KR200156404Y1 - Coolant leakage protection structure of linear compressor - Google Patents

Abstract

The present invention relates to a linear compressor, in particular a housing; A cylinder block installed in the housing; A valve assembly coupled to one surface of the cylinder block to guide the introduction and discharge of refrigerant; One side is embedded in the inner cylinder to form a refrigerant compression chamber inside the cylinder block and the other side is a piston immersed in oil; A linear compressor installed between the inner cylinder and the outer cylinder, the linear compressor including a linear motor reciprocating the piston by receiving current from the outside; An auxiliary housing storing oil provided on a bottom of the housing and installed on a bottom of the housing corresponding to the piston to allow the piston to pass therethrough; The oil stored in the auxiliary housing is supplied to the contact portion of the piston and the cylinder block to smoothly reciprocate the piston and at the same time the refrigerant in the compression chamber does not leak to the contact portion of the cylinder block and the piston. Refrigerant leakage prevention structure of the linear compressor consisting of a flow path formed by going up from the portion contained in the oil and bent to the cylinder block side at an appropriate height, and an oil flow prevention portion formed at the end of the piston so that the oil supplied to the flow path does not flow down The oil is supplied to the contact portion between the piston and the cylinder block, so that the piston smoothly reciprocates inside the cylinder block and the refrigerant in the compression chamber does not leak into the gap between the piston and the cylinder block, thereby improving the efficiency of the compressor. do.

Description

Refrigerant Leakage Prevention Structure of Linear Compressor

The present invention relates to a linear compressor for compressing a refrigerant at a high temperature and high pressure. More specifically, oil is supplied to the outer peripheral surface side of a piston which is linearly reciprocated by a linear motor so that the refrigerant does not leak to the contact portion between the piston and the cylinder block. It relates to a refrigerant leakage prevention structure of a linear compressor.

A compressor is used to perform a compression process of compressing a refrigerant at high temperature and high pressure in an apparatus for performing a refrigeration cycle. A conventional linear compressor will be briefly described with reference to FIG.

A cylinder block 1 having an inner cylinder 1a and an outer cylinder 1b is provided in the sealed housing 10, and a valve assembly 7 is coupled to the upper side of the cylinder block 1. In addition, the inner cylinder 1a is provided with a piston 3 provided concentric with the cylinder block 1, and the compression chamber 2 is formed in the cylinder block 1 by the piston 3. A flange 3a bent outwardly and upward is formed on the outer circumferential surface of the other piston 3 of the compression chamber 2, and a magnet 4a integrally coupled with the flange 3a between the inner cylinder 1a and the outer cylinder 1b. A linear motor 4 having) is provided. The cylinder block 1 and the piston 3 are coupled to the leaf spring 5a supported by the suspension gas spring 5b on the lower side of the housing 10. One side of the valve assembly 7 is provided with a suction muffler 8 through which refrigerant flows, and a discharge tube 6 for guiding the compressed refrigerant into the condenser is provided on the other side. Reference numeral 7a denotes a discharge chamber.

To explain the action, when the current is supplied to the motor from the outside, the magnet 4a is vibrated by the electromotive force, thereby causing the piston 3 to linearly reciprocate. Then, the refrigerant introduced into the compression chamber 2 through the suction muffler 8 is compressed and discharged into the discharge chamber 7a and supplied to the condenser through the discharge tube 6.

The conventional linear compressor as described above has a disadvantage in that the refrigerant flowing into the compression chamber formed inside the cylinder block leaks. That is, there was a disadvantage that the refrigerant leaked to the site where the piston and the cylinder block contact.

The present invention is devised to solve the above disadvantages, an object of the present invention is to provide a refrigerant leakage preventing structure of the linear compressor that the oil is injected into the contact portion of the piston and the cylinder block does not leak the refrigerant.

In addition, since the oil supplied to the contact portion of the piston and the cylinder block for the purpose of sealing also lubricating at the same time to provide a refrigerant leakage preventing structure of the linear compressor that can smoothly move the piston to improve its efficiency.

1 is a cross-sectional view showing the configuration of a conventional linear compressor,

Figure 2 is a cross-sectional view showing the configuration of a linear compressor according to the present invention,

Figure 3 is an enlarged cross-sectional view of the end of the piston according to the present invention,

Figure 4 is a sectional view showing another embodiment of the piston according to the present invention.

* Explanation of symbols for main parts of the drawings

50: cylinder block 51: inner cylinder

52: outer cylinder 53: compression chamber

60: piston 62: flow path

65: auxiliary pipe 70: linear motor

80: valve assembly 93: auxiliary housing

100: housing

The present invention for achieving the above object is a sealed housing; A cylinder block installed in the housing and having an inner cylinder and an outer cylinder; A valve assembly coupled to one surface of the cylinder block to guide the introduction and discharge of refrigerant; One side is embedded in the inner cylinder to form a refrigerant compression chamber inside the cylinder block and the other side is a piston immersed in oil; A linear compressor installed between the inner cylinder and the outer cylinder, the linear compressor including a linear motor reciprocating the piston by receiving current from the outside; An auxiliary housing storing oil provided on a bottom of the housing and installed on a bottom of the housing corresponding to the piston to allow the piston to pass therethrough; The oil stored in the auxiliary housing is supplied to the contact portion of the piston and the cylinder block to smoothly reciprocate the piston and at the same time the refrigerant in the compression chamber does not leak to the contact portion of the cylinder block and the piston. It is composed of an oil flow prevention portion formed at the end of the piston so that the oil is supplied to the flow path is formed to be bent up to the cylinder block side at an appropriate height up to the upper portion in the oil flow.

With reference to the accompanying drawings will be described in detail a preferred embodiment of the refrigerant leakage preventing structure of the linear compressor according to the present invention.

As shown in FIG. 2, the linear compressor according to the present invention is provided with a sealed housing 100 containing oil on its bottom. A cylinder block 50 is installed in the housing 100, and the cylinder block 50 is provided with an inner cylinder 51 and an outer cylinder 52. The valve assembly 80 is coupled to the upper surface of the cylinder block 50, and the other side of the piston 60 contained in oil is installed in the inner cylinder 51 so that the linear reciprocating motion is possible. A discharge chamber 81 is provided inside the valve assembly 80, a suction muffler 86 through which refrigerant is introduced is provided at one side of the discharge chamber 81, and a discharge tube 89 at which the refrigerant is discharged is provided at the other side. Prepared.

A compression chamber 53 is formed in the inner cylinder 51 by the piston 60 embedded in the inner cylinder 51. A refrigerant flows into the compression chamber 53 through the suction muffler 86 and is compressed. The refrigerant compressed in the compression chamber 53 flows into the discharge chamber 81 and is discharged into the discharge tube 89. The outer periphery of the piston 60 located outside the cylinder block 50 is formed with a frame 61 extending outwardly and upwardly. Reference numeral 82 denotes a valve that opens and closes communication portions between the compression chamber 53 and the discharge chamber 81.

The linear motor 70 is installed to surround the cylinder block 50. The linear motor 70 is between the first stator 71 coupled to the inner cylinder 51, the second stator 72 coupled to the outer cylinder 52, and the first and second stators 71 and 72. The magnet 73 is positioned and integrally coupled to the frame 61 of the piston 60, and the coil 74 press-fits to the second stator 72. When a current is supplied to the coil 74 from the outside, a magnetic circuit is formed between the stators 71 and 72 and the magnet 73 by the current flowing through the coil 74. At this time, the magnet 73 is magnetized in the radial direction, and receives the electromotive force by the interaction with the magnetic flux induced by the stator (71, 72). This electromotive force is generated because the frequency of the external power supplied is alternatingly. As the magnetic flux vibrates, the piston 60 integrally coupled thereto is linearly reciprocated.

The cylinder block 50 and the piston 60 are coupled to the leaf spring 91a, and the leaf spring 91a is coupled to the other side of the current gas spring 91b having one side coupled to the bottom surface of the housing 100. . That is, the cylinder block 50, the piston 60, and the linear motor 70 are elastically supported by the elastic member 91.

The linear compressor according to the present invention is configured such that the refrigerant introduced into the compression chamber 53 does not leak to the contact portion between the cylinder block 50 and the piston 60. In detail, the body of the piston 60 is formed with a flow path 62 which is a supply path of oil. The flow path 62 rises upward from the portion contained in the oil, is bent toward the cylinder block 50 at an appropriate height, and communicates with the contact portion between the cylinder block 50 and the piston 60. The piston 60 is linearly reciprocated in the sealed housing 100, the contact portion of the cylinder block 50 and the piston 60 changes similar to the pressure change of the compression chamber 53. Therefore, the oil is supplied through the flow path 62 by the pressure difference between the pressure at the contact portion between the piston 60 and the cylinder block 50 and the housing 100 in which the oil is located.

The bottom of the housing 100 in which the oil is accumulated is provided with a closed auxiliary housing 93 in which the oil is stored. Oil is separately stored in the auxiliary housing 93, and an end portion of the piston 60 on which the flow path 62 is formed is immersed in oil. If the space where the oil is stored becomes more sealed, the pressure difference between the space and the compression chamber becomes larger, so that the oil is smoothly supplied. When oil is supplied to the contact portion of the piston 60 and the cylinder block 50 through the flow path 62, the refrigerant flowing into the compression chamber 53 does not leak, and due to the oil, the piston 60 is the cylinder block 50 ) It is a smooth movement inside.

The flow path 62 formed in the piston 60 is provided with means for preventing the oil flowing into the flow path 62 from flowing down again, which will be described with reference to FIGS. 3 and 4.

The end side flow path 62 of the piston 60 contained in the oil is provided with an oil flow prevention part 62a formed in the shape of a funnel having a lower side. This is because the oil acts as a resistance to the inner surface of the funnel-shaped flow path to prevent the oil flowing into the flow path to flow downward.

In addition, the auxiliary pipe 65 is coupled to the oil passage 62 on the side of the piston 60 contained in oil. The cross-sectional area of the auxiliary pipe 65 is provided smaller than the cross-sectional area of the flow path 62, which also prevents the oil flowing into the flow path to flow down.

The operation and effects of the refrigerant leakage preventing structure of the linear compressor according to the present invention having the above structure will be described.

When a current is supplied to the linear motor 70 from the outside, a magnetic circuit is generated between the first and second stators 71 and 72 and the magnet 73, and the magnet is magnetized in the radial direction. The magnet is then subjected to electromotive force by interaction with the magnetic flux induced by the stator. When the direction of the current flowing through the coil is changed, the magnet vibrates up and down, thereby causing the piston 60 to linearly reciprocate. The refrigerant introduced into the compression chamber 53 through the suction muffler 86 is compressed by the movement of the piston and discharged to the discharge chamber 81 and discharged to the condenser through the discharge tube 89. At this time, when the piston 60 is moved upward, the compression chamber 53 is compressed to maintain high pressure, and when the piston is moved below the auxiliary housing 93, the compression chamber is low pressure. That is, if the body of the piston is contained a lot in the interior of the auxiliary housing the compression chamber 53 is a low pressure, since the interior of the auxiliary housing is a high pressure, the oil inside the auxiliary housing is introduced between the piston and the cylinder block through the passage 62 of the piston. . Then, the refrigerant flowing into the compression chamber is not leaked to the contact portion between the piston and the cylinder block by the oil.

When the piston is moved upward, the compression chamber is high pressure, and the inside of the auxiliary housing is low pressure. At this time, the oil in the flow path may flow down. However, since the oil flow passage 62 formed in the piston according to the present invention has an oil flow prevention portion 62a formed in a funnel shape at the end thereof, the oil contacting the cross-sectional area of the oil passage at the end of the piston acts as a resistance so that the oil in the flow path flows. It doesn't get off. Alternatively, since the cross-sectional area of the auxiliary pipe 65 communicating with the flow path is very small, the oil in the flow path does not flow down.

As described above, in the refrigerant leakage preventing structure of the linear compressor according to the present invention, since oil is injected into the contact portion between the piston and the cylinder block, the piston smoothly reciprocates in the cylinder block and the refrigerant in the compression chamber is There is a very practical effect that the leakage of the cylinder block is not leaked to improve the efficiency of the compressor.

Claims (5)

(Correction) hermetically sealed housing 100 provided with oil; A cylinder block 50 installed in the housing 100 and having an inner cylinder 51 and an outer cylinder 52; A valve assembly (80) coupled to one surface of the cylinder block (50) to guide the introduction and discharge of refrigerant; One side is built in the inner cylinder 51 so that the refrigerant compression chamber 53 is formed in the cylinder block 50 and the other side is a piston 60 immersed in oil; In the linear compressor is provided between the inner cylinder (51) and the outer cylinder (52) and made of a linear motor (70) for linearly reciprocating the piston (60) by receiving a current from the outside; An auxiliary housing (93) for storing oil provided on the bottom of the housing (100) and installed on the bottom of the housing (100) corresponding to the piston (60) so that the piston (60) passes; Oil stored in the auxiliary housing 93 is supplied to the contact portion of the piston 60 and the cylinder block 50 to smoothly reciprocate the piston 60 and at the same time the refrigerant in the compression chamber 53 A flow path 62 formed by bending upward to the cylinder block 50 at an appropriate height while rising upward from the portion contained in the oil in the piston 60 so as not to leak into the contact portion between the cylinder block 50 and the piston 60. And an oil flow prevention part (62a) formed at an end of the piston (60) so that oil supplied to the flow path (62) does not flow down. (delete) (delete) (Correction) The auxiliary pipe 65 according to claim 1, wherein an auxiliary pipe 65 having a cross-sectional area smaller than the cross-sectional area of the flow path 62 is provided at an end of the piston 60 so that oil supplied to the flow path 62 does not flow down. Refrigerant leakage preventing structure of a linear compressor. (delete)