KR19990057587A - Refrigerant Gas Suction Structure of Compressor - Google Patents

Abstract

The present invention relates to a refrigerant gas suction structure of a compressor. In the related art, while a piston is moved by a driving force of a driving motor, the refrigerant gas is guided by a suction flow path formed inside the piston and a suction valve that opens and closes the suction gas to be sucked into the cylinder. Part of the refrigerant gas introduced into the suction flow path is reversed and collides with the refrigerant gas flowing into the suction flow path to generate suction loss, thereby reducing the suction efficiency of the refrigerant gas. In order to prevent the refrigerant gas flowing into the cylinder by preventing the reverse flow of the refrigerant gas flowing into the suction flow path by forming a back flow prevention portion for preventing the back flow of the refrigerant gas in the suction flow path for guiding the refrigerant gas into the cylinder It is to increase the suction efficiency of refrigerant gas. .

Description

Refrigerant Gas Suction Structure of Compressor

The present invention relates to a compressor, and more particularly, to a refrigerant gas suction structure of a compressor capable of reducing the suction loss of the refrigerant gas by smoothing the suction flow of the refrigerant gas sucked into the cylinder.

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.

As an example of the compressor, as shown in Figure 1, the compressor is an inner container formed to have a predetermined inner space, and the inner container formed in the middle of the inside of the sealed container 1 and has a predetermined inner space A case 2, a drive motor M coupled to the inner side of the inner case 2, a cylinder 4 coupled to an inner stator 3 of the drive motor M, and the inner case 2. The cover plate (5) through which one side of the cylinder (4) penetrates and is coupled to one side of the cylinder (4), and the piston (6) coupled to reciprocate in the cylinder (4), and one side of the cover plate (5). The magnet paddle 8 coupled to the magnet 7 constituting the drive motor and the other side is coupled to one side of the piston 6 to transfer the movement of the drive motor M to the piston 6 and the magnet paddle ( The piston (6) is supported between the inner side of 8) and the side of the inner stator (3) of the drive motor (M). Inner spring (9) elastically supporting the movement of the), the cover 10 is coupled to the other side of the inner case (2), the outer surface of the magnet paddle (8) and the cover (10) It is supported between the inner surface of the outer spring 11, which supports the movement of the piston (6) and stores the kinetic energy, and the refrigerant gas is sucked into the cylinder (4) and compressed And a valve assembly for discharging the refrigerant gas.

Reference numeral 12 shows a winding coil constituting the drive motor, and reference numeral 13 shows an outer stator constituting the drive motor.

In the compressor as described above, when a current is applied to the driving motor M, the piston 7 reciprocates in the cylinder 4 by the linear reciprocation of the magnet 7, and the piston 6 moves in the cylinder 4. As the reciprocating motion in the inside of the container (1), the refrigerant gas introduced into the sealed container (1) is sucked into the cylinder (4) through the refrigerant suction flow path (F) formed in the piston (6), compressed and discharged through the valve system Will repeat.

On the other hand, the piston (6) for receiving and compressing the refrigerant gas while receiving the driving force of the drive motor (M) in the reciprocating motion in the cylinder (4), as shown in Figure 2, the inside of the cylinder (4) An oil storage groove 6b having a predetermined depth and width in which oil is supplied and stored is formed on an outer circumferential surface of the body portion 6a formed in a cylindrical shape so as to be inserted therein, and guides suction of refrigerant gas into the body portion 6a. A refrigerant suction flow path F is formed, and a suction valve 15 for opening and closing the suction flow path F is mounted at one end of the body part 6a. The suction passage F has a larger diameter at the inlet side through which the refrigerant gas is sucked and a smaller diameter at the side on which the suction valve 15 is mounted due to the oil storage groove 6b being formed.

Reference numeral 4a denotes an oil passage, 16 is a discharge valve assembly, and 17 is a head cover.

When the piston 6 moves from the top dead center to the bottom dead center in the cylinder 4 by the driving force of the driving motor M, the piston 6 is caused by the suction force due to the pressure difference between the inside of the sealed container 1 and the inside of the cylinder 4. When the suction valve 15 opens, the refrigerant gas is sucked into the cylinder 4 through the suction flow path F, and when the piston 6 moves from the bottom dead center to the top dead center, the suction valve 15 closes and the piston ( 6) Compresses the refrigerant gas sucked into the cylinder (4).

However, in the compressor as described above, the conventional refrigerant gas suction structure for sucking the refrigerant gas into the cylinder 4 is lowered at the top dead center as the piston 6 receives the driving force of the driving motor M from the cylinder 4. While the suction valve 15 is opened while moving to the point, the refrigerant gas is sucked into the cylinder 4 through the suction flow path F formed inside the piston 6, and the suction flow path formed inside the piston 6 Since the diameter of the outlet (b) is smaller than the diameter of the inlet (a) through which the refrigerant gas flows in (F), all of the refrigerant gas introduced into the inlet (a) is discharged through the outlet (b). There is a problem in that the suction efficiency of the refrigerant gas sucked into the cylinder 4 is lowered due to the flow of the refrigerant flowed back through the inlet (a) without being sucked into the cylinder.

Accordingly, an object of the present invention is to provide a refrigerant gas intake structure of a compressor that facilitates the suction flow of refrigerant gas sucked into a cylinder to reduce the suction loss of the refrigerant gas.

1 is a cross-sectional view showing an example of a general compressor.

2 is a cross-sectional view showing a refrigerant gas suction structure of a conventional compressor.

3 is a cross-sectional view showing a refrigerant gas suction structure of the compressor of the present invention.

* Explanation of symbols for main parts of the drawings

4 cylinder 6 cylinder

6c: Cylinder bump 15: Intake valve

a: suction passage inlet F: suction passage

M: drive motor

In order to achieve the object of the present invention as described above, a suction flow passage for guiding the suction of refrigerant gas is formed therein, and a piston equipped with a suction valve for opening and closing the suction flow passage at one end thereof receives a driving force of a driving motor. In the refrigerant gas suction structure of the compressor in which the refrigerant gas is sucked into the cylinder through the suction passage while the suction valve is opened by the movement inside; There is provided a refrigerant gas suction structure of a compressor, wherein a backflow prevention unit is formed to prevent a backflow of the refrigerant gas sucked into the suction flow path guiding the suction of the refrigerant gas.

The backflow prevention unit is provided with a refrigerant gas suction structure of the compressor, characterized in that formed on the inlet side through which the refrigerant gas flows.

The backflow prevention unit is provided with a refrigerant gas suction structure of the compressor, characterized in that formed in the inner circumferential surface of the piston forming the suction flow passage formed in the form of a plurality of prevention jaws protruding in the form of a circular ring at a predetermined interval. .

The prevention jaw is provided with a refrigerant gas suction structure of the compressor, characterized in that the end is formed to be inclined toward the suction valve side.

The refrigerant gas suction structure of the compressor is provided so that the diameter and height of the bumps are formed to match the resonance frequency.

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

In the compressor refrigerant gas suction structure of the present invention, as shown in Figure 3, the suction passage (F) for guiding the suction of the refrigerant gas is formed therein and the suction valve for opening and closing the suction passage (F) at one end ( The piston 6 equipped with the 15 receives the driving force of the driving motor M, and the suction valve 15 is opened by the movement inside the cylinder 4, and the refrigerant gas is introduced into the cylinder 4 through the suction flow path F. Is similar to the conventional structure. A backflow prevention part is formed to prevent a backflow of the refrigerant gas sucked into the suction flow path F for guiding the suction of the refrigerant gas.

The reverse flow prevention part is formed at an inflow side of the suction passage F through which the refrigerant gas is introduced.

The backflow prevention part is formed of a plurality of prevention jaws 6c protruding in a circular ring shape having a predetermined width and height on the inner circumferential surface of the piston 6 forming the suction flow path F at predetermined intervals. The prevention jaw 6c is formed to be inclined such that its end faces the intake valve 15 side.

The inner diameter of the prevention jaw 6c formed in the shape of the circular ring is formed to correspond to or smaller than the diameter of the suction flow path F of the portion located on the oil storage groove 6b side formed on the outer circumferential surface of the piston 6.

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

First, the intake valve 15 is opened while the piston 6 receives the driving force of the driving motor M from the top dead center to the bottom dead center in the cylinder 4, and the refrigerant gas is formed inside the piston 6. It is sucked into the cylinder 4 through the suction flow path F. At this time, if a part of the refrigerant gas flowing into the suction channel F and moving toward the suction valve 15 is not sucked into the cylinder 4 through the suction valve 15 and flows backward, the backflow prevention part formed in the suction channel F is prevented. The backflow is prevented by the prevention jaw (6c) to be formed along the suction flow path (F) flows back to the suction valve 15 side is sucked into the cylinder (4). As a result, a collision between the refrigerant gas flowing into the suction flow path F and the refrigerant gas flowing back may be prevented to reduce the suction loss of the refrigerant gas, thereby smoothly inhaling the refrigerant gas and increasing the suction amount.

In another embodiment of the present invention, the diameter of the portion in which the refrigerant gas flows in the suction flow path F formed inside the piston 6 is formed to match the resonant frequency so that the reverse flow of the refrigerant gas flows into the suction flow path F. Can be prevented.

As described above, the refrigerant gas intake structure of the compressor according to the present invention is formed in the piston, the inlet flow path for preventing the backflow of the refrigerant gas is formed in the intake flow path for guiding the refrigerant gas in the cylinder is formed into the suction flow path As the refrigerant gas is smoothly sucked into the cylinder, the suction amount of the refrigerant gas is increased to increase the suction efficiency of the refrigerant gas.

Claims (5)

A suction passage is formed inside the suction passage for guiding the suction of the refrigerant gas, and a piston equipped with a suction valve for opening and closing the suction passage at one end receives the driving force of the driving motor, and the suction valve opens by moving in the cylinder. In the refrigerant gas suction structure of the compressor through which the refrigerant gas is sucked into the cylinder through; Refrigerant gas suction structure of the compressor, characterized in that the reverse flow prevention portion for preventing the back flow of the refrigerant gas sucked into the suction flow path for guiding the suction of the refrigerant gas is formed. The refrigerant gas intake structure of claim 1, wherein the backflow prevention part is formed at an inlet side through which the refrigerant gas is introduced. The compressor of claim 1, wherein a plurality of stoppers protruding in a circular ring shape having a predetermined width and height are formed at predetermined intervals on the inner circumferential surface of the piston forming the suction passage. Gas intake structure. 4. The refrigerant gas suction structure of a compressor of claim 3, wherein the prevention jaw is formed to be inclined so that an end thereof faces the suction valve side. 5. The refrigerant gas suction structure of claim 4, wherein the diameter and height of the bumps are formed to match the resonance frequency.