KR20180100903A - Reciprocating compressor - Google Patents

Abstract

The present invention relates to a reciprocating compressor. The reciprocating compressor of the present invention comprises: a shell forming an enclosed space, in which oil is stored; a drive unit provided in the shell and including a rotary shaft, a rotor connected to the rotary shaft, and a stator disposed outside the rotor; a compression mechanism unit connected to the rotary shaft for compressing a refrigerant; an oil supply mechanism connected to the rotary shaft to supply the refrigerant stored in the shell to the rotary shaft; and a fixation unit for supporting the oil supply mechanism. The oil supply mechanism has: a gear unit connected to the rotary shaft and rotating together with the rotary shaft to pump the oil; and a case accommodating the gear unit. The fixation unit supports the case.

Description

[0001] Reciprocating compressor [0002]

The present invention relates to a reciprocating compressor.

The reciprocating compressor is a compressor in which the piston sucks and compresses the refrigerant while reciprocating linearly in the cylinder.

In Korean Patent Laid-Open Publication No. 10-2010-0083652 (published on July 22, 2010), which is a prior art document, a reciprocating compressor is disclosed.

The reciprocating compressor of the prior art includes a case having a closed space formed therein, a driving part provided in the case to generate a rotating force, and a connecting rod coupled to the rotating shaft of the driving motor, And a compression mechanism for converting the refrigerant into a linear reciprocating motion of the piston to be positioned.

The reciprocating compressor requires oil supply for lubrication of the compression mechanism section and the drive section.

Oil for lubrication and cooling of the electromotive portion and the compression mechanism is stored in a bottom portion of the case, and an oil passage is formed in the rotation shaft.

The lower end of the rotary shaft is provided with an oil feeder for pumping up the oil stored in the bottom of the case to the oil passage in the rotary shaft.

The oil feeder is formed in a screw shape so that the oil is transported upward along the outer circumferential surface of the oil feeder during the rotation of the rotary shaft and scattered by the centrifugal force when the rotary shaft is rotated to be supplied into the piston and the cylinder.

However, according to the prior art, the oil can smoothly flow along the outer circumferential surface of the oil feeder during high-speed operation, but the oil does not flow smoothly along the outer circumferential surface of the oil feeder at low speed operation.

In this case, there is a problem in that the lubrication at the friction portion such as the piston and the rotary shaft is not smooth, resulting in abrasion of the friction portion.

An object of the present invention is to provide a reciprocating compressor capable of maintaining the amount of oil pumped even at a low-speed operation, and capable of lubrication at a friction portion.

It is also an object of the present invention to provide a reciprocating compressor in which noises due to vibration of the oil supply mechanism can be prevented during high-speed operation.

It is also an object of the present invention to provide a reciprocating compressor in which assembly of the oil supply mechanism is simplified.

The reciprocating compressor of the present invention includes a rotary shaft rotated for refrigerant compression and an oil supply mechanism connected to the rotary shaft to supply the refrigerant stored in the shell to the rotary shaft. The oil supply mechanism may include a gear portion connected to the rotation shaft and rotating together with the rotation shaft to pump the oil, and a case accommodating the gear portion. Therefore, the oil can be smoothly pumped by the gear portion not only during high-speed operation but also during low-speed operation.

Further, in the reciprocating compressor of the present invention, the oil supply mechanism can be fixed to the supporter that supports the mover of the driving portion by using the fixed portion. At this time, since the fixing portion supports the bottom surface and the side surface of the case, deflection and rotation of the oil supply mechanism can be prevented, and vibration of the oil supply mechanism can be reduced.

Further, in the reciprocating compressor of the present invention, since the shaft connecting portion of the inner gear constituting the gear portion is inserted into the rotary shaft, the assembly of the oil supply mechanism can be facilitated.

Further, in the reciprocating compressor of the present invention, as the case is press-fitted into the cover for covering the gear portion, the assembly of the oil supply mechanism can be facilitated.

Further, in the reciprocating compressor of the present invention, since the wire-shaped fixing portion is fixed to the supporter in a state of supporting the case, assembly of the oil supply mechanism can be facilitated.

According to the proposed invention, since the gear portion connected to the rotary shaft pumps the oil using a plurality of oil chambers, the oil can be stably supplied into the rotary shaft not only in the high speed operation but also in the low speed operation. Therefore, the oil can be stably supplied to the friction portion where lubrication is required.

In addition, according to the present invention, since the oil supply mechanism connected to the rotary shaft is prevented from being bent downward by the fixed portion, and horizontal movement and rotation are prevented, vibration of the oil supply mechanism and thus noises are minimized .

Further, according to the present invention, since a part of the oil supply mechanism is fitted to the rotary shaft, and the case and the cover are press-fitted, the oil supply mechanism can be easily assembled and coupled.

In addition, since the wire-like fixing portion is coupled to the coupling portion of the supporter in a state of supporting the oil supply mechanism, there is an advantage that the user can easily fix the oil supply mechanism.

1 is a longitudinal sectional view of a reciprocating compressor according to an embodiment of the present invention;
2 is a perspective view showing a state in which the oil supply mechanism of the present invention is supported by a supporter on a supporter;
3 is a cross-sectional view showing a state in which the oil supply mechanism is supported by the supporter on the supporter;
4 is a perspective view of the oil supply mechanism of the present invention.
Fig. 5 is an exploded perspective view of the oil supply mechanism of Fig. 4; Fig.
6 is a plan view of a gear portion of the present invention.
7 is a perspective view schematically showing a state in which oil flows by the oil supply mechanism of the present invention;
8 is a plan view illustrating a process of pumping oil in the gear portion of the present invention.

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

1 is a longitudinal sectional view of a reciprocating compressor according to an embodiment of the present invention.

1, a reciprocating compressor 1 according to an embodiment of the present invention includes a shell 10 forming a closed internal space, a driving unit 20 installed inside the shell 10, And a compression mechanism 30 that receives the driving force of the driving unit 20 and compresses the refrigerant.

The driving unit 20 includes a stator 21, a rotor 22 rotatably installed inside the stator 21, and a rotor 22 coupled to the center of the rotor 22, And a rotation shaft 24 for transmitting the rotation of the rotating shaft 30 to the rotating shaft 24.

The rotation shaft 24 may have a fin 25 formed thereon. The fin 25 is eccentrically formed so as to have a constant amount of eccentricity from the center of the rotation shaft 24.

The compression mechanism 30 includes a frame 31 having a cylinder 32, a piston 34 reciprocating linearly in a compression space V1 in the cylinder 32, To the piston (34).

The frame 31 may be elastically supported by a support spring 50 supported by the shell 10.

The connecting rod 33 converts the rotational motion of the rotational shaft 24 into a linear motion of the piston 34.

The connecting rod 33 includes a piston connecting portion 332 rotatably connected to the piston 34, a rod portion 334 extending from the piston connecting portion 332, And a shaft connecting portion 336 formed on the fin portion 25 and coupled to the pin portion 25.

The piston connecting portion 332 may be rotatably connected to the piston 34 by a pin 338 passing through the piston 34 and the piston connecting portion 332 up and down.

The pin 25 of the rotating shaft 24 can be inserted into the shaft connecting portion 336 and rotated about the shaft connecting portion 336.

The frame 31 may include a bearing portion 310 through which the rotation shaft 24 passes. At least a portion of the bearing portion 310 may be inserted into the rotor 22.

The compression mechanism 30 includes a valve assembly 36 arranged to cover the compression space V1 of the cylinder 32, a suction muffler 38 provided on the suction side of the valve assembly 36, And a discharge cover (37) covering the discharge side of the valve assembly (36).

Although not shown, the valve assembly 36 may be provided with a suction valve and a discharge valve.

The suction muffler 38 serves to reduce noise during the suction of the refrigerant. The refrigerant flowing through the suction muffler 38 may be introduced into the compression space V1 by opening the suction valve. The suction muffler 38 can communicate with a suction pipe (not shown).

The refrigerant introduced into the compression space V1 is compressed by the piston 34 and then discharged to the discharge space V2 formed in the discharge cover 37 by opening the discharge valve.

The refrigerant discharged into the discharge space V2 is discharged to the outside of the shell 10 through the discharge pipe 39 after passing through the discharge muffler (not shown).

In order to compress the refrigerant in the compression space V1, the rotary shaft 24 is rotated in the bearing portion 310 of the frame 31, and the fin portion 25 is rotated relative to the shaft connecting portion 336 .

Further, in order to compress the refrigerant in the compression space (V1), the piston (34) linearly moves in the cylinder (32).

Therefore, oil for lubrication must be supplied to the friction region between the relative moving parts so that friction between the relative moving parts is prevented.

For this purpose, the oil may be stored in the shell 10 at a certain level.

An oil supply mechanism 40 for supplying the oil stored in the shell 10 to the friction portion may be connected to the rotary shaft 24.

In addition, a plurality of oil passages 242, 244, and 246 for allowing oil to flow may be formed on the rotary shaft 24. [

The plurality of oil passages 242, 244 and 246 may include a first oil passage 242 for allowing the oil to flow in the axial direction within the rotary shaft 24.

And may be discharged to the upper portion of the rotary shaft 24 after being lifted along the rotary shaft 24 of the oil by the first oil passage 242 and scattered.

The oil that has been discharged to the upper portion of the rotary shaft 24 and is scattered can be supplied into the cylinder 32.

The plurality of oil passages 242, 244 and 246 may include a second oil passage 244 extending spirally along the outer circumferential surface of the rotary shaft 24. The second oil passage 244 may communicate with the first oil passage 242.

The oil introduced into the second oil passage 242 lubricates between the outer circumferential surface of the rotary shaft 24 and the inner circumferential surface of the bearing portion 310.

The plurality of oil passages 242, 244 and 246 may include a third oil passage 246 communicating with the second oil passage 244 and extending along the fin 25.

The oil flowing along the third oil passage (246) may be discharged into the shaft connecting portion (336) and scattered. Therefore, lubrication between the shaft connecting portion 336 and the fin portion 25 becomes possible.

A part of the oil discharged into the shaft connecting portion 336 and scattered may be supplied into the cylinder 32 along the connecting rod 33.

The oil supply mechanism 40 may be inserted through an opening 241 formed at the lower end of the rotary shaft 24.

The oil supply mechanism 40 draws the oil stored in the shell 10 into the first oil passage 242 of the rotary shaft 24 during the rotation of the rotary shaft 24.

Hereinafter, the structure of the oil supply mechanism 40 will be described.

FIG. 2 is a perspective view showing a state in which the oil supply mechanism of the present invention is supported by the fixing unit by the fixing unit, and FIG. 3 is a sectional view showing the state in which the oil supply mechanism is supported by the fixing unit on the supporter.

FIG. 4 is a perspective view of the oil supply mechanism of the present invention, FIG. 5 is an exploded perspective view of the oil supply mechanism of FIG. 4, and FIG. 6 is a plan view of the gear portion of the present invention.

2 to 6, the oil supply mechanism 40 of the present invention includes a case 410, oil guides 420 and 430 that are seated on the case 410 and guide the flow of the oil, And gear portions 440 and 450 connected to the rotation shaft 24 and rotated.

At least a portion of the case 410 may be submerged in the oil stored in the shell 10.

The case 410 may include a first case 411 having an opened bottom and a second case 413 having a larger diameter or width than the first case 411.

The second case 413 may be positioned above the first case 411.

For example, the first case 411 and the second case 413 may be formed in a cylindrical shape.

A step 415 is formed between the upper end of the first case 411 and the lower end of the second case 413 due to the difference in diameter between the first case 411 and the second case 413 .

The step 415 may include at least one fixing protrusion 417 coupled to the oil guides 420 and 430 to prevent the oil guides 420 and 430 from rotating.

The one or more fixing protrusions 417 may be spaced apart from the inner circumferential surface of the second case 413 and protrude upward from the stepped portion 415.

A plurality of fixing protrusions 417 may be provided in the stepped portion 415 so that the effect of preventing rotation of the oil guides 420 and 430 is increased.

The oil guides 420 and 430 may include a first guide 420 and a second guide 430.

The first guide 420 may be formed in a disc shape and may be seated in the stepped portion 415. For this, the outer diameter of the first guide 420 may be smaller than the inner diameter of the second case 413.

The height of the first guide 420 may be lower than the height of the second case 413.

The first guide 420 may be formed with a first inlet slot 422 for guiding the oil drawn into the first case 411.

The first inlet slot 422 may be formed in an arc shape, for example, and may be formed to pass through the first guide 420 vertically.

The first inlet slot 422 may be disposed so as to overlap with an inner space of the first case 411. Therefore, oil in the first case 411 can be drawn into the first inflow slot 422.

In addition, the first guide 420 may have at least one first projection hole 424 through which the at least one fixing protrusion 417 passes.

The second guide 430 may be formed in a disc shape and may be seated on the upper surface of the first guide 420. For this, the outer diameter of the second guide 430 may be smaller than the inner diameter of the second case 413.

The height of the second guide 430 may be lower than the height of the second case 413. The sum of the heights of the first guide 420 and the second guide 430 may be lower than the height of the second case 413.

A second inlet slot 432 may be formed in the second guide 430. The second inlet slot 432 may be formed in an arc shape, for example, and may be formed to pass through the second guide 430 vertically.

In addition, the second inflow slot 432 is vertically aligned with the first inflow slot 422. Thus, the oil drawn into the first inlet slot 422 may flow into the second inlet slot 432.

The oil introduced into the second inlet slot 432 may be supplied to the gear portions 440 and 450.

In addition, the second guide 430 may have at least one second projection hole 438 through which the at least one fixing protrusion 417 passes.

The gears 440 and 450 may be seated on the upper surface of the second guide 430.

The sum of the heights of the first guide 420, the second guide 430 and the gears 440 and 450 may be equal to or less than the height of the second case 413.

The gear portions 440 and 450 include an outer gear 440 having a gear 442 formed on an inner circumferential surface thereof and an inner gear 440 having a gear 452 formed inside the outer gear 440, 450).

The center C1 of the outer gear 440 is eccentric with the center C2 of the inner gear 450 while the inner gear 450 is received in the outer gear 440.

The gear teeth 452 of the inner gear 450 and the gear teeth 432 of the outer gear 440 are not completely engaged when the inner gear 450 is housed in the outer gear 440.

Therefore, a plurality of predetermined chambers 460 are formed between the outer peripheral surface of the inner gear 450 and the inner peripheral surface of the outer gear 440. Wherein the chamber 460 provides a space for the oil to be pumped.

Therefore, when the gears 440 and 450 are rotated in a state where the oil flows into the plurality of chambers 460, the oil can be pumped by the rotational pressure.

An axial coupling portion 454 for coupling with the rotary shaft 24 is formed on the upper surface of the inner gear 450. The shaft coupling portion 454 may be press-fitted into the lower side of the rotary shaft 24, for example.

The oil supply passage 456 is formed so as to pass through the shaft coupling portion 454 vertically.

The second guide 430 has a first discharge slot 434 through which the oil pumped by the gears 440 and 450 is discharged. The first discharge slot 434 is not limited, but may be formed in an arc shape.

The first discharge slot 434 is formed to pass through the second guide 430 vertically.

The second guide 430 may further include a second discharge slot 436 for guiding the oil discharged into the first discharge slot 434 to the oil supply passage 456.

The second discharge slot 436 may extend toward the center of the guide 430 in the first discharge slot 434. Or the second outlet slot 436 may extend from the first outlet slot 434 toward the second inlet slot 432.

However, the second discharge slot 436 is spaced apart from the second discharge slot 432.

The second discharge slot 436 may be formed to penetrate the second guide 430 vertically.

The first discharge slot 434 and the second discharge slot 436 may be connected to the second guide 434 to guide the oil pumped from the gear portions 440 and 450 to the oil supply passage 454. [ 430 may be formed to be depressed downward from the upper surface.

The oil supply mechanism may further include a cover 470 for covering the gear portions 440 and 450 received in the case 410.

The cover 470 may include a side cover 471 surrounding the second case 413 and a top cover 472 covering the upper side of the gears 440 and 450.

The second case 413 may be coupled to the side cover 471 by press fitting. Therefore, there is an advantage that a separate fastening means for joining the case 410 and the cover 470 is unnecessary.

The upper surface cover 472 may have a hole 475 through which the shaft coupling portion 454 passes.

The oil supply mechanism 40 may be fixed in position by the fixed portion 60 while the oil supply mechanism 40 is connected to the rotation shaft 24. [

The fixing portion 60 is provided on the side of the oil supply mechanism 40 to prevent (prevent sagging) the oil supply mechanism 40 from moving in the extending direction of the rotary shaft 24 The lower side can be supported.

The fixing portion 60 may be coupled to at least two portions of the side surface of the oil supply mechanism 40 to prevent rotation of the case 410 and the cover 470.

The fixing portion 60 may be fixed to the supporter 26 supporting the stator 21 while supporting the oil supply mechanism 40.

Specifically, the supporter 26 includes a support body 262, a plurality of extending portions 264 extending in the inner radial direction from the inner circumferential surface of the support body 262, And may include a plurality of engaging portions 266 extending in an outer radial direction.

The rotation shaft 24 may penetrate a region formed by the plurality of extending portions 264. [

The fixing portion 60 may be formed in a wire shape and the both ends of the fixing portion 60 may be connected to each of the plurality of engaging portions 266 in a state in which the lower portion of the oil supplying mechanism 40 is supported. Can be combined.

The plurality of engaging portions 266 may include a receiving slot 267 in which the securing portion 60 is received and an engaging groove 268 in which the end portion of the securing portion 60 is engaged.

The receiving slot 267 may be formed at a side end portion of each of the engaging portions 266 and the engaging groove 268 may be recessed downward from the lower surface of the engaging portions 266.

The fixing portion 60 includes a first fixing portion 602 fitted to the case 410, a pair of second fixing portions 604 fitted to the cover 470, And a third fixing part 606 coupled to the second fixing part 266.

The first fixing part 602 may extend in the horizontal direction and the case 410 may have a first slot 412 in which the first fixing part 602 is inserted. The first slot 412 may be formed on a lower surface of the first case 411.

The first fixing portion 602 serves to prevent the oil supply mechanism 40 from being sagged downward.

The pair of second fixing portions 604 extend upward from both ends of the first fixing portion 602, respectively. The cover 470 may be provided with a plurality of second slots 473 through which the second fixing portions 604 are inserted.

Each of the second slots 473 may extend vertically in the cover 470. The pair of second fixing portions 604 are horizontally spaced apart from each other while being fitted in the second slot 473 of the cover 470.

Therefore, the pair of second fixing portions 604 prevent the cover 470 from being rotated. When rotation of the cover 470 is prevented, rotation of the case 410 coupled with the cover 470 can be prevented.

When rotation of the case 410 is prevented, rotation of the oil guides 420 and 430 is prevented.

In addition, the pair of second fixing portions 604 prevents the cover 470 from moving in the horizontal direction.

When the rotation of the cover 470, the case 410 and the oil guides 420 and 430 is prevented, the rotation of the gears 440 and 450 causes the inflow slots 422 and 432 and the discharge The positions of the slots 434 and 436 are not changed. Therefore, the oil can be stably supplied to the rotary shaft 24.

Each of the plurality of third fixing portions 606 extends in a direction away from the upper end of each of the second fixing portions 604. [

At this time, each of the third fixing portions 606 may extend in the horizontal direction in the second fixing portion 604 and may extend upward.

The upper end of each of the third fixing parts 606 may be provided with a locking part 608 extending in a direction approaching each other and seated in the locking groove 268.

FIG. 7 is a perspective view schematically showing how oil flows by the oil supply mechanism of the present invention, and FIG. 8 is a plan view illustrating a process of pumping oil in the gear portion of the present invention.

The process of pumping oil by the oil supply mechanism 40 will be described with reference to FIGS. 1 to 8. FIG.

First, when the rotary shaft 24 is rotated by the driving unit 20, the oil located in the case 410 passes through the first inlet slot 422 and the second inlet slot 432, 440 and the inner gear 450. In this case,

At this time, since the case 410 is immersed in the oil stored in the shell 10, the case 410 is filled with oil.

A filter (not shown) may be provided upstream of the first inlet slot 422 so that foreign matter contained in the oil is filtered before the oil enters the first inlet slot 422.

The filter may be positioned below the first inlet slot 422 in the first case 411, although not limited thereto.

Alternatively, the filter may be formed in the form of a disk, is seated on the step 415 of the case 410, and the first guide 420 may be seated on the upper surface of the filter.

Alternatively, the filter may be disposed so as to surround the first case 411. In this case, the filter may be provided with a slot through which the fixing portion 60 is inserted.

The inner gear 450 and the outer gear 440 are rotated by the rotation of the rotating shaft 24. [

When the inner gear 450 coupled with the rotary shaft 24 is rotated together with the rotary shaft 24, the gear teeth 452 of the inner gear 450 are engaged with the teeth 442 of the outer gear 440 ). The outer gear 440 is rotated together with the rotation of the inner gear 450.

When the gears 440 and 450 are rotated at a predetermined angle, the oil in the plurality of chambers 460 moves toward the first discharge slot 434. And, when at least one chamber 60 in which the oil is received is aligned up and down with the first discharge slot 434, oil is dropped into the first discharge slot 434 in the chamber 60.

The oil dropped into the first discharge slot 434 flows along the second discharge slot 436 and then is supplied into the rotary shaft 24 along the oil supply passage 456 in the inner gear 450 do.

According to the proposed invention, since the gear portion connected to the rotary shaft pumps the oil using a plurality of oil chambers, the oil can be stably supplied into the rotary shaft not only in the high speed operation but also in the low speed operation. Therefore, the oil can be stably supplied to the friction portion where lubrication is required.

Further, according to the present invention, since the oil supply mechanism connected to the rotary shaft is prevented from being sagged downward by the fixed portion, and horizontal movement and rotation are prevented, vibration of the oil supply mechanism is minimized during high- Can be minimized.

Further, according to the present invention, since a part of the oil supply mechanism is fitted to the rotary shaft, and the case and the cover are press-fitted, the oil supply mechanism can be easily assembled and coupled.

In addition, since the wire-like fixing portion is coupled to the coupling portion of the supporter in a state of supporting the oil supply mechanism, there is an advantage that the user can easily fix the oil supply mechanism.

In the above embodiment, the plurality of guides 420 and 430 guide the flow of oil. Alternatively, it is also possible to guide the flow of oil using one oil guide.

For example, an inflow slot may be formed in the oil guide so as to penetrate up and down. The first discharge slot and the second discharge slot may be formed to be depressed downward from the upper surface of the oil guide.

In the above embodiment, the oil supply mechanism is supported by using a single fixing portion, but it is also possible to support the oil supply mechanism using a wire-shaped fixing portion.

For example, one end of each of the plurality of fixing portions may be coupled to the supporter, and the other end may be hooked to the lower end of the case.

As another example, it is possible to support the oil supply mechanism using a leaf spring without using a wire-shaped fixing portion.

For example, the upper end portions of the plurality of leaf springs can support the stepped portion of the case, and the lower end portions can be fixed to the bottom surface of the shell. It is preferable that the plurality of leaf springs contact the side surface of the case to prevent rotation of the oil supply mechanism.

10: shell 20:
30: compression mechanism section 40: oil supply mechanism
60:

Claims (13)

A shell forming an enclosed space and storing oil therein;
A driving unit provided in the shell and including a rotating shaft, a rotor connected to the rotating shaft, and a stator disposed outside the rotor;
A compression mechanism connected to the rotary shaft for compressing the refrigerant;
An oil supply mechanism connected to the rotary shaft to supply the refrigerant stored in the shell to the rotary shaft; And
And a fixing portion for supporting the oil supply mechanism,
The oil supply mechanism includes a gear portion connected to the rotation shaft and rotating together with the rotation shaft to pump the oil, and a case accommodating the gear portion,
And the fixing portion supports the case. The method according to claim 1,
Further comprising a supporter for supporting a lower side of the stator,
Wherein the fixing portion is fixed to the supporter while supporting the case. 3. The method of claim 2,
Wherein the fixing portion is formed in a wire shape and is coupled to the supporter in a state of being fitted to a lower surface and a side surface of the oil supply mechanism. The method of claim 3,
Wherein the fixing portion includes a first fixing portion fitted to a lower surface of the oil supply mechanism,
A pair of second fixing portions extending upward from an end of the first fixing portion,
And a pair of third fixing portions extending in directions away from each other at the pair of second fixing portions and coupled to the supporter. 5. The method of claim 4,
Wherein the supporter includes a plurality of engaging portions to which the pair of third securing portions are engaged,
Wherein each of the plurality of engaging portions includes a slot in which each of the third engaging portions is fitted and a retaining groove in which the engaging portion formed in an end of each of the third fixing portions is engaged. The method according to claim 1,
The oil supply mechanism includes a case,
An oil guide accommodated in the case and guiding the flow of the oil,
And a cover that covers the gear portion that is seated on the oil guide. The method according to claim 6,
The case includes a first case,
A second case having a larger diameter than the first case,
And a stepped portion formed between the first case and the second case,
And the oil guide is seated on the stepped portion. The method according to claim 6,
The oil guide includes a first guide having a first inflow slot for guiding oil in the first case,
And a second guide that is seated above the first guide,
The second guide includes the second inflow slot aligned with the first inflow slot and a discharge slot for guiding the oil discharged from the gear portion to the rotation axis. 9. The method of claim 8,
Wherein the first inlet slot and the second inlet slot are formed in an arc shape,
The discharge slot includes a first discharge slot formed in an arc shape,
And a second discharge slot extending from the first discharge slot toward the second inlet slot. 8. The method of claim 7,
Wherein the oil guide includes an inlet slot for guiding the oil in the first case to the gear portion side and a discharge slot for guiding the oil pumped in the gear portion to the rotary shaft. 8. The method of claim 7,
Wherein at least one fixing protrusion for preventing rotation of the oil guide is provided in the stepped portion,
Wherein the oil guide is provided with at least one protrusion hole for receiving the at least one fixing protrusion. The method according to claim 6,
A first slot in which the fixing part is fitted is formed on a lower surface of the case,
And a plurality of second slots extending in a vertical direction are formed on a side surface of the cover in order to fit the fixing portion. 11. The method according to claim 8 or 10,
The gear portion includes an outer gear,
And an inner gear accommodated in the outer gear,
Wherein the inner gear includes a shaft connecting portion for connecting to the rotating shaft,
And an oil supply passage for guiding the refrigerant flowing along the discharge slot to the rotation shaft is formed in the shaft connection portion.

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