KR19990016948A - Spring fixing structure of linear compressor - Google Patents

Abstract

The present invention relates to a spring fixing structure of a linear compressor, and in the related art, a spring supporting structure is simply a structure supporting a coil spring so that the inner and outer coil springs that elastically support the movement of the piston during the reciprocating movement of the piston are In addition to rotational movement, the lateral vibration is generated, which hinders the reciprocating motion of the piston, and the wear caused by the coil spring causes the performance not only to deteriorate but also to damage the parts. By fixing one side of the inner and outer coil springs to elastically support the movement, the inner and outer coil springs are prevented from rotating or laterally vibrating during the reciprocating movement of the piston, thereby minimizing the wear of parts and the coil spring The reciprocating motion of the piston is not constant due to the horizontal vibration This is to prevent the degradation of the compression performance generated.

Description

Spring fixing structure of linear compressor

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spring fixing structure of a linear compressor, and more particularly to a spring fixing structure of a linear compressor capable of suppressing lateral vibration and movement of a spring that elastically supports the movement of a piston.

Recently, instead of eliminating the use of the crankshaft to solve various disadvantages of the compressor using the crankshaft, a linear compressor that can reduce noise and increase efficiency by compressing refrigerant by directly reciprocating the piston using a magnet and a coil has been used. It is widely used.

1 illustrates an example of the linear compressor, and as shown in the drawing, a conventional linear compressor is installed in a sealed container 1 formed to have a predetermined inner space and an inner middle of the sealed container 1. An inner case 2 formed to have a predetermined inner space, a linear motor M coupled to the inner side of the inner case 2, and a cylinder 4 coupled to the inner stator 3 of the linear motor M; ), A cover plate 5 coupled to one side of the inner case 2 and penetrated and coupled to one side of the cylinder 4, and a piston coupled to reciprocate in the cylinder 4. 6 and the magnet paddle (1) is coupled to the magnet (7) constituting the linear motor and the other side is coupled to one side of the piston (6) to transfer the movement of the linear motor (M) to the piston (6). 8), the inner side and the back of the magnet paddle (8) An inner coil spring 9 supported between the side surfaces of the inner stator 3 of the air motor M and elastically supporting the movement of the piston 6, and a cover which is opened and coupled to the other side of the inner case 2. (10), an outer coil spring (11) supported between the outer surface of the magnet paddle (8) and the inner surface of the cover (10) to support the movement of the piston (6), and the piston (6) It is configured to include a valve system (V) coupled to the other side of the discharge to discharge the gas compressed in the cylinder (4) at a constant pressure.

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

In the linear compressor as described above, when a current is applied to the linear 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 moves inside, the refrigerant gas introduced into the sealed container 1 is sucked into the cylinder 4 through the refrigerant flow path F formed at the center of the piston 6, compressed and discharged through the valve system V. The process is repeated.

In the linear compressor, four inner and outer coil springs (9) (11), each of which acts as a storage of kinetic energy while elastically supporting the reciprocating motion of the piston (6), are usually combined.

In the conventional spring-supported structure in which the inner and outer coil springs 9 and 11 are coupled, as shown in FIG. 2, an annular support 14 having a cross section is provided on one side of the inner stator 3. One side of the first coil spring 9a constituting the inner coil spring 9 is supported by the annular support 14 and the other side is supported and coupled to the inner side of the magnet paddle 8, and the inner coil The second coil spring 9b constituting the spring 9 is inserted into the first coil spring 9a so that one side is supported by the annular support 14 and the other side is supported by the inner side of the magnet paddle 8. And the inner coil spring 9 is fixed. And the outer coil spring 11 is fixed to the outer surface of the magnet paddle (8) is a circular inner projection (8a) having a straight cross section having a predetermined height in the direction perpendicular to the surface is formed and the inner projection ( The outer protrusion 8b is formed concentrically with a predetermined distance to the outer side of the 8a), and one side of the third coil spring 11a constituting the outer coil spring 11 is the inner side of the outer protrusion 8b. The other side is supported and coupled to the inner surface of the cover 10 covering the inner case 2. In addition, the fourth coil spring 11b constituting the outer coil spring 11 is inserted into the third coil spring 11a, and one side of the fourth coil spring 11a is inserted into and supported by the outer side of the inner protrusion 8a and the other side of the cover 10. Supported and coupled to the inner side of the.

However, the conventional spring supporting structure as described above is simply configured to support the coil spring, so that the inner and outer coil springs that support the elasticity of the piston movement during the reciprocating movement of the piston are driven by the motor. In addition, the lateral vibration is generated to interfere with the reciprocating motion of the piston, and wear caused by the coil spring may occur, thereby degrading performance and damaging components.

Accordingly, an object of the present invention is to provide a spring fixing structure of a linear compressor that can suppress lateral vibration and movement of a spring that elastically supports the movement of a piston.

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

Figure 2 is a half sectional view showing a spring fixing structure of a conventional linear compressor,

Figure 3 is a half sectional view showing a spring fixing structure of the linear compressor of the present invention,

Figure 4a is a front sectional view showing a holding member in the spring fixing structure of the linear compressor of the present invention,

Figure 4b is a side cross-sectional view showing a holding member in the spring fixing structure of the linear compressor of the present invention.

＊ Explanation of symbols on main parts of drawing

One ; Airtight container 2; Inner case

3; Medial stator 4; cylinder

6; Piston 7; Magnet

8 ; Magnet paddle 8c; First Government

8d; Second fixed government 9; Inner Coil Spring

10; Cover 11; Outer coil spring

15; Fixing member 15a; Contact surface part

15b; Vertical surface portion 15c; Hanging jaw

P; Vertical projection S; Jam

An object of the present invention as described above consists of a sealed container, an inner case coupled to the interior of the sealed container, a linear motor coupled to the inner case, and a plurality of iron pieces are laminated to the lead motor. A cylinder coupled to the inner stator, a piston coupled to the cylinder, a valve system coupled to one side of the cylinder to discharge the compressed refrigerant gas, and a magnet of the linear motor to connect the piston to move the magnet. A magnet paddle for transmitting the piston to the piston, a cover positioned on the side of the magnet paddle to cover one side of an inner case, and coupled between the magnet paddle and the inner stator and between the magnet paddle and the cover, respectively, to move the piston. Including the inner and outer coil spring to elastically support the In the formed linear compressor, one side of each coil spring constituting the inner coil spring is fixed to a fixing member supported on the side of the inner stator, the fixing means is formed on one side of the magnet paddle to form the outer coil spring. A spring fixing structure of the linear compressor is provided, wherein one side of each coil spring to be configured is fixed to the fixing means.

The fixing member is formed of an annular ring, the contact surface portion of which the cross section of the annular ring is in contact with the side of the inner stator, the vertical surface portion of which both ends of the contact surface portion is extended and bent inwardly extending to each vertical surface portion The locking jaw portion is formed and the inner coil spring is fixed to each of the locking jaw portion is provided with a spring fixing structure of the linear compressor.

The fixing means extends and protrudes on one side of the magnet paddle so as to have a first fixing portion formed in an annular shape, and a second height extending and protruding on one side of the magnet paddle so as to form a predetermined interval with the first fixing portion. The first and second fixing parts are each made of a vertical projection protruding perpendicularly to the surface of the magnet paddle and a locking jaw extended to the vertical protrusion, and the outer coil springs are fixed to the locking jaws, respectively. A spring fixing structure of a linear compressor is provided.

Hereinafter, the linear compressor spring fixing structure of the present invention will be described according to the embodiment shown in the accompanying drawings.

In the linear compressor spring fixing structure of the present invention, as shown in FIG. 3, in the linear compressor structure, one side of each coil spring constituting the inner coil spring 9 is supported on the side of the inner stator 3. It is fixed to the fixing member 15, the fixing means is formed on one side of the magnet paddle (8) is made of one side of each coil spring constituting the outer coil spring 11 is fixed to the fixing means.

As shown in FIGS. 4A and 4B, the fixing member 15 is formed of an annular ring having a constant thickness, and a contact surface portion 15a having a cross section of the annular ring contacting the side surface of the inner stator 3. And a vertical surface portion 15b having both ends of the contact surface portion 15a extended and bent, and a locking jaw portion 15c extending inwardly formed at each of the vertical surface portions 15b. ) Are fitted into and fixed to the locking jaw portions 15c, respectively. The contact surface portion 15a is formed to have a predetermined straight length, the vertical surface portion 15b is formed perpendicular to the contact surface portion 15a, and the locking jaw portion 15c is bent perpendicularly to the vertical surface portion 15b. The locking jaw portions 15c are bent inward to each other. In addition, the length of the locking step 15c is preferably larger than the coil diameter of the coil spring (9). In addition, when the coil spring 9 is fitted to the locking jaw portion 15c, the coil spring is spirally wound to form the coil spring 9 such that the coil spring 9 is screwed onto the locking jaw portion 15c to be screwed together.

The fixing means extends and protrudes on one side of the magnet paddle 8 so as to form a predetermined interval with the first fixing part 8c and the first fixing part 8c formed in an annular shape. The second fixing part 8d extends and protrudes on the side surface and is formed in an annular shape. The first and second fixing parts 8c and 8d are vertical protrusions P protruding perpendicular to the surface of the magnet paddle 8 and locking jaws S extending and bent in the vertical protrusions P. Each is formed, the vertical projection (P) and the locking step (S) is formed to the same thickness and the locking step (S) is preferably formed slightly larger than the coil diameter of the coil spring (11). The coil springs 11 are fitted into the locking jaws S, respectively. In addition, when the coil spring 11 is fitted to the locking jaw S, the coil spring 11 is formed to be wound in a spiral so that the coil spring 11 can be screwed into the locking jaw S by turning a screw. do.

Hereinafter, the operation and effect of the linear compressor spring fixing structure of the present invention will be described.

First, when the linear compressor is applied with a current to the linear motor to operate the motor, the piston 6 coupled to the magnet paddle 8 is introduced into the cylinder 4 while repeatedly reciprocating in the cylinder 4. The refrigerant gas is sucked, compressed and discharged, and the inner and outer coil springs 9 and 11 are tensioned and compressed as the piston reciprocates. As the piston 6 repeatedly reciprocates, the inner and outer coil springs 9 and 11 are repeatedly stretched and compressed, and in this process, the inner and outer coil springs 9 and 11 rotate. This is because one side of the inner and outer coil springs (9) (11) is fixed, respectively, the rotational movement is suppressed. In addition, since one side of the inner and outer coil springs 9 and 11 is fixed, vibration occurs in the transverse direction of the inner and outer coil springs 9 and 11 during the reciprocating movement of the piston 6, not in the axial direction of the coil spring. It is suppressed. In addition, the inner and outer coil springs (9) (11) are assembled by turning the screw like a screw to simplify the assembly work.

As described above, the spring fixing structure of the linear compressor according to the present invention fixes one side of the inner and outer coil springs to elastically support the reciprocating motion of the piston, so that the inner and outer coil springs rotate during the reciprocating motion of the piston. By suppressing the movement or the vibration in the lateral direction to minimize the wear of the parts and the coil spring is vibrated in the lateral direction has the effect of preventing the deterioration of the compression performance caused by the constant reciprocation of the piston.

Claims (3)

A cylinder coupled to an inner stator constituting the sealed container, an inner case coupled to the inside of the sealed container, a linear motor coupled to the inner case, and a plurality of iron pieces are stacked to form the lead motor, and the cylinder A piston coupled to the inside, a valve system coupled to one side of the cylinder to discharge the compressed refrigerant gas, a magnet paddle connecting the magnet and the piston of the linear motor to transfer the movement of the magnet to the piston, and the magnet paddle The inner and outer coil springs, which are positioned on the side of the cover and cover one side of the inner case, are respectively coupled between the magnet paddle and the inner stator and between the magnet paddle and the cover to elastically support the movement of the piston. A linear compressor configured to include; One side of each coil spring constituting the inner coil spring is fixed to a fixing member supported on the side of the inner stator, the fixing means is formed on one side of the magnet paddle to form the outer coil spring of each coil spring Spring fixing structure of the linear compressor, characterized in that one side is fixed to the fixing means. The method of claim 1, wherein the fixing member is formed of an annular ring, the contact surface portion of the annular ring is in contact with the side of the inner stator, the vertical surface portion of which both ends of the contact surface portion is bent, respectively, the vertical surface Spring engaging structure of the linear compressor, characterized in that the engaging jaw portion is formed to be extended inwardly formed in the inner portion is fixed to the inner coil spring is fitted into each of the engaging jaw portion. The method of claim 1, wherein the fixing means is extended and protruded on one side of the magnet paddle extending and protruding on one side of the magnet paddle to form a predetermined interval with the first fixing part and the first fixing part formed in an annular shape The first and second fixing parts are formed in an annular shape, and the first and second fixing parts are each formed of a vertical protrusion protruding perpendicular to the surface of the magnet paddle and a locking jaw extended to the vertical protrusion, respectively. A spring fixing structure of a linear compressor, characterized in that the coil spring is fitted into each other and fixed.