KR100624821B1 - Linear compressor - Google Patents

Abstract

In the linear compressor according to the present invention, the linear compression part is directly fixed to one inner side of the shell, and the vibration absorbing means is installed on the other side, so that the vibration of the linear compression part is absorbed and the structure is simplified, so that the compressor can be downsized. In addition, since the vibration absorbing means is configured such that the mass is supported by the coil spring, it is easy to manufacture and there is an effect that the manufacturing cost can be reduced.

Linear compressor, shell, linear compression unit, vibration, copper reducer, coil spring

Description

Linear compressor {Linear compressor}             

1 is a cross-sectional view showing a linear compressor according to the prior art,

2 is a cross-sectional view showing a linear compressor according to a first embodiment of the present invention;

3 is a sectional view showing a linear compressor according to a second embodiment of the present invention.

<Explanation of symbols on main parts of the drawings>

50: shell 51: inlet

52: discharge port 53: suction pipe

54 discharge part assembly 55 silencer

56: discharge cover 57: discharge spring

58: discharge valve 59: discharge pipe

60: linear compression unit 61: linear motor

62: cylinder 63: piston

64: stator cover 65: back cover

66: main spring 67: spring support

68: suction valve 70: vibration absorbing means

71: mass 72: elastic member

73: first coil spring 74: second coil spring

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a linear compressor, and in particular, comprising a linear compression unit fixedly mounted inside a shell, and vibration absorbing means for absorbing vibrations of the linear compression unit, wherein the vibration absorbing means is configured such that the mass is supported by a coil spring. By being configured, the present invention relates to a linear compressor that can be manufactured easily and the manufacturing cost can be reduced.

In general, a linear compressor is a device that sucks, compresses and discharges a fluid while linearly reciprocating a piston inside a cylinder by using a linear driving force of a linear motor.

1 is a cross-sectional view of a linear compressor according to the prior art.

As shown in FIG. 1, the linear compressor according to the related art has a shell 4 to which a suction pipe 2 into which a fluid is sucked is connected, and a cylinder block in which a cylinder 6 is mounted inside the shell 4. 8) and a back cover 12 equipped with a fluid inlet 10, wherein the cylinder block 8 and the back cover 12 are formed by the first damper 14 and the second damper 16 by the shell. It is supported by (4) so that cushioning is possible.

A linear motor 20 is disposed between the cylinder block 8 and the back cover 12 to generate a driving force to compress the fluid, and the linear motor 20 linearly reciprocates within the cylinder 6. A piston 18 is connected to compress the fluid sucked into the cylinder 6.

The linear motor 20 is largely composed of a stator and a mover. The stator includes an outer stator 22 formed of a laminate, an inner stator 24 arranged to have a constant gap with the outer stator 22, and the outer stator. And a coil 26 mounted on the 22 to form a magnetic field, and the movable member is positioned between the outer stator 22 and the inner stator 24 and linearly moved by a magnetic force formed around the coil 26. The magnet 28 and the magnet 28 and the piston 18 is fixed is made of a magnet frame 30 to transmit a linear movement force to the piston (18).

The piston 18 is formed with a flange portion 18a fixed to the magnet frame 30 at the rear, the first spring 32 disposed between the flange portion 18a and the cylinder block 8, It is elastically supported by a second spring 34 disposed between the flange portion 18a and the back cover 12.

In addition, the piston 18 is formed with a suction flow path 18b through which fluid is sucked, and a plurality of suction ports 18c are formed on a front surface thereof, and a suction valve 36 for opening and closing the suction port 18c. Is provided.

A discharge part for discharging the compressed fluid is provided in front of the compression chamber C of the cylinder 6. The discharge part is fixed to the cylinder block 8, and an inner discharge cover 38 having a fluid discharge hole formed at one side thereof. And a discharge valve 42 which is supported by the discharge spring 40 on the inner discharge cover 38 to open and close the compression chamber C of the cylinder 6, and on the outside of the inner discharge cover 38. The outer discharge cover 44 is disposed to form a predetermined space.

The outer discharge cover 44 is provided with a discharge pipe 46 through which the fluid is discharged, and the discharge pipe 46 has one end of the loop pipe 48 for guiding the discharged fluid to the outside of the shell 4. Connected, the loop pipe 48 penetrates the shell 4 and is exposed to the outside.

Looking at the operation of the linear compressor according to the prior art configured as described above are as follows.

As the linear motor 20 is operated, the magnet 28 linearly reciprocates in interaction with the magnetic field around the coil 26, and this movement force is transmitted to the piston 18 through the magnet frame 30. ), The piston 18 continuously compresses and discharges the fluid while linearly reciprocating.

When the piston 18 moves backward, the suction valve 36 is opened due to the pressure difference between the suction passage 18b and the compression chamber C, and the suction passage 18b of the piston 18 is opened. The fluid flows into the compression chamber C through the suction port 18c.

On the other hand, when the piston 18 is advanced in the discharge direction, the suction valve 36 is closed by the pressure difference between the suction flow path (18b) and the compression chamber (C), the compression chamber (C) The fluid inside is compressed and then discharged through the discharge unit.

However, since the linear compressor according to the prior art is provided with not only a moving part for compressing the fluid inside the shell 4 but also all the parts for supporting it and reducing vibration, there is a limitation in miniaturizing the compressor. There is a problem.

On the other hand, when mounting a copper reducer (not shown) consisting of a mass (not shown) and a leaf spring (not shown) on the outside of the shell 4, the leaf spring is processing a scroll-shaped hole in a thin plate In addition, processing is very demanding, and since only one or two springs are used, the variation of spring stiffness caused by the material and processing error of the leaf spring is greatly generated, thereby reducing vibration absorbing ability. have.

The present invention has been made to solve the above-mentioned problems of the prior art, by providing a vibration absorbing means on the outside of the shell can realize a miniaturization, while at the same time easy to manufacture, cost can be reduced and the vibration absorbing ability can be improved The purpose is to provide a linear compressor.

The linear compressor according to the present invention for solving the above problems is a shell formed with the suction port and the discharge port; A linear compression unit fixedly mounted in the shell and configured to suck the fluid and then compress and discharge the fluid; And a vibration absorbing means installed inside the shell to absorb vibration of the linear compression portion, wherein the vibration absorbing means is provided on the mass and the shell and the linear compression portion, respectively, to elastically support the mass. It is configured to include an elastic member.

The linear compressor according to the present invention includes a shell having a suction port and a discharge port; A linear compression unit fixedly mounted in the shell and configured to suck the fluid and then compress and discharge the fluid; A support member fixed to the outside of the shell; And a vibration absorbing means provided between the shell and the support member, wherein the vibration absorbing means includes a mass body and an elastic member installed on the shell and the support member, respectively, to elastically support the mass body. do.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view showing a linear compressor according to a first embodiment of the present invention.

As shown in FIG. 2, the linear compressor according to the first embodiment of the present invention is fixed to the shell 50 having the inlet 51 and the outlet 52 formed therein, and fixed inside the shell 50. It includes a linear compression unit 60 for sucking and then compressing and discharging, and vibration absorbing means (70) installed inside the shell (50) to absorb vibration of the linear compression unit (60). .

The shell 50 is formed in a cylindrical structure, the discharge port 52 is located on the front surface and the suction port 51 is located on the rear side, the suction pipe 51 in which fluid is sucked from the outside of the suction port 51 ) Is penetrated, and in front of the discharge port 52, a discharge unit assembly 54 through which the fluid compressed by the linear compression unit 60 is discharged is installed.

The linear compression unit 60 is a linear motor 61 fixed to the inside of the shell 50 to generate a linear motion force, a cylinder 62 fixed to the inside of the shell 50, and the linear motor ( A piston 63 disposed in the cylinder 62 so as to be linearly reciprocated by a 61; a stator cover 64 fixed to the shell 50 to support the linear motor 61; and the shell ( The back cover 65 is fixed to 50 and spaced apart from the stator cover 64 by a predetermined distance, and elastically supports the piston 63 between the stator cover 64 and the back cover 65. It is configured to include a main spring (66).

The linear motor 61 is largely composed of a stator and a mover. The stator includes an outer stator 61a formed of a laminated body, an inner stator 61b disposed to have a predetermined gap with the outer stator 61a, and the outer stator. A coil 61c mounted on the 61a to form a magnetic field, and the mover is positioned between the outer stator 61a and the inner stator 61b and linearly moved by a magnetic force formed around the coil 61c. The magnet 61d and the magnet 61d and the piston 63 are fixed to each other, and are formed of a magnet frame 61e that transmits the linear movement force of the magnet 61d to the piston 63.

In addition, the cylinder 62 is fixed to the discharge port 52 side inside the shell 50 and has a cylindrical structure in which both sides are open. The cylinder 62 and the discharge part assembly 54 are provided by the cylinder 63. The compression chamber C is formed.

The piston 63 is coupled to a spring support 67 for supporting the main spring 66 in the rear, the suction passage (63a) is formed therein in which the fluid is sucked through the suction pipe 53, The front surface of the piston 63 is equipped with a plurality of suction ports 63b and a suction valve 68 for opening and closing the plurality of suction ports 63b.

In addition, the rear of the piston 63 is provided with a silencer 55 is connected to the suction pipe 53 to reduce the suction noise.

The discharge part assembly 54 is fixed to the outside of the shell 50, the discharge cover 56 for buffering the fluid discharged through the discharge port 52, and the discharge spring (57) in the discharge cover 56 It is composed of a discharge valve 58 that is supported by a) and opens and closes the compression chamber (C) of the cylinder (62).

One side of the discharge cover 56 is connected to the discharge pipe 59 for guiding the fluid discharged into the discharge cover 56 to the outside.

On the other hand, the vibration absorbing means 70 is installed between the inner surface of the shell 50 and the back cover 65 is connected to the movement direction of the linear motor 61 is configured to reduce the vibration.

Here, the vibration absorbing means 70 is a dynamic absorber configured to absorb the vibration by adding the mass 71 and the elastic member 72, disposed between the shell 50 and the back cover 65. And a resilient member 72 provided on the shell 50 and the back cover 65 to elastically support the mass 71.

The mass body 71 has a through hole 71a formed at the center thereof to allow the suction pipe 53 to pass therethrough.

In addition, the elastic member 72 is disposed long in the front-rear direction, and is a coil spring that imparts elastic force in the front-rear direction. The coil spring is connected between the front surface of the mass body 71 and the rear surface of the back cover 65. A first coil spring 73 and a second coil spring 74 connected between the rear surface of the mass 71 and the inner surface of the shell 50.

The plurality of first coil springs 73 and the second coil springs 74 are mounted to be spaced apart by a predetermined angle along the circumferential direction.

Looking at the operation of the linear compressor according to the first embodiment of the present invention configured as described above are as follows.

When the linear motor 61 is operated, the magnet 61d is linearly reciprocated in interaction with the magnetic field around the coil 61c, and this movement force is transmitted to the piston 63 through the magnet frame 61e. The piston 63 is discharged into the discharge cover 56 by compressing the fluid sucked into the compression chamber C of the cylinder 62 while continuously reciprocating linearly in the cylinder 62. The process is repeated.

That is, when the piston 63 moves backward, the suction valve 68 is opened while the fluid in the suction passage 63a of the piston 63 is compressed by the cylinder 62 through the suction port 63b. When the piston (63) is introduced into the chamber (C) and the piston (63) is advanced toward the compression chamber (C), the fluid compressed in the compression chamber (C) pushes the discharge valve (58) to the The compressed fluid is discharged to the outside through the discharge cover 56 and the discharge pipe 59 while the discharge valve 58 is opened.

On the other hand, the vibration absorbing means 70 is to absorb the vibration in the movement direction of the linear motor 61 and the piston 63 when the linear motor 61 is operating.

That is, the vibration absorbing means 70 constituted by the mass body 71 and the first and second coil springs 73 and 74 is mounted on the linear compression unit 60, thereby driving the linear compression unit 60. When the frequency coincides with the natural frequency of the vibration absorbing means 70, the vibration absorbing means 70 cancels out all the vibrations of the linear compression unit 60, and the vibration of the linear compressor is attenuated.

Meanwhile, the linear compression unit 60 is directly fixed to one side of the shell 50, and the vibration absorbing unit 70 is installed on the other side, whereby the vibration of the linear compression unit 60 is absorbed. The structure can be simplified to enable the construction of a compact compressor.

3 is a cross-sectional view of a linear compressor equipped with vibration absorbing means according to a second embodiment of the present invention.

The linear compressor according to the second embodiment of the present invention is fixed to the shell 80 having the suction port 81 and the discharge port 82, and is fixed to the inside of the shell 80, and sucks the fluid and then compresses and discharges it. The first embodiment is constituted by including a linear compression unit 83, except that the vibration absorbing means 100 for absorbing the vibration of the linear compression unit 83 is provided outside the shell 80. Is the same as

The shell 80 is formed in a cylindrical structure, the discharge port 82 is located on the front surface and the suction port 81 is located on the rear side, the suction pipe 81 is a suction pipe 84 is sucked from the outside from the outside ) Is installed to penetrate through.

The linear compression unit 83 is a linear motor 85 fixed to the inside of the shell 80 to generate a linear motion force, a cylinder 86 fixed to the inside of the shell 80, and the linear motor ( A piston 87 disposed in the cylinder 86 so as to be linearly reciprocated by a cylinder 85; a stator cover 88 fixed to the shell 80 to support the linear motor 85; and the stator cover. A main spring 89 elastically supporting the piston 87 between the 88 and the shell 80, and a spring support coupled to the rear of the piston 87 to support the main spring 89; 90).

Here, the linear motor 85 includes an outer stator 85a formed of a laminated body, an inner stator 85b arranged to have a predetermined gap with the outer stator 85a, a coil 85c forming a magnetic field, and the A magnet 85d linearly moved by a magnetic force formed around the coil 85c, and a magnet frame 85e to which the magnet 85d and the piston 87 are fixed.

On the other hand, the vibration absorbing means 100 is installed on the back of the shell 80, between the support member 101 fixed to the shell 80, between the shell 80 and the support member 101 It is configured to include a mass body 102 disposed, and an elastic member 103 installed on the shell 80 and the support member 101 to elastically support the mass body 102.

The elastic member 103 is a plurality of coil springs to give elastic force in the front and rear direction, the coil spring is a first coil spring 104 connected between the front surface of the mass body 102 and the shell 80, The second coil spring 105 is connected between the rear surface of the mass body 102 and the support member 101.

The plurality of first coil springs 104 and second coil springs 105 may be mounted to be spaced apart from each other by a predetermined angle along the circumferential direction.

The support member 101 may protect the mass body 102 and the first and second coil springs 103 and 104 from external foreign matter or impact and support the end of the second coil spring 104. It is formed in a cover shape surrounding the mass body 102 and the first and second coil springs 104 and 105.

That is, the support member 101 has a cylindrical structure with one side open, and the open end of the support member 101 is coupled to the outer surface of the shell 80 by a method such as welding or bonding. It is fixed or fastened by a fastening member or the like.

In addition, the support member 101 is formed with a first through hole 101a through which the suction pipe 84 passes, and a second through hole through which the suction pipe 84 passes through the center of the mass body 102. 102a is formed.

On the other hand, not limited to the above embodiment, the support member 101 can be changed in shape as long as it can support the end of the second coil spring (104).

In the vibration absorbing means 100 of the linear compressor configured as described above, the operation frequency of the linear compression part 83 is equal to the natural frequency of the vibration absorbing means 100 when the linear compression part 83 operates. When the vibration absorbing means 100 cancels out all the vibrations of the linear compression unit 83, the vibration of the linear compressor is attenuated.

On the other hand, the linear compression portion 83 is directly fixed to the inside of the shell 80, the vibration absorbing means 100 is mounted to the outside of the shell 83, thereby the In addition to absorbing vibration, the structure is simplified, and assembling property is improved because the vibration absorbing means 100 can be easily attached and detached.

The linear compressor according to the present invention configured as described above has a linear compression part directly fixed to one inner side of the shell, and a vibration absorbing means is installed on the other side, whereby vibration of the linear compression part is absorbed and the structure is simplified, thereby miniaturizing the compressor. There is a possible advantage.

In addition, since the vibration absorbing means is configured such that the mass is supported by the coil spring, not only the manufacturing cost can be easily reduced due to the manufacture of the mass, but also the stiffness variation between the springs is reduced because a plurality of coil springs are used, so that reliability There is an effect that can be improved.

In addition, the linear compression portion is directly fixed to the inside of the shell, the vibration absorbing means is provided on the outside of the shell, not only the structure is simple, but also the effect of the assembly can be improved because the vibration absorbing means can be easily removed. have.

Claims (9)

A shell formed with a suction port and a discharge port; A linear compression unit fixedly mounted in the shell and configured to suck the fluid and then compress and discharge the fluid; It is configured to include a vibration absorbing means installed in the shell to absorb the vibration of the linear compression portion, And said vibration absorbing means comprises a mass body and an elastic member provided respectively in said shell and linear compression part to elastically support said mass body. The method of claim 1, And the elastic member comprises a first coil spring connected between the front face of the mass body and the linear compression part, and a second coil spring connected between the back face of the mass body and the shell. The method according to claim 1 or 2, The linear compression unit is a linear motor fixed to the inside of the shell to generate a linear motion force, a piston for linear reciprocating motion in a cylinder fixed to the inside of the shell by the linear motor, and fixed to the shell It comprises a stator cover for supporting a, a back cover fixed to the shell and spaced apart from the stator cover at regular intervals, and a main spring for elastically supporting the piston between the stator cover and the back cover, And the vibration absorbing means is installed between the shell and the back cover. A shell formed with a suction port and a discharge port; A linear compression unit fixedly mounted in the shell and configured to suck the fluid and then compress and discharge the fluid; A support member fixed to the outside of the shell; It is configured to include a vibration absorbing means provided between the shell and the support member, The vibration absorbing means is a linear compressor, characterized in that it comprises a mass body and an elastic member which is respectively installed on the shell and the support member to elastically support the mass body.  The method of claim 4, wherein And the elastic member comprises a first coil spring connected between the front face and the shell of the mass body, and a second coil spring connected between the back face and the support member of the mass body.  The method according to claim 4 or 5, A discharge part assembly is mounted on the front of the shell to discharge the compressed fluid connected to the discharge port, and a suction pipe connected to the suction port is installed to the rear of the shell. The vibration absorbing means is a linear compressor, characterized in that installed on the back of the shell. The method of claim 6, The support member is a linear compressor, characterized in that the through-hole is formed so that the suction pipe penetrates. The method according to claim 1 or 4, The elastic member is a linear compressor, characterized in that a plurality of coil springs formed to impart an elastic force in the front-rear direction. delete

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