KR20000032082A - Device for guiding suction of refrigerant gas of linear compressor - Google Patents

Abstract

PURPOSE: A device for guiding suction of refrigerant gas of a linear compressor is provided to increase the amount of the sucked refrigerant gas by minimizing the amount of the refrigerant gas sucked into a cylinder mixed with the high temperature refrigerant gas filled in a sealed container. CONSTITUTION: A magnet(32) composing a starter of a motor reciprocates in rectilinear if current is fed to the motor. The rectilinear reciprocation is delivered to a piston(40) via a frame(33) so the piston reciprocates in rectilinear in a cylinder(20). The suction and venting strokes are performed repeatedly by the rectilinear reciprocation of the piston and vent the refrigerant gas in high pressure and high temperature. Herein, a suction inducting pipe(100) combined to the end portion of the piston reciprocates in rectilinear in a suction guiding pipe(90) with the reciprocation of the piston. If the piston moves from the upper dead point to the lower dead point, the refrigerant gas passing through an evaporator according to the low pressure in the cylinder is sucked to the suction guide pipe via a suction hole and sucked into the cylinder via a suction valve(62) by passing through a refrigerant channel(F) of the piston and the suction inducing pipe.

Description

Refrigerant gas suction guide device of linear compressor

The present invention relates to a refrigerant suction device of a linear compressor, and particularly, a refrigerant gas introduced into a suction port of a sealed container and sucked into a cylinder by minimizing the amount of refrigerant gas mixed with a high temperature refrigerant gas filled in the sealed container. It relates to a refrigerant gas suction guide device of a linear compressor to increase the amount of.

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.

FIG. 1 illustrates an example of the linear compressor. As shown in the drawing, a linear compressor has a discharge container (not shown) formed on one side and a suction container 1a having a suction port 2a coupled to the other side thereof. (1), the cylinder 20 is formed into a predetermined shape and inserted into the frame 10 to be mounted inside the sealed container 1, and the through-hole 11 formed through the middle of the frame 10 in multiple stages. ), An outer stator assembly 30 coupled to one side of the frame 10, and an outer stator assembly 31 coupled to the inner stator assembly 30 at predetermined intervals, and the inner stator assembly. The magnet 32 is inserted into the gap between the 30 and the outer stator assembly 31, and the magnet 32 is inserted into the cylinder 20 and connected to the magnet frame 33 coupled to the magnet 32. Linear movement of It comprises a piston 40 reciprocating by, the inside of the piston 40 is formed through the refrigerant passage (F) through which the refrigerant gas flows.

A discharge cover 60 formed in a cap shape is coupled to one side of the cylinder 20, and a discharge valve assembly 61 for opening and closing one side of the cylinder 20 is inserted into the discharge cover 60. At the end of the piston 40 is coupled to the suction valve 62 which 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.

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. Main springs 51 to be supported by each is inserted.

Reference numeral 34 is a coil assembly constituting the motor.

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

In the linear compressor, when a current is applied to the motor, the magnet 32 linearly reciprocates, and the linear movement is transmitted to the piston 40 through the magnet frame 33, so that the piston 40 moves inside the cylinder 20. Linear reciprocating motion. The refrigerant gas introduced into the sealed container 1 through the suction port 1a by the linear movement of the piston 40 flows into the refrigerant flow path F formed in the piston 40, and the cylinder through the suction valve 62. 20, the process of being sucked into the inside, compressed and discharged through the discharge valve assembly 61 and the discharge cover 60 is repeated.

The refrigerant gas in the high temperature and high pressure state discharged through the discharge cover 60 is filled in the sealed container 1 and discharged through the discharge port of the sealed container 1 to flow into the condenser constituting the refrigeration cycle device. The refrigerant gas flowing into the suction port of the compressor is introduced into the compressor at a low temperature low pressure state through the evaporator.

Meanwhile, the compression efficiency of compressing the refrigerant gas while the piston 40 reciprocates in the cylinder 20 is proportional to the amount of refrigerant gas sucked in the suction stroke, that is, the specific volume of the refrigerant gas. In order to increase the specific volume of the gas, when the refrigerant gas flowing into the suction port 1a flows into the cylinder 20, the refrigerant gas is minimized by the high temperature of the inside of the sealed container 1.

As an example of the conventional structure for preventing the refrigerant gas is heated when the refrigerant gas through the inlet (1a) of the sealed container 1 is introduced into the cylinder 20, as shown in Figure 2, one side is expanded In addition, the suction induction pipe 80 having a predetermined length is a refrigerant flow path of the piston 40 at a predetermined distance from the inlet port 1a so that the refrigerant gas flowing into the inlet port 1a flows directly into the cylinder 20. (F) It is inserted and fixed inside. The interval between the suction induction pipe 80 and the suction port (1a) is installed at a distance to avoid the collision of the suction induction pipe 80 with the inner surface of the sealed container (1) when the piston 40 reciprocates.

However, in such a structure, the space between the suction induction pipe 80 and the suction port 1a is always spaced, and the refrigerant gas sucked when the refrigerant gas is inhaled by the interval is the refrigerant gas in the high temperature state inside the sealed container 1. Mixing with the cylinder 20 has a problem that reduces the specific volume of the refrigerant gas sucked into the inside.

In addition, as shown in FIG. 3, the end of the suction induction pipe 80 ′ inserted into the piston 40 and the suction port 1a of the sealed container 1 have a structure that compensates for the above problems. Is directly connected to the suction guide 81, the refrigerant gas sucked into the cylinder 20 directly through the suction guide 81 and the suction induction pipe (80 ').

However, such a structure prevents the refrigerant gas from mixing with the refrigerant gas in the high temperature state filled in the sealed container 1, but the sealed container in a fixed state with the suction induction pipe 80 'which moves together with the piston 40 ( It is not easy to install the suction guide 81 between 1), and there is a fear that the suction guide 81 may be easily broken even when installed.

An object of the present invention devised in view of the above problems is to minimize the amount of refrigerant gas introduced into the inlet of the sealed container and sucked into the cylinder is mixed with the refrigerant gas of the high temperature state filled in the sealed container. It is to provide a refrigerant gas suction guide device of the linear compressor to increase the amount of gas.

In addition, another object of the present invention is to provide a refrigerant gas suction guide device of a linear compressor to facilitate the installation of the components for guiding the suction of the refrigerant gas.

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

2 is a cross-sectional view schematically showing an example of a conventional linear compressor refrigerant gas suction structure;

3 is a cross-sectional view schematically showing another example of a conventional linear compressor refrigerant gas suction structure;

Figure 4 is a cross-sectional view of the linear compressor with a linear compressor refrigerant gas suction guide device of the present invention,

5 is a cross-sectional view showing a modification of the linear compressor refrigerant gas suction guide device of the present invention.

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

One ; Hermetic container 1a; Airtight container inlet

10; Frame 20; cylinder

33; Magnet frame 40; piston

50; Cover 50a; Cover through hole

51; Main spring 90; Suction guide tube

100; Suction induction pipe 110; Spacing spring

a; Suction guide pipe first inner diameter b; Suction Guide Tube 2nd Inner Diameter

F; Refrigerant flow path

In order to achieve the object of the present invention as described above

A sealed container having a suction port on one side, a frame mounted inside the sealed container, a motor mounted on one side of the frame, a cylinder coupled to the frame, and a refrigerant flow path through which refrigerant gas flows is formed. And a piston inserted into the cylinder, a mover for transmitting the driving force of the motor to the piston, and a cap formed with a through hole formed at one side and a through hole formed at the other side, and fixed to one side of the motor to surround the cylinder and the piston. A linear compressor comprising a cover coupled and a main spring for elastically supporting the movement of the piston; It is formed to have a predetermined length so as to communicate with the suction port of the sealed container and the suction guide tube is inserted into the through hole of the cover and fixed to the cover, and one side is in communication with the suction guide tube and the other side is coupled and fixed to the end of the piston There is provided a refrigerant gas suction guide device for a linear compressor, comprising a suction induction pipe guiding the refrigerant gas flowing into the suction guide tube while moving together with the piston to the refrigerant flow path of the piston.

The suction guide tube is provided with a refrigerant gas suction guide device of the linear compressor, characterized in that the first inner diameter located on the suction port side is larger than the second inner diameter which is the portion into which the suction induction pipe is inserted.

A refrigerant gas suction guide device of the compressor is provided in the suction guide tube, wherein a space keeping spring is inserted to prevent the suction guide tube from colliding with the sealed container.

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

The refrigerant gas suction guide device of the linear compressor of the present invention, as shown in Figure 4, first, is provided in the sealed container (1) having a suction port (1a) on one side, and the inside of the sealed container (1) A frame 10, a motor mounted on one side of the frame 10, a cylinder 20 coupled to the center of the frame 10, and a refrigerant flow path F through which refrigerant gas flows are formed. The cylinder 40 is inserted into the cylinder 20, the motor of the motor for transmitting the driving force of the motor to the piston, the one side is opened and the other side is formed in the form of a cap formed with a through hole (50a) the cylinder ( 20 and the cover 50 which is fixedly coupled to one side of the motor to surround the piston 40, and the main spring 51 which is located on both sides of the piston 40 to elastically support the movement of the piston 40 It is configured to include a similar to the general linear compressor.

The suction guide tube 90 is formed to have a predetermined length to communicate with the suction port 1a of the airtight container 1 and is inserted into the through hole 50a of the cover and is fixed to the cover 50. The refrigerant gas is movably inserted into the suction guide tube 90 and the other side is fixedly coupled to the end of the piston 40 to move the refrigerant gas into the suction guide tube 90 while moving together with the piston 40. It is configured to include a suction induction pipe 100 to guide to (F).

As an example of the suction guide tube 90, a first pipe portion 91 having a predetermined thickness and having an outer diameter corresponding to the through hole 50a of the cover and having a first diameter (a) having a predetermined diameter, and the first pipe portion A predetermined thickness and height of the second pipe part 92 formed in the second inner diameter b larger than the outer diameter of the suction induction pipe 100 and the middle outer peripheral surface of the first pipe part 91 in a contraction-extending manner to 91. It is formed to have a latching portion 93 is extended and protruded to be in contact with the inner surface of the cover 50. The suction guide tube 90 is installed on the side of the suction port 1a so as to maintain a minimum distance in a state where the end of the first tube portion 91 does not contact the inner surface of the sealed container 1. The suction guide tube 90 is preferably fastened by fastening with a screw in a state in which the engaging portion 93 is in contact with the inner surface of the cover 50 at the time of fixing.

As an example of the suction induction pipe 100, the pipe part 101 having a predetermined length and an inner diameter smaller than the inner diameter of the second pipe part 92 of the suction guide pipe 90 and one side of the pipe part 101. It is formed with a locking portion 102 protruding to a predetermined thickness and height on the outer peripheral surface. One side of the pipe portion 101 of the suction guide tube 100 is inserted into the second pipe portion 92 of the suction guide tube 90 and the other side of the pipe portion 101 is inserted into the refrigerant flow path F of the piston 40. In addition, the engaging portion 102 is supported in contact with the end surface of the piston (40). The suction induction pipe 100 is preferably fixed by fastening with a screw in a state in which the engaging portion 102 is in contact with the end surface of the piston 40 when fixed.

As another modification of the present invention, as shown in Figure 5, the suction guide tube (90) inside the suction guide tube 90 is a gap maintaining spring (110) to collide with the sealed container (1) Is inserted. The spacing holding spring 110 inserted into the suction guide tube 90 prevents the suction guide tube 90 from colliding with the hermetic container 1 when vibration of the frame 10 to which the cover 50 is fixedly coupled. do.

A plurality of through holes 50b are formed at one side of the cover 50 that is fixedly coupled to one side of the motor so that the gas located inside the cover 50 and the gas located outside the cover 50 flow.

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

In the linear compressor refrigerant gas suction guide device of the present invention, first, when a current is applied to the motor, the magnet 32 constituting the mover of the motor is linearly reciprocated, and the linear motion is the piston 40 through the magnet frame 33. The piston 40 is linearly reciprocated inside the cylinder 20, and the suction, compression, and discharge strokes are repeatedly performed by the linear reciprocating motion of the piston 40, thereby refrigerating the refrigerant gas at a high temperature and high pressure. To be discharged. At this time, the suction induction pipe 100 coupled to the end of the piston 40 along with the linear reciprocation of the piston 40 is a linear reciprocating motion in the suction guide tube (90). When the piston 40 moves from the top dead center to the bottom dead center during the suction stroke, the refrigerant gas passing through the evaporator is sucked into the suction guide tube 90 through the suction port due to the low pressure inside the cylinder 20 and at the same time induction of suction. It is sucked into the cylinder 20 through the intake valve 62 while passing through the refrigerant passage F of the pipe 100 and the piston 40.

At this time, the suction guide tube 90 is fixed to the cover 50 is fixed to the motor and the suction induction pipe 100 is coupled to the piston 40 so as to move relative to each other suction guide fixed to the cover 50 When the movement of the tube 90 is very small, the suction guide tube 90 is brought close to the inner surface of the sealed container 1 to connect the suction guide tube 90 and the suction port 1a to inhale the refrigerant gas. The amount of the refrigerant gas in the high temperature state inside the sealed container 1 is mixed with the refrigerant gas to be sucked is minimized. In addition, since the sealed container 1 and the suction guide tube 90 are separated, there is no risk of damage during operation of the compressor, and the suction guide tube 90 and the suction guide tube 100 constituting the component can be easily installed. do.

As described above, the refrigerant gas suction guide device of the linear compressor according to the present invention is a cylinder because the amount of the refrigerant gas sucked into the cylinder during the intake stroke of the piston is mixed with the refrigerant gas of the high temperature state inside the sealed container is minimized As the specific volume of the refrigerant gas sucked into the inside increases, the compression efficiency is improved, and as well as the assembly of the component parts is easy, and there is no fear of breakage of the parts during the operation of the compressor, there is an effect that can be safely operated.

Claims (3)

A sealed container having a suction port on one side, a frame mounted inside the sealed container, a motor mounted on one side of the frame, a cylinder coupled to the frame, and a refrigerant flow path through which refrigerant gas flows is formed. And a piston inserted into the cylinder, a mover for transmitting the driving force of the motor to the piston, and a cap formed with a through hole formed at one side and a through hole formed at the other side, and fixed to one side of the motor to surround the cylinder and the piston. A linear compressor comprising a cover coupled and a main spring for elastically supporting the movement of the piston; It is formed to have a predetermined length so as to communicate with the suction port of the sealed container and the suction guide tube is inserted into the through hole of the cover and fixed to the cover, and one side is in communication with the suction guide tube and the other side is coupled and fixed to the end of the piston And a suction induction pipe guiding the refrigerant gas flowing into the suction guide tube while moving together with the piston to the refrigerant flow path of the piston. According to claim 1, wherein the suction guide tube is a refrigerant gas suction guide device of the linear compressor, characterized in that the first inner diameter located on the suction port side is formed larger than the second inner diameter that is the portion in which the suction induction pipe is inserted. The refrigerant gas suction guide device of a linear compressor according to claim 1, wherein an interval maintaining spring is inserted into the suction guide tube to prevent the suction guide tube from colliding with the sealed container.