KR100390430B1 - Axial compliance mechanism of scroll machine - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scroll fluid machine, and in particular, by combining a back pressure plate with a rotating member to form a pressure chamber under the swing scroll to provide an axially compliant structure, thereby ensuring the stability of the swing scroll and the swing scroll. The frictional loss of the contact surface between the fixed scroll is to be reduced.

To this end, the present invention provides a scroll fluid machine having a swing scroll having a spiral wound wrap and a fixed scroll seated on an upper portion of the swing scroll to form a compression chamber; Back pressure plate is combined with the rotating member inside the compressor, or integrally formed, the pressure chamber for pushing the swing scroll to the fixed scroll side by allowing the gas or oil having a pressure higher than the suction gas flows between the swing scroll and the back pressure plate It is to provide an axially compliant structure of the scroll fluid machine, characterized in that forming a.

More preferably, the back pressure plate is combined with or integrally formed with a drive shaft or counterweight or slide bush or eccentric bush.

Description

Axial compliance mechanism of scroll machine

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scroll fluid machine, and more particularly, to an axially compliant structure formed of a back pressure structure formed below the swing scroll to offset the swing scroll rollover moment generated in the scroll fluid machine.

In general, a scroll fluid machine is a device equipped with a spiral scroll, such as a scroll compressor.

As shown in FIG. 1, the scroll compressor 1 includes a fixed scroll 10 having an involute-shaped wrap 11 and an involute-shaped wrap 21 having a phase difference of 180 degrees from the involute curve. It is provided with a turning scroll (20) having.

In such a scroll compressor (1), the rotating scroll 20 and the fixed scroll 10 are engaged with each other to form a compression chamber 12 is formed so that the rotating scroll 20 is prevented from rotating relative to the fixed scroll (10) When the rotary motion is performed while the compression chamber 12 moves toward the center portion, the volume is reduced to compress the refrigerant.

When the refrigerant is compressed, leakage of the refrigerant occurs from the inner compression chamber of high pressure to the compression chamber of relatively low pressure. The radius through the axial clearance generated between the gap between the tip portion of the scroll wrap and the bottom of the counter scroll Directional leakage and tangential leakage through the radial clearance occurring between the lateral clearances between the wraps 21 and the wraps 11 of the turning and fixed scrolls.

As a method for preventing radial leakage for stable operation of the swing scroll, a tip seal method, a fixed scroll back pressure method, and a swing scroll back pressure method are used.

In this tip seal method, as shown in FIG. 2, the tip scroll, which is the end of the wrap 21, is sealed 22 so that the turning scroll 20 is pushed toward the main frame 30 on which the turning scroll is seated by the axial gas force. It is to be rotated with respect to the fixed scroll in a state.

However, when the tip seal method is applied, a thrust reaction force _Ra corresponding to the axial gas force Fga generated in the compression chamber is generated, and all of the moments generated by the axial gas force are applied to the main frame 30. It is transmitted to the thrust bearing 31 to generate a friction loss, the tip chamber 22 is worn by the friction of the bottom of the relative scroll, the leakage of the refrigerant may occur.

Meanwhile, the fixed scroll back pressure method (not shown) uses the discharge pressure and the intermediate pressure to push the fixed scroll 10 (see FIG. 1) to the turning scroll 20 (see FIG. 2) to prevent leakage of the refrigerant. Since the thrust bearing 31 (see FIG. 2) of the frame 30 (see FIG. 2) is applied to the axial gas force Fga and the back pressure formed on the rear surface of the fixed scroll, the main frame 30 and the turning scroll 20 are applied. The friction loss of the liver becomes even greater.

In addition, as shown in FIG. 3, the swing scroll back pressure method uses the discharge pressure or the intermediate pressure to push the swing scroll 20 to the fixed scroll side 10 (see FIG. 1) and the main frame 30. Loss due to friction between the swinging scrolls 20 is prevented, but the thrust reaction force acting on the contact surface between the fixed scroll and the swinging scroll (F _ra =) is required because the back pressure (F _b ) must be considerably increased to prevent the turning scrolls overturning. F _b -F _ga ) is similar to the tip seal method, which still causes large friction losses.

In order to solve the above problems, the present invention provides a back pressure structure that can effectively offset the overturning moment of the swing scroll to destabilize the behavior of the swing scroll, thereby increasing the safety of the swing scroll and between the fixed scroll and the swing scroll The purpose is to minimize the friction losses generated.

1 is a longitudinal sectional view showing a typical scroll compressor in a scroll fluid machine;

2 is a schematic sectional view showing a pivoting scroll of a scroll compressor to which a tip thread method is applied;

3 is a schematic sectional view showing a pivoting scroll of a scroll compressor to which a pivoting scroll method is applied;

Figure 4 is a longitudinal sectional view showing a scroll compressor according to the present invention

5 is a cross-sectional view of the compression chamber showing the pressure chamber formed by the back pressure plate on the lower portion of the turning scroll.

Figure 6 is a schematic sectional view of the main portion of the turning scroll showing the thrust reaction force acting on the turning scroll of the scroll compressor is applied back pressure according to the present invention

* Explanation of Signs of Main Parts *

1, 2: scroll compressor 10: fixed scroll

20: turning scroll 30: upper frame

40: drive shaft 50: back pressure plate

60: stator 70: rotor

To this end, the present invention provides a scroll fluid machine having a swing scroll having a spiral wound wrap and a fixed scroll seated on an upper portion of the swing scroll to form a compression chamber; Back pressure plate is combined with the rotating member inside the compressor, or integrally formed, the pressure chamber for pushing the swing scroll to the fixed scroll side by allowing the gas or oil having a pressure higher than the suction gas flows between the swing scroll and the back pressure plate It is to provide an axial compliance structure of the scroll fluid machine, characterized in that forming a.

More preferably, the back pressure plate is combined with or integrally formed with a drive shaft or counterweight or slide bush or eccentric bush.

Referring to the accompanying drawings, the scroll fluid machine according to the invention as follows, Figure 4 is a longitudinal sectional view showing a scroll compressor according to the present invention, Figure 5 is a pressure chamber formed by a back pressure plate in the lower portion of the swing scroll Figure 6 is a cross-sectional view of the compression chamber, Figure 6 is a schematic cross-sectional view of the main portion of the turning scroll showing the thrust reaction force that appears during the behavior of the turning scroll in the back pressure method according to the present invention.

The scroll compressor in the scroll fluid machine according to the present invention, as shown in Figures 4 and 5, the upper and lower frames 30 are installed on the upper and lower inner sides of the sealed container, the involute curve on the upper surface of the upper frame 30 The rotating scroll 20 formed with a wrap is placed thereon, and the wrap 11 is provided on the upper side of the rotating scroll 20 to be engaged with the wrap 21 of the rotating scroll 20 to form the compression chamber 12. Fixing scroll 10 is mounted is fastened to the edge of the upper frame 30 with a bolt.

In addition, a boss 23 is formed on the rear surface of the swing scroll 20 so as to be eccentrically coupled to the drive shaft 40, and a plane formed on the top of the drive shaft 40 to surround one side of the lower portion of the swing scroll 20. The back pressure plate 50 is positioned integrally with the portion.

In addition, a crank pin (not shown) protruding a predetermined amount eccentrically is coupled to an end portion of the drive shaft 40 coupled to the boss 23 formed on the rear surface of the swing scroll, and the crank pin and the swing scroll 20 A driving bush (not shown) may be interposed between the bosses 23.

At this time, the oil storage unit 100 is located below the drive shaft 40, the oil supply passage 42 is formed in the longitudinal direction of the drive shaft to terminate the entire drive shaft 40, the oil supply passage ( The oil flows into the back pressure plate through 42).

In addition, a seal member 51 is installed between the pressure chamber 52 formed between the back pressure plate 50 and the swing scroll 20 and the inside of the scroll compressor to provide high pressure air and oil introduced into the pressure chamber 52. To prevent leakage.

Meanwhile, between the upper and lower frames, the stator 60 is press-fitted to the inner surface of the sealed container, and the rotor 70 is inserted into the inner circumferential surface of the stator 60, and the drive shaft 40 is installed at the center of the rotor. It is positioned to penetrate the center of the upper frame.

When power is applied to the scroll compressor 2 having such a structure, the rotor 70 is rotated inside the stator 60 to rotate the drive shaft 40. As a result, the pivoting scroll 20 has the drive shaft. (40) At the center of gravity, a turning movement is made at a distance as far as the turning radius.

Therefore, as shown in FIG. 5, when the turning scroll 20 pivots about the fixed scroll 10 while the rotation is prevented from rotating, the compression chamber moves toward the center portion, whereby the volume of the refrigerant decreases to increase the pressure, thereby discharging the discharge port. The discharged gas is discharged through the discharge chamber 13 and passes through the discharge pipe 13 to the other device of the air conditioner.

At this time, the pressure chamber 52 formed on the lower surface of the swing scroll 20 is orthogonal to the direction in which the contact between the fixed scroll 10 and the swing scroll 20 occurs so as to face the axial gas force F _gt . Are located in the direction of being.

On the other hand, the oil sucked from the oil storage unit 100 as the drive shaft rotates is sucked along the oil supply passage 42 to the compression mechanism portion, the portion of the oil is sucked through each of the oil supply port of the upper frame 30 It enters the friction part and lubricates it.

Then, the remaining oil is introduced between the back pressure plate 50 formed integrally with the drive shaft 40 and the lower side of the turning scroll 20, as shown in Figure 6 fixed the scroll scroll 20 The axial scrolling of the revolving scroll is achieved by pushing the revolving scroll 20 in close contact with the fixed scroll 10.

That is, the oil sucked up through the oil supply passage 42 of the drive shaft in the oil storage unit 100 of the lower compressor has a pressure higher than the suction gas flowing into the compression chamber, and the lower surface of the turning scroll 20 and the back pressure plate 50. Inflow into the pressure chamber 52 formed between the), holding a portion of the turning scroll 20 to bring the turning scroll 20 in close contact with the fixed scroll (10).

Accordingly, in the scroll compressor, as shown in FIG. 6, as the swing scroll 20 is pushed toward the fixed scroll 10 due to the pressure in the pressure chamber 52 formed by the back pressure plate 50, the scroll scroll is rotated. When 20 is turned, a thrust reaction force _Ra is formed between the turning scroll 20 and the friction surface of the fixed scroll 10.

The thrust reaction force _Ra is a shaft formed by the sum of the reaction force F _b1 generated by the high pressure gas force of the shaft center and the back pressure F _b2 by oil or high pressure air in the pressure chamber 52. _Equivalent to subtracting fragrance gas force (F _ga ).

At this time, since the position of the back pressure F _b2 by the pressure chamber 52 acts in the same direction as the tangential gas force F _gt applied to the turning scroll 20, the moment of the turning scroll 20 is reduced. Since the equilibrium occurs naturally, the thrust reaction force _Ra becomes very small, while the overturning moment of the turning scroll cancels out.

On the other hand, according to another embodiment of the present invention, the back pressure plate 50, the balance weight 80 is installed on the upper end surface of the rotor to offset the unbalanced force, such as turning scroll eccentric with the drive shaft 40 and It can also be formed integrally to reduce the vibration of the scroll compressor.

On the contrary, in another embodiment of the present invention, the back pressure plate 50 may rotate the back pressure plate 50 such as a slide bush, an eccentric bush, or a swing link to prevent radial leakage of the refrigerant. By combining with other members to form or integrally, the compression chamber may be formed between these members and one side of the lower surface of the swing scroll.

At this time, the slide bush (not shown) to rotate the rotating scroll 20 to drive the rotating scroll 20 while having the same center as the rotating scroll and to slide along the protruding plane portion eccentric to the top of the drive shaft 40 And between the drive shaft 40.

In addition, the eccentric bush (not shown) has the same center as the revolving scroll 20 and eccentrically rotates around the crank pin coupled to the drive shaft 40 to rotate the revolving scroll 20 with respect to the fixed scroll 10. It is interposed between the turning scroll 20 and the drive shaft 40 to vary the length.

Meanwhile, in another embodiment according to the present invention, the outer diameter of the crank pin (not shown) coupled to the upper portion of the drive shaft is smaller than the outer diameter of the drive shaft 40 so that the drive shaft 40 is formed by the pressure difference formed at both ends of the drive shaft. By moving upward, the turning scroll is in close contact with the fixed scroll side to reduce the thrust loss that may occur between the bottom surface of the back pressure plate 50 and the main frame 30.

At this time, it is understood that the back pressure plate 50 may be combined with or integrally formed with a member that rotates inside the compressor such as a drive shaft and a slide bush.

As described above, since the pressure chamber is formed on the lower side of the turning scroll by using a back pressure plate so that oil or high pressure air drawn up along the drive shaft can push the lower side of the turning scroll to the fixed scroll side. Since the overturning moment can be canceled, the turning scroll behaves stably, and the frictional loss formed on the surface where the turning scroll and the fixed scroll meet.

Claims (7)

Swivel scroll with spiral wrap A scroll fluid machine having a fixed scroll seated on an upper portion of the swing scroll to form a compression chamber, The back pressure plate is combined with or integrally formed with a member that rotates inside the compressor, An axially compliant structure of a scroll fluid machine, characterized in that a pressure chamber for pushing gas or oil having a pressure higher than the suction gas into the swing scroll and the back pressure plate to push the swing scroll to the fixed scroll side. The method of claim 1, An axial compliant structure of a scroll fluid machine, characterized in that a seal member is provided between the compression chamber and the outside formed between the back pressure plate and the swing scroll. The method of claim 1, The back pressure plate is coupled to the swing scroll axially compliant structure of the scroll fluid machine, characterized in that coupled to or integral with the top of the drive shaft for transmitting a driving force. The method of claim 1, The back pressure plate is axially compliant structure of the scroll fluid machine, characterized in that coupled to or integrally formed with the counterweight installed on the top surface of the rotor. The method of claim 1, The back pressure plate is axially compliant structure of the scroll fluid machine, characterized in that coupled to or integral with the slide bushing between the bush and the drive shaft of the swing scroll. The method of claim 1, The back pressure plate is axially compliant structure of the scroll fluid machine, characterized in that coupled to or integral with the eccentric bushing between the bush and the drive shaft of the swing scroll. The method according to any one of claims 1 to 6, An axially compliant structure of a scroll fluid machine, characterized in that the outer diameter of the crank pin coupled to the drive shaft is smaller than the outer diameter of the drive shaft.