KR20090102081A - Scroll type compressor - Google Patents

Abstract

PURPOSE: A scroll compressor is provided to supply proper amount of oil to the inside of housing and improve the lubrication and efficiency of the compressor. CONSTITUTION: A scroll compressor comprises a housing of compressor (100), rotation shaft (170), turning scroll (300), fixation scroll (400), and oil separator (190). The housing of compressor comprises a refrigerant inhalation room (130) and refrigerant exhausting room (140). A bearing at the housing of compressor is installed at one side of the rotation shaft. A main frame (160) is rotatably installed at the other end of the rotation shaft. The turning scroll is installed inside the housing of compressor and is coupled to a driving pin (180). The fixation scroll pressurizes refrigerant by coupling to the turning scroll.

Description

Scroll compressor {Scroll type compressor}

The present invention relates to a scroll compressor, and more particularly, to a scroll compressor in which an oil flow path is formed.

In general, the compressor applied to the refrigeration air conditioner is developed and used in the compressor of various operation methods according to the operation method, it is divided into reciprocating, rotary and scroll compressor according to the operation method.

Here, the reciprocating compressor is a compressor in which a piston reciprocates in a cylinder and sucks, compresses, and discharges a working fluid, that is, a refrigerant, and a rotary compressor is a compressor in which a compressor rotates while a rotor rotates in a cylinder. .

On the other hand, the scroll compressor is a compressor in which the refrigerant is sucked, compressed and discharged while the scroll formed between the fixed scroll and the swing scroll rotates once.

Hereinafter, a scroll compressor according to the prior art will be described with reference to FIGS. 1 and 2.

1 is a cross-sectional view showing a scroll compressor according to the prior art, Figure 2 is an enlarged cross-sectional view showing a portion A of FIG.

As shown in FIG. 1, the scroll compressor according to the related art has a housing 10 in which a refrigerant suction chamber 13 and a refrigerant discharge chamber 14 are formed, and one end thereof is installed through a bearing in the housing 10. And the other side is a rotation shaft 16 rotatably installed on the main frame 15 coupled to the inside of the housing 10, and a driving pin installed inside the housing 10 and installed at the tip of the rotation shaft 16. A swing scroll 18 coupled to the swing scroll 18, a fixed scroll 19 mounted inside the housing 10 and coupled to the swing scroll 18 to compress the refrigerant, and installed in the refrigerant discharge chamber 14. And an oil separator 20 for separating oil from the refrigerant compressed to high pressure in the turning scroll 18 and the fixed scroll 19.

On the other hand, the housing 10 is composed of a front housing 11 and the rear housing 12, the rear housing 12 is provided with a refrigerant suction chamber 13, and the inner main surface of the front housing 11 and The refrigerant discharge chamber 14 is provided between the fixed scrolls 19.

In addition, in the housing 10, the motor 21 for rotating the rotation shaft 16 from the rear, the main frame 15, the thrust bearing 22, the turning scroll 18, and the fixed scroll 19 are ordered. Are placed as.

Here, the rotation shaft 16, the rotation is supported freely by a bearing provided in the main frame 15 and the rear housing 12, the drive pin 17 eccentrically by a predetermined amount relative to the center of the shaft at its front end It is installed, the rotating scroll 18 is coupled to the drive pin (17).

On the other hand, both the rotating shaft 16 and the driving pin 17 is a hollow formed with a refrigerant passage through which the refrigerant passes, and the refrigerant flowing into the refrigerant suction chamber 13 is provided in front of the driving pin 17 Supply to the scroll 18 and the fixed scroll (19).

In addition, the fixed scroll 19 is coupled to the swinging scroll 18 coupled to the driving pin 17 of the rotating shaft 16. The surface of the rotating scroll 18 and the fixed scroll 19 is formed of a refrigerant. To realize the compression effect, the vortex wraps are formed to protrude from each other.

Accordingly, the refrigerant is compressed to high pressure between the fixed scroll 19 and the wrap of the swing scroll 18 as the swing scroll 18 rotates.

On the other hand, since the swinging scroll 18 receives a strong thrust load when compressing the refrigerant, the rear surface of the swinging scroll 18, i.e., to obtain a smooth swinging movement of the swinging scroll 18 while supporting the thrust load, A thrust bearing 22 is interposed between the main frame 15 and the surface opposite to the surface on which the wrap is formed.

In addition, a discharge hole (not shown) is formed in the fixed scroll 19 to discharge the refrigerant compressed in the center of the refrigerant discharge chamber 14, and a discharge valve is formed in the discharge hole of the fixed scroll 19. 23) is installed to prevent backflow of refrigerant.

In the vicinity of the discharge valve 23, an oil passage 24 for supplying the oil separated from the oil separator 20 to each of the driving parts disposed in the housing 10 is illustrated in FIG. As it is, it is formed to penetrate from the front to the rear of the fixed scroll (19).

The fixed scroll (19) is installed in contact with the anti-rotation portion 25 for preventing the rotation, the oil passing through the oil passage 24, the housing 10 along the through hole (26) formed in the main frame (15) Is supplied to each drive part arranged in the

Hereinafter, a process of compressing a refrigerant in the scroll compressor of the related art will be briefly described with reference to FIG. 1.

When the motor 21 is driven through an external control device, the rotating shaft 16 rotates, and the refrigerant flows into the housing 10 from the suction port (not shown).

The refrigerant that has reached the refrigerant suction chamber 13 is compressed at high pressure between the lap of the swing scroll 18 and the lap of the fixed scroll 19 as the swing scroll 18 revolves.

The compressed high pressure refrigerant is discharged to the refrigerant discharge chamber 14 through the discharge valve 23 of the fixed scroll 19 and then discharged to the refrigerant pipe connected to the condenser of the cooling cycle through the refrigerant discharge pipe 27.

On the other hand, in the scroll compressor according to the prior art described above, after separating the oil contained in the refrigerant discharged into the refrigerant discharge chamber 14 through the oil separator 20, the separated oil of the fixed scroll (19) It is supplied into the housing 10 through the oil passage 24 to lubricate the driving parts.

However, when the diameter of the oil passage 24 is greater than or equal to a predetermined value, the efficiency of the compressor is reduced due to the excessive supply of oil. Therefore, in order to prevent this, the necessity of processing the diameter of the oil passage 24 finely is necessary. Although raised, there was a problem that the microhole processing was not easy.

An object of the present invention is to solve the above problems, to provide a scroll compressor that can prevent the efficiency of the compressor due to the excessive supply of oil.

In order to achieve the above object, the scroll compressor of the present invention includes a compressor housing having a refrigerant suction chamber and a refrigerant discharge chamber, one end of which is installed through a bearing in the compressor housing, and the other side of the compressor housing. A rotating shaft rotatably installed on the main frame coupled to the rotating frame, a rotating scroll installed inside the compressor housing and coupled to a driving pin formed at the tip of the rotating shaft, and installed inside the compressor housing and coupled to the rotating scroll to provide a refrigerant. A scroll compressor including a fixed scroll for compressing and an oil separator installed in the refrigerant discharge chamber to separate oil from a refrigerant compressed at high pressure in the swing scroll and the fixed scroll, wherein the fixed scroll includes oil separated from an oil separator. Reservoir for feeding oil into the compressor housing Is formed, the oil passage is connected to the first oil inlet of the groove formed inside the wrap of the fixed scroll, the turning scroll has an oil passage for supplying the oil introduced into the first oil inlet toward the rear of the turning scroll Characterized in that formed.

In addition, a tip seal is inserted into the tip seal insertion groove of the fixed scroll, and the tip seal is provided with a first oil outlet for supplying oil to the oil passage of the revolving scroll.

In addition, the first oil outlet is characterized in that formed on the end of the tip seal adjacent to the outer peripheral surface of the fixed scroll.

In addition, the bottom surface of the tip seal insertion groove formed in the fixed scroll is characterized in that the oil groove having a step with the tip seal insertion groove is formed.

The oil groove may be formed such that the first oil inlet communicates with the first oil outlet.

In addition, the oil passage formed in the turning scroll is composed of a second oil inlet formed on the front surface and the rear surface facing the fixed scroll and the second oil outlet which is connected to the second oil inlet, the rear surface It characterized in that the oil discharge groove connected to the second oil discharge port is formed.

In addition, the second oil inlet formed in the turning scroll is formed on the turning scroll surface is formed wrap, characterized in that formed in a position close to the outer peripheral surface.

In addition, the oil passage formed in the turning scroll comprises a second oil inlet formed on the front surface facing the fixed scroll and the rear surface thereof and a second oil outlet connected to the second oil inlet, the second The oil inlet is characterized in that it is in communication with the first oil outlet formed in the tip seal of the fixed scroll intermittently during the swinging movement of the swinging scroll.

According to the scroll compressor according to the present invention, as the oil is intermittently supplied into the compressor housing according to the swinging movement of the swing scroll, only an appropriate amount of oil can be supplied into the housing, thereby improving the lubricity and efficiency of the compressor. There is.

In addition, the oil flowing into the groove of the fixed scroll wrap from the refrigerant discharge chamber via the oil passage to raise the tip seal, thereby increasing the sealing effect between the fixed scroll and the swing scroll to improve the efficiency of the compressor.

1 is a cross-sectional view showing a scroll compressor according to the prior art.

FIG. 2 is an enlarged cross-sectional view of a portion A of FIG. 1. FIG.

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

4 is an enlarged cross-sectional view of a portion B of FIG. 3.

5 is a front view showing a fixed scroll according to an embodiment of the present invention.

Figure 6 is an exploded perspective view showing a fixed scroll and the tip seal in accordance with an embodiment of the present invention.

7 is a perspective view showing the front surface of the swing scroll according to an embodiment of the present invention.

8 is a perspective view showing a rear surface of the revolving scroll according to the embodiment of the present invention.

*** Explanation of symbols for the main parts of the drawing ***

100: compressor housing 110: front housing

120: rear housing 130: refrigerant suction chamber

140: refrigerant discharge chamber 160: mainframe

170: rotating shaft 180: drive pin

190: oil separator 200: thrust bearing

210: anti-rotation unit 220: discharge valve

230: refrigerant discharge pipe 240: oil passage

250: oil filter 260: motor

300: turning scroll 310: lap

320: tip seal 330: tip seal insertion groove

340: second oil inlet 350: second oil outlet

360: oil discharge groove 400: fixed scroll

410: wrap 420: tip seal

430: tip seal insertion groove 431: oil groove

440: first oil inlet 450: first oil outlet

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

3 is a cross-sectional view showing a scroll compressor according to an embodiment of the present invention, Figure 4 is an enlarged cross-sectional view showing part B of Figure 3, Figure 5 is a front view showing a fixed scroll according to an embodiment of the present invention, 6 is an exploded perspective view showing a fixed scroll and a tip seal according to an embodiment of the present invention, Figure 7 is a perspective view showing a front surface of the swing scroll according to an embodiment of the present invention, Figure 8 is a swing scroll according to an embodiment of the present invention A perspective view showing the rear side of the.

Scroll compressor according to an embodiment of the present invention, as shown in Figure 3, the compressor housing 100, one end is installed through the bearing in the compressor housing 100 and the other side is the compressor housing 100 The rotating shaft 170 is rotatably installed on the main frame 160 coupled to the inside of the motor, the motor 260 for driving the rotating shaft 170, and installed inside the compressor housing 100 and the rotating shaft ( 170) a rotating scroll 300 coupled to the driving pin 180 formed at the front end, a fixed scroll 400 installed inside the compressor housing 100 and coupled to the turning scroll 300 to compress the refrigerant; It is installed in the refrigerant discharge chamber 140 comprises an oil separator 190 for separating the oil from the refrigerant compressed to high pressure in the rotating scroll 300 and the fixed scroll (400).

On the other hand, the compressor housing 100 is composed of a front housing 110 and a rear housing 120, the rear housing 120 is provided with a refrigerant suction chamber 130, the inner main surface of the front housing 110 The refrigerant discharge chamber 140 is provided between the fixed scroll 400 and the fixed scroll 400.

In addition, the fixed scroll 400 is coupled to the front surface of the turning scroll 300 coupled to the driving pin 180 of the rotating shaft 170, and the surfaces of the turning scroll 300 and the fixed scroll 400 face each other. The vortex wraps 310 and 410 are formed to protrude, respectively, and the tip seal insertion grooves 330 and 430 in which the tip seals 320 and 420 are installed are formed inside the wraps 310 and 410.

In addition, the compressor housing 100, the anti-rotation unit 210 for preventing the rotation of the thrust bearing 200 and the rotating scroll 300 in order to support the strong thrust load acting on the rotating scroll 300 to revolve ) Is interposed, the anti-rotation unit 210 may be applied, such as old dam ring.

In the scroll compressor according to an embodiment of the present invention, the compressor housing 100, the motor 260, the main frame 160, the rotating shaft 170, the turning scroll 300, the fixed scroll 400, the thrust bearing ( 200), the anti-rotation unit 210 and the oil separator 190 and the like are the same as the prior art, detailed description of the above configuration will be omitted below.

In addition, the compression process of the refrigerant flowing in the compressor is also the same as in the prior art, it will be omitted below.

On the other hand, the present invention is characterized in the feedback structure of the oil flowing in the compressor housing 100 in order to lubricate parts such as the thrust bearing 200 and the anti-rotation unit 210 is installed in the compressor housing 100, Hereinafter, the lubrication structure of the oil flowing in the compressor housing will be described in detail.

In the embodiment of the present invention, the fixed scroll 400 is formed with a discharge hole (not shown) for discharging the refrigerant compressed in the center to the refrigerant discharge chamber 140, the discharge of the fixed scroll 400 The discharge valve 220 is installed in the ball (not shown) to prevent the backflow of the refrigerant.

On the other hand, the refrigerant discharged into the refrigerant discharge chamber 140, the oil is separated through the oil separator 190, the pure refrigerant separated oil is a refrigerant discharge pipe 230 connected to the refrigerant discharge chamber 140. It is discharged through the refrigerant pipe connected to the condenser of the cooling cycle.

In addition, the fixed scroll 400 is oil so as to communicate with the tip seal insertion groove 430 formed in the refrigerant discharge chamber 140 and the wrap 410 of the fixed scroll 400, as shown in Figure 3 and 4 A passage 240 is formed.

In an embodiment of the present invention, an oil groove 431 having a step with the tip seal insertion groove 430 may be formed on a bottom surface of the tip seal insertion groove 430, and the oil flowing in the oil groove 431. May increase the flotation force of the tip seal 420.

On the other hand, the diameter of the oil passage 240 is preferably formed below a certain size so that the oil in the refrigerant discharge chamber 140 can be easily introduced into the oil passage 240 due to the pressure difference due to the Bernoulli effect. .

In addition, the oil passage 240 is gradually reduced in diameter toward the turning scroll 300 from the end in communication with the refrigerant discharge chamber 140 so that the flow rate of the oil flowing in the oil passage 240 gradually increases. It is also possible to form.

In addition, the fixed scroll 400 is preferably provided with an oil filter 250 at the inlet side of the oil passage 240, the oil filter 250 is contained in the oil separated from the oil separator 190 It will filter out foreign substances.

On the other hand, the oil separated from the oil separator 190 is supplied into the compressor housing 100 along the oil passage 240 to lubricate driving parts and the like.

Here, the oil passing through the oil passage 240 is specifically supplied into the compressor housing 100 through the fixed scroll 400 and the revolving scroll 300, hereinafter the structure of the fixed scroll and the revolving scroll This will be explained.

5, 7 and 8, the tip seal insertion groove 430 formed inside the wrap 410 of the fixed scroll 400 is in communication with the oil passage 240 to introduce oil. 1 oil inlet 440 is formed, the front surface of the turning scroll 300 in contact with the fixed scroll 400 in the tip seal insertion groove 430 of the fixed scroll 400 when turning the turning scroll 300 A second oil inlet 340 is formed to allow oil to flow therein, and a second oil outlet 350 is formed at a rear surface thereof to communicate with the second oil inlet 340.

On the other hand, the tip seal 420 is inserted into the tip seal insertion groove 430 of the fixed scroll 400, as shown in Figure 6, to form a first oil outlet 450, the fixed scroll 400 The oil flowing in the tip seal insertion groove 430 is introduced into the second oil inlet 340 through the first oil outlet 450.

Here, the oil groove 431 formed on the bottom surface of the tip seal insertion groove 430 is formed such that the first oil inlet 440 and the first oil outlet 450 communicate with each other.

On the other hand, the first oil outlet 450 and the second oil inlet 340 is formed at a position corresponding to each other so as to intermittently communicate during the pivoting movement of the revolving scroll (300).

In addition, the second oil inlet 340 is preferably formed at a position close to the outer circumferential surface of the turning scroll 300 in which the wrap 310 is not formed, the first oil outlet 450, the fixed scroll ( It is preferably formed at the end of the tip seal 420 adjacent to the outer surface of the 400.

Here, the oil discharged through the second oil outlet 350 of the turning scroll 300 lubricates the thrust bearing 200 and the anti-rotation part 210 in the compressor housing 100. The other surface of the scroll 300 may be formed along the circumference of the turning scroll 300 to form an oil discharge groove 360 connected to the second oil outlet 350 to increase its lubrication effect.

Specifically, the oil discharged through the oil discharge groove 360 may properly lubricate or simultaneously lubricate the thrust bearing 200 and the anti-rotation part 210.

Hereinafter, the flow of oil flowing in the compressor housing will be described in detail.

First, the oil separated through the oil separator 190 in the refrigerant discharge chamber 140 is fixed through the oil filter 250 naturally according to the pressure difference between the refrigerant discharge chamber 140 and the oil passage 240. It flows into the oil passage 240 in the scroll 400.

Then, the oil passing through the oil passage 240 flows into the tip seal insertion groove 430 through the first oil inlet 440 formed in the tip seal insertion groove 430 of the fixed scroll 400, and the pressure difference. After flowing through the tip seal insertion groove 430 by the discharge, it is discharged to the first oil outlet 450 of the tip seal 420.

Here, as the oil floats the tip seal 420 installed in the tip seal insertion groove 430 while flowing in the tip seal insertion groove 430 and the oil groove 431, the fixed scroll 400 and the turning scroll ( The effect of improving the adhesion between the 300) occurs.

Subsequently, the oil discharged through the first oil outlet 450 is formed at the moment when the first oil outlet 450 and the second oil inlet 340 communicate with each other during the pivoting movement of the turning scroll 300. 2 is introduced into the oil inlet 340, and is intermittently discharged to the second oil outlet (350).

The oil discharged from the second oil outlet 350 moves along the oil discharge groove 360 as the turning scroll 300 rotates, and thus, the compressor housing near the turning scroll 300. Lubricating the thrust bearing 200 and the anti-rotation unit 210 installed in the (100).

Although the preferred embodiments of the present invention have been described above, the scope of the present invention is not limited to such specific embodiments, and those skilled in the art may appropriately change within the scope described in the claims of the present invention. This will be possible.

Claims (8)

A compressor housing having a refrigerant suction chamber and a refrigerant discharge chamber, one end of which is installed through a bearing in the compressor housing, and the other side of which is rotatably installed in a main frame coupled to the inside of the compressor housing, and inside the compressor housing. A rotating scroll coupled to a driving pin formed at the tip of the rotary shaft, a fixed scroll installed inside the compressor housing and coupled to the rotating scroll to compress a refrigerant, and installed in the refrigerant discharge chamber to be fixed to the rotating scroll. A scroll compressor comprising an oil separator for separating oil from a refrigerant compressed to high pressure in a scroll, The fixed scroll has an oil passage for supplying the oil separated from the oil separator into the compressor housing, wherein the oil passage is connected to the first oil inlet of the tip seal insertion groove formed inside the wrap of the fixed scroll, And the oil passage is formed in the swing scroll to supply oil introduced into the first oil inlet toward the rear side of the swing scroll. The method of claim 1, The tip seal is inserted into the tip seal insertion groove of the fixed scroll, The tip seal is a scroll compressor, characterized in that the first oil outlet for supplying oil to the oil passage of the revolving scroll. The method of claim 2, The first oil discharge port is a scroll compressor, characterized in that formed on the end of the tip seal adjacent to the outer peripheral surface of the fixed scroll. The method of claim 3, The bottom surface of the tip seal insertion groove formed in the fixed scroll scroll compressor, characterized in that the oil groove having a step with the tip seal insertion groove is formed. The method of claim 4, wherein The oil groove is a scroll compressor, characterized in that the first oil inlet and the first oil outlet is formed in communication with each other. The method according to any one of claims 1 to 5, The oil passage formed in the turning scroll comprises a second oil inlet formed on the front face opposite to the fixed scroll and a second oil outlet formed on the rear face thereof and subsequent to the second oil inlet. The rear surface is a scroll compressor, characterized in that the oil discharge groove is connected to the second oil outlet is formed. The method of claim 6, And a second oil inlet formed in the turning scroll is formed on the turning scroll surface on which the wrap is formed, and is formed at a position close to the outer circumferential surface. The method according to any one of claims 1 to 5, The oil passage formed in the turning scroll comprises a second oil inlet formed on the front face opposite to the fixed scroll and a second oil outlet formed on the rear face thereof and subsequent to the second oil inlet. And the second oil inlet communicates with the first oil outlet formed in the tip seal of the fixed scroll intermittently during the swinging movement of the turning scroll.