KR20050060335A - The friction losses decreasing device of eccentric bush for scroll compressor - Google Patents

Abstract

The present invention relates to a scroll compressor, and more particularly, to reduce the viscosity and friction generated between the eccentric bush and the boss portion of the scroll compressor to the relative rotation to the crankshaft at the beginning of the compressor. It relates to a friction loss reduction device of the scroll compressor to reduce the leakage and frictional loss of the refrigerant gas, which comprises: a boss portion formed on the lower side of the swing scroll; An eccentric bush rotatably inserted with the crank pin in the boss portion; It is composed of a floating ring which can be rotated between the eccentric bush and the boss to reduce the viscosity and friction between the eccentric bush and the boss, and thus the eccentric bush is applied to the crankshaft at the start of the compressor. It is possible to reduce the leakage and frictional loss of the refrigerant gas by the relative rotation with respect to, thereby improving the compression performance and reduce the noise at the initial start-up.

Description

The friction losses decreasing device of eccentric bush for scroll compressor}

The present invention relates to a scroll compressor, and more particularly, to reduce the viscosity and friction generated between the eccentric bush and the boss portion of the scroll compressor to the relative rotation to the crankshaft at the beginning of the compressor. The present invention relates to a friction loss reducing device of a scroll compressor capable of reducing leakage and frictional loss of refrigerant gas.

In general, the scroll compressor is provided with a main frame 2 and a subframe 3 above and below the inside of the shell 1, as shown in Figure 1, the main frame 2 and the subframe (3) of Between the stator 4 and the inside of the shell (1) is pressed in between, the stator (4) is provided with a rotor (5) rotated by an applied power source, the rotor (5) A vertical crankshaft 6 is inserted into and fixed to a central portion of the crankshaft 6 so as to rotate together with the rotor 5, and the upper and lower portions of the crankshaft 6 have a main frame 2 and a subframe 3. Is rotatably supported.

And the upper surface of the main frame (2) is provided with a rotating scroll (7) having a lower side coupled to the crankshaft (6) and an involute-shaped swing wrap (7a) formed on the upper side, the turning scroll (7) On the upper side of the fixed scroll (8) having a fixed wrap (8a) to engage the swing wrap (7a) is fixed to the inside of the shell (1) the swing scroll (7) by the rotation of the crank shaft (6) By doing so, the refrigerant gas introduced into the compression chamber 22 formed between the turning wrap 7a and the fixed wrap 8a is compressed.

In addition, the combination of the crankshaft 6 and the swinging scroll (7) is the crank pin (10) protruding upward from the position spaced apart from the center of the upper surface of the crankshaft 6 by a predetermined distance to the pivoting scroll (7) It is made by inserting into the boss portion 7b protruding from the lower side central portion of the lower portion, the floating ring 11 is forcibly pressed into the boss portion 7b, the eccentric bush on the outside of the crank pin 10 (12) is rotatably coupled.

On the other hand, between the main frame (2) and the revolving scroll (3) is provided an anti-rotation mechanism Olddam ring (9), the oil passage (6a) is formed in the crankshaft 6 through the upper and lower through, The upper balance weight 13 and the lower balance weight 14 are formed in the electron 5, respectively, to prevent rotational imbalance of the crankshaft 6 by the crank pin 10.

Here, reference numerals 15 and 16 are suction pipes and discharge pipes, 17 and 18 are discharge ports and discharge chambers, 19 is reverse displacement, 20 is oil, and 21 is oil propeller.

In the scroll compressor configured in this manner, the rotor 5 rotates inside the stator 4 by an applied power source, and the crankshaft 6 rotates by the rotor 5. Slewing scroll (7) coupled to the pivoting motion along the turning radius between the center of the crankshaft (6) and the turning scroll (7).

In addition, the compression chamber 22 formed between the swing wrap 7a and the fixed wrap 8a reduces the volume by the continuous swing motion of the swing scroll 7 to further compress the sucked refrigerant gas. The high pressure refrigerant gas is discharged to the discharge chamber 18 through the discharge port 17, and the refrigerant gas inside the discharge chamber 18 is discharged to the outside through the discharge pipe 16 again.

On the other hand, the scroll compressor is a fixed-radial scroll compressor in which the swing scroll 7 always swings along the same trajectory regardless of the change in the compression conditions, and the liquid refrigerant, oil or foreign matter is introduced into the compression chamber 22 When the pressure in the compression chamber rises abnormally, it is divided into a variable radius scroll compressor which retracts the turning scroll 7 radially so that each wrap 7a, 8a is not damaged by the elevated pressure.

In addition, the eccentric bush 12 is coupled to the crank pin 10 as described above in order to vary the turning radius of the turning scroll 7 in the variable radius scroll compressor, and the eccentric bush 12 is cranked. The sealing function for the compression chamber 22 is also performed by the centrifugal force of the turning scroll 7 according to the amount of eccentricity between the center of the pin 10 and the center of the eccentric bush 12.

Figure 2 is an exploded perspective view showing the configuration of the conventional eccentric bush coupling portion, Figure 3 is a cross-sectional view showing the assembled state, as shown therein the swing wrap (7a) is formed on the upper side of the swing scroll (7), The boss | hub part 7b is formed in the side, and the bearing 11 is forcibly pressed in the inner surface of the said boss | hub part 7b.

In addition, the eccentric bush 12 is rotatably coupled to the crank pin 10 which is spaced from the center of the upper end of the crank shaft 6 and protrudes upward, and the eccentric bush 12 is inserted into the boss 7b. By the rotation of the crankshaft (6) is to rotate with the turning scroll (7) along the turning radius between the center of the crankshaft (6) and the center of the eccentric bush (12).

In this way, the eccentric bush 12 rotates together with the crankshaft 6 so that the centrifugal force of the swing scroll 7 is reduced by the continuous swing motion of the swing scroll 7 from the start of the compressor. It takes some time until the gas force is greater than

This is because the eccentric bush 12 does not follow the rotation of the crankshaft 6 due to the viscosity and friction between the eccentric bush 12 and the boss 7b at the initial stage of the compressor, and thus the crankshaft 6 When the eccentric bush 12 makes a relative rotation with respect to the crankshaft 6, the turning wrap 7a of the turning scroll 7 is moved from the fixed wrap 8a of the fixed scroll. Spaced apart.

Therefore, the refrigerant gas inside the compression chamber leaks through the gap between the turning wrap 7a and the fixed wrap 8a, thereby lowering the initial compression performance and causing noise.

When the rotation speed of the crankshaft 6 increases during the normal operation, the friction force between the eccentric bush 12 and the boss portion 7b also increases, thereby forcing the bearing pressed against the inner surface of the boss portion 7b. There is a problem that (11) is worn early, which leads to difficulties in replacement of the bearing (11).

Therefore, the present invention was devised to solve the conventional problems as described above, and the present invention can reduce the viscosity and friction generated between the eccentric bush and the boss portion, so that the eccentric bush is crankshaft at the start of the compressor. The purpose of the present invention is to reduce the leakage of refrigerant gas and frictional losses due to relative rotation with respect to.

In addition, an object of the present invention is to be able to support the lower portion of the floating ring having a friction rising function between the eccentric bush and the boss portion.

In addition, an object of the present invention is to enable the oil between the floating ring and the eccentric bush and the boss portion to be easily discharged to the outside without clogging.

A boss formed on the lower side of the turning scroll to achieve the object of the present invention; An eccentric bush rotatably inserted with the crank pin in the boss portion; Provided is a friction loss reduction apparatus for a scroll compressor, characterized in that the floating ring is provided between the eccentric bush and the boss to be rotated.

In addition, the supporter is formed of a cylindrical opening of the upper opening is blocked in the lower portion to support the lower portion of the floating ring is inserted into the outside of the boss portion, the supporter is formed in the bottom portion through hole eccentric bushing; Characterized in that it is composed of means for fixing the supporter to the outer surface of the boss portion.

In addition, the supporter fixing means is formed by forming at least two or more fixing grooves on both sides of the outer surface of the boss portion, characterized in that formed on the inner surface of the supporter to form an elastic fixing projection corresponding to the fixing groove.

In addition, it is characterized in that the means for discharging the oil between the eccentric bush and the floating ring and the oil between the floating ring and the eccentric bush to the outside.

In addition, the oil discharge means is characterized in that it is formed by forming a plurality of oil through the approximately middle portion of the side of the floating ring and the bottom of the supporter.

In addition, at least one oil through-hole is formed in the side portion of the floating ring.

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

Figure 4 is an exploded perspective view showing a friction reducing device of a scroll compressor according to the present invention.

As shown in the present invention, the turning wrap 7a is formed on the upper side of the turning scroll 7, the boss part 7b is formed on the lower side, and one side from the center of the top surface of the crankshaft 6. The eccentric bush 12 is rotatably coupled to the crank pin 10 protruding upwardly and spaced apart.

A cylindrical floating ring 110 penetrates up and down to rotate between the eccentric bush 12 and the boss portion 7b, and a lower portion of the floating ring 110. It consists of a supporter 120 formed of an upper opening cylindrical body which is closed with a lower portion so as to be closed, and means for fixing the supporter 120 to an outer surface of the boss portion 7b.

The supporter 120 is formed of a sintered alloy or plastic-based material having lubricity and wear resistance, and is formed to have a diameter corresponding to the boss portion 7b so that the supporter 120 can be inserted to the outside of the boss portion 7b. An eccentric bushing through hole 122 through which the eccentric bush 12 penetrates in the vertical direction is formed in the center portion.

In addition, the supporter fixing means forms at least two or more fixing grooves 120a on both sides of the outer surface of the boss portion 7b, and fixing protrusions 121 corresponding to the fixing grooves 120a on the side portions of the supporter 120. ) Is formed to protrude inward.

Along the side of the floating ring 110 and the eccentric bush through hole 122 of the supporter 120, a plurality of oil through holes (110a, 123) are respectively formed to form the oil through holes (110a, 123) The oil between the eccentric bush 12 and the floating ring 110, and the oil between the floating ring 110 and the boss 7b is to be discharged.

5 is a longitudinal sectional view showing the assembled state of FIG.

According to the present invention, first, the floating ring 110 is rotatably inserted into the boss portion 7b of the turning scroll 7, and then the supporter 120 is inserted into the boss portion 7b of the lower portion of the pivoting scroll 7. The supporter 120 is fixed to the boss portion 7b, wherein the support protrusion 120 of the supporter 120 is inserted into the fixing groove 120a of the boss portion 7b to support the supporter 120 and the boss. The fixing between the parts 7b is made.

Then, the eccentric bush 12 is rotatably coupled to the crank pin 10, and the eccentric bush 12 to which the eccentric bush 12 is coupled is provided through the eccentric bush through hole 122 of the supporter 120. As a result of the insertion, a series of assembling is completed, and the oil between the eccentric bush 12 and the floating ring 110 and the oil between the floating ring 110 and the boss portion 7b are floating ring 110. It is discharged to the outside through the oil through hole (110a) and the oil through hole (123) formed on the bottom surface of the supporter 120 formed in the side portion.

6 is a plan sectional view of FIG. 5 showing an operating state of the present invention.

As shown in the present invention, the eccentric bush 12 is rotatably inserted into the boss portion 7b, and a floating ring 10 is disposed between the eccentric bush 12 and the boss portion 7b. ) Is rotatably provided, and when the eccentric bush 12 is rotated by the start of the compressor, the eccentric bush 12 generates the relative speed N1 generated between the eccentric bush 12 and the boss 7b. ) And the relative speeds (N1-N2) between the floating ring 110 and the floating ring 110 and the relative speeds (N2) between the floating ring 110 and the boss portion 7b. Viscosity and friction between the eccentric bush 12 and the boss portion 7b can be reduced, so that leakage and frictional loss of refrigerant gas can be reduced as the eccentric bush 12 rotates relative to the crankshaft 6. As a result, it is possible to improve the compression performance and reduce the noise.

As described above, the present invention not only reduces the viscosity and friction between the eccentric bush and the boss by interposing a floating ring that rotates between the eccentric bush and the boss, but also causes the eccentric bush to crank at the start of the compressor. It is possible to reduce the leakage and friction loss of the refrigerant gas by the relative rotation with respect to the shaft, thereby improving the compression performance and reduce the noise at the initial start-up.

In addition, the floating ring is prevented from premature wear and at the same time the replacement of the floating ring has an effect that can be made more easily.

In addition, the present invention has the effect of ensuring the stability and reliability of the device by supporting the lower portion of the floating ring having a friction rising function between the eccentric bush and the boss portion.

In addition, the present invention by forming a plurality of oil through holes in the side portion of the floating ring and the supporter for supporting the floating ring from the bottom, the oil between the floating ring and the eccentric bush and boss portion more easily without clogging outwards It also has the advantage of being discharged.

1 is a longitudinal sectional view showing the overall configuration of a general scroll compressor.

Figure 2 is an exploded perspective view showing the configuration of the eccentric bush coupling portion of FIG.

3 is a longitudinal sectional view showing the assembled state of FIG.

Figure 4 is an exploded perspective view showing a friction loss reduction device of the scroll compressor according to the present invention.

5 is a longitudinal sectional view showing the assembled state of FIG.

Figure 6 is a plan sectional view of Figure 5 showing the operating state of the present invention.

※ Explanation of codes for main parts of drawing

7: turning scroll 7b: boss

10: crank pin 12: eccentric bushing

11a: floating ring 110: floating ring

110a, 123: Oil through hole 120a: Fixed groove

121: fixed protrusion 122: eccentric bushing through hole

Claims (6)

A boss portion formed on the lower side of the revolving scroll; An eccentric bush rotatably inserted with the crank pin in the boss portion; Friction loss reduction device of the scroll compressor, characterized in that consisting of a floating ring which is provided between the eccentric bush and the boss to rotate. The method of claim 1, A supporter formed of an upper opening cylindrical body of which a lower portion is blocked to support a lower portion of the floating ring and inserted into an outside of the boss portion, and having an eccentric bushing through-hole formed in a bottom portion thereof; And a means for fixing the supporter to an outer surface of the boss portion. The method of claim 2, The supporter fixing means forms at least two fixing grooves on both sides of the outer surface of the boss, and an elastic fixing protrusion corresponding to the fixing groove is formed on the inner surface of the supporter to reduce frictional losses of the scroll compressor. Abatement system. The method according to any one of claims 1 to 3, And a means for discharging oil between the eccentric bush and the floating ring and oil between the floating ring and the eccentric bush to the outside. The method of claim 4, wherein The oil discharging means is a frictional loss reduction device of the scroll compressor, characterized in that by forming a plurality of oil holes in the middle portion of the side of the floating ring and the bottom of the supporter. The method according to any one of claims 1 to 3, At least one oil through-hole is formed in the side portion of the floating ring friction loss reduction device of the scroll compressor.