KR20030042818A - Apparatus for compressing gas in reciprocating compressor - Google Patents

Abstract

PURPOSE: A gas compression apparatus for a reciprocating compressor is provided to increase productivity by reducing assembling process with compact and simple structure, and to improve the reliability by minimizing noise in opening and closing the valve. CONSTITUTION: A gas compressor comprises a piston(70) reciprocating linearly in a compression space of a cylinder by receiving linear reciprocating force of a motor; an intake/discharge cover(80) having a guide part extended cylindrically, an intake port connected to the guide part, a discharge port and a discharge passage; a valve body(100) inserted to the guide part and reciprocated according to pressure difference in reciprocating the piston to open and close the discharge passage; a valve spring(140) inserted to the guide part of the intake/discharge cover to elastically support the valve body; and a suction valve(130) placed in the compression space of the cylinder and combined with the valve body to open and close the suction passage of the valve body. The productivity is improved by processing the piston simply, and noise in opening the valve is shut off.

Description

Gas Compressor of Reciprocating Compressor {APPARATUS FOR COMPRESSING GAS IN RECIPROCATING COMPRESSOR}

The present invention relates to a gas compressor of a reciprocating compressor, and more particularly to a gas compressor of the reciprocating compressor to simplify the configuration and processing, as well as to minimize the transmission of the valve opening and closing sound to the outside.

Generally, a compressor is a device that compresses a fluid. The compressor may be of various types such as a rotary compressor, a scroll compressor, a reciprocating compressor, and the like according to a method of compressing a gas.

The reciprocating compressor is composed of a power mechanism for generating a linear reciprocating drive force and a compressor mechanism for compressing gas by receiving the driving force of the power mechanism. When the reciprocating compressor generates a linear reciprocating driving force in the electric mechanism part as the current is applied to the electric mechanism part, the linear reciprocating driving force generated in the electric mechanism part is transmitted to the compressor mechanism to suck the refrigerant in the compression mechanism part and compress it. To be discharged.

FIG. 1 illustrates an example of a compression mechanism of the reciprocating compressor. As shown in FIG. 1, the compression mechanism of the reciprocating compressor includes a cylinder having a through hole 11 constituting a compression space P therein ( 10) and a piston 20 inserted into the through hole 11 of the cylinder 10 so as to be linearly movable, and having a hollow flow path F provided therein, and a through hole at an end of the cylinder 10. A discharge cover 30 coupled to cover 11 and a valve assembly 40 positioned inside the discharge cover 30 to open and close the cylinder compression space P are configured.

The piston 20 has a head portion 22 formed on one side of the cylindrical body portion 21 having a predetermined length and the gas suction flow path F passing through the body portion 21 and the head portion 22 is provided. Is formed and is provided with a connecting portion 23 is connected to the power mechanism on the other side of the body portion (21).

And an intake valve 50 for opening and closing the gas suction flow path (F) is mounted on the end surface of the piston head portion 22.

The discharge cover 30 is formed of a cover portion 31 is formed in the form of a cap and a flange portion 32 is formed to be bent extending to the open end surface of the cover portion 31, the valve assembly 40 is A discharge valve 41 positioned on the cover 31 of the discharge cover to open and close the cylinder compression space P, and an inside of the cover 31 of the discharge cover to elastically support the discharge valve 41. It consists of a valve spring (42).

The compression mechanism of the reciprocating compressor as described above transmits linear driving force of the electric mechanism to the piston 20 so that the piston 20 linearly reciprocates inside the cylinder 10. In the above process, as shown in FIG. 2, when the piston 20 moves in the bottom dead center a direction, the discharge valve 41 contacts the end of the cylinder 10 due to the pressure difference, At the same time as blocking the P) and the suction valve 50 coupled to the piston 20 is bent to open the gas suction flow path (F), the refrigerant flows through the gas suction flow path (F) of the piston 20 cylinder It is sucked into the compression space P of (10).

When the piston 20 reaches the bottom dead center (a) and moves from the bottom dead center (a) to the top dead center (b), the inlet valve 50 is unfolded due to the pressure difference, and the gas suction flow path ( The refrigerant sucked into the compression space P of the cylinder 10 is compressed while the F is blocked. Then, when the piston 20 reaches the top dead center b, the discharge valve 41 is opened to compress the refrigerant. Discharged. This process is repeated continuously to compress the gas.

However, the conventional structure as described above is difficult to process the piston 20 because the gas suction flow path (F) through which the gas is sucked into the compression space (P) of the cylinder is formed inside the piston 20, In addition, since the intake valve 50 is mounted on the end surface of the piston 20, the valve opening and closing sound generated when the intake valve 50 is operated at the end surface of the cylinder is transmitted through the piston 20 and the cylinder 10. There is a problem that is transmitted to the outside to increase the noise generation.

The object of the present invention devised in view of the problems described above is to provide a gas compression device of a reciprocating compressor to simplify the configuration and processing, as well as to minimize the transmission of the valve opening and closing sound to the outside.

1 is a cross-sectional view showing an example of a conventional reciprocating compressor compressor mechanism,

2 is a cross-sectional view showing an operating state of the reciprocating compressor compressor mechanism;

3 is a cross-sectional view showing a reciprocating compressor gas compressor of the present invention;

4 and 5 are cross-sectional views each showing an operating state of the reciprocating compressor gas compressor of the present invention.

** Explanation of symbols for main parts of drawings **

70; Piston 80; Absorption Discharge Cover

81; Cover portion 82; Guide part

83; Inlet 84; Outlet

100; Valve body 102; Suction euro

104; Sealing member 105; Oil Eurohome

110; Sealing means 120; Oil suction line

121; Oil discharge tube 130; Intake valve

140; Valve spring P; Compressed space

In order to achieve the object of the present invention as described above, the piston is linearly reciprocated in the compression space of the cylinder by receiving a linear reciprocating driving force of the electric mechanism, and formed in the form of a cap on the inner wall of the cover to cover the compression space of the cylinder. A guide portion extending in a cylindrical shape to have a predetermined length is formed, and a suction port communicating with the inside of the guide portion is formed at one side of the cover portion, and the cover portion communicates with an inner space formed by the inner wall of the cover portion and the outer wall of the guide portion. A discharge port is provided to be provided and coupled to cover the compression space of the cylinder to form a discharge flow passage which communicates with the inner space between the guide surface and the upper surface of the cylinder, the guide of the suction discharge cover The pressure difference due to the reciprocating motion of the piston A valve body that opens and closes the discharge flow path while performing a double movement, a valve spring inserted into a guide portion of the intake and discharge cover to elastically support the valve body, and coupled to the valve body so as to be located at the cylinder compression space side; Provided is a gas compression device for a reciprocating compressor comprising a suction valve for opening and closing a suction flow passage formed through a sieve.

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

3 illustrates an embodiment of the reciprocating compressor gas compressor of the present invention. Referring to this, the compressor gas compressor of the present invention includes a through hole 61 forming a compression space P. FIG. The piston 70 is inserted into the through hole 61 of the cylinder 60, and the piston 70 is connected to an electric mechanism part that generates a linear reciprocating driving force.

The piston 70 is provided with a head portion 72 is formed on one side of the cylindrical body portion 71 having a predetermined length, and the connection portion (not shown) connected to the power mechanism portion on the other side of the body portion 71 Is done.

And the suction discharge cover 80 is coupled to one side of the cylinder 60 to cover the compression space (P) of the cylinder. The suction discharge cover 80 is formed in the form of a cap formed on the inner wall of the cover 81 for covering the compression space (P) of the cylinder is formed with a guide portion 82 extending to have a predetermined length in a cylindrical shape and the A suction port 83 communicating with the inside of the guide part 82 is formed at one side of the cover part 81, and an inner wall of the cover part 81 and an outer wall of the guide part 82 are formed in the cover part 81. The discharge port 84 is provided to communicate with the internal space (C) formed by the. The open end surface of the guide portion 82 is formed to be located inside the open end surface of the cover portion 81 and the inner diameter of the guide portion 82 is formed larger than the inner diameter of the through hole 61 of the cylinder. .

The suction discharge cover 80 is coupled so that the cover portion 81 is in contact with the flange portion 62 of the cylinder, wherein the end surface of the guide portion 82 and the upper surface of the cylinder 60, that is, the cylinder flange A gap G is formed between the side surfaces and is formed by a gap G between the upper surface of the cylinder 60 and the end surface of the guide portion 82, and an outer circumferential surface of the guide portion 82 and an inner circumferential surface of the cover portion 81. The discharge flow path is formed by the internal space C that becomes. A suction pipe 90 and a discharge pipe 91 are connected to the suction port 83 and the discharge port 84 of the suction discharge cover 80, respectively.

And the valve body 100 for opening and closing the discharge flow path while being reciprocated by the pressure difference according to the reciprocating motion of the piston 70 is inserted into the guide portion 82 of the suction and discharge cover to be movable. The valve body 100 has a suction passage 102 penetrating both side surfaces of the annular body 101 having a predetermined thickness and an outer diameter corresponding to the inner diameter of the guide portion 82. The valve body 100 is inserted and coupled so that the outer circumferential wall of the annular body 101 is in contact with the inner circumferential wall of the guide portion 82.

And a sealing means 110 is provided between the outer peripheral wall of the annular body 101 of the valve body and the inner peripheral wall of the guide portion 82 of the suction discharge cover. The sealing means 110 has an annular sealing groove 103 having a predetermined width and depth on the outer circumferential wall of the valve body 100 and has an annular shape in the sealing groove 103 of the valve body 100. Sealing member 104 is inserted.

In addition, an oil flow path groove 105 having a predetermined width and depth is formed on the outer circumferential wall of the valve body 100 in contact with the inner circumferential wall of the suction part cover 82, and one side of the suction discharging cover 80. The oil intake pipe 120 is coupled to communicate with the oil flow path groove 105 of the valve body 100 and the oil flow path groove 105 of the valve body 100 on the other side of the suction discharge cover 80. The oil discharge pipe 121 is coupled through to communicate.

An intake valve 130 is fixedly coupled to one side surface of the valve body 100, that is, one side surface of the valve body 100 positioned at the cylinder compression space P side.

And the valve spring 140 for elastically supporting the valve body 100 is coupled to the guide portion 82 of the suction discharge cover. The valve spring 140 is preferably made of a coil spring.

Hereinafter, the operational effects of the reciprocating compressor gas compressor of the present invention will be described.

First, the linear reciprocating driving force of the electric motor unit is transmitted to the piston 70 so that the piston 70 linearly reciprocates the compression space P of the cylinder 60. At this time, when the piston 70 moves in the direction of the bottom dead center (a) from the top dead center (b) as shown in FIG. 4, the valve body 100 is the end surface of the cylinder 60 by the pressure difference In other words, the inlet valve 130 coupled to the valve body 100 is bent while opening the suction flow path 102 while being in close contact with the surface of the flange part 62 to block the compression space P of the cylinder. The gas sucked through the suction port 83 of the suction discharge cover is sucked into the compression space P of the cylinder through the guide part 82 and the suction flow path 102. At this time, the valve body 100 is in close contact with the end surface of the cylinder 60 to prevent the gap (G) of the discharge flow path formed between the end surface of the cylinder 60 and the end surface of the guide portion 82.

After the piston 70 reaches the bottom dead center (a), as shown in FIG. 5, when the piston 70 moves from the bottom dead center (a) to the top dead center (b), the intake valve 130 is moved by the pressure difference. Is expanded to its original state and the refrigerant sucked in the compression space P of the cylinder 60 is compressed while the suction passage 102 is blocked. Then, when the piston 70 reaches the top dead center b, the valve As the valve body 100 supported by the spring 140 moves toward the valve spring 140 side, the cylinder compression space P is opened to discharge the compressed refrigerant. The gas in the high temperature and high pressure state discharged from the cylinder compression space P is discharged, that is, the gap G between the end surface of the guide portion 82 and the end surface of the cylinder 60 and the outer circumferential surface and cover of the guide portion 82. It is discharged through the discharge port 84 while flowing through the inner space (C) formed by the negative inner circumferential surface, wherein the gas discharged to the discharge passage is reduced through the internal space (C).

As this process is continuously repeated, the gas is sucked, compressed and discharged.

In addition, the gas is sucked into the cylinder compression space P by the sealing means 110 provided between the inner circumferential wall of the guide part 82 of the suction and discharge cover and the outer circumferential wall of the valve body 100, or the cylinder is compressed. The gas compressed in the space P is prevented from leaking in the process of being discharged to the discharge passage.

In addition, the oil flowing into the oil flow path groove 105 of the valve body 100 minimizes friction and wear between the outer circumferential wall of the valve body 100 and the inner circumferential wall of the guide part 82.

According to the present invention, the inlet flow path through which gas is sucked into the cylinder compression space P is provided in the valve body 100, and the inlet valve 130 is provided in the valve body 100. The suction and discharge of the gas is performed, thereby not only compacting the component but also simplifying the component and excluding the gas suction flow path through which the gas is sucked into the piston 70, thereby simplifying the processing of the piston 70. Done.

In addition, since the inlet valve 130 is mounted on the valve body 100, the opening and closing action of the inlet valve 130 is performed in the valve body 100. The sound is alleviated in the guide portion 82 and the suction pipe 90 and the inner space (C) of the suction discharge cover to minimize the transmission to the outside.

As described above, the gas compression device of the reciprocating compressor of the present invention not only has a compact and simple component configuration for compressing gas, but also the processing of the piston can be simplified, thereby reducing the number of assembly steps in the assembly line, thereby increasing the assembly productivity. In addition to reducing the processing cost of the piston, it is also possible to minimize the valve opening and closing sound generated when opening and closing the intake valve to the outside has the effect of increasing the reliability of the compressor.

Claims (4)

A piston which linearly reciprocates in the compression space of the cylinder by receiving a linear reciprocating driving force of the electric mechanism part, and a guide part which is formed in a cap shape and extends to have a predetermined length in a cylindrical shape on the inner wall of the cover part covering the compression space of the cylinder And a suction port is formed on one side of the cover part to communicate with the inside of the guide part, and the discharge part is provided to communicate with an inner space formed by the inner wall of the cover part and the outer wall of the guide part. And a suction discharge cover which is coupled to cover the upper end of the guide part and the upper surface of the cylinder to form a discharge passage communicating with the internal space, and is inserted into the guide part of the suction discharge cover to generate pressure according to the reciprocating motion of the piston. Valve body for opening and closing the discharge flow path while reciprocating by a car A valve spring inserted into the guide part of the suction discharge cover and elastically supporting the valve body, and an suction valve coupled to the valve body so as to be positioned at the cylinder compression space side and opening and closing a suction flow path formed through the valve body; Gas compression device of a reciprocating compressor characterized in that it comprises a. The gas compression apparatus of the reciprocating compressor according to claim 1, wherein a sealing means is provided on an outer circumferential wall of the valve body in contact with the inner circumferential wall of the guide part of the suction and discharge cover. According to claim 2, The sealing means is characterized in that the annular sealing groove having a predetermined width and depth is formed on the outer peripheral wall of the valve body and the annular sealing member is inserted into the sealing groove of the valve body Gas compression device of a reciprocating compressor. According to claim 1, wherein the oil flow path groove having a predetermined width and depth is formed on the outer peripheral wall of the valve body in contact with the inner peripheral wall of the guide portion of the suction discharge cover and the oil flow path groove of the valve body and the suction discharge cover; The gas compression device of the reciprocating compressor, characterized in that the oil suction pipe and the oil discharge pipe is coupled through.