KR100417423B1 - Structure for feeding oil in scroll compressor - Google Patents

Abstract

The present invention relates to an oil supply structure of a scroll compressor. The present invention relates to a scroll compressor in which a rotating scroll receiving a driving force of an electric mechanism unit is supported by an upper frame and compresses a gas while rotating in engagement with a fixed scroll. Old Daming's key to form a complex oil groove for reducing contact wear and oil supply on the thrust bearing surface of the turning scroll that is in contact with the edge of the boss insertion groove of the upper frame into which the boss is inserted, and preventing the turning scroll from rotating. It is configured to form a communication flow path for communicating the key groove of the rotating scroll and the complex oil groove is inserted into the rotating scroll is engaged with the fixed scroll acts on the rotating scroll in the process of sucking, compressing and discharging the refrigerant while rotating Due to uneven pressure distribution In addition to preventing uneven wear, oil supply is smoothly provided between the thrust bearing surface of the turning scroll and the bearing surface of the upper frame and the key groove into which the keys of the Olddam ring are inserted to smooth the lubrication of parts in which relative movement occurs and to ensure reliability. It is to increase the.

Description

STRUCTURE FOR FEEDING OIL IN SCROLL COMPRESSOR}

The present invention relates to a scroll compressor, and in particular, a scroll compressor that is capable of smoothly supplying oil to a portion of a rotating scroll and a relative movement in which a rotating scroll is engaged with a fixed scroll by receiving a driving force of an electric mechanism, and prevents abrasion. It is about oil supply structure.

Generally, a compressor is a device that compresses a fluid such as refrigerant gas. As an example of the compressor, as shown in FIG. 1, as illustrated in FIG. 1, upper and lower frames 2 and 3 are respectively coupled to a sealed container 1 having a predetermined internal space, and the upper frame 2 And a stator 4 and a rotor 5 constituting the electric mechanism part are mounted between the bottom frame 3 and the bottom frame 3.

The rotating shaft 6 having the eccentric portion 6a formed in the rotor 5 is press-fitted, and the fixed scroll 7 is fixedly coupled to the upper side of the upper frame 2 at predetermined intervals, and the upper frame 2 The swing scroll 8 is inserted between the fixed scroll 7 so that the fixed scroll 7 and the swinging movement are possible. The eccentric portion 6a of the rotating shaft 6 is connected to the swinging scroll 8 and is an anti-rotation mechanism that prevents rotation of the swinging scroll 8 between the swinging scroll 8 and the upper frame 2. 9) is combined.

The fixed scroll (7) is coupled to the high and low pressure separating plate 10 for separating the inside of the sealed container (1) into a high pressure region and a low pressure region, the high and low pressure separation plate 10 and the fixed scroll (7) Gas flow control means 11 for controlling the flow of the refrigerant gas of high temperature and high pressure is coupled between the upper surface. The suction tube 12 and the discharge tube 13 are respectively coupled to the low pressure region and the high pressure region of the hermetic container 1.

And oil is filled in the bottom surface of the airtight container 1, the oil suction means 14 is coupled to the end of the rotary shaft 6, the oil fed from the oil suction means 14 to the rotary shaft 6 is sucked up The oil flow path 6b is formed.

The operation of the scroll compressor is, first, when the power is applied to the electric mechanism to operate the rotor (5) constituting the electric mechanism is rotated through the rotary shaft 6, the rotational force is pressed into the rotor (5) The rotating scroll 8 is transmitted to the scroll 8 and the rotating scroll 8 is prevented from rotating by the old dam ring 9 so that the rotating wrap 8a is engaged with the fixed scroll wrap 7a. Refrigerant gas sucked through the suction pipe 12 by the swinging movement of the swinging scroll 8 is wrapped around the fixed scroll wrap 7a and the swinging scroll through an intake port (not shown) formed at one side of the fixed scroll 7. The refrigerant gas in the high temperature and high pressure state discharged through the discharge port 7b formed in the fixed scroll 7 while being compressed into the center portion while being sucked into the center portion 8a is compressed and discharged to the discharge port 7b. Through 13).

As the rotary shaft 6 rotates, the oil filled in the bottom surface of the sealed container 1 is pumped by the oil suction means 14 and sucked through the oil passage 6b formed on the rotary shaft 6, thereby making sliding contact. It is supplied to the part and the supplied oil is returned to the bottom of the sealed container 1.

On the other hand, the part where the sliding contact occurs most is the lower surface of the turning scroll 8 which compresses the gas while turning, that is, the upper part supporting the thrust bearing surface 8b of the turning scroll and the thrust bearing surface 8b of the turning scroll. The upper surface of the frame 2, that is, the thrust bearing surface 2b of the upper frame.

2 illustrates a conventional structure in which oil is supplied to the revolving scroll 8 and the upper frame 2 supporting the revolving scroll 8, which will be described below in more detail.

First, the upper frame has a predetermined inner diameter and depth such that a thrust bearing surface 2b is formed on the upper surface of the frame body 2a and the boss portion 8c of the pivoting scroll is inserted in the thrust bearing surface 2b. A boss insertion groove 2c is formed, and a shaft insertion hole 2d into which the rotary shaft 6 is inserted is formed following the boss insertion groove 2c, and the boss insertion groove 2c communicates with the outer peripheral surface of the body 2a. An oil hole 2e is formed so as to form an annular oil groove 2f having a predetermined width and depth with respect to the boss insertion groove 2c on the thrust bearing surface 2b. On the other hand, the key groove (2g) is formed in the upper surface of the frame body (2a) is inserted into the key of the old dam ring (9).

The turning scroll 8 has a turning wrap 8a formed on an upper surface of a hard plate 8d having a predetermined thickness and an area, and a thrust bearing surface 8b facing the thrust bearing surface 2b of the upper frame on the lower surface thereof. Is formed, and a boss portion 8c is inserted into the boss insertion groove 2c, and a key groove 8e into which the key of the old dam ring 9 is inserted is formed on the lower surface of the hard plate 8d. have.

The pivoting scroll 8 is coupled such that its boss portion 8c is inserted into the upper frame boss insertion groove 2c and its thrust bearing surface 8b faces the thrust bearing surface 2b of the upper frame. The rotary shaft 6 is inserted into the shaft insertion hole 2d of the upper frame, and the eccentric portion 6a is inserted into the boss portion 8c of the turning scroll.

In such a structure, the oil sucked into the oil passage 6b of the rotating shaft 6 and discharged is filled in the boss insertion groove 2c and flows into the oil groove 2f of the upper frame, so that the thrust bearing surface of the turning scroll ( 8b) and the thrust bearing surface 2b of the upper frame. A part of the oil supplied to the thrust bearing surface 8b of the swing scroll and the thrust bearing surface 2b of the upper frame is returned to the bottom surface of the sealed container 1 while passing through the key groove 2g, and the boss insertion groove 2c. The oil flowing into the) is returned to the bottom surface of the sealed container 1 through the oil hole 2e.

However, in the conventional structure as described above, as shown in FIG. 3, in the process of sucking, compressing and discharging the refrigerant while the rotating scroll wrap 8a and the fixed scroll wrap 7a are engaged with each other and pivotally move, as shown in FIG. The largest pressure acts on the center portion of the turning plate 8d of the turning scroll to form a pressure distribution, and the turning scroll contacts the inner edge of the boss insertion groove 2c of the upper frame and the inner edge of the boss insertion groove 2c. There is a problem that wear occurs between the thrust bearing surface (8b).

In addition, since the largest pressure is applied among the hard plates 8d of the turning scroll, the oil flowing through the boss insertion groove 2c flows into the thrust bearing surface 2b of the upper frame and the thrust bearing surface 8b of the turning scroll. Of course, there is a problem that the oil supply is not smoothly supplied to the key groove 8e of the turning scroll into which the key of the Oldham ring 9 is inserted, as well as not being smoothly supplied therebetween.

The object of the present invention devised in view of the above points is to smoothly supply the oil to the rotating scroll and the relative movement of the rotational movement that rotates in engagement with the fixed scroll by receiving the driving force of the electric mechanism to prevent wear and to prevent wear It is to provide an oil supply structure of a scroll compressor.

1 is a cross-sectional view showing a typical scroll compressor,

2 is a cross-sectional view showing an oil supply structure of a conventional scroll compressor;

Figure 3 is a front view showing the pressure distribution acting on the swing scroll of the scroll compressor,

4 is a cross-sectional view of a scroll compressor having a scroll compressor oil supply structure of the present invention,

5 is a plan view showing a scroll compressor oil supply structure of the present invention,

6 is a plan view showing another embodiment of the scroll compressor oil supply structure of the present invention.

(Explanation of symbols for the main parts of the drawing)

2 ; Upper frame 2b; Upper frame thrust bearing face

2c; Boss insertion groove 7; Fixed scroll

8 ; Turning scroll 8b; Slewing Scroll Thrust Bearing Face

8c; Swing scroll boss 8f; Combined Oil Groove

8g; Communication channels 9; Oldhamling

D; Boss Insert Groove Border

In order to achieve the object of the present invention as described above, in the scroll compressor that receives the driving force of the power transmission unit is supported on the upper frame and the rotating scroll to engage the fixed scroll to compress the gas while rotating, the boss portion of the turning scroll On the thrust bearing surface of the revolving scroll that is in contact with the edge of the boss insertion groove of the upper frame to be inserted, an annular compound oil groove in which the edge of the boss insertion groove of the upper frame is always located therein during the revolving movement of the revolving scroll. Is formed so that the annular composite oil groove is always in communication with the boss insertion groove, and the key groove of the swing scroll and the compound oil groove are inserted into which the key of the old dam ring is inserted to prevent rotation of the swing scroll. The communication flow path is formed on the thrust bearing surface of the turning scroll. A lubrication structure of a scroll compressor is provided.

Hereinafter, the oil supply structure of the scroll compressor of the present invention will be described according to the embodiment shown in the accompanying drawings.

First, as shown in FIG. 4, the upper and lower frames 2 and 3 are respectively coupled to the inside of the airtight container 1, and the scroll compressor is disposed between the upper frame 2 and the lower frame 3. A stator 4 and a rotor 5 constituting the electric mechanism part are mounted on the rotary shaft 6, and the rotating shaft 6 provided with the eccentric portion 6a is pressed into the rotor 5. The fixed scroll 7 is fixedly coupled to the upper side of the upper frame 2 at predetermined intervals, and the rotating scroll is engaged with the fixed scroll 7 between the upper frame 2 and the fixed scroll 7 to enable the pivoting movement. (8) is combined. At this time, the boss portion 8c of the swinging scroll is inserted into the boss insertion groove 2c of the upper frame and the thrust bearing surface 8b of the swinging scroll is in contact with and coupled to the thrust bearing surface 2b of the upper frame. Then, the rotary shaft 6 is inserted into the shaft insertion hole 2d formed through the boss insertion groove 2c of the upper frame, and the eccentric portion 6a is inserted into the boss portion 8c of the swing scroll, and the pivot Between the scroll 8 and the upper frame 2 is combined the old dam ring 9 to prevent the rotation of the swing scroll (8).

The fixed scroll (7) is coupled to a high and low pressure separator (10) for separating the inside of the sealed container (1) into a high pressure region and a low pressure region, and the flow of refrigerant gas of high temperature and high pressure to the high low pressure separator (10). The gas flow adjusting means 11 for controlling is coupled, and the suction pipe 12 and the discharge pipe 13 are coupled to the low pressure region and the high pressure region of the hermetic container 1, respectively.

The oil is filled in the bottom surface of the sealed container (1) and the oil suction means (14) is coupled to the end of the rotary shaft (6) and the oil fed from the oil suction means (14) is sucked into the rotary shaft (6). The oil passage 6b is formed through.

Then, as shown in Fig. 5, contact wear reduction and oil supply are made to the lower surface of the turning plate 8d of the swinging scroll in contact with the edge of the boss insertion groove 2c of the upper frame, that is, the thrust bearing surface 8b. Compound oil groove 8f is formed.

The complex oil groove 8f may be formed in an annular shape having a predetermined width and depth such that the edge D of the boss insertion groove 2c of the upper frame is always positioned therein during the pivoting movement of the swinging scroll. Do. That is, the oil groove 8f is always configured to maintain a state of communication with the boss insertion groove 2c.

As another embodiment of the present invention, as shown in FIG. 6, the lower plate 8d of the pivoting scroll contacting the edge D of the boss insertion groove 2c of the upper frame, that is, the thrust bearing surface ( The key groove 8e of the turning scroll into which the combined oil groove 8f is formed in 8b) for reducing contact wear and supplying oil, and the key of the old dam ring 9 is inserted to prevent rotation of the turning scroll 8. And a communication flow path 8g for communicating the composite oil groove 8f with each other is formed.

The composite oil groove 8f has a predetermined width and depth such that the edge D of the boss insertion groove 2c of the upper frame 2 is always positioned therein during the pivoting movement of the swinging scroll 8. It is preferable that it is formed in an annular shape, and the communication flow path 8g is preferably formed in a straight shape having a predetermined width and depth.

Hereinafter, the operation and effect of the scroll compressor oil supply structure of the present invention will be described.

First, when power is applied and the rotor 5 of the electric machine part rotates, the rotary shaft 6 press-fitted to the rotor 5 rotates, thereby turning to the eccentric portion 6a of the rotary shaft 6. The scroll 8 is pivoted while the rotation is prevented by the old dam ring 9. As the swinging scroll 8 pivots, the compression pocket formed by the fixed scroll lap 7a and the swinging scroll lap 8a moves to the center to suck, compress and discharge the refrigerant gas.

As the rotary shaft 6 rotates, oil filled in the bottom surface of the sealed container 1 is pumped by the oil suction means 14 to be sucked up through the oil channel 6a of the rotary shaft 6, and the oil sucked up is It is accumulated in the boss insertion groove 2c of the upper frame through the eccentric portion 6a of the rotary shaft and the boss portion 8c of the swinging scroll.

The oil that accumulates in the boss insertion groove 2c of the upper frame flows through the complex oil groove 8f formed in the thrust bearing surface 8b of the swinging scroll by centrifugal force and at the same time, the thrust bearing surface 8b of the swinging scroll. And oil supplied between the thrust bearing surface 2b of the upper frame and at the same time into the composite oil groove 8f is the keyway of the turning scroll in which the key of the old dam ring 9 is inserted through the communication passage 8g. It is supplied to 8e. The oil supplied between the thrust bearing surface 8b of the swinging scroll and the thrust bearing surface 2b of the upper frame and the oil supplied to the key groove 8e of the swinging scroll each play a role of lubrication, and then the airtight container 1 Return to the bottom.

On the other hand, the edge of the boss insertion groove (2c) of the upper frame by the composite oil groove (8f) of the swinging scroll (8) in the process of the swinging scroll (8) swings in engagement with the fixed scroll (7) ), That is, the edge portion does not come into contact with the thrust bearing surface 8b of the turning scroll, so that the turning scroll generated by the pressure distribution increases toward the center portion of the turning scroll 8 in the process of compressing the refrigerant. 8) and to prevent uneven wear of the boss insertion groove rim (D) of the upper frame.

As described above, the lubrication structure of the scroll compressor according to the present invention is generated due to the nonuniform pressure distribution acting on the swing scroll in the process of sucking, compressing and discharging the refrigerant while the swing scroll rotates in engagement with the fixed scroll. In addition to preventing uneven wear, oil is smoothly supplied between the thrust bearing surface of the turning scroll and the bearing surface of the upper frame and the key groove into which the keys of the old dam ring are inserted so that the lubrication of the parts in which the relative motion occurs is smoothly performed. In addition to being made to prevent wear of the parts has the effect of increasing the reliability.

Claims (3)

delete In a scroll compressor that receives the driving force of the electric mechanism unit is supported by the upper frame and the rotating scroll, while compressing the gas while the rotating scroll is engaged with the fixed scroll, On the thrust bearing surface of the turning scroll which is in contact with the edge of the boss insertion groove of the upper frame into which the boss portion of the turning scroll is inserted, the edge of the boss insertion groove of the upper frame is always located therein during the turning movement of the turning scroll. An annular compound oil groove is formed so that the annular compound oil groove is always in communication with the boss insertion groove. The oil supply structure of the scroll compressor, characterized in that a communication flow path for communicating the key groove of the swing scroll and the combination oil groove is inserted into the thrust bearing surface of the swing scroll to prevent the rotation of the swing scroll is inserted. delete