularly, to change the valve shape and the assembly structure of the reciprocating compressor to improve the durability and discharge performance of the discharge valve assembly parts and reduce the number of the assembly parts, thereby improving productivity. It relates to a homogeneous compressor.

Generally, the reciprocating compressor functions to compress the refrigerant to a high temperature and high pressure in a refrigeration cycle in which a compression, condensation, expansion, and evaporation process is continuously performed as a medium to deliver the refrigerant to the outside of the container.

As shown in FIGS. 1 and 2, a general reciprocating compressor having such a function includes a driving unit for generating power inside the hermetically sealed container 1 by combining the upper container 1a and the lower container 1b. It is composed of a compression unit for receiving the power from the drive unit to suck and compress the refrigerant.

The driving unit is installed on the upper part of the sealed container 1, the stator (3) and the rotor (2), also coupled to the rotor (2) to rotate and the rotary shaft is integrally provided with an eccentric shaft (9) at the bottom (4) is provided.

The compression section reciprocates inside the cylinder 6 having a compression chamber 5 for sucking and compressing the refrigerant into the cylinder 6, the cylinder head 7 having a suction chamber for guiding suction and discharge of the refrigerant, and a cylinder 6. The piston 8 and the piston 8 and the eccentric shaft 9 are provided with a connecting rod 10 and installed in the lower part of the sealed container 1. The piston 8 is connected by the connecting rod 10. This reciprocating motion causes the cylinder head 7 to be attached to the front end of the cylinder 1, which is provided with a suction silencer.

Figure 2 is an exploded perspective view showing a compression portion, Figure 3 is an exploded perspective view showing the assembly structure of a conventional discharge valve.

4 and 5 are combined cross-sectional views showing the state before and after opening of the conventional discharge valve.

The cylinder 6 is integrally coupled to the block 11 forming the body of the compression unit, and the gasket 16 for sealing and the suction suction of the refrigerant are formed between the cylinder 6 and the valve plate 15. The provided suction valve 17 is provided.

The valve plate 15 is provided with a groove 15a for coupling several valves for discharging the compressed refrigerant. A discharge head 12 and a stopper valve 13 and a keeper valve 14 are sequentially coupled to the groove 15a, and a cylinder head gasket for sealing between the valve plate 15 and the cylinder head 7 ( 18) is provided.

Inside the cylinder head 7, a discharge chamber 18 is formed to form a flow path through which discharged refrigerant is discharged to the outside, and a valve plate 15 is provided between the cylinder 6 and the cylinder head 7.

The valve plate 15 is provided with a groove portion 15a formed in two stages, and a stopper valve 13 and a stopper valve 13 which come into contact with and support the discharge valve 12 and the discharge valve 12 which open and close the discharge port 17. ) Is composed of a keeper valve 14 for pressing and fixing both ends.

In the reciprocating compressor having such a configuration, a suction force is generated by the piston 8 reciprocating in the cylinder 6, and the suction force flows into the suction silencer to push the suction valve 17 into the cylinder 6. Flows into. The refrigerant compressed at high temperature and high pressure by the reciprocating motion of the piston 8 pushes the discharge valve 12 out of the compression stroke of the piston 8, and the discharge valve 12 discharges the high pressure refrigerant, and then the valve plate. The discharge port 17 provided in the 15 is closed by the pressure difference between the cylinder 6 and the outside and the elastic force of the discharge valve 12. The discharged high-pressure refrigerant is discharged through a discharge tube (not shown) and sealed. It is discharged to the outside of the compressor through the discharge tube 20 is coupled to the container (1).

In the refrigerant discharging structure, when the compressed refrigerant is discharged, the discharge valve 12 having the front surface contacted with the bottom surface of the groove 15a of the valve plate 15 is coupled to the valve plate 15 by the stopper valve 13. The other end fixed to the groove 15a and rotatably provided pushes the stopper valve 13 to open the discharge port 17.

Above the stopper valve 13, a keeper valve 14 is formed so that both ends thereof are in contact with the cylinder head 7 and supported, and the center portion is bent in two stages so that a space is provided between the stopper valve 13 and the stopper valve 13. .

When the discharge valve 12 which is subjected to the high pressure refrigerant pressure is opened, the stopper valve 13 is strongly pressed by the high pressure refrigerant discharged from the rotating part 12a of the discharge valve 12, which is in contact with the stopper valve 13. By being pushed, the stopper valve 13 is provided with a bent portion 13a.

As the pivoting portion 12a of the discharge valve 12 exerts a continuous load on the bent portion 13a of the stopper valve 13, the stopper valve 13 is abraded by friction at the end of the pivoting portion 12a. As a result, when the pushing force of the discharge valve 12 due to excessive refrigerant pressure is large, there is a problem in that the bent portion 13a of the stopper valve 13 breaks.

Therefore, the present invention is to solve the above problems, an object of the present invention is to change the shape of the stopper valve defining the rotational position when opening the discharge valve to improve the reliability of the operation of the discharge valve and the durability of the stopper valve and The present invention provides a reciprocating compressor which simplifies the structure and improves productivity.

1 is a cross-sectional view showing the structure of a typical compressor,

2 is an exploded perspective view showing a conventional compression unit,

3 is an exploded perspective view showing an assembly of a conventional discharge valve,

4 is a cross-sectional view showing a state before opening of a conventional discharge valve;

Figure 5 is a cross-sectional view showing a state after opening the conventional discharge valve,

6 is an exploded perspective view showing a compression unit according to the present invention;

7 is an exploded perspective view showing the assembly of the discharge valve according to the present invention;

8 is a cross-sectional view showing a state before opening of the discharge valve according to the present invention;

Figure 9 is a cross-sectional view showing a state after opening of the discharge valve according to the present invention.

* Description of symbols on the main parts of the drawings *

6 ... cylinder 7 ... cylinder head

12.Discharge valve 12a ... Rotating part

13 ... Stopper valve 13a ... Rotating support

The present invention for achieving the above object,

A compression chamber is provided therein and includes a cylinder body consisting of a cylinder block and a cylinder head, a discharge chamber provided inside the cylinder head to form a flow path of discharge refrigerant, and provided for discharging the compressed refrigerant between the cylinder block and the cylinder head. A reciprocating compressor comprising a valve plate, a discharge port provided in the valve plate to communicate the compression chamber with the discharge chamber, a discharge valve for opening and closing the discharge port, and a stopper valve supporting the discharge valve.

One end of the discharge valve is fixed, the other end is provided to be rotatable, and the stopper valve is characterized in that the rotation support is formed in the inclined surface to support the rotating part of the discharge valve during the discharge stroke.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

The general configuration and operation of the reciprocating compressor will be described with reference to the same names and same numbers in FIGS. 1 and 2.

6 is an exploded perspective view showing a compression unit according to the present invention, Figure 7 is an exploded perspective view showing the assembly structure of the discharge valve according to the present invention.

8 is a cross-sectional view showing a pre-opening state of the discharge valve according to the present invention, Figure 9 is a cross-sectional view showing a post-open state of the discharge valve according to the present invention.

The upper container (1a) and the lower container (1b) is composed of a drive unit for generating power in the hermetically sealed container (1) and a compression unit for receiving and compressing the refrigerant by receiving power from the drive unit.

The driving unit is installed on the upper part of the sealed container 1, the stator (3) and the rotor (2), and also coupled to the rotor (2) to rotate and the rotary shaft with an eccentric shaft (9) integrally provided at the bottom (4) is provided.

The compression unit reciprocates inside the cylinder 6 having a compression chamber 5 for sucking and compressing the refrigerant into the cylinder 6, the cylinder head 7 having a suction chamber for guiding suction and discharge of the refrigerant, and a cylinder 6. The piston 8, and the piston 8 and the eccentric shaft 9 are provided at the lower part of the sealed container 1 with a connecting rod 10.

The connecting rod 10 causes the piston 8 to reciprocate, and a cylinder head 7 is attached to the front end of the cylinder 1, which forms a flow path through which discharge refrigerant is discharged to the outside. The discharge chamber 18 is provided, and a suction silencer for suppressing noise during discharge is provided.

A cylinder 6 is integrally coupled to the block 11 forming the body of the compression unit, and a gasket 16 for sealing is provided between the cylinder 6 and the valve plate 15, and the suction of the refrigerant is performed. Intake valve 17 is provided in the shape.

The valve plate 15 is provided with a groove portion 15a for coupling the valve, and the discharge portion 12 and the stopper valve 13 are coupled to the groove portion 15a and between the valve plate 15 and the cylinder head 7. A cylinder head gasket 18 is provided for sealing.

The valve plate 15 provided between the cylinder head 7 and the cylinder 6 is provided with a groove 15a to enable this function, and presses the discharge valve 12 and the discharge valve 12 to open and close the discharge port 17. It consists of a stopper valve 13 to support.

The stopper valve 13 is coupled by pressing the discharge valve 12 from the upper side of the discharge valve 12. The stopper valve 13 and the discharge valve 12 are groove portions 15a provided in the valve plate 15. It is installed in the coupling.

The discharge valve 12 is coupled to the bottom of the groove 15a of the valve plate 15, and one end of the discharge valve 12 is connected to the discharge port 17 provided to communicate the groove 15a with the inside of the cylinder 6. It is combined to seal the inside of the cylinder (6).

The stopper valve 13 coupled to the upper side of the discharge valve 12 has one end supported by the cylinder head 7 and bent to press the discharge valve 12 at the bottom of the groove 15a to be coupled to the valve plate. 15) to form the other end and the inclined surface protruding upward.

The inclined surface of this stopper valve 13 is provided with a rotation support part 13a which defines the rotation position while supporting the rotation part 12a of the discharge valve 12 at the time of discharge of compressed refrigerant.

One end of the stopper valve 13 is supported in contact with the bottom of the cylinder head 7 and is bent downward from the center to be coupled to the discharge valve 12 in a shape parallel to the bottom of the groove 15a. The part protrudes upward of the valve plate 15 and is provided on the inner side surface of the cylinder head 7 so as to be supported by a support groove 7a on which one end of the stopper valve 13 is seated and fixed to form a rotational support part ( 13a) is provided.

One side of the stopper valve 13 is provided with a rotation support portion 13a formed with an inclined surface, so that the rotational portion 12a of the discharge valve 12 sealing the discharge port 17 is rotated, that is, the discharge valve 12 When opened, the pivot 12a is smoothly supported along the inclined surface of the pivot support 13a of the stopper valve 13.

The stopper valve 13 is provided with a groove extending from one end to the center, and the width of one end is extended and the center and the other end are formed to have the same width.

One end of the discharge valve 12 is extended to both sides, the width thereof is narrowed at the center portion thereof, and the width thereof is widened at the other end portion thereof so as to draw a circular arc.

Referring to the operation according to the present invention having such a structure, when the discharge valve 12 is pushed up by the compressed refrigerant in the cylinder 6, the rotating portion 12a of the discharge valve 12 is applied to the stopper valve 13. The stopper valve 13 can be prevented from being bent while being smoothly contacted and supported by the rotation support part 13a formed in the inclined surface.

In addition, when the discharge valve 12 is opened by the pressure of the excessive discharge refrigerant, the stopper valve 13 is composed of a plate-shaped non-deformable material having a constant thickness and the stopper valve 13 to minimize the deformation of the stopper valve 13 By providing a support groove 7a of the cylinder head 7 at which the end of the cylinder is supported, the deformation of the stopper valve 13 is minimized to prevent damage to the discharge valve 12 and to keep the opening position of the discharge valve 12 constant. By doing so, the performance of the discharge valve 12 is improved.

As described above, the reciprocating compressor according to the present invention prevents breakage of the stopper valve in advance by bending at the stopper valve supporting the same by the discharge valve and prevents the smooth inclined surface of the stopper valve when the discharge valve is opened. Therefore, there is an advantage to improve the product performance by being located at a certain height.

In addition, by reducing the number of parts of the valve required for the discharge stroke of the compressed refrigerant has the advantage of lowering the manufacturing cost to improve productivity.

Claims (3)

A compression chamber is provided inside the cylinder and the cylinder head, the discharge chamber is provided in the cylinder head to form a flow path of the discharge refrigerant, the valve plate provided for discharging the compressed refrigerant between the cylinder and the cylinder head, the valve plate In the reciprocating compressor having a discharge port for communicating the compression chamber and the discharge chamber, a discharge valve for opening and closing the discharge port, a stopper valve for supporting the discharge valve, One end of the discharge valve is fixed and the other end is provided to be rotatable, and the stopper valve is a reciprocating compressor, characterized in that provided with a rotation support formed in the inclined surface to support the rotating part of the discharge valve during the discharge stroke. The method of claim 1, One end of the discharge valve is provided between the stopper valve and the valve plate is fixed and the other end is provided to seal the discharge port to open and close. The method of claim 1, One end of the stopper valve is bent and fixed in contact with the inner surface of the cylinder head, the central portion forms an inclined surface extending upwards and the other end is fixedly coupled to the support groove provided on one side of the discharge chamber Homogeneous compressor.