KR20090105469A - Reciprocating compressor - Google Patents

Abstract

PURPOSE: A reciprocation compressor is provided to increase motion straightness of a magnet holder and piston by making the side force generated in a resonance spring offset. CONSTITUTION: A frame is elastically supported with the inside of a sealed container. A reciprocating motor includes a stator core and a magnet holder. The stator core is formed at the frame and has an air gap. A coil is wound in the stator core to form the magnetic field. A magnet holder(35) reciprocates and supports the magnet arranged to the air gap of the stator core. A cylinder(41) is supported in the frame. A piston(42) compresses a refrigerant while reciprocating, is combined with the magnet holder and is inserted in the cylinder. Resonance springs(51,52) induce a piston resonance-exercise by supporting flexibly the piston.

Description

Reciprocating Compressor {RECIPROCATING COMPRESSOR}

The present invention relates to a reciprocating compressor, and more particularly, to a technique for preventing wear of a piston and a cylinder by side force.

In general, reciprocating compressors can be classified into connection type and vibration type according to the driving motor. The connecting type is a piston is connected to the crank shaft of the rotating drive motor is connected to the connecting rod, the rotational movement of the crank shaft is converted to the reciprocating motion of the piston to compress the refrigerant, the vibration type is a mover mover of the reciprocating motion The piston is coupled to the mover to make linear movements together.

The vibration-type reciprocating compressor (hereinafter, abbreviated as reciprocating compressor) is provided with a resonant spring to correspond to the direction of movement of the piston to compress the refrigerant while the piston resonates in both directions by the resonant spring. Accordingly, the reciprocating compressor has advantages of high efficiency and low vibration compared to other types of compressors, and low noise.

However, in the conventional reciprocating compressor as described above, the resonant spring for resonating the piston is composed of a compression coil spring, but the resonant spring is stretched to resonate the piston. A side force is generated, and the straightness of the mover or piston is reduced by the side force, and friction loss or abrasion between the mover and the stator or the piston and the cylinder or damage to a member that is severely rubbed occurs. There was a problem.

The present invention solves the problems of the conventional reciprocating compressor as described above, and to provide a reciprocating compressor that can maintain the operation straightness of the mover or the piston even when the side force is generated when the resonant spring is stretched. There is a purpose.

In order to solve the object of the present invention, the frame is elastically supported in the sealed container; It is fixed to the frame and is formed to have a predetermined air gap (outside) in the inner side and the coil is wound on one side to form a magnetic field, and the reciprocating support for the magnet disposed in the air gap of the stator core A reciprocating motor including a magnet holder for exercising; A cylinder supported by the frame; A piston inserted into the cylinder and coupled to the magnet holder to compress the refrigerant while reciprocating together; And a resonant spring for elastically supporting the piston to induce the piston to perform a resonant motion. The reciprocating compressor includes a side force transfer suppression part installed between the magnet holder and the piston to allow relative movement of the magnet holder and the piston. Is provided.

In the reciprocating compressor according to the present invention, a side force absorbing member or a sliding member capable of suppressing side force transfer between the magnet holder and the piston is provided so that the side force generated in the resonance spring is canceled by the side force absorbing member or the sliding member. It is possible to increase the movement straightness of the magnet holder and the piston. As a result, friction loss between the piston and the cylinder or friction loss between the mover and the stator may be reduced, thereby increasing the performance and reliability of the compressor.

Hereinafter, the reciprocating compressor according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

As shown in FIG. 1, in the reciprocating compressor according to the present invention, a frame 20 is elastically installed in a sealed casing 10, and a mover 33 is linearly reciprocated in the frame 20. A reciprocating motor 30 is installed, and the piston 42 is inserted into the frame 20 to fix the cylinder 41 and inserted into the cylinder 41 to compress the refrigerant while reciprocating in a straight line. Coupled to the mover 33 of the reciprocating motor 30, resonant springs (51) and (52) for inducing the resonant movement of the piston (42) are respectively provided on both sides of the movement direction of the piston (42), the mover Between the 33 and the piston 42, the side force transmission inhibiting portion 60 is provided so that the mover 33 and the piston 42 can perform relative movement to suppress side force transfer.

The reciprocating motor 30 has an outer core 31 in which a plurality of stator sheets are radially stacked to form a cylindrical shape, and a plurality of stator sheets are radially stacked to form a cylindrical shape. The inner core 32 disposed with a predetermined air gap inside the 31, and the mover 33 disposed axially movable in the gap between the outer core 31 and the inner core 32. )

The outer core 31 is inserted and coupled to the bobbin (unsigned) wound around the coil 34, the inner core 32 is formed in a plate shape having a predetermined width. The mover 33 is formed in a cylindrical shape with a magnet holder 35, and a magnet 36 is attached to an outer circumferential surface of the magnet holder 35. The piston 42 is coupled to the center of the magnet holder 35 in the axial direction.

At one end of the magnet holder 35, that is, at the end at which the plate part 42b of the piston 42 to be described later is coupled, a receiving part 35a is formed larger than the thickness of the plate part 42b. A side force absorbing member 61 constituting the side force transfer inhibiting portion 60 is provided between an inner side surface of the portion 35a and an outer side surface of the plate portion 42b corresponding thereto.

The side force absorbing member 61 may be formed of a wave type plate spring having a ring shape to absorb side force as shown in FIGS. 1 to 3. For example, the housing members 37 and 38 which are formed in an annular shape and bent so as to form the receiving portions 35a on both sides of the connecting end of the magnet holder 35 are bolted to the housing member 37. A side force absorbing member 61 made of the corrugated leaf spring is interposed between the inner side surface of one side of 38 and the plate portion 42b of the piston 42 corresponding thereto. Here, the side force absorbing member 61 may be a coil spring or rubber that can withstand high temperatures.

And the side force transfer inhibiting portion 60 may use a sliding member 62, such as a ball (boll). For example, as illustrated in FIG. 5, a plurality of balls are interposed between the inner side surfaces of the housing members 37 and 38 and the plate portions 42b of the piston 42 corresponding to each other in the circumferential direction or the ball bearings. Can be intervened. Here, the sliding member 62 may be a roller or a ring (ring).

And the guide member 39 between the plate portion 42b of the piston 42 and the one housing member 38 corresponding thereto so as not to be separated when the magnet holder 35 or the piston 42 performs the self-aligning operation. ) May be further provided. The guide member 39 may be made of any one of a ball, a roller, or a ring.

On the other hand, although not shown in the drawings, the housing member may be coupled to the plate portion of the piston, the coupling end of the magnet holder may be coupled to the receiving portion provided in the plate portion of the piston. Even in this case, the side force absorbing member and the guide member may be configured in the same manner.

The cylinder 41 is supported through the center of the frame 20, and the inner circumferential surface of the inner core 32 is inserted and supported by the outer circumferential surface of the cylinder 41. In addition, the front of the cylinder 41 has a fixing protrusion 41a is formed to support the front surface of the frame 20 and the fixing protrusion 41a of the discharge cover 46 is fastened to the frame 20 It is fixed by being pressed by the flange part 46a. The discharge valve 44 is detachably disposed at the front end surface of the cylinder 41 so as to open and close the compression space S1 of the cylinder 41, and the valve spring 45 is provided at the compression rear surface of the discharge valve 44. Is supported, and the discharge valve 44 and the valve spring 45 are accommodated in the discharge space S2 of the discharge cover 46. The discharge valve 44 may be formed of any one material of a metal plate or a plastic plate.

The piston 42 is composed of a body portion 42a formed in a hollow cylindrical shape, and a plate portion 42b extending in a flange shape at a rear end of the body portion 42a and coupled to the magnet holder 35. . The suction part (F) is formed through the body portion (42a). In addition, a suction valve 43 is mounted on the front end surface of the piston 42 to open and close the suction flow path F.

The resonant spring is formed of a compression coil spring and includes a first resonant spring 51 and a second resonant spring 52, which are provided at each of the front and rear sides of the piston 42. Each of the first and second resonant springs 51 and 52 may be provided at the front and rear sides of the plate portion 42b of the piston 42, respectively, and the front and rear of the piston 42. Only a plurality of each may be provided on both sides. For example, as shown in FIG. 1, when only one resonance spring 51 or 52 is provided, one end of the first resonance spring 51 may have a front surface of the plate portion 42b of the piston 42. The other end is supported by the rear surface of the cylinder 41. The second resonant spring 52 has one end supported by the rear surface of the plate portion 42b of the piston 42 while the other end thereof is in the back cover 22 coupled to the rear side of the reciprocating motor. Supported on the side. On the other hand, as shown in Figure 6, when the plurality of resonant spring (51) 52 is provided in each of the front and rear both sides, the spring supporter 43 is coupled to the plate portion 42b, the spring supporter 43 Corresponding ends of the first resonant spring 41 and the second resonant spring 42 are respectively fixed to the front and rear sides of the first resonant spring 41 and the rear end of the first resonant spring 41 and the second resonant spring 42. The stages are fixed to the inner surfaces of the support plate 21 and the back cover 22 respectively supporting the rear side of the reciprocating motor.

In the drawings, reference numeral 11 denotes a closed space, 12 a suction pipe, and 13 a discharge pipe.

Effects of the reciprocating compressor according to the present invention as described above are as follows.

That is, when power is applied to the coil 34, magnetic flux is formed around the coil 34, and the flux is a closed loop along the outer core 31 and the inner core 32 of the stator. And the magnets 36 move together with the magnet holder 35 by the interaction of the magnetic flux formed between the outer core 31 and the inner core 32 with the magnetic flux formed by the magnet 36. Direction, and when the direction of the current applied to the coil 34 is alternately changed, the magnetic flux direction of the coil 34 is changed to cause the magnet 36 to reciprocate in a straight line.

For example, when the piston 42 retreats, the refrigerant of the sealed container 10 is sucked into the compression space S1 through the suction flow path F formed in the piston 42, and when the piston 42 is advanced, As the suction flow path F is closed by the suction valve 43, the refrigerant inside the compression space S1 is compressed, and the compressed refrigerant is discharged to an external refrigeration cycle through the discharge pipe 13.

At this time, as the resonant spring is formed as a compression coil spring, the resonant springs 51 and 52 are stretched and resonate with the magnet holder 35 and the piston 42 of the reciprocating motor 30. In the process of stretching (51) (52), the lateral force is generated due to the characteristics of the compression coil spring. In particular, compared to the case where a plurality of resonant springs 51 and 52 are provided on each of the front and rear sides, the side force of the spring is increased. In addition, the linearity of movement of the magnet holder 35 and the piston 42 is lowered by the lateral force of the resonant springs 51 and 52, so that abrasion may occur between the piston 42 and the cylinder 41.

However, when the side force absorbing member 61 capable of suppressing side force transfer between the magnet holder 35 and the piston 42 is provided as in the present invention, the resonance springs 51 and 52 are generated. The side force is absorbed by the side force absorbing member 61 to increase the straightness of movement of the magnet holder 35 and the piston 42. For example, when the side force absorbing member 61 made of an elastic body such as a leaf spring is interposed between the receiving portion 35a of the magnet holder 35 and the piston 42, as shown in FIG. Even if the linearity of movement of the magnet holder 35 is changed by the lateral force, the piston 42 maintains the straightness as the elastic body such as the leaf spring absorbs it, and thereby the piston 42 and the cylinder. The friction loss between the 41 can be reduced to increase the performance and reliability of the compressor. 5, the sliding member 62 absorbs the side force even when a sliding member 62 such as a ball is interposed between the receiving portion 35a of the magnet holder 35 and the piston 42. As a result, friction loss between the piston 42 and the cylinder 41 may be reduced, thereby increasing the performance and reliability of the compressor.

On the other hand, if there is another embodiment of the reciprocating compressor according to the present invention.

That is, in the above-described embodiment, the receiving portion is formed in the magnet holder, the piston is coupled to the receiving portion of the magnet holder, and the side force transfer suppression portion is interposed between the receiving portion and the piston of the magnet holder. As shown in FIG. 7, an accommodating portion 42c is formed at the connecting end of the piston 42, the magnet holder 35 is coupled to the accommodating portion 42c, and the accommodating portion 42c and the magnet of the piston 42 are formed. The side force transmission restraining portion 60 such as the side force absorbing member 61 or the sliding member 62 is provided between the holders 35.

Even in this case, the resonant springs 51 and 52 are compressed coil springs, so that the lateral force is generated when the resonant springs 51 and 52 are expanded and contracted so that the straightness of the piston 42 is changed. The side force transmitted to) can be prevented from being absorbed by the side force transfer inhibiting part 60 and transmitted to the magnet holder 35. Through this, the straightness of the magnet holder 35 is distorted, thereby preventing friction loss between the mover 33 and the outer core or the mover 33 and the inner core 32 or damage to the mover or stator. .

The reciprocating compressor according to the present invention can be applied evenly to a home appliance refrigerator such as a refrigerator or an air conditioner. It can be applied not only to home appliances but also to industrial equipment using a refrigeration cycle.

1 is a longitudinal sectional view showing an embodiment of the reciprocating compressor of the present invention;

Figure 2 is a longitudinal cross-sectional view showing a mover of the reciprocating motor provided with a side force transfer suppressing portion in the reciprocating compressor according to Figure 1,

3 is a perspective view of the mover of the reciprocating motor according to FIG. 2 broken;

4 is a schematic view showing a side force suppression process in the reciprocating motor according to FIG.

Figure 5 is a longitudinal cross-sectional view showing another embodiment of the side force transfer inhibiting portion in the reciprocating compressor according to Figure 1,

Figure 6 is a longitudinal cross-sectional view showing another embodiment of the resonant spring in the reciprocating compressor of the present invention,

Figure 7 is a longitudinal cross-sectional view showing another embodiment for the side force transfer inhibiting portion in the reciprocating compressor of the present invention.

** Explanation of symbols for main parts of the drawing **

10: casing 20: frame

21: support plate 22: back cover

30: reciprocating motor 31: outer core

32: inner core 33: mover

34: coil 35: magnet holder

35a: accommodating part 36: magnet

37,38 housing member 39 guide member

41 cylinder 42 piston

42b: plate portion 42c: receiving portion

43: suction valve 44: discharge valve

51,52: resonant spring 53: spring supporter

Claims (9)

A frame elastically supported in the sealed container; It is fixed to the frame and is formed to have a predetermined air gap (outside) in the inner side and the coil is wound on one side to form a magnetic field, and the reciprocating support for the magnet disposed in the air gap of the stator core A reciprocating motor including a magnet holder for exercising; A cylinder supported by the frame; A piston inserted into the cylinder and coupled to the magnet holder to compress the refrigerant while reciprocating together; And And a resonant spring for elastically supporting the piston to induce the piston to resonate. A reciprocating compressor having a side force transfer inhibiting portion installed between the magnet holder and the piston so that the magnet holder and the piston can perform relative movement. The method of claim 1, At least one of the connection portion of the magnet holder or the piston, the receiving portion is formed to have a space wider than the thickness of the other connection portion, the reciprocating compressor is provided with a side force absorbing member between the receiving portion and the corresponding connection portion. The method of claim 2, The side force absorbing member is a reciprocating compressor is formed of an elastic body. The method of claim 3, The elastic body is a reciprocating compressor comprising any one of a corrugated leaf spring or coil spring or rubber that can withstand high temperatures. The method of claim 2, The side force absorbing member is a reciprocating compressor consisting of a sliding member. The method of claim 5, The sliding member is a reciprocating compressor comprising any one of a ball, a roller or a ring. The method of claim 2, And a guide member is further provided between the receiving portion and the corresponding connecting portion to prevent the magnet holder or the piston from being separated when performing the self-aligning operation. The method of claim 7, wherein The guide member is a reciprocating compressor consisting of any one of a ball, a roller or a ring. The method according to any one of claims 1 to 8, The resonant spring is a reciprocating compressor disposed one each on both front and rear sides of the piston.

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