KR20050052011A - Hermetic compressor - Google Patents

Abstract

The present invention discloses a hermetic compressor with improved oil supply structure. The hermetic compressor disclosed above is installed in the frame in an up-down direction to transmit the rotational force of the frame accommodated in the sealed case, the lower power mechanism portion and the upper compression mechanism portion mounted on the frame, and the power mechanism portion to the compression mechanism portion. Rotating shaft having a portion, and the oil supply guide means provided on the rotating shaft to supply the oil of the bottom of the sealed case to each drive portion, the oil supply guide means is the first oil installed in the lower portion of the rotating shaft for the rise of oil accumulated in the sealed case A helical lubrication groove formed in the pick-up member, the rotary shaft of the upper part of the first oil pick-up member and eccentric with respect to the center of the rotary shaft, formed on the outer surface of the rotary shaft of the upper part of the first fuel passage, and communicating with the first fuel passage; The second oil supply passage formed in the eccentric portion of the rotating shaft to communicate with the lubricating oil lubrication groove, the first oil lubrication to increase the lifting force of the oil Intended to include the second oil pick-up member provided in a. Such a hermetic compressor enables a smooth oil supply to each driving part of the rotating shaft while generating sufficient oil lift force even if the rotating shaft rotates at a low speed.

Description

Hermetic compressor

The present invention relates to a hermetic compressor, and more particularly, to a hermetic compressor having an improved oil supply structure such that an effective oil supply can be made to each drive part by using a rotation of a rotating shaft.

As a technique related to a general hermetic compressor, Japanese Laid-Open Patent Publication No. 2000-205130 discloses a technique for lubricating each driving part of the compressor by using a rotation of a rotating shaft. This compressor is for raising oil accumulated in the bottom of the sealed case when the rotating shaft rotates, and an oil supply piece is installed in the lower part of the rotating shaft, and an oil supply passage eccentric with respect to the center of the rotation shaft is formed in the rotation axis above the oil supply piece. A spiral oil supply guide groove is formed on the outer surface of the rotating shaft of the oil supply passage communicating with the oil supply passage. In addition, an upper oil supply passage communicating with the upper end of the oil supply guide groove is formed in the eccentric portion of the upper portion of the rotary shaft to enable oil supply to the piston.

The hermetic compressor is configured to raise oil through the oil supply piece when the rotating shaft rotates, and the rising oil is supplied to the spiral oil supply guide groove along the eccentric oil supply passage. In addition, the oil rising along the lubrication guide groove is supplied to the upper oil supply passage formed in the upper eccentric while lubricating and cooling the inner surface of the shaft support portion supporting the rotating shaft, and the oil in the upper oil supply passage is supplied to the piston to lubricate the piston. Will be performed.

However, such a conventional hermetic compressor has an oil supply passage formed inside the rotary shaft on the upper side of the oil supply piece in a straight line so as to be parallel to the center of the rotary shaft. Therefore, when the rotary shaft rotates at a low speed, the oil lift force is increased in the process of oil rising through the oil supply passage. There was a drawback that the oil supply to the spiral oil supply guide groove was weakened.

In addition, since the oil supply structure of the conventional compressor is a structure in which the upper oil supply passage formed in the eccentric portion of the upper rotary shaft is also formed in a straight line so as to be parallel to the rotary shaft, the lifting force of the oil is weakened during the oil feeding process, and thus the oil supply to the piston is not smooth. .

The present invention is to solve such a problem, it is an object of the present invention to provide a hermetic compressor to enable a smooth oil supply to each drive portion of the rotary shaft while generating a sufficient lifting force of the oil even if the rotary shaft rotates at a low speed.

The hermetic compressor according to the present invention for achieving the above object, the closed case, the frame accommodated in the sealed case, the lower power mechanism and the upper compression mechanism portion mounted to the frame, the transmission of the rotational force of the power mechanism to the compressor mechanism. Rotating shaft having an eccentric portion connected to the compression mechanism portion in the upper and lower directions to the frame, and oil supply guide means provided on the rotating shaft to supply oil to the driving portion of the bottom of the sealed case, the oil supply The guide means is formed in the first oil pick-up member installed below the rotary shaft to raise oil accumulated in the sealed case, in the rotary shaft above the first oil pick-up member, and eccentric with respect to the center of the rotary shaft. A distribution passage, formed on the outer surface of the rotary shaft above the first feed passage, the first grade A spiral oil supply groove communicating with a passage, a second oil supply passage formed in an eccentric portion of the rotary shaft so as to communicate with the spiral oil supply groove, and a second oil pickup member installed in the first oil supply passage to increase the lifting force of the oil; Characterized in that.

In addition, the first oil supply passage is characterized in that the center is inclined in the direction away from the center of the rotary shaft from the bottom to the top.

In addition, the second oil supply passage is characterized in that the center is formed inclined in the direction away from the center of the rotary shaft from the bottom to the top.

The present invention further includes a bearing interposed between the upper portion of the frame and the lower end of the eccentric portion of the rotating shaft, wherein the second feed passage is formed from the eccentric portion of the rotating shaft to the inside of the rotating shaft at a lower position of the bearing and is radial It is characterized in that it communicates with the spiral lubrication groove through a communication hole formed as.

In addition, the bearing is characterized in that the thrust bearing for supporting the axial load.

In addition, the outer surface of the rotating shaft is characterized in that the oil induction portion is formed from the top of the spiral oil supply groove to the position of the bearing so that the oil is made toward the bearing.

In addition, the oil guide portion is characterized in that it is made of a plane formed in the vertical direction on the outer surface of the rotating shaft.

In addition, the first oil pick-up member is characterized in that it comprises a cylindrical oil guide portion formed with an oil inlet smaller than the outer diameter at the lower end, and a spiral wing accommodated in the oil guide portion.

In addition, the second oil pick-up member is characterized in that it comprises a spiral wing accommodated in the first oil supply passage.

In addition, the eccentric portion of the rotating shaft is characterized in that the auxiliary flow path is formed in the radial direction so that the second oil supply passage and the outer surface communicate.

In addition, the hermetic compressor according to the present invention includes a closed case, a frame accommodated in the sealed case, a lower electric mechanism part and an upper compressor part mounted on the frame, and a vertical direction to the frame to transmit the rotational force of the electric machine part to the compressor part. And a lubrication shaft having an eccentric portion connected to the compression mechanism portion at an upper portion thereof, and a lubrication guide means provided at the rotary shaft to supply oil to each driving portion of the bottom of the sealed case, wherein the lubrication guide means is the sealed case. A first oil pick-up member installed at a lower portion of the rotary shaft to raise oil accumulated in the first oil passage, a first oil passage formed in the rotary shaft above the first oil pick-up member, and eccentric with respect to a center of the rotary shaft; A spiral class formed on an outer surface of the rotary shaft above an oil supply passage and communicating with the first oil supply passage; And a second oil supply passage formed in an eccentric portion of the rotary shaft so as to communicate with the oil groove and the spiral oil feed groove, the center of which is inclined in a direction spaced apart from the center of the rotary shaft from the lower portion to the upper portion thereof.

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

As shown in FIG. 1, the hermetic compressor according to the present invention includes a frame 12 installed in the sealed case 10 through a plurality of shock absorbers 11 and an upper side of the frame 12. Compressor 20, and the drive mechanism 30 is provided on the lower side of the frame 12 for driving the compression mechanism (20).

In addition, the compressor has a rotating shaft 40 which is disposed in the vertical direction by transmitting the rotational force of the electric mechanism unit 30 to the compression mechanism unit 20 and rotatably supported by the shaft support 13 of the frame 12. In addition, the rotary shaft 40 has an eccentric portion 41 formed to be eccentric with respect to the center of the connection to the compression mechanism 20 in the upper portion, the lower portion of the eccentric portion 41 in the upper portion of the frame 12 It is provided with a bearing support portion 42 formed larger than the outer diameter of the rotary shaft 40 to be supported. A thrust bearing 43 is interposed between the lower surface of the bearing support part 42 and the upper surface of the frame 12 to support the axial load of the rotating shaft 40 and to facilitate the rotation of the rotating shaft 40. .

The above-described electric mechanism unit 30 is coupled to the outer surface of the rotary shaft 40, the rotor 31 and rotates together with the rotary shaft 40, and the stator 32 is installed in a fixed state on the outside of the rotor 31 Is made of. In addition, the compression mechanism 20 includes a cylinder 21 and a cylinder head 22 forming a compressed space of the refrigerant, a piston 23 for compressing the refrigerant while advancing the inside of the cylinder 21, and one end of the piston ( The connecting rod 25 is connected to the pin 24 of the 23 and the other end is connected to the eccentric portion 41 of the rotation shaft 40. Such a configuration is achieved by converting the rotary motion into a linear reciprocating motion through the eccentric portion 41 and the connecting rod 25 of the rotating shaft 40 when the rotating shaft 40 rotates by the operation of the electric mechanism part 30. 23) is made, through which the compression of the refrigerant can be performed.

In addition, the hermetic compressor according to the present invention is for lubrication and cooling of each driving part, and a predetermined amount of oil is filled in the bottom of the hermetic case 10. In addition, the rotary shaft 40 is provided with a lubrication guide means for supplying the oil accumulated in the bottom of the sealed case 10 by using the rotation of the rotary shaft 40 to each of the driving parts.

As shown in FIG. 2, the oil supply guide means includes a first oil pick-up member 51 installed below the rotary shaft 40 and a first oil pick-up member 51 formed in the rotary shaft 40 above the first oil pick-up member 51. Swivel shaft 40 to be connected to the upper portion of the spiral oil supply groove 54, the spiral oil supply groove 54 formed on the upper outer surface of the rotary shaft 40 to be connected to the oil supply passage 52, the first oil supply passage (52) And a second oil supply passageway 56 formed in the eccentric portion 41 of the.

More specifically, the first oil pick-up member 51 is provided in a cylindrical shape whose outer diameter decreases from the upper side to the lower side coupled to the lower end of the rotation shaft 40, and the oil inlet 51c smaller than the outer diameter of the circumference at the lower end submerged in oil. ) Is formed with an oil guide portion (51a), and the spiral blade (51b) is provided inside the oil guide portion (51a). This is to allow the oil introduced into it through the oil inlet 51c when the rotary shaft 40 rotates to rise through the rotation of the spiral blade 51b to be supplied toward the first oil supply passage 52.

The first oil supply passage 52 is for guiding the rise of the oil raised by the action of the first oil pick-up member 51, and supports the rotating shaft 40 from the top of the first oil pick-up member 51. It is formed longer in the vertical direction than the lower end of the shaft support portion 13 of the frame 12, the center is formed to be eccentric with respect to the center of the rotation shaft (40). In addition, the first oil supply passage 52 is formed to be inclined at a predetermined angle (1) in a direction in which the center thereof is spaced apart from the center of the rotation shaft 40 from the lower portion to the upper portion. In addition, a communication hole 52a is formed in a radial direction of the rotation shaft 40 so as to communicate with a lower portion of the spiral oil supply groove 54 at an upper portion of the first oil supply passage 52. This configuration is to increase the centrifugal force acting on the oil in the first oil supply passage 52 when the rotating shaft 40 rotates so that the smooth rise of the oil can be guided.

In addition, a second oil pickup member 53 having a spiral wing shape is installed inside the first oil supply passage 52 to further increase the lifting force of the oil. This is to increase the lift force of the oil by the action of the second oil pick-up member 53 as well as the centrifugal force generated when the rotating shaft 40 rotates so that the oil can be smoothly guided to the upper spiral oil feed groove (54).

The spiral lubrication groove 54 is formed of a groove of a predetermined depth spirally formed along the outer surface of the rotation shaft 40. The spiral oil lubrication groove 54 is such that the oil flow path is formed between the inner surface of the shaft support 13 of the frame 12 so that the oil ascending guide through the spiral oil lubrication groove 54 when the rotating shaft 40 rotates. It is to be done. In addition, lubrication and cooling may be performed between the outer surface of the rotating shaft 40 and the inner surface of the shaft support part 13 by the oil that is raised.

The second oil supply passage 56 is formed to be inclined at a predetermined angle (2) in a direction in which the center thereof is spaced apart from the center of the rotation shaft 40 from the lower portion to the upper portion, and the lower end of the communication hole formed in the radial direction of the rotation shaft 40. It communicates with the upper end of the spiral lubrication groove 54 through the 55 and the upper end is in communication with the upper end of the eccentric portion 41 of the rotary shaft 40. This increases the lift force of the oil by the centrifugal force generated by the rotation of the rotary shaft 40, so that the oil raised to the upper portion through the spiral lubrication groove 54 can be smoothly supplied toward the upper compression mechanism 20 of the frame 12. It would be. At this time, the auxiliary portion communicated in the radial direction so that the oil rising through the second oil supply passage 56 to the connecting rod 25 coupled to the eccentric portion 41 to the eccentric portion 41 of the rotating shaft 40 The flow path 57 is formed.

In addition, as shown in FIG. 3, the second oil supply passage 56 extends from the eccentric portion 41 of the rotation shaft 40 to the inside of the rotation shaft 40 at the lower position of the thrust bearing 43. That is, the position of the communication hole 55 formed so that the second oil supply passage 56 and the spiral oil supply groove 54 communicate with each other is disposed at the lower position of the thrust bearing 43. When the upper end of the spiral lubrication groove 54 formed on the outer surface of the rotary shaft 40 reaches the position of the thrust bearing 43, the oil rising along the helical lubrication groove 54 has a radius through a gap of the thrust bearing 43. This is to prevent such a phenomenon by placing the position of the communication hole 55 in the lower portion of the thrust bearing 43 because it is scattered in the direction and no further rise is made.

In addition, a portion of the oil raised through the spiral lubrication groove 54 is supplied to the thrust bearing 43 on the outer surface of the rotary shaft 40 so as to perform lubrication and cooling of the thrust bearing 43 side. An oil induction part 58 is provided which is formed from the upper portion of the upper portion 54 to the position of the thrust bearing 43. In this case, as shown in FIG. 4, the oil induction part 54 is disposed on the outer surface of the rotation shaft 40 so that an oil flow path is formed between the inner surface of the shaft support part 13 of the frame 12 and the outer surface of the rotation shaft 40. It consists of a plane formed in the direction.

The following describes the compression and oil supply operation of such a hermetic compressor.

As shown in FIG. 1, when the rotation shaft 40 is rotated by the operation of the lower electric mechanism unit 30, the connecting rod 25 of the eccentric portion 41 and the compression mechanism 20 on the upper rotation shaft 40 is rotated. As the rotary motion is converted into a linear reciprocating motion by the) motion, the piston 23 moves forward and backward. In addition, the refrigerant is sucked into the cylinder 21 by the advancing and retracting operation of the piston 23, and the compression is performed while being pressurized and discharged.

During this operation, the oil accumulated in the bottom of the sealed case rises along the rotating shaft by the action of the lubrication guide means provided on the rotating shaft 40, and lubrication is performed to each driving part. This makes the compressor operate smoothly. Specifically, the oil supply operation is as follows.

When the first oil pickup member 51 rotates together with the rotation shaft 40, oil accumulated in the bottom of the sealed case 10 flows into the inside of the oil inlet 51c of the first oil pickup member 51. , The introduced oil is supplied to the first oil supply passage 52 of the upper portion by the action of the spiral blade 51b inside the first oil pick-up member 51.

The oil supplied to the first oil supply passage 52 not only has the first oil supply passage 52 eccentric from the center of the rotation shaft 40 but also has an inclination of a predetermined angle (1) as well as the first oil supply passage ( 52) Since the second oil pick-up member 53 is installed therein, even when the rotating shaft 40 rotates at a low speed, the lifting force of the oil is increased, and the oil is smoothly guided toward the upper spiral oil feed groove 54. At this time, the oil raised along the first oil supply passage 52 is supplied to the spiral oil supply groove 54 through the communication hole 52a on the upper side of the first oil supply passage 52.

The oil supplied to the spiral lubrication groove 54 is raised upward by the action of the spiral lubrication groove 54 and performs lubrication and cooling between the outer surface of the rotary shaft 40 and the inner surface of the shaft support portion 13. The oil is subsequently guided upward by the helical lubrication groove 54 and then supplied to the second oil supply passage 56 through the radial communication hole 55, and ascends along the second oil supply passage 56. Then, it is supplied to each drive part of the compression mechanism 20. At this time, since the second oil supply passage 56 is formed to be inclined at a predetermined angle (2), even if the rotation shaft 40 rotates at a low speed, the oil supply force toward the compressor sphere 20 is smoothly increased by the centrifugal force. Become. In addition, some of the oil guided to the upper portion of the spiral lubrication groove 54 is also supplied to the thrust bearing 43 through the oil guide portion 58, so that the lubrication and cooling of the thrust bearing 43 is smoothly performed.

As described in detail above, the hermetic compressor according to the present invention has a structure in which the first oil supply passage inside the rotating shaft is eccentric with respect to the center of the rotating shaft, and is inclined in a direction spaced apart from the rotating center from the lower part to the upper part, and the second Since the structure accommodates the oil pick-up member, even if the rotating shaft rotates at a low speed, the upward force of the oil guided along the first oil supply passage is increased and oiling in the upward direction is smoothly performed.

In addition, the present invention has a structure in which the second oil supply passage in the upper portion of the rotary shaft is inclined in the direction away from the center of rotation from the bottom to the upper portion, even if the rotating shaft rotates at a low speed, the upward force of the oil guided along the second oil supply passage increases, There is an effect that the oil supply to the compression mechanism portion is smoothly made.

In addition, the present invention has the effect that the lubrication and cooling of the thrust bearing smoothly because the oil is made to the thrust bearing through the oil guide portion of the upper surface of the rotary shaft.

1 is a cross-sectional view showing the configuration of a hermetic compressor according to the present invention.

Figure 2 is a view showing the configuration of the lubrication guide means provided in the hermetic compressor rotary shaft according to the present invention.

3 is a cross-sectional view illustrating a configuration of an upper second oil supply passage and an oil induction part of the sealed compressor rotating shaft according to the present invention.

4 is a cross-sectional view taken along line IV-IV of FIG. 3.

Explanation of symbols on the main parts of the drawings

10: sealed case, 12: frame,

13: shaft support portion, 20: compression mechanism portion,

30: electric mechanism part, 40: rotating shaft,

41: eccentric, 43: trust bearing,

51: first oil pick-up member, 52: first oil supply passage,

53: second oil pick-up member, 54: spiral lubrication groove,

56: second oil supply passage, 58: oil guide.

Claims (13)

Hermetic case, the frame accommodated in the hermetic case, the lower power mechanism portion and the upper compression mechanism portion mounted to the frame, is installed in the frame in the vertical direction to transfer the rotational force of the power mechanism portion to the compression mechanism portion and the compression mechanism portion on the top A rotating shaft having an eccentric portion connected to the rotating shaft, and oil supply guide means provided on the rotating shaft to supply oil to the driving portion to the bottom of the sealed case. The lubrication guide means is formed in the first oil pick-up member installed below the rotary shaft to raise oil accumulated in the sealed case, in the rotary shaft above the first oil pick-up member and eccentric with respect to the center of the rotary shaft. A first oil supply passage, a spiral oil supply groove formed on the outer surface of the rotary shaft in the upper portion of the first oil supply passage and communicated with the first oil supply passage, a second oil supply passage formed in the eccentric portion of the rotary shaft to communicate with the spiral oil supply groove And a second oil pick-up member installed in the first oil supply passage so as to increase the lifting force of the oil. The method of claim 1, The first oil supply passage is hermetic compressor characterized in that the center is formed inclined in the direction away from the center of the rotation shaft from the lower to the upper. The method of claim 1, The second oil supply passage is hermetic compressor characterized in that the center is formed inclined in the direction away from the center of the rotary shaft from the bottom to the top. The method of claim 1, Further comprising a bearing interposed between the upper portion of the frame and the lower end of the eccentric portion of the rotating shaft, And the second oil supply passage communicates with the helical oil lubrication groove through a communication hole formed in a radial direction from the eccentric portion of the rotation shaft to the inside of the rotation shaft at the bearing lower position. The method of claim 4, wherein Said bearing is a thrust bearing for supporting an axial load. The method of claim 4, wherein Hermetic compressor, characterized in that the oil guide portion is formed on the outer surface of the rotating shaft from the upper portion of the spiral lubrication groove to the position of the bearing so that lubrication is made toward the bearing. The method of claim 6, The oil-inducing unit is a hermetic compressor, characterized in that formed in the plane formed in the vertical direction on the outer surface of the rotating shaft. The method of claim 1, The first oil pick-up member is a hermetic compressor, characterized in that it comprises a cylindrical oil guide portion formed with an oil inlet smaller than the outer diameter at the bottom, and a spiral wing accommodated in the oil guide portion. The method of claim 1, The second oil pick-up member is a hermetic compressor characterized in that it comprises a spiral wing accommodated in the first oil supply passage. The method of claim 1, The eccentric portion of the rotary shaft is a hermetic compressor characterized in that the auxiliary flow path is formed in the radial direction so as to communicate with the second oil supply passage and the outer surface. Hermetic case, the frame accommodated in the hermetic case, the lower power mechanism portion and the upper compression mechanism portion mounted to the frame, is installed in the frame in the vertical direction to transfer the rotational force of the power mechanism portion to the compression mechanism portion and the compression mechanism portion on the top A rotating shaft having an eccentric portion connected to the rotating shaft, and oil supply guide means provided on the rotating shaft to supply oil to the driving portion to the bottom of the sealed case. The lubrication guide means is formed in the first oil pick-up member installed below the rotary shaft to raise oil accumulated in the sealed case, in the rotary shaft above the first oil pick-up member and eccentric with respect to the center of the rotary shaft. A first oil supply passage, a spiral oil supply groove formed on the outer surface of the rotary shaft in the upper portion of the first oil supply passage and communicated with the first oil supply passage, formed in the eccentric portion of the rotary shaft to communicate with the spiral oil supply groove, from bottom to top The hermetic compressor of claim 1, further comprising a second oil supply passage formed to be inclined in a direction in which the center thereof is spaced apart from the center of the rotation shaft. The method of claim 11, Further comprising a thrust bearing interposed between the upper portion of the frame and the lower end of the eccentric portion of the rotating shaft, The second oil supply passage is hermetic compressor characterized in that it communicates with the helical lubrication groove through a communication hole formed in the radial direction from the eccentric portion of the rotary shaft to the inside of the rotary shaft in the lower position of the thrust bearing. The method of claim 12, Hermetic compressor characterized in that the outer surface of the rotating shaft is provided with a flat oil guide portion formed from the upper portion of the spiral lubrication groove to the position of the thrust bearing so that lubrication is made toward the thrust bearing.