KR20080033752A - A hermetic type compressor - Google Patents

Abstract

A hermetic type compressor is provided to allow the smooth lubrication between a piston pin and a connection rod even when the compressor is initially started or restarted. A hermetic type compressor comprises a connecting rod(60) having a large diameter portion(61) and a small diameter portion(62), and an oil passageway(64) formed in the connecting rod. The connecting rod consists of an upper body and a lower body assembled together. The oil passageway is formed between the upper and lower bodies before the upper and lower bodies are assembled. The oil passageway includes an inlet channel formed at the large diameter portion, an outlet channel formed at the small diameter portion, and a connection channel for connecting the inlet channel with the outlet channel. The connection channel includes a lower end which has a lower level than those of the inlet and outlet channels.

Description

Hermetic Compressor {A HERMETIC TYPE COMPRESSOR}

1 is a cross-sectional view showing a connecting rod side structure in a conventional hermetic compressor.

2 is an enlarged cross-sectional view illustrating the structure of the connecting rod of FIG. 1.

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

Figure 4 is an enlarged cross-sectional view showing a connecting rod side structure in a hermetic compressor according to an embodiment of the present invention.

5 is an enlarged cross-sectional view illustrating the structure of the connecting rod in the hermetic compressor according to the preferred embodiment of the present invention.

6 is a perspective view illustrating a structure of a connecting rod in the hermetic compressor according to the preferred embodiment of the present invention, showing a state in which the upper body and the lower body are separated.

7 is a perspective view illustrating a structure of a connecting rod in a hermetic compressor according to an exemplary embodiment of the present invention, showing a state in which the upper body and the lower body are assembled to each other.

Explanation of symbols on the main parts of the drawings

22: piston 25: piston pin

41: eccentric shaft portion 60: connecting rod

60A: Upper Body 60B: Lower Body

61: large neck 62: small neck

63: connecting portion 64: oil euro

64A: Oil Groove 65,66: Extension

65a, 66a: bolt assembly

The present invention relates to a hermetic compressor, and more particularly to a hermetic compressor provided to lubricate between the piston pin and the connecting rod through an oil passage formed in the connecting rod.

In general, a hermetic compressor employed in a refrigeration cycle such as a refrigerator or an air conditioner has a refrigerant inside the compression chamber 1 through a piston 2 linearly reciprocating in the compression chamber 1 as shown in FIG. 1. It is provided to compress the, for this purpose to transfer the rotational movement of the rotary shaft 3 to the linear reciprocating motion between the eccentric shaft portion 4 and the piston 2 formed on the rotary shaft 3 to the piston (2) The connecting rod 5 is installed.

The connecting rod 5 has a large diameter portion 5a provided at one end to be rotatably coupled to an outer surface of the eccentric shaft portion 4, and a piston pin inserted into the piston 2 and fastened to the piston 2 ( 2a) It comprises a small diameter part 5b provided at the other end so that it may be rotatably fitted to an outer surface, and the connection part 5c which connects the said large diameter part 5a and the small diameter part 5b.

When the eccentric shaft portion 4 is eccentrically rotated by the rotational movement of the rotary shaft 3 by the driving of the drive unit not shown through this structure, the piston connected through the eccentric shaft portion 4 and the connecting rod 5 (2) linearly reciprocates in the compression chamber 1 to perform a compression action of the refrigerant.

In addition, a first oil hole 3a formed along the axial direction is formed in the lower inner side of the rotary shaft 3, and oil stored in the bottom of the sealed container is disposed at the lower end of the rotary shaft 3 at the lower side of the first oil hole 3a. An oil pick-up member 6 is installed to suck the upper portion, and the eccentric shaft portion 4 is supplied with the oil of the first oil hole 3a to the outer surface of the eccentric shaft portion 4 so that the eccentric shaft portion 4 and the connecting rod are provided. A second oil hole 4a for lubricating and cooling between the large diameter portions 5a of (5) is formed to intersect the first oil hole 3a, and the outlet side eccentric shaft portion of the second oil hole 4a ( 4) The first oil groove 4b is formed on the outer surface over a predetermined section along the circumferential direction so that the oil spilled from the second oil hole 4a is temporarily stored.

In addition, a large diameter portion is formed inside the connecting rod 5 such that oil supplied to the first oil groove 4b may be continuously supplied between the small diameter portion 5b of the connecting rod 5 and the piston pin 2a. An oil flow passage 5d is formed which communicates between 5a) and the small diameter portion 5b.

Referring to FIG. 2, the oil flow path 5d is drilled from the end of the small diameter portion 5b toward the large diameter portion 5a in a state where an approximate outer shape of the connecting rod 5 is prepared. It is formed and takes the form of a straight hole having the same diameter between both ends.

Therefore, when the rotating shaft 3 rotates through this structure, the oil stored in the bottom of the sealed container by the centrifugal force of the rotating shaft 3 is sucked upward along the oil pick-up member 6 and the first oil hole (3a), Some of the oil guided to the first oil hole 3a is supplied to the first oil groove 4b through the second oil hole 4a on the side of the eccentric shaft portion 4 so that the eccentric shaft portion 4 and the connecting rod 5 are provided. Lubrication is performed between the large diameter portion 5a of the oil, and the oil of the first oil groove 4b is continuously transferred toward the small diameter portion 5b along the oil flow passage 5d to the small diameter portion 5b and the piston. Lubricates and cools between the pins 2a.

However, in the conventional hermetic compressor, since the oil channel 5d is provided in the form of a straight hole having the same diameter between both ends, the oil inside the oil channel 5d is reduced in the state in which the rotation of the rotary shaft 3 is stopped. Since it has a structure in which all of them are transmitted to the (5b) side and are exhausted, when the rotating shaft (3) is stopped and driven, such as at the time of initial start-up and restart of the hermetic compressor, the immediate oil between the small-diameter portion (5b) and the piston pin (2a) As the supply becomes difficult, there is a problem in that severe wear occurs due to lack of oil between the small diameter portion 5b of the connecting rod 5 and the piston pin 2a during initial and restarting.

The present invention is to solve such a problem, an object of the present invention is to provide a hermetic compressor provided to smoothly lubricate between the piston pin and the connecting rod during the initial and restart.

In order to achieve the above object, the hermetic compressor according to the present invention has a large diameter portion rotatably coupled to an outer surface of the eccentric shaft portion of the rotary shaft so as to convert the rotational movement of the rotary shaft into a linear reciprocating motion of the piston. The other end inserted into the connecting rod formed with a small diameter portion to be rotatably fitted to the outer surface of the piston pin fastened to the piston, and the oil transferred between the large diameter portion and the eccentric shaft portion by communicating between the large diameter portion and the small diameter portion, It is characterized in that it comprises an oil flow path formed on the connecting rod to be transmitted between the neck and the piston pin to store a predetermined amount of oil therein in a state in which the rotational movement of the rotating shaft is stopped.

The connecting rod is provided with an upper body and a lower body assembled with each other, and the oil channel is provided between the upper and lower bodies before assembling the upper and lower bodies.

In addition, the oil passage includes a large diameter portion side inlet flow passage, the small diameter portion side outlet flow passage, and a connection flow passage provided to connect between the inlet flow passage and the outlet flow passage, the connection flow passage at the lower end of the inlet flow passage and the outlet flow passage It is characterized by being provided lower.

In addition, the width of the connecting passage is characterized in that the larger than the inlet passage and the outlet passage.

In addition, the upper surface of the lower body to form the oil flow path is formed with a flow path groove, the lower surface of the upper body of the portion corresponding to the flow path groove is characterized in that it is configured as a plane covering the upper flow path groove.

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

As shown in FIG. 3 and FIG. 4, the hermetic compressor according to the present embodiment includes an hermetic container 10 formed by combining an upper container 10a and a lower container 10b, and inside the hermetic container 10. It is provided that the compression unit 20 for compressing the refrigerant, the drive unit 30 for providing the compression power according to the compression of the refrigerant, and the drive unit 30 to transfer the driving force of the drive unit 30 to the compression unit. And a rotation shaft 40 connecting the compression unit 20.

The dual drive unit 30 is to provide a driving force of the compressor, the stator 31 is fixed to the upper outer side of the cylinder block 50, the stator 31 is installed in the interior of the stator 31 and the electromagnetic mutual And a rotor 32 provided to rotate by action. Here, the upper end of the rotating shaft 40 is pressed into the center of the rotor 32 is provided to rotate with the rotor 32, the rotating shaft 40 of the lower rotor 32 is the center of the cylinder block 50 It is rotatably supported by a journal bearing 51 assembled to the through hole.

In addition, the compression unit 20 has a cylinder 21 provided with an inner space at a lower side of the cylinder block 50 to form a compression chamber 21a, and linearly reciprocates in the compression chamber 21a to compress the refrigerant. A cylinder head 23 coupled to one end of the cylinder 21 to seal the piston 22 and the compression chamber 21a, and configured to partition the refrigerant suction chamber 23a and the refrigerant discharge chamber 23b from each other; And interposed between the cylinder 21 and the cylinder head 23 to interrupt the flow of the refrigerant sucked into the compression chamber 21a from the refrigerant suction chamber 23a or discharged from the compression chamber 21a to the refrigerant discharge chamber 23b. It is comprised including the valve apparatus 24 provided.

In addition, an eccentric shaft portion 41 is formed at the lower end of the rotating shaft 40 extending below the cylinder block 50 so as to eccentrically rotate, and the eccentric shaft portion 41 is eccentrically rotated between the eccentric shaft portion 41 and the piston 22. Is connected to the connecting rod 60 to convert the piston 22 into a linear reciprocating motion.

The connecting rod 60 is provided at one end with a large diameter portion 61 having a ring shape so as to be rotatably fastened to the outer circumference of the eccentric shaft portion 41, and at the other end so as to be engaged with the piston 22. It comprises a neck portion 62 and a connecting portion 63 for connecting the large diameter portion 61 and the small diameter portion 62, the small diameter portion 62 is inserted into the piston 22 in the state It is rotatably fastened to the outer circumference of the piston pin 25 which is fastened to the piston 22.

The hermetic compressor configured as described above is connected to the connecting rod 60 when the rotating shaft 40 rotates together with the rotor 32 by the electrical interaction between the stator 31 and the rotor 32 according to power application. The piston 22 connected to the eccentric shaft portion 41 makes a linear reciprocating motion inside the compression chamber 21a, and a pressure difference is formed between the inside and the outside of the compression chamber 21a. Therefore, the refrigerant introduced into the refrigerant suction chamber 23a of the cylinder head 23 from the outside of the sealed container 10 through this pressure difference is sucked into the compression chamber 21a and compressed, and the refrigerant compressed in the compression chamber 21a. The discharge is again discharged to the refrigerant discharge chamber (23b) of the cylinder head 23 and then discharged to the outside of the sealed container 10, the compression process of the refrigerant through the hermetic compressor is performed as this process is repeated repeatedly.

In addition, various friction sliding parts in the sealed container 10, that is, between the rotating shaft 40 and the journal bearing 51, the eccentric shaft portion 41 of the rotating shaft 40 and the inner diameter of the large diameter portion 61 of the connecting rod 60 Between the inner diameter of the small diameter portion 62 of the connecting rod 60 and the piston pin 25 and the like, abrasion occurs with high heat due to friction when the compressor is driven. It has a lubrication structure for the purpose of cooling.

In detail, an oil storage space 11 is formed at the bottom of the sealed container 10 so that a predetermined amount of oil is stored, and the oil inside the oil storage space 11 is guided upward in the lower inner side of the rotating shaft 40. The first oil hole 42 is formed in the axial direction, and a cylindrical oil pick-up member 70 for communicating the oil storage space 11 and the first oil hole 42 at the bottom of the eccentric shaft portion 41 is predetermined. It is installed to be inclined to form an angle.

Therefore, the oil sucked upward through the oil pick-up member 70 and the first oil hole 42 by the centrifugal force according to the rotation of the rotary shaft 40 is supplied to the upper outer surface of the rotary shaft 40 to provide the journal bearing 51 and the rotary shaft. Lubrication and cooling are performed between the 40, and a part of the oil drawn up upward along the first oil hole 42 is supplied to the friction portion of the connecting rod 60.

To this end, the eccentric shaft portion 41 is supplied with the oil of the first oil hole 42 to the eccentric shaft portion 41 outer surface to lubricate between the eccentric shaft portion 41 and the inner diameter of the large diameter portion 61 of the connecting rod 60. And a second oil hole 41a for cooling intersects with the first oil hole 42, and is formed on the outer surface of the eccentric shaft 41 of the outlet side of the second oil hole 41a from the second oil hole 41a. A first oil groove 41b is formed along a circumferential direction over a predetermined section so that the spilled oil is temporarily stored.

In addition, the large diameter portion 61 and the small diameter portion 62 so that the oil supplied to the first oil groove 41b can be continuously supplied between the inner diameter of the small diameter portion 62 of the connecting rod 60 and the piston pin 25. A connecting flow path 64 is formed in the connecting rod 60 between the large diameter part 61 and the small diameter part 62 to communicate between the inner diameter of the large diameter part 61 and the small diameter part 62. A second oil groove 25a is formed on the outer circumference of the center portion in the circumferential direction along the circumferential direction so as to communicate with the connection flow path 64.

Therefore, when the rotating shaft 40 rotates through this structure, the oil stored in the oil storage space 11 at the bottom of the sealed container 10 by the centrifugal force of the rotating shaft 40 is the oil pick-up member 70 and the first oil hole. Some of the oil drawn up to the upper side along the 42 and guided to the first oil hole 42 is supplied to the first oil groove 41b through the second oil hole 41a on the eccentric shaft 41 side to be eccentric. Lubrication is performed between the shaft portion 41 and the inner diameter of the large diameter portion 61 of the connecting rod 60, and the oil passing through the first oil groove 41b continues through the connecting passage 64. The neck portion 62 is moved toward the inner diameter and guided to the second oil groove 25a to lubricate and cool the inner diameter of the small diameter portion 62 and the piston pin 25.

On the other hand, in the present embodiment, the oil passage 64 is provided to store a predetermined amount of oil therein even when the rotational movement of the rotary shaft 40 is stopped.

As such, the configuration of the oil flow path 64 provided to store oil therein in a state in which the rotational movement of the rotation shaft 40 is stopped is a state in which the rotation shaft 40 is stopped as in the initial startup or restart of the hermetic compressor. Even if it is rotated again in the oil passage 64 is provided so as to immediately lubricate between the inner diameter of the small diameter portion 62 and the piston pin 25 through the oil stored in, the initial startup of the hermetic compressor and Even when restarting is to smoothly lubricate between the piston pin 25 and the connecting rod (60).

That is, as shown in FIG. 5, in the present embodiment, the oil passage 64 has an inlet passage 64a toward the large diameter portion 61, an outlet passage 64b toward the small diameter portion 64b, and an inlet passage. It comprises a connecting passage 64c provided to connect between the 64a and the outlet passage 64b, wherein the connecting passage 64c has a lower end lower than the inlet passage 64a and the outlet passage 64b. Even when the rotational movement of the rotary shaft 40 is stopped, a predetermined amount of oil is provided so as to be stored in the lower portion, and the width of the connection channel 64c is also the inlet channel 64a so as to store a larger amount of oil. And a width larger than the width of the outlet flow path 64b.

Therefore, when the refrigerant is compressed, the oil flow path 64 which supplies the oil supplied between the large diameter portion 61 and the eccentric shaft portion 41 between the small diameter portion 62 and the piston pin 25 stops the rotation of the rotation shaft 40. Even when the oil inside is not all exhausted between the small diameter portion 62 and the piston pin 25, it is possible to store a predetermined amount of oil inside the lower portion of the connecting flow path 64c. The oil stored in the oil passage 64 in the state where the rotation is stopped is to be immediately supplied between the small diameter portion 62 and the piston pin 25 during the initial startup and restart of the hermetic compressor.

In addition, the connecting rod 60 has an upper body 60A forming an upper side, and a lower body forming a lower side, as shown in FIGS. 6 and 7 so as to facilitate processing of the oil channel 64. 60B are formed to be assembled to each other, and the oil passage 64 is provided between the upper and lower bodies 60A and 60B before the upper and lower bodies 60A and 60B are assembled to each other.

Extension pieces (65,66) formed with bolt assembly holes (65a.66a) on the outer side of the upper body (60A) and the outer side of the lower body (60B) toward the connecting portion 63 for the assembly of the upper body (60A) and the lower body (60B) It is formed integrally extending, the connecting rod 60 is mutually through the fixing bolts 100 which are fastened to the respective extension pieces (65, 66) in a state where the upper body (60A) and the lower body (60B) are mutually superimposed Are assembled.

In the present embodiment, the upper flow path groove 64A is opened on the upper surface of the lower body 60B while the upper and lower bodies 60A and 60B are manufactured to form the oil passage 64, respectively. The lower surface of the upper body 60A of the portion corresponding to the flow path groove 64A is provided as a plane when the upper body 60A is manufactured to cover and seal the upper portion of the flow path groove 64A.

Therefore, the hermetic compressor according to the present invention can more freely form the shape of the connection passage 64 capable of storing oil through the divided structure of the connecting rod 60. Of course, unlike the present embodiment, the oil groove 64A may be formed on the lower surface of the upper body 60A, and when the lower body 60B is manufactured by changing the shape of a mold for manufacturing the lower body 60B. It can also be formed at the same time. That is, the oil passage 64 is provided in a split type through the upper and lower bodies 60A and 60B to which the connecting rods 60 are assembled, and the upper and lower bodies before assembly of the upper and lower bodies 60A and 60B. It can be formed in various other ways within the range provided between (60A, 60B).

As described above in detail, the hermetic compressor according to the present invention has a connection flow path provided inside the connecting rod for transferring oil transferred between the eccentric shaft portion and the large diameter portion of the connecting rod between the piston pin and the small diameter portion of the connecting rod to rotate the rotation shaft. It is provided to store a predetermined amount of oil therein even when the movement is stopped. Therefore, the hermetic compressor according to the present invention is able to supply the oil immediately between the piston pin and the small diameter portion during the initial start-up and restart through the configuration of the oil flow path can be smoothly lubricated between them.

Claims (5)

A large diameter portion is formed at one end to be rotatably coupled to an outer surface of the eccentric shaft portion of the rotating shaft to convert the rotational movement of the rotating shaft into a linear reciprocating motion of the piston, and the other end inserted into the piston has an outer surface of the piston pin fastened to the piston. A connecting rod having a small diameter portion formed to be rotatably fitted to the connecting rod, and formed between the large diameter portion and the eccentric shaft portion so as to transfer oil transferred between the large diameter portion and the eccentric shaft portion between the small diameter portion and the piston pin. The hermetic compressor comprising an oil passage provided to store a predetermined amount of oil therein while the rotation movement of the rotary shaft is stopped. The method of claim 1, The connecting rod is provided with an upper body and a lower body assembled with each other, and the oil passage is provided between the upper and lower bodies before assembling the upper and lower bodies. The method of claim 1, The oil passage includes a large diameter portion side inlet flow passage, the small diameter portion side outlet flow passage, and a connection flow passage provided to connect between the inlet flow passage and the outlet flow passage, The hermetic compressor of claim 4, wherein the lower end of the connection passage is lower than the inlet passage and the outlet passage. The method of claim 3, wherein The hermetic compressor of claim 4, wherein a width of the connection passage is larger than that of the inlet passage and the outlet passage. The method of claim 1, The upper surface of the lower body to form the oil flow path is processed flow path groove, the lower surface of the upper body of the portion corresponding to the flow path groove is hermetic compressor characterized in that it is composed of a flat surface covering the flow path groove.

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