KR100855255B1 - Hermetic type compressor - Google Patents

Abstract

A hermetic compressor is provided to allow lower and upper ends of a journal bearing to be contacted with an elastic member and to a rotor respectively with reduced friction by interposing a first friction reduction unit between the elastic member and the lower end of the journal bearing, thereby capable of preventing abrasion and noise. A hermetic compressor comprises a rotary shaft(50), an elastic member(70), and a first friction reduction unit(80). The rotary shaft, on which a rotor is press-fitted, has an eccentric unit(51) at a lower end, of which an outer periphery between the rotor and the eccentric unit is rotatively supported by a journal bearing(60) fixed on a frame. The elastic member elastically supports between the journal bearing and the eccentric unit. The first friction reduction unit is formed at the outer periphery of the rotary shaft between a lower end of the journal bearing and the elastic member in order to reduce friction.

Description

Hermetic Compressor {HERMETIC TYPE COMPRESSOR}

1 is a cross-sectional view showing the overall structure of a hermetic compressor according to an embodiment of the present invention.

2 is a cross-sectional view of the hermetic compressor according to the preferred embodiment of the present invention, in which the rotating shaft, the journal bearing fitted to the rotating shaft, the first and second friction reducing units, and the elastic member are extracted.

3 is a perspective view illustrating the structure of an elastic member in the hermetic compressor according to the preferred embodiment of the present invention.

4 is a cross-sectional view of a main part for showing a buffering effect on the elastic member in the hermetic compressor according to the preferred embodiment of the present invention, showing a state in which the rotor and the rotating shaft are flowed upward.

FIG. 5 is a cross-sectional view of main parts for showing a buffering effect on the elastic member in the hermetic compressor according to the preferred embodiment of the present invention, showing a state in which the rotor and the rotating shaft flow downward.

Explanation of symbols on the main parts of the drawings

50: rotation axis 51: eccentric portion

60: journal bearing 70: elastic member

71: support portion 72: extension portion

80: first friction reducing unit 81: first ball bearing

82: first thrust washer 90: second friction reducing unit

91: 2nd ball bearing 92: 2nd thrust washer

The present invention relates to a hermetic compressor, and more particularly, to a hermetic compressor provided to reduce wear and noise between components due to vertical vibration of the rotor.

In general, the hermetic compressor is adopted to compress the refrigerant in a refrigerating cycle of a refrigerator or an air conditioner, and first forms an appearance through a hermetically sealed container. In the sealed container, a driving unit providing a compression driving force of the refrigerant and a compression unit receiving the driving force from the driving unit to perform the compression operation of the refrigerant are installed, and the driving unit and the compression unit are installed through the frame.

The drive unit is composed of a stator and a rotor rotatably provided inside the stator to rotate by electromagnetic interaction with the stator. In a hermetic compressor, such a drive unit is positioned above the hermetic container and is provided by a piston or the like. The compression unit may be one located at the bottom of the sealed container.

In the case of the hermetic compressor in which the dual drive unit is located above, the stator is fixed to the upper outer side of the frame, and the rotor is rotatably installed inside the stator.

In addition, the compression unit is configured to include a piston and a cylinder is installed on the lower side of the frame, the driving force of the drive unit is transmitted to the compression unit through the rotating shaft.

The rotating shaft is installed to penetrate the center of the frame, the rotor is pressed into the upper portion of the upper rotation axis of the frame, the lower end of the lower rotation axis of the frame forms an eccentric rotation, the eccentric portion through the piston and the connecting rod Connected.

Therefore, in the hermetic compressor having such a structure, when the rotor is rotated by the electromagnetic interaction between the stator and the rotor, the eccentric portion is rotated eccentrically while the rotor is press-fitted, and the eccentric portion and the connecting rod are rotated. The piston connected through the linear reciprocating motion in the cylinder while the refrigerant is compressed.

On the other hand, the outer circumference of the rotating shaft between the rotor and the eccentric portion is rotatably supported through a journal bearing installed in the frame. This journal bearing is fixed to the frame through the bottom, and the top of the journal bearing is supported to abut the rotor.

In addition, an oil storage space in which oil is stored is formed at the bottom of the sealed container, and an oil pick-up member for sucking up the oil in the oil storage space through the centrifugal force of the rotation shaft is coupled to the bottom of the eccentric portion of the rotation shaft. An oil flow path is formed inside the rotating shaft to guide the oil sucked upward through the oil pickup member to the friction sliding portion of the driving unit and the compression unit. The oil flow path is also formed on the outer surface of the rotating shaft of the journal bearing side.

Therefore, when the rotating shaft rotates during the compression of the refrigerant, the oil of the oil storage space is drawn up through the oil pickup member in the state of the compression unit and the driving unit, such as between the journal bearing and the rotating shaft along the oil passage It is delivered to the friction sliding part to perform lubrication.

However, the conventional hermetic compressor configured as described above repeatedly collides between the journal bearing and the eccentric part and the journal bearing and the rotor through vertical vibration of the rotor and the rotating shaft during the compression of the refrigerant, thereby preventing excessive wear and abnormal noise between components. There was a problem that caused it.

That is, when the drive unit is driven, the rotor converts electrical energy into mechanical energy in a form of rotating in a magnetic field of the stator, and the magnetic center of the stator and the rotor are coincident for stable rotation of the rotor. In some cases, when the magnetic center of the stator and the rotor do not coincide due to an external shock or a change in the magnetic field, the rotor flows upward while being thrust upward and downward. In addition, when the rotation shaft becomes high speed and the amount of oil supplied to the oil passage is excessively large, the rotation shaft flows upward due to the oil pressure. Thus, when any one of the rotor and the rotation shaft flows upward, The other one connected also flows upward together, and the rotor and the rotating shaft which flows upward are lowered again by its own weight, and the rotor and the rotating shaft vibrate up and down by repetition of this phenomenon.

Therefore, during the vertical vibration of the rotor, the lower end of the journal bearing fixed to the frame repeatedly collides with the eccentric portion, and the upper end of the journal bearing repeatedly collides with the rotor. Excessive wear occurs between journal bearings and eccentrics, causing abnormal noise.

The present invention is to solve such a problem, an object of the present invention is to provide a hermetic compressor provided to reduce the wear and noise generated between the parts by suppressing the vertical vibration of the rotor and the rotating shaft.

The hermetic compressor according to the present invention for achieving the above object is a rotary shaft provided so that the rotor is press-fitted in the upper portion and the eccentric portion is formed in the lower portion, and the outer circumference between the rotor and the eccentric portion is rotatably supported through a journal bearing fixed to the frame. And, characterized in that it comprises an elastic member provided to elastically support between the journal bearing and the eccentric portion.

And a first friction reducing unit is provided on the outer periphery of the rotating shaft between the lower end of the journal bearing and the elastic member to reduce the friction between the journal bearing and the elastic member.

In addition, the first friction reducing unit includes a first ball bearing and a first thrust washer, the first thrust washer is provided to be supported on the elastic member, the first ball bearing is the first thrust washer and the lower end of the journal bearing Characterized in that provided.

In addition, a second friction reducing unit is provided on the outer periphery of the rotating shaft between the upper end of the journal bearing and the rotor to reduce the friction between the journal bearing and the rotor.

In addition, the second friction reducing unit includes a second ball bearing and a second thrust washer, the second ball bearing is provided to be supported on the top of the journal bearing, the second thrust washer between the second ball bearing and the rotor Characterized in that provided.

In addition, the elastic member is characterized in that it is provided with a leaf spring.

In addition, the elastic member is characterized in that it comprises a support portion provided to support the eccentric portion having an axial coupling hole to be coupled to the outer circumference of the rotating shaft, and an extension part inclined upwardly outward from the support portion.

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

As shown in FIG. 1, the hermetic compressor according to the present invention forms an exterior through the hermetic container 10, and the refrigerant passing through the evaporator of the refrigeration cycle is sealed on one side and the other side of the hermetic container 10. The suction pipe 11 for guiding to the discharge vessel and the discharge tube 12 for guiding the refrigerant compressed in the sealed container 10 toward the condenser of the refrigerating cycle, respectively.

In addition, the inside of the sealed container 10 is provided with a driving unit 30 for providing a compression driving force of the refrigerant, and a compression unit 20 for receiving the driving force of the driving unit 30 to perform the compression action of the refrigerant, The drive unit 30 and the compression unit 20 is installed through the frame 40.

First of all, the drive unit 30 is a stator 31 fixed to the upper outer side of the frame 40 and a rotor 32 rotatably provided inside the stator 31 so as to rotate by electromagnetic interaction with the stator 31. ).

In addition, the compression unit 20 is a cylinder 21 formed integrally with the frame 40 on one side of the frame 40 to form a compression chamber 21a, and a straight reciprocating inside the compression chamber 21a. A piston 22 provided to be movable and a cylinder head 23 coupled to one end of the cylinder 21 to seal the compression chamber 21a are provided. The cylinder head 23 has a refrigerant suction chamber 23a and a refrigerant discharge chamber 23b which are provided to be partitioned with each other, and the double refrigerant suction chamber 23a is connected to the suction pipe 11 to the refrigerant chamber 21a. The refrigerant discharge chamber 23b is connected to the discharge tube 12 to guide the refrigerant compressed in the compression chamber 21a to the discharge tube 12, and the cylinder head 23 and the cylinder 21. ) Is provided with a valve device 24 for controlling the flow of the refrigerant sucked into the compression chamber 21a from the refrigerant suction chamber 23a or discharged from the extrusion chamber 21a to the refrigerant discharge chamber 23b.

The driving force of the driving unit 30 is transmitted to the compression unit 20 through the rotation shaft 50.

The rotating shaft 50 is installed to penetrate the center of the frame 40, the center of the rotor 32 is pressed into the upper portion of the upper rotating shaft 50 of the frame 40, the rotating shaft of the lower portion of the frame 40 50, the lower end forms an eccentric portion 51 that rotates eccentrically.

A connecting rod 25 is connected between the eccentric portion 51 and the piston 22 to convert the eccentric rotational movement of the eccentric portion 51 into a linear reciprocating movement of the piston 22, and the rotor 32. The outer circumference of the rotation shaft 50 between the eccentric portion 51 is rotatably supported by a journal bearing 60 installed in the frame 40 so that the lower end thereof is fitted into the through hole 41 formed in the center portion of the frame. Here, the upper end of the journal bearing 60 is provided to be caught by the rotor 32, the journal bearing 60 and the lower end is provided to be caught by the upper support jaw (5a1) of the eccentric (51).

The journal bearing 60 is framed by the support portion 61 extending from the side is coupled to the frame 40 through the fixing bolt 100 to be supported on the upper surface of the frame 40 in a state in which the lower end is fitted in the through hole 41. Is installed in the 40, the lower portion of the rotor 32 is formed so that the upper end of the journal bearing 60 is received inside the rotor. In addition, the length of the rotating shaft between the rotor 32 and the eccentric portion 51 of the upper side of the journal bearing 60 for smooth rotation of the rotor 32 and the rotating shaft 50 is somewhat larger than the vertical length of the journal bearing 60. It is formed long.

In addition, the hermetic compressor according to the present embodiment is provided with an oil lubrication structure to lubricate the friction sliding parts of the driving unit 30 and the compression unit 20 such as between the rotating shaft 50 and the journal bearing 60 through oil. do.

That is, an oil storage space 13 for storing a predetermined amount of oil is formed at the bottom of the sealed container 10, and oil is stored at the bottom of the eccentric portion 51 of the rotary shaft 50 by using centrifugal force of the rotary shaft 50. An oil pick-up member 110 is installed to suck up the oil in the space 13 to the upper portion, and the oil sucked up through the oil pick-up member 110 is rotated on the rotation shaft 50 to the driving unit 30 and the compression unit 20. An oil passage 52 is formed to guide the friction sliding portion of the.

The oil passage 52 has a first oil passage 52a provided to guide the oil upwards inside the eccentric 51, and the rotary shaft 50 toward the journal bearing 60 so as to communicate with the first oil passage 52a. And a second oil oil 52b formed on an outer surface thereof, although not shown in the drawing, a side for guiding oil toward the connecting rod 25 and the piston 22 on the side of the first oil flow path 52a. Three oil paths are formed.

Through the oil lubrication structure, the oil in the oil storage space 13 is sucked upward along the oil pickup member 110 during the rotational movement of the rotation shaft 50 according to the compression action of the refrigerant. The oil is supplied to the friction sliding portion of the driving unit 30 and the compression unit 20 along the oil passage 52 and the lubrication function is recovered and then returned to the oil storage space 13 to repeat the lubrication of the friction sliding portion. do. At this time, between the rotating shaft 50 and the journal bearing 60 is lubricated through the oil flowing along the second oil oil (52b).

On the other hand, when the drive unit 30 is driven, the rotor 32 converts electrical energy into mechanical energy in a form of rotating in the magnetic field of the stator 31, and for stable rotation of the rotor 32 It is preferable that the magnetic centers of the stator 31 and the rotor 32 coincide with each other. Sometimes, when the magnetic centers of the stator 31 and the rotor 32 do not coincide through an external impact or a change in the magnetic field, The rotor 32 flows upward while being subjected to thrust in the vertical direction. In addition, when the rotation shaft 50 becomes a high speed and the amount of oil supplied to the second oil passage 52b becomes excessively large, the rotation shaft 50 flows upward by the oil pressure. When either one of the 32 and the rotating shaft 50 flows upward, the other interconnected one also flows upward, and the rotor 32 and the rotating shaft 50 flowing upward are lowered by their own weight again. The rotor 32 and the rotating shaft 50 is vibrated up and down by repetition of this phenomenon.

Therefore, in the case of the upper and lower vibrations of the rotor 32 and the rotating shaft 50, the lower end of the journal bearing 60 fixed to the frame 40 repeatedly collides with the eccentric portion 51, and the journal bearing In the case of the upper end of the 60, such as repeatedly collide with the rotor 32, excessive wear phenomenon between the rotor 32 / journal bearing 60 / eccentric portion 51 occurs, causing abnormal noise 2 and 3, in the hermetic compressor according to the present embodiment, the journal bearing 60 and the journal bearing 60 are separated in order to suppress the vertical vibration of the rotor 32 and the rotation shaft 50. An elastic member 70 is provided on the outer periphery of the rotation shaft 50 between the core portions 51 to elastically support the journal bearing 60 and the eccentric portion 51. In this embodiment, the elastic member 70 is a plate. It is provided with a spring.

Therefore, when the elastic bearing 70 is elastically supported between the journal bearing 60 and the eccentric portion 51, the vertical vibration of the rotor 32 and the rotating shaft 50 is absorbed through the elastic member 70. It is suppressed.

 The elastic member 70 is provided with a shaft coupling hole (71a) to be coupled to the outer circumference of the rotating shaft 50, the support portion 71 provided to be supported by the eccentric portion (51), and from the support portion 71 to the upper outward It comprises a pair of extensions 72 extending obliquely. The support portion 71 is formed to be flat for stable contact with the eccentric portion 51, and is also provided at the ends of each of the extension portions 72 for flat contact with the first thrust washer 82, which will be described later. A washer contact portion 72a is provided. The elastic member 70 is a vibration of the rotating shaft 50 and the rotor 32 through the stretching action between the support portion 71 and the washer contact portion 72a in a state in which the support portion 71 is supported by the eccentric portion 51. Will absorb. 4 and 5, the vibration damping effect of the elastic member 70 in the state in which the rotor 32 and the rotating shaft 50 flow in the upper portion (arrow A direction) and in the lower state (arrow B direction) is shown. Each is shown.

In addition, the upper end of the journal bearing 60 is always in contact with the rotor 32 in a state in which the lower end of the journal bearing 60 and the eccentric portion 51 are elastically supported by the elastic member 70, and the journal bearing 60 Since the lower end is always in contact with the elastic member 70, the upper and lower vibrations of the rotor 32 and the rotating shaft 50 are absorbed through the buffering action of the elastic member 70, while the rotor 32 and When the rotary shaft 50 rotates, excessive friction between the journal bearing 60, the rotor 32, and the eccentric portion 51 may hinder the smooth rotation of the rotor 32 and the rotary shaft 50. .

Therefore, in the hermetic compressor according to the present embodiment, first, the friction between the journal bearing 60 and the elastic member 70 is reduced on the outer circumference of the rotating shaft 50 between the lower end of the journal bearing 60 and the elastic member 70. A first friction reduction unit 80 is provided to the outer surface of the rotating shaft 50 between the upper end of the journal bearing 60 and the rotor 32 between the journal bearing 60 and the rotor 32. The second friction reducing unit 90 is provided to reduce the friction of the.

First, the first friction reducing unit 80 is composed of a first ball bearing 81 and the first thrust washer 82, the first thrust washer 82 is in contact with the washer contact portion 72a Sliding on the elastic member 70, the first ball bearing 81 is provided between the first thrust washer 82 and the lower end of the journal bearing 60 to support the rolling between them.

The second friction reducing unit 90 includes a second ball bearing 91 and a second thrust washer 92. The second ball bearing 91 is roll-supported on the top of the journal bearing 60, and the second thrust washer 92 slides between the second ball bearing 91 and the rotor 32 so as to slide between the second ball bearing 91. It is provided between the 92 and the rotor 32.

Therefore, the first friction reduction unit 80 is interposed between the lower end of the journal bearing 60 and the elastic member 70, the second friction reduction unit 90 is the top of the journal bearing 60 and the rotor ( In the state interposed between the 32 and the upper and lower vibrations of the rotor 32 and the rotating shaft 50 through the elastic member 70 is suppressed, as well as the lower and upper ends of the journal bearing 60 are respectively the elastic member 70 and Since the rotor 32 is contacted and supported in a state where friction is reduced, smooth rotational movement of the rotor 32 and the rotating shaft 50 is also possible.

As described above in detail, the hermetic compressor according to the present invention is suppressed up and down vibrations of the rotating shaft and the rotor through an elastic member provided between the journal bearing and the eccentric portion of the rotating shaft, so that the upper and lower ends of the journal bearing are separated from the rotor. Avoiding collisions with the core can effectively reduce excessive wear and abnormal noise between them.

In addition, in the hermetic compressor according to the present invention, since the first friction reducing unit is interposed between the elastic member and the lower end of the journal bearing, and the second friction reducing unit is interposed between the rotor and the upper end of the journal bearing, the rotor through the elastic member. While the up and down vibration of the rotating shaft is suppressed, the lower end and the upper end of the journal bearing are in contact with the elastic member and the rotor with reduced friction, respectively, and thus the smooth rotational movement of the rotor and the rotating shaft is possible.

Claims (7)

The rotor is press-fitted in the upper portion and the eccentric portion is formed at the lower end and the rotation axis is provided so that the outer circumference between the rotor and the eccentric portion is rotatably supported through the journal bearing fixed to the frame, so as to elastically support between the journal bearing and the eccentric portion Including an elastic member provided, Hermetic compressor characterized in that the first friction reducing unit is provided on the outer periphery of the rotating shaft between the lower end of the journal bearing and the elastic member to reduce the friction between the journal bearing and the elastic member. delete The method of claim 1, The first friction reducing unit includes a first ball bearing and a first thrust washer, The first thrust washer is provided to be supported on the elastic member, the first ball bearing is a hermetic compressor, characterized in that provided between the first thrust washer and the lower end of the journal bearing. The method of claim 1, Hermetic compressor characterized in that the second friction reducing unit is provided on the outer periphery of the rotating shaft between the upper end of the journal bearing and the rotor to reduce the friction between the journal bearing and the rotor. The method of claim 4, wherein The second friction reducing unit includes a second ball bearing and a second thrust washer, The second ball bearing is provided to be supported on the top of the journal bearing, the second thrust washer is characterized in that the compressor is provided between the second ball bearing and the rotor. The method of claim 1, The elastic member is a hermetic compressor characterized in that it is provided with a leaf spring The method of claim 6, The elastic member is a hermetic compressor comprising a support portion provided to support the eccentric portion having an axial coupling hole to be coupled to the outer circumference of the rotary shaft, and an extension portion inclined upwardly outward from the support portion.

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