KR20020012898A - Structure for sucking active gas in compressor - Google Patents

Abstract

PURPOSE: A refrigerant gas suction structure for compressor is provided to prevent damage of the suction valve and enhance compression performance, while allowing the refrigerant gas to be smoothly sucked and compressed in the compression space of the cylinder. CONSTITUTION: A refrigerant gas suction structure comprises a piston(50) having an insertion hole(52) formed at a piston body(51) to be inserted into a cylinder(10), and a gas inlet hole formed at a wall(52) of the insertion hole so as to communicate a compression space(P) of the cylinder to the insertion hole; an inner support pipe(60) having an outer diameter corresponding to the inner diameter of the insertion hole of the piston, and a gas inlet channel(f) formed inside of the inner support pipe, wherein the inner support pipe is inserted into the insertion hole of the piston in such a manner that a valve insertion space(V) is formed between an end surface(e) of the inner support pipe and an inner side wall(d) of the insertion hole of the piston; and a suction valve(70) inserted into the valve insertion space, and which moves along the reciprocating motion of the piston and opens/shuts the gas inlet channel so as to allow the refrigerant gas to be sucked into or cut off from the compression space of the cylinder.

Description

Refrigerant gas suction structure of compressor {STRUCTURE FOR SUCKING ACTIVE GAS IN COMPRESSOR}

The present invention relates to a refrigerant gas suction structure of a compressor, and in particular, to allow the refrigerant gas to be smoothly sucked and compressed into a compression space of a cylinder into which the refrigerant gas is compressed, as well as to prevent breakage of an intake valve that opens and closes. It relates to a refrigerant gas suction structure of the compressor.

Generally, a compressor is a machine that compresses a fluid such as air or refrigerant gas. In one example of the compressor, the linear compressor transmits the driving force of the electric mechanism generating linear driving force to a piston constituting the compression mechanism for compressing the gas so that the piston sucks, compresses and discharges the refrigerant gas while linearly reciprocating the inside of the cylinder. do.

FIG. 1 illustrates an example of the linear compressor compression mechanism. As shown in FIG. 1, the compression mechanism of the linear compressor includes a cylinder 10 and a cylinder having a through hole forming a compression space P therein. And a discharge valve assembly 30 coupled to cover the through hole at an end of the cylinder 10 and a piston 20 inserted into the through hole so as to linearly move.

The piston 20 has a head portion 22 is formed on one side of the body portion 21 having a predetermined length, and the connection portion 23 is formed on the other side of the body portion 21 and connected to the electric mechanism. A gas flow path F is formed to allow the refrigerant gas to flow through the piston 20, and the gas flow path F is formed to have a predetermined depth among the body parts 21. And a second gas passage 25 formed in the head portion 22 so as to communicate with the 24 and the first gas passage 24. In addition, the piston head portion 22 is equipped with a suction valve 40 for opening and closing the second gas passage 25, that is, the gas flow path (F).

As shown in FIG. 2, the suction valve 40 is formed of a thin circular thin plate corresponding to the end face S of the piston head portion 22 and the circular thin plate so that a part of the circular thin plate can be bent. Open grooves having a predetermined width in the form of a cutting groove 41 is formed in the circular thin plate is divided into a fixed region 42 and the opening and closing region 43 by the cut groove 41. The suction valve 40 is fixed to the fixed area portion 42 in a state where the opening and closing portion 43 is in contact with the head end surface S of the piston so as to block the second gas suction passage 25 of the piston. Welded to and fixed.

The discharge valve assembly 30 is inserted into the discharge cover 31 and the discharge cover 31 coupled to cover the end of the cylinder 10 and is formed by the through hole and the piston 20 of the cylinder 10. The discharge valve 32 which opens and closes the compression space P formed, and the valve spring 33 which elastically supports the discharge valve 32 are comprised.

The operation of the compression mechanism as described above is as follows.

The linear driving force generated in the transmission mechanism is transmitted to the piston 20 so that the piston 20 linearly reciprocates inside the cylinder 10. In the above process, as shown in FIG. 3, when the piston 20 moves in the bottom dead center (a) direction, the discharge valve 32 contacts the end of the cylinder 10 to block the compression space P. At the same time, the opening / closing area 43 of the suction valve 40 coupled to the piston 20 is bent to open the gas flow path F of the piston through the gas flow path F formed inside the piston 20. The refrigerant gas is sucked into the compression space P of the cylinder 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 opening / closing area portion 43 of the intake valve 40 is opened to expand the gas flow path of the piston. While blocking (F), the refrigerant gas sucked in the compression space P of the cylinder 10 is compressed, and when it reaches the top dead center b, the discharge valve 32 is opened and the compressed refrigerant gas is discharged. This process is repeated continuously to compress the gas.

However, as described above, in the prior art of sucking and blocking refrigerant gas into the compression space P of the cylinder, a suction valve 40 is coupled to the head end surface S of the piston so that a part of the suction valve 40 is provided. As the stress is applied to the intake valve 40 in the process of opening and closing the gas flow path F of the piston while continuously bending and unfolding, there is a fear of fatigue destruction of the intake valve 40 as well as a refrigerant in a liquid state. There was a disadvantage that can be broken if the inflow.

The object of the present invention devised in view of the above disadvantages is to receive the linear driving force of the electric mechanism part, while the piston is linearly reciprocating in the cylinder while inhaling and compressing and discharging the refrigerant gas into the compression space of the cylinder. The present invention provides a refrigerant gas suction structure of a compressor to smoothly suck and compress refrigerant gas into a compression space and to prevent breakage of a suction valve that opens and closes.

1 is a front sectional view showing a compression mechanism of a linear compressor;

Figure 2 is a perspective view showing the end and the suction valve of the piston constituting the compression mechanism,

3 is a front sectional view showing an operating state of the linear compressor compressor mechanism;

Figure 4 is a sectional front view of the compression mechanism of the compressor with a compressor refrigerant gas suction structure of the present invention,

5 is a cross-sectional view taken along line AA ′ of FIG. 4;

6 is a cross-sectional view taken along line BB ′ of FIG. 4;

7, 8 is a cross-sectional view showing an operating state of the refrigerant refrigerant gas suction structure of the present invention.

(Explanation of symbols for the main parts of the drawing)

10; Cylinder 50; piston

51; Piston body part 52; Insertion hole

53; Gas suction through hole 60; Medial support tube

65; Guide pin 70; Suction valve

P; Compression space V; Valve insertion space

f; Gas suction flow path d; Insertion Hole Inner Wall

In order to achieve the object of the present invention as described above, an insertion hole having a predetermined inner diameter and a length is formed at one side of the piston body portion inserted into the cylinder, and the compression space of the cylinder and the insertion hole are formed at one side wall of the insertion hole. A piston having a gas suction through-hole communicating therewith, an outer diameter corresponding to the inner diameter of the piston insertion hole, and a predetermined length, and a gas suction passage is formed therein and inserted into and coupled to the insertion hole of the piston. An inner support pipe which is coupled at intervals so as to form a valve insertion space between inner walls, and the gas suction so that refrigerant gas is sucked into or blocked by the cylinder compression space while being inserted into the valve insertion space and moving according to the reciprocating motion of the piston Compressor comprising a suction valve for opening and closing the flow path A refrigerant gas suction structure is provided.

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

4 is a view illustrating an embodiment of a compressor intake valve structure of the present invention. Referring to this, first, a piston 50 inserted into a cylinder 10 constituting a compression mechanism for compressing gas is capable of linear reciprocating motion. ) Has a predetermined length and an insertion hole 52 having a predetermined inner diameter and length is formed at one side of the piston body 51 inserted into the cylinder 10, and one side wall d of the insertion hole 52 is formed. ) Is a gas suction through-hole (53) for communicating the compression space (P) of the cylinder and the insertion hole (52). That is, the body portion 51 is formed in the shape of a round bar having a predetermined length so that it can be inserted into the cylinder 10, there is formed an insertion hole 52 having a predetermined inner diameter and length therein and the body portion A connecting portion 54 is bent and extended at one end of the 51 to be connected to the power mechanism. As shown in FIG. 5, the gas suction through holes 53 are formed as through holes smaller than the inner diameter of the insertion hole 52, and a plurality of gas suction through holes 53 are formed at equal intervals.

The inner support pipe 60 has an outer diameter corresponding to the inner diameter of the piston insertion hole 52 and a predetermined length, and is bent and extended to one side of the trunk portion 61 in which a gas suction flow path f is formed. Extension 62 is formed. The gas suction passage (f) is a main passage (63) having a predetermined inner diameter and length inside the body portion (61) and a plurality of inflow holes (64) penetrated through the inner wall of the main passage (63). Is done.

The inner support tube 60 is the body portion 61 is inserted into the insertion hole 52 of the piston and the extension portion 62 is fixedly coupled to one side of the piston (50). At this time, the end surface (e) of the side in which the inflow hole (64) is formed is inserted to form a predetermined interval with the inner wall (d) of the insertion hole (52) of the piston, the valve insertion space (V) in which the valve is located therein Will form.

As shown in FIG. 6, the suction valve 70 has an outer diameter smaller than the inner diameter of the piston insertion hole 52 and larger than the gas suction flow path of the inner support pipe 60, that is, the inflow holes 64. It is formed into a circular thin plate having. The suction valve 70 is inserted to be movable in the valve insertion space (V).

A guide pin 65 is formed in the valve insertion space V to guide the linear movement of the suction valve 70, and the suction valve 70 is inserted through the guide pin 65. The guide pin 65 is preferably extended to have a predetermined outer diameter and a predetermined length on the end surface e of the inner support tube 60 forming the valve insertion space (V).

The piston 50 is inserted into the cylinder 10 to form a compression space P inside the cylinder 10, and the connecting portion 54 of the piston is connected to the electric mechanism part. And the discharge valve assembly 80 is coupled to the cylinder (10).

Hereinafter, the operational effects of the compressor refrigerant gas suction structure of the present invention will be described.

First, the piston 50 is linearly reciprocated in the cylinder by receiving the linear driving force of the electric mechanism. In the process of linearly reciprocating the piston 50, as shown in FIG. 7, when the piston 50 moves in the bottom dead center (a) direction, the suction valve 70 is inserted into the insertion hole due to the pressure difference. The gas suction flow path f is opened while moving to the inner wall d of the valve 52, and the refrigerant gas flows through the main passage 63 and the inflow hole 64 forming the gas suction flow path f. The refrigerant gas introduced into the valve insertion space (V) is sucked into the compression space (P) of the cylinder through the gas suction hole (53).

When the piston 50 reaches the bottom dead center (a) and moves from the bottom dead center (a) to the top dead center (b), the suction valve 70 is the end face of the inner support pipe 60 due to the pressure difference. Moving to (e) side to block the gas intake passage (f) to compress the refrigerant gas sucked into the compression space (P) of the cylinder and then reaches the top dead center (b) is compressed by the discharge valve assembly (80) The refrigerant gas is discharged. As this process is continuously repeated, the refrigerant gas is sucked into the cylinder compression space P, compressed and discharged.

According to the present invention, the suction valve 70 moves or stops the refrigerant gas into the cylinder compression space P while moving by the pressure difference in the valve insertion space V, so that the suction valve 70 is not bent. do.

In addition, the suction valve 70 sucks or blocks the refrigerant gas while reciprocating in the valve insertion space V due to the pressure difference according to the linear reciprocating motion of the piston 50, so that the suction action and the compression action of the refrigerant gas are smooth. Will be done.

As described above, the refrigerant gas suction structure of the compressor according to the present invention receives the linear reciprocating driving force of the electric mechanism, and the suction valve reciprocates by the pressure difference generated as the piston reciprocates linearly in the cylinder. By opening and closing the suction flow path and inhaling the refrigerant gas into the cylinder compression space, it is possible to increase the reliability by preventing damage to the suction valve by minimizing the problems occurring in the existing suction valve, and suction of the refrigerant gas into the cylinder compression space. This smoothly has the effect of increasing the compression performance.

Claims (3)

A piston having an insertion hole having a predetermined inner diameter and a length formed at one side of the piston body part inserted into the cylinder, and having a gas suction through-hole communicating the compression space of the cylinder and the insertion hole on one side wall of the insertion hole; It has an outer diameter and a predetermined length that corresponds to the inner diameter of the piston insertion hole, and a gas suction flow path is formed therein, and is inserted into and coupled to the insertion hole of the piston. And an inlet valve coupled to the inner support tube and the inlet valve inserted into the valve insertion space to open and close the gas intake passage so that the refrigerant gas is sucked into or blocked by the cylinder compression space while moving in accordance with the reciprocating motion of the piston. Refrigerant gas suction structure of the compressor. The compressor gas suction structure according to claim 1, wherein a guide pin is inserted in the center of the valve insertion space and the suction valve is inserted into the guide pin to move the guide pin. The compressor gas suction structure of claim 1, wherein the suction valve is formed of a circular thin plate having an outer diameter smaller than an inner diameter of the insertion hole and larger than the gas suction passage.