KR200158564Y1 - Linear compressor - Google Patents

Abstract

The present invention relates to a linear compressor. The linear compressor of the present invention has a cylinder (53) forming a compression chamber (S) and an inlet (56) connected to one end of the cylinder (53) and communicating with the compression chamber (S). An oil supply pipe in which the inlet end 62a is immersed in oil and the outlet end 62b communicates with the suction chamber 54a so as to lubricate the cylinder head 54 having the suction chamber 54a formed therein and the compression chamber S ( 62 is provided, and the cylinder 53 is formed with an adultery hole 73 extending from an end adjacent to the bottom of the sealed container 50 in which oil is stored to the suction chamber 54a of the cylinder head 54. The oil supply pipe 62 penetrates the through hole 73 of the cylinder 53 at the inlet end 62a and the inlet end 62a immersed in the oil stored in the bottom of the sealed container 50 to suck the suction chamber 54a. And having an outlet end (62b) formed to be bent to the inlet (56) side extending to), the oil lubrication device in the linear compressor according to the present invention It can prevent oil lubrication caused by damage of oil pipe and also prevent foreign matter floating in the airtight container from flowing into the oil supply pipe to prevent oil supply blockage and at the same time block the entry of metal foreign materials into the compression chamber. By reducing the frictional wear inside the seal, it is possible to contribute to the improvement of the operation reliability and the coefficient of performance of the compressor.

Description

Linear compressor

The present invention relates to a linear compressor, and more particularly to a linear compressor having an improved oil lubrication structure for smooth operation of the cylinder portion of the linear compressor.

In general, a compressor is a device of a refrigeration cycle that is used in an air conditioner or a freezer to generate the rough air by circulation of the refrigerant, and is a device that compresses and discharges the refrigerant at a high temperature and a high pressure.

One type of such compressor is a linear compressor, which has a linear motor driven by an interaction caused by a change in the direction of magnetic flux to linearly reciprocate a piston.

1 is a cross-sectional view of a conventional linear compressor. As shown therein, the linear compressor includes an airtight container 10 in which an upper airtight container 11 and a lower airtight container 12 are coupled to each other, and a compression unit for sucking, compressing, and discharging a refrigerant in the airtight container 10. And a driving unit for generating an extrusion force in the compression unit.

First, the compression section includes a cylindrical cylinder 13 and a rod-shaped piston 25 for linearly reciprocating up and down the inside of the cylinder 13. And a cylinder head 14 in which a suction tube 20 for sucking refrigerant into the cylinder 13 and a discharge tube 21 for guiding discharge of the sucked and compressed refrigerant are in communication with each other. ) And a valve plate (15) fitted between the cylinder (13) and the cylinder (13) and having an inlet (16) and an outlet (17) formed therein, the inlet valve (18) for opening and closing each of the inlets (16) and outlets (17). And a discharge valve 19. Meanwhile, an oil lubrication device is provided in the sealed container 10 to prevent abrasion due to friction in the operating portion of the piston 25 inside the cylinder 13. The oil lubrication device is provided with an oil lubrication pipe 22 communicated with the upper portion of the cylinder head 14, and the oil lubrication pipe 22 extends from the lower portion of the sealed container 10 to the upper part and extends downward. The stage is partially submerged in the oil stored in the lower portion of the sealed container 10.

Next, the driving unit includes an inner stator 24 and an outer stator 23, respectively, and a permanent magnet 26 radially magnetized between the stators 23 and 24 is mounted. A cylindrical support frame 27 for fixing the magnet 26 is included. The support frame 27 has a coupling shaft 29 extending from the lower portion of the piston 25 is screwed through the bottom surface of the support frame 27, the end of the coupling shaft 29 is a leaf spring 28 It is bolted to the leaf spring 28 through the center of the.

The operation of the conventional linear compressor configured as described above changes the polarity of the stators 23 and 24 according to the polarity of the supplied current as an external AC power is applied, and thus a constant distance between the permanent magnet 26 and the permanent magnet 26. While securing the support frame 27 is rotated up and down with the permanent magnet (26).

The driving of the support frame 27 causes the piston 25 to reciprocate up and down together with the support frame 27. When the piston 25 moves from the top to the bottom, the suction force in the compression chamber S is increased. As a result, the suction valve 18 is opened, whereby the refrigerant is introduced into the compression chamber S through the suction pipe 20. Then, when the piston 25 moves from the lower part to the upper part, the refrigerant in the compression chamber S is gradually compressed and compressed by a predetermined compression to open the discharge valve 19 at this pressure. It is discharged through the discharge tube 21.

On the other hand, the suction force is generated in the suction pipe 20 as the piston 24 toward the bottom dead center during the suction stroke, but the suction force is also generated in the oil supply pipe 22 as well. At this time, the oil accumulated in the bottom of the sealed container 10 by the suction force is forcibly sucked through the oil lubrication pipe 22 to be supplied to the cylinder head 14, and is continuously introduced into the compression chamber (S) and the compression chamber ( S) to help facilitate the operation of the piston 25 inside.

In this conventional linear compressor, the oil lubrication structure is formed on the upper side of the compressor, so the lubrication pipe 22 must bypass the actuator inside the sealed container 10 so that the lubrication pipe 22 has a plurality of bending portions. Also, the length becomes too long. Thus, since the oil supply section 22 of the related art is placed in an unstable state, the oil supply pipe 22 excessively vibrates due to vibration generated by driving of the compressor, and noise is generated by the vibration at this time. The bending portion of the oil supply pipe 22 may be damaged by noise and vibration. If the bending portion is damaged at this time, the supply of oil to the compression chamber (S) is interrupted and the frictional wear of the piston 25 and the cylinder 13 cannot be controlled.

In addition, since the conventional linear compressor is made of a metal material and constitutes a plurality of friction parts, a considerable amount of metal foreign matter is generated by continuous operation, and most of the metal foreign material is accumulated at the bottom of the sealed container 10. . Therefore, the metal foreign matter may flow into the oil supply pipe 22 together with the oil, or may accumulate inside the oil supply pipe 22 or may enter the compression chamber S. As a result, these foreign metals have a problem in that the oil supply to the compression chamber (S) is stopped, or the piston 25 or the inner circumferential surface of the cylinder 13 is damaged, thereby lowering the reliability of operation of the compressor.

The present invention is to solve the above-mentioned problems, the present invention is to improve the installation structure to more securely support the oil supply pipe to prevent the oil supply pipe from being damaged by the vibration generated by the drive of the compressor To provide.

Still another object according to the present invention is to provide a compressor that can further improve the operation reliability by purifying the metal foreign matter suspended in the oil flowing into the oil supply pipe so that the purified oil can be introduced into the oil supply pipe.

1 is a cross-sectional view showing a conventional linear compressor.

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

3 is a perspective view showing an oil lubrication device in the linear compressor according to the present invention.

* Explanation of symbols for main parts of the drawings

50: airtight container 53: cylinder

54 cylinder head 55 valve plate

56: suction port 57: discharge port

58: suction valve 59: discharge valve

62: oil supply pipe 70: filtering member

71: inlet 72: filtering magnet

In order to achieve the above object, the present invention provides a sealed container in which oil is accumulated at a bottom thereof, a linear motor which generates lifting driving force by an induction magnetic field formed by the application of an external power source inside the sealing container, and a piston lifting and lowering by the lifting driving force. A cylinder head including a cylinder forming a compression chamber for guiding the lifting and lowering of the piston, a suction chamber coupled to one end of the cylinder and having a suction port communicating with the compression chamber, and a discharge chamber having a discharge port communicating with the compression chamber; A linear compressor having an oil supply pipe whose one end is immersed in the oil and the other end communicates with the suction chamber so as to lubricate the compression chamber, wherein the cylinder head is disposed from an end adjacent to the bottom of the sealed container in which the oil is stored. The through hole is formed to be opened to extend to the suction portion of the, the oil supply pipe is for the An inlet end immersed in oil stored in the bottom of the machine and an outlet end extending through the through hole of the cylinder from the inlet end to the suction chamber and bent to the suction port side.

Hereinafter, one preferred embodiment according to the present invention will be described in detail with reference to the drawings.

2 is a cross-sectional view showing a linear push according to the present invention. As shown therein, the linear compressor according to the present invention includes an airtight container 50 in which an upper airtight container 51 and a lower airtight container 52 are combined, and the refrigerant is sucked and compressed in the airtight container 50. A compression unit for discharging and a driving unit for generating a compression force are provided. At the bottom of the sealed container 50, oil for lubrication of the driving part is accumulated.

First, the compression unit includes a cylindrical cylinder 53 forming a compression chamber S therein, and a rod-shaped piston 65 linearly reciprocating up and down in the compression chamber S inside the cylinder 53. This is installed. And a suction chamber 54a and a discharge chamber in which the suction tube 60 for sucking the refrigerant into the cylinder 53 and the discharge tube 61 for guiding discharge of the refrigerant compressed through the suction tube through the suction tube are coupled to each other. A cylinder head 54 forming a 54b is installed at the upper end of the cylinder 53, and is interposed between the cylinder head 54 and the cylinder 53, and the inlet port 56 and the discharge port 57 are formed. The plate 55 is provided. The valve plate 55 is further provided with a suction valve 58 and a discharge valve 59 for opening and closing each of the suction ports 56 and the discharge ports 57.

On the other hand, inside the sealed container 50 is provided with an oil lubrication device for supplying oil for lubrication between the inner surface of the compression chamber (S) and the outer periphery of the piston (65). The oil lubrication device includes an oil supply pipe in which an inlet end 62a at the lower end is contained in the oil at the bottom of the sealed container 50, and an outlet end 62b at the upper end communicates with the suction chamber 54a of the cylinder head 54. 62). The oil supply pipe 62 vertically penetrates the cylinder 53. To this end, the cylinder 53 has a through hole 73 extending upward from the lower side of the sealed container 50.

Next, the drive unit constitutes a linear motor, and includes an inner stator 64 and an outer stator 63, and a permanent magnet 66 magnetized in a radial direction is installed between each of the stators 63 and 64. A cylindrical support frame 67 is installed to fix the permanent magnet 66. The support frame 67 is screwed through the bottom surface of the coupling shaft 69 extending from the lower portion of the piston 65, the coupling shaft 66 of the piston 56 is the support frame 67 After penetrating through it, it penetrates through the center of the leaf spring 68, and is bolted to the leaf spring 68. FIG. And the hole 67a for the oil supply pipe 62 which penetrates the cylinder 53 to penetrate to the side of the part in which the coupling shaft 69 of the piston 65 in the bottom surface of this support frame 67 was coupled. Is formed.

Hereinafter, the oil supply pipe 62 of the present invention will be described in more detail. As shown in FIG. 2 and FIG. 3, the oil supply pipe 62 of the present invention has an upper end extending to the suction chamber 54a of the cylinder head 54, that is, an outlet end 62b formed at the valve plate 55. As shown in FIG. The outlet portion is bent gently to face the suction port 56. The lower end of the oil supply pipe 62, that is, the inlet end 62a is partially submerged in the oil, and as the peripheral portion of the oil submerged part, floating foreign matter floating in the oil is introduced into the inlet end 62a of the oil supply pipe 62. Filtering member 70 is provided to block the inflow.

Although the filtering member 70 is provided in the cylindrical shape which the upper and lower ends opened, it is preferable to form the width | variety of a lower side as much as possible. A plurality of oil inlets 71 are formed on the side surface of the filtering member 70. The oil inlet 71 is to allow foreign substances of a predetermined size in the oil flowing into the inlet end 62a of the oil supply pipe 62 to be filtered by the inlet 71 so that the purified oil flows into the oil supply pipe 62. It is preferable that the diameter D ₂ is formed to have a size equal to or smaller than the inner diameter D ₁ of the oil supply pipe 62. (D ₁ ≥D ₂ )

Meanwhile, the filtering magnet 72 is installed inside the filtering member 70. The filtering magnet is for preventing the fine metal particles in the foreign matter introduced into the filtering member 70 from being attached to the filtering magnet 72 so as not to enter the inlet end 62a of the oil supply pipe 62.

The operation of the conventional linear compressor configured as described above, when an external AC power is first applied, the polarity of the stator 63 and 64 is changed according to the polarity of the supplied current. The support frame 67 is secured at regular intervals and rotates up and down together with the permanent magnet 66. The piston 65 is linearly reciprocated vertically by the drive of the support frame 67, and the piston 65 is lowered. When moved upward, the refrigerant is introduced into the compression chamber S by opening the suction valve 58 through the suction pipe 60. Then, when the piston 65 moves from the upper side to the lower side, the refrigerant sucked in the compression chamber S is compressed and compressed at a predetermined pressure, so that the discharge tube 59 is opened through the discharge tube 61 to open the discharge valve 59. 61).

On the other hand, in this suction stroke, when the piston 65 is driven toward the bottom dead center, suction force is generated in the suction pipe 60, but similarly, suction force is generated in the oil oil supply pipe 62 as well. Due to the suction force generated at this time, the oil accumulated in the bottom of the sealed container 50 is forcibly sucked through the oil lubrication pipe 62 to be supplied to the suction chamber 54a of the cylinder head 54, and the compression chamber S continues. Is introduced into the interior to help facilitate the operation of the piston 65 in the compression chamber (S). In this case, the oil flowing into the oil supply pipe 62 is first filtered out of the foreign matter having a large diameter in the foreign matter suspended in the standing oil without being introduced into the inlet 71 of the filtering member 70, and the filtering member 70 continues. Fine metal particles in the oil introduced into the inside) are filtered by the filtering magnet 72 so that the oil flowing into the inlet end 62a of the oil supply pipe 62 is introduced into the purified state.

The oil lubrication device in the linear compressor according to the present invention as described above can prevent the oil unlubricated due to the damage of the oil supply pipe, and also prevent the foreign matters floating in the sealed container from entering the oil supply pipe and block the oil supply pipe. At the same time, it prevents the entry of metal foreign matter into the compression chamber and reduces frictional wear in the compression chamber, thereby contributing to the improvement of operation reliability and performance coefficient of the compressor.

Claims (4)

A sealed container 50 having oil accumulated at its bottom, a linear motor generating lifting driving force by an induction magnetic field formed by application of an external power source inside the sealing container 50, a piston 65 lifting and lowering by the lifting driving force, Cylinder 53 forming a compression chamber (S) for guiding the lifting and lowering of the piston 65, the suction chamber is coupled to one end of the cylinder 53 and the suction port 56 is connected to the storage chamber (S) is formed A cylinder head 54 having a discharge chamber 54b having a discharge port 57 in communication with the compression chamber S, and the inlet end 62a for lubricating the compression chamber S. Cylinder head 54 having a torch reel 54b, which is immersed in the outlet port 62b, the outlet end 62b communicating with the suction chamber 54a, and the inlet end lubricating the compression chamber S. In a linear compressor having an oil supply pipe 62 in which 62a is wound on the oil and an outlet end 62b communicates with the suction chamber 54a. The lining 53 is formed with a through hole 73 extending from the end adjacent to the bottom of the sealed container 50 in which oil is stored to the suction chamber 54a of the cylinder head 54 to open. The oil pipe 62 penetrates the inlet end 62a immersed in the oil stored in the bottom of the sealed container 50 and the through hole 73 of the cylinder 53 at the inlet end 62a to allow the suction chamber ( 54a), the linear compressor having an outlet end (62b) is formed to be bent to the inlet (56) side extending. According to claim 1, The inlet end (62a) of the oil supply pipe 62 is located on the bottom in which the oil of the sealed container 50 is stored therein floating in the oil flowing into the inlet end (62a) Linear compressor, characterized in that the filtering member 70 is installed to filter foreign matter. According to claim 2, wherein the filtering member 70 is provided in a cylindrical shape with both ends open, a plurality of oil formed in the side portion having a diameter (D ₂ ) of the inner diameter (D ₁ ) or less of the oil supply pipe (62) Linear compressor characterized in that the inlet 71 is formed. The linear compressor of claim 3, wherein a filtering magnet (72) is installed inside the filtering member (70) so that metal foreign matter in the foreign matter passing through the oil inlet (71) is attached and filtered.