KR20040098457A - Scroll compressor - Google Patents

Abstract

PURPOSE: A scroll compressor is provided to prevent a piston from being pressed by high-pressure refrigerant gas or fitted in a vacuum prevention device-mounting groove and according to rectilinearly move the piston in the mounting groove. CONSTITUTION: A scroll compressor is composed of a closed container being an outer case; a driving motor fixed in the closed container and composed of a stator and a rotor; a driving shaft rotated by the driving motor; an orbiting scroll and a fixed scroll(8) for revolving an orbiting wrap in a fixed wrap by the rotation of the driving shaft to compress the sucked refrigerant; an Oldham's coupling for preventing the rotation of the orbiting scroll and orbiting the orbiting scroll in the fixed scroll; a main frame for supporting the Oldham's coupling and the orbiting scroll; and a vacuum prevention device(120). The vacuum prevention device comprises a vacuum prevention device-mounting groove(130) communicating to the intake pressure side of the fixed scroll; a bypass hole(132) communicating to the discharge pressure side from the mounting groove; a through-hole(131) communicating from the mounting groove to a compression chamber(P) with middle pressure; a piston(121) for rectilinearly moving in the mounting groove to open and close the bypass hole according to difference between the middle pressure and the intake pressure; a moving groove(125) formed on the outer peripheral surface of the piston to correspond to the bypass hole closed by the piston; a spring(122) positioned at the intake pressure side of the piston to support the piston; and a stopper(123) for restricting the piston and spring from being separated from the mounting groove.

Description

Scroll compressor

The present invention relates to a scroll compressor, and more particularly, the mounting groove formed to form a predetermined space with the lower surface of the piston through the flow groove of the piston of the high pressure refrigerant gas acting from the bypass hole during normal operation. The present invention relates to a scroll compressor having an improved structure of the vacuum preventing device such that the piston is vertically balanced by a refrigerant pressure flowing into the gap groove therein.

In general, a scroll compressor combines two vortices to perform compression through the relative movement of a fixed scroll and a swivel scroll, and is used in a room air conditioner or a car air conditioner because of its high efficiency, low noise, small size, and light weight. Usability is on the rise.

Such a conventional scroll compressor, as shown in Figure 1, the closed container 15, which is an outer case; A suction pipe 1 and a suction chamber 4 for introducing a fluid from the outside; A drive motor 2 fixed in the sealed container 15 and composed of a stator 2a and a rotor 2b; And a drive shaft 3 rotated by the drive motor 2; A drive shaft eccentric portion (3a) provided eccentrically at the center of the drive shaft (3) on an upper end of the drive shaft (3); A pivoting scroll (7) fixed to the drive shaft eccentric (3a) and supported above the main frame (5) so as to compress the refrigerant sucked through the suction pipe (1), and engaged with the pivoting scroll (7); A compressed scroll unit comprising a fixed scroll 8 fixed above the frame 5; An old dam ring (6) for preventing rotation of the swing scroll (7) and allowing the swing scroll to swing within the fixed scroll (8); A main frame (5) supporting the old dam ring (6) and the orbiting scroll (7); A discharge port (9) for discharging the compressed high-pressure refrigerant through the compression action of the fixed scroll (8) and the revolving scroll (7); A check valve (10) fixed to the discharge port (9) for preventing a backflow of the refrigerant discharged through the discharge port (9); An upper diaphragm coupled to a rear surface of the fixed scroll 8 and partitioning the inside of the sealed container 15 into a suction chamber 4 through which low pressure refrigerant is sucked and a discharge chamber 11 through which high pressure refrigerant is discharged and accumulated ( 12); It is coupled to the discharge chamber 11 is composed of a discharge tube 14 for discharging the high pressure fluid. Reference numeral 13 denotes an upper shell 13.

Referring to the operation of the scroll compressor having such a configuration as follows.

When power is applied to the drive motor 2 among the components of the scroll compressor having the above-described configuration, the drive shaft 2 is inserted into and fixed to the rotor 2b of the drive motor 2 through the drive of the drive motor 2. As the rotation is performed, the turning scroll 7 fixed to the driving shaft eccentric 3a on the top of the driving shaft 3 also makes a turning (idle) motion in the fixed scroll 8 as a related action.

As described above in detail, the turning (orbiting) movement process of the turning scroll 7 in the fixed scroll 8 through the rotational force of the drive shaft 3 will be described. (8) in an involute shape above the swing scroll 7 in a state in which the swing scroll 7 is engaged, i.e., a fixed wrap 8a formed in an involute shape below the fixed scroll 8; The pivoting scroll 7 fixed to the eccentric portion 3a of the drive shaft 3 in the state where the swing wrap 7a formed is staggered is inserted into the center of the drive shaft 3 through the rotational force of the drive shaft 3. As a reference, the pivoting scroll 7 is eccentric to pivot (idle) within the fixed scroll 8.

At this time, in the case of the turning scroll 7, the old dam ring 6 provided between the turning scroll 7 and the main frame 5, that is, formed on the bottom surface of the turning scroll 7 and the upper surface of the main frame 5. The rotational movement of the pivoting scroll 7 is suppressed by the old dam ring 6 coupled with the upper key 6a and the lower key 6b formed on the upper and lower surfaces of the ring in the key grooves 7c and 5a. When the rotational movement suppression process of the turning scroll 7 is described with reference to the turning scroll 7, the turning scroll 7 which is eccentrically rotated through the rotation of the driving shaft 3 is fixed scroll 8. The upper key 6a of the old dam ring 6, that is, the upper key of the old dam ring 6 coupled to the key groove 7c of the bottom of the swing scroll 7 so that only the swing (orbit) movement can be made therein. The rotating movement of the turning scroll 7 is suppressed by 6a), and the turning scroll 7 is the upper key 6a of the old dam ring 6. A straight reciprocating motion is performed in this direction, and the old dam ring 6 is formed on an upper surface of the main frame 5 in the longitudinal direction of the lower key 6b of the old dam ring 6 on an upper surface of the main frame 5. By performing a straight reciprocating motion in the keyway 5a, only the turning (idle) movement of the turning scroll 7 is made in the fixed scroll 8.

When the swing scroll 7 is pivoted in the fixed scroll 8 as described above, a plurality of compression chambers P are formed between the swing scroll 7 and the fixed scroll 8, and the compression When the low-pressure gas phase refrigerant passing through the evaporator (not shown) of the refrigeration cycle equipment flows into the chamber P, the low-pressure gas phase refrigerant is shown in FIG. 2 in accordance with the swing (orbital) motion of the swing scroll 7. As described above, the gaseous refrigerant of a high pressure is compressed in the compression chamber P in which the volume is changed, and the gaseous refrigerant compressed to high pressure as described above is discharged to the discharge chamber 11 through the discharge port 9. .

Thus, the high-pressure gas phase refrigerant discharged to the discharge chamber 11 through the discharge port 9 is discharged to the condenser (not shown) side through the discharge tube 14 coupled to the discharge chamber 11. . In addition, the refrigerant introduced into the condenser is introduced into the scroll compressor through the condensation and expansion and evaporation in the evaporator through a general refrigeration cycle.

On the other hand, when the scroll compressor is applied to the air conditioner, the scroll compressor with the service valve (not shown) locked to collect the refrigerant in the evaporator (indoor) to the condenser (outdoor) side during the carelessness of the installer or the movement and repair of the air conditioner. When operating the engine for a long time, the pressure of the low pressure part on the suction pipe 1 side gradually decreases and the inside of the sealed container 15 becomes a high vacuum state, and an arc is generated between terminal terminals (not shown) connecting the power to the compressor, resulting in damage to the terminal. In order to solve this problem, there is a problem in that the compressor is burned out due to high heat generated by friction between the parts in contact with each other. In order to solve such a problem, the fixed scroll 8 and the turning scroll 7 At the one end of the upper end of the fixed scroll (8) is a vacuum preventing device (20) for flowing the high-pressure refrigerant gas compressed by the low pressure portion The vacuum prevention device 20 includes a vacuum prevention device mounting groove 30 formed to communicate with the suction pressure side of the fixed scroll 8, as shown in FIG. 3; A piston 21 inserted into the vacuum preventing device mounting groove 30; A spring (22) positioned behind the piston (21), that is, on the suction pressure side, to move the piston (21) to its original position by an elastic force when the refrigerant pressure is released; It prevents the detachment of the piston 21 and the spring 22 inserted into the vacuum preventing device mounting groove 30, and in a hollow form so that the refrigerant gas of high pressure can flow to the suction pipe 1 of the low pressure during the pump-down operation The stopper 23 is formed, and in order to prevent the stopper 23 from being separated from the vacuum preventing device mounting groove 30, the fixing pin 24 is disposed behind the stopper 23. The prevention device mounting groove 30 is inserted through the vertical.

In addition, a through hole 31 is formed at a lower end of the vacuum preventing device mounting groove 30 so as to communicate with a compression chamber P having an intermediate pressure, and the suction pressure of the compressor is provided at the upper end of the vacuum preventing device mounting groove 30. When the pressure falls below the set suction pressure condition, the high pressure refrigerant gas flows into the vacuum preventing device mounting groove 30 and flows to the low pressure suction pipe 1 through the stopper 23 of the vacuum preventing device 20. The bypass hole 32 to allow the through hole 32 to communicate with the vacuum preventing device mounting groove 30.

Therefore, since the pressure of the compression chamber P having the intermediate pressure is larger than the elastic force of the spring 22 during the normal operation, the piston 21 moves to the piston 21 as shown in FIG. 4. As a result, the bypass hole 32 is blocked so that the refrigerant gas of the high pressure part is not bypassed to the low pressure part.

On the other hand, when the suction pressure of the compressor due to the pump-down operation or the abnormal operation falls below the set suction pressure condition and is very low, the pressure of the compression chamber P having the intermediate pressure is smaller than the elastic force of the spring 22, so that the piston ( As the 21 moves as shown in FIG. 3, the bypass hole 32 is opened so that the refrigerant gas of the high pressure portion flows into the vacuum prevention device mounting groove 30 through the bypass hole 32, It flows to the low pressure part through the stopper 23.

Through this process, when the suction pressure of the compressor drops below the set suction pressure condition by the pump down operation or the abnormal operation, the refrigerant gas of the high pressure part flows to the low pressure part through the vacuum preventing device 20 to prevent the low pressure part from becoming high vacuum. At the same time, the temperature rise due to the friction between the parts can be delayed.

However, since the pressure of the refrigerant gas acting through the bypass hole 32 formed at the upper end of the vacuum preventing device mounting groove 30 is very high pressure, the compression chamber P having the intermediate pressure in the normal operation of the compressor is When the high pressure refrigerant gas is applied to the circumferential surface of the piston 21 through the bypass hole 32 while the piston 21 is pressurized by the refrigerant pressure as shown in FIG. 4, the piston 21 There was a big problem of being pinched in the vacuum preventing device mounting groove 30 while being pressed by the high-pressure refrigerant gas.

In addition, when the suction pressure of the compressor drops below the set suction pressure condition by the pump down operation or the abnormal operation in the state of the above problem, the piston 21 is returned to its original position by the elastic restoring force of the compressed spring 22. When moved to, the friction caused by the friction between the piston 21 and the vacuum preventing device mounting groove 30 was generated, there was a big problem that the smooth operation of the compressor is not made.

Furthermore, when the piston 21 is pressurized for a long time as shown in FIG. 4 by the refrigerant pressure of the compression chamber P having the intermediate pressure during the normal operation of the compressor, the piston 21 is bent by the high pressure of the refrigerant gas. There was also a big problem that the deformation of itself occurred.

In order to solve the above problems, the present invention, when the suction pressure of the compressor by the pump down operation or abnormal operation falls below the set suction pressure conditions, and very low, by flowing the refrigerant gas of the high pressure portion to the low pressure portion high vacuum of the low pressure portion By improving the structure of the vacuum preventing device to prevent the pressure, the mounting groove formed to form a predetermined space with the lower surface of the piston through the flow groove of the piston of the high pressure refrigerant gas acting from the bypass hole during normal operation The piston flows up and down by the refrigerant pressure, and the piston is vertically balanced by the refrigerant pressure. As a result, the piston is pressed by the high-pressure refrigerant gas as in the prior art, so that the piston can be smoothly moved in the vacuum prevention device mounting groove without being caught in the vacuum prevention device mounting groove. The purpose is to make it.

The object of the present invention is a vacuum preventing device for preventing high vacuum of the low pressure part by flowing the refrigerant gas of the high pressure part to the low pressure part when the suction pressure of the compressor is lower than the set suction pressure condition by the pump down operation or the abnormal operation is very low. It can be solved by the scroll compressor of the present invention configured by improving the structure of, will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of a typical scroll compressor.

Figure 2 is a state diagram of the operation of the swinging scroll coupled to the swinging and fixed scroll of the components of the conventional scroll compressor.

3 is a schematic view of a vacuum cleaner installed on a conventional fixed scroll;

4 is a state diagram of a conventional vacuum preventing device.

5 is a cross-sectional view and a detailed view of the scroll compressor of the present invention.

6 is an exploded perspective view of the vacuum prevention device installed on the fixed scroll of the present invention.

7 is an operation state of the vacuum preventing device applied to the present invention in normal operation.

8 is an operational state diagram of the vacuum preventing device applied to the present invention when the suction pressure of the compressor drops below the set suction pressure condition by the pump down operation or the abnormal operation.

Explanation of symbols on the main parts of the drawings

1. Suction line 2. Drive motor

3. Drive shaft 5. Main frame

6. Oldhamling 7. Turning Scroll

8. Fixed scroll 9. Discharge port

10. Check valve 11. Discharge chamber

12. Upper diaphragm 14. Discharge tube

15. Airtight containers 20, 120. Vacuum devices

21, 121.Piston 22, 122.Spring

23, 123. Stopper 24, 124. Locking Pin

125. Flow groove 30, 130. Vacuum prevention device mounting groove

31, 131.Through Hole 32, 132. Bypass Hole

133. Clearance groove 34, 134. Push pin groove

Figure 5 shows a cross-sectional view and a detailed view of the scroll compressor of the present invention, Figure 6 shows an exploded perspective view of the vacuum preventing device installed on the fixed scroll of the present invention.

The scroll compressor of the present invention includes: an airtight container (15) which is an outer case; A drive motor 2 fixed in the sealed container 15 and composed of a stator 2a and a rotor 2b; A drive shaft 3 rotated by the drive motor 2; A swing scroll (7) and a fixed scroll (8) for compressing the sucked refrigerant while the swing wrap (7a) pivots in the fixed wrap (8a) through the rotation of the drive shaft (3); An old dam ring (6) for preventing rotation of the swing scroll (7) and allowing the swing scroll (7) to swing within the fixed scroll (8); A main frame (5) supporting the old dam ring (6) and the orbiting scroll (7); A vacuum prevention device mounting groove 130 formed to communicate with the suction pressure side of the fixed scroll 8, a bypass hole 132 formed to communicate with the discharge pressure side from the vacuum prevention device mounting groove 130, and the vacuum Preventing the vacuum to open and close the bypass hole 132 according to the differential pressure between the intermediate pressure and the suction pressure, and the through-hole 131 formed to communicate with the compression chamber (P) having an intermediate pressure from the prevention device mounting groove 130 Flow groove 125 formed on the outer circumferential surface of the piston 121 to correspond to the piston 121 linearly moving in the device mounting groove 130 and the bypass hole 132 in a closed state by the piston 121 And a spring 122 positioned on the suction pressure side of the piston 121 to support the piston 121, and the piston 121 and the spring 122 are separated from the vacuum preventing device mounting groove 130. Vacuum prevention device 120 consisting of a stopper (123) to prevent being; It is configured to include.

In addition, a coolant of the discharge pressure is more smoothly supplied to the flow groove 125 on the opposite sidewall of the vacuum preventing device mounting groove 130 in which the bypass hole 132 is formed, thereby maintaining the vertical balance of the piston 121. The gap groove 133 having a predetermined depth is further formed to achieve the same.

Hereinafter, the scroll compressor of the present invention will be described in detail.

In the scroll compressor of the present invention, the high-pressure refrigerant gas acting from the bypass hole 132 during the normal operation and the lower surface of the piston 121 through the flow groove 125 of the piston 121 of the vacuum prevention device 120 As the structure of the vacuum prevention device 120 is improved to flow into the gap groove 133 in the vacuum prevention device mounting groove 130 formed to form a predetermined space so that the piston 121 can be balanced up and down by the refrigerant pressure. This will be described in detail the present invention. The same reference numerals will be applied to the same configurations as those of the present invention and the conventional art described above.

The scroll compressor of the present invention, as shown in FIG. 5, includes a closed container 15 which is an outer case; A drive motor 2 fixed in the hermetic container 15; A drive shaft 3 rotated by the drive motor 2; A rotating scroll (7) and a fixed scroll (8) for compressing the sucked refrigerant while the rotating wrap (7a) pivots in the fixed wrap (8a) through the rotation of the drive shaft (3); An old dam ring (6) for preventing rotation of the pivoting scroll (7); A main frame (5) supporting the old dam ring (6) and the orbiting scroll (7); A vacuum prevention device mounting groove 130 formed to communicate with the suction pressure side of the fixed scroll 8, a bypass hole 132 formed to communicate with the discharge pressure side from the vacuum prevention device mounting groove 130, and the vacuum Preventing the vacuum to open and close the bypass hole 132 according to the differential pressure between the intermediate pressure and the suction pressure, and the through-hole 131 formed to communicate with the compression chamber (P) having an intermediate pressure from the prevention device mounting groove 130 Flow groove 125 formed on the outer circumferential surface of the piston 121 to correspond to the piston 121 linearly moving in the device mounting groove 130 and the bypass hole 132 in a closed state by the piston 121 And a spring 122 positioned on the suction pressure side of the piston 121 to support the piston 121, and the piston 121 and the spring 122 are separated from the vacuum preventing device mounting groove 130. Vacuum prevention device 120 consisting of a stopper (123) to prevent being; It is configured to include.

Since the scroll compressor of the present invention configured as described above has the same configuration as that of the conventional scroll compressor shown in FIG. 1, detailed description of the same configuration as the conventional scroll compressor among the scroll compressor components of the present invention will be omitted. As described above, the high pressure refrigerant gas acting from the bypass hole 132 during the normal operation is formed to form a predetermined space with the lower surface of the piston 121 through the flow groove 125 of the piston 121. Only the vacuum prevention device 120 having an improved structure so that the piston 121 is balanced up and down by the refrigerant pressure introduced to the gap groove 133 in the mounting groove 130 will be described in detail.

As shown in FIG. 6, the vacuum preventing device 120 is inserted into the vacuum preventing device mounting groove 130 and is pressurized by the refrigerant pressure of the compression chamber P having an intermediate pressure during normal operation. A piston 121 having a linear motion to block the bypass hole 132 formed at the upper end of the vacuum preventing device mounting groove 130; The piston 121 so that the high-pressure refrigerant gas acting from the bypass hole 132 smoothly flows into the lower end of the vacuum preventing device mounting groove 130 through the circumferential surface of the piston 121 during the normal operation. A flow groove 125 formed at a predetermined position of the piston 121 corresponding to the bypass hole 132 when the pressure is applied; A spring (122) positioned behind the piston (121), that is, on the suction pressure side, to move the piston (121) to its original position by an elastic force when the refrigerant pressure is released; It prevents the detachment of the piston 121 and the spring 122 inserted into the vacuum preventing device mounting groove 130, and in a hollow form so that the refrigerant gas of high pressure can flow to the suction pipe (1) of the low pressure during the pump-down operation A stopper 123 formed; A fixing pin 124 fixed to the rear of the stopper 123 and preventing separation of the stopper 123 in the vacuum preventing device mounting groove 130; A vacuum preventing device mounting groove (130) formed to communicate with the suction pressure side of the fixed scroll (8); A through hole 131 formed at a lower end of the vacuum preventing device mounting groove 130 to communicate with a compression chamber P having an intermediate pressure; When the suction pressure of the compressor drops below the set suction pressure condition, the high pressure refrigerant gas flows into the vacuum prevention device mounting groove 130 and flows to the low pressure suction pipe 1 side 130. Bypass hole 132 formed on the top; It is formed with a predetermined depth at the bottom of the vacuum preventing device mounting groove 130 to form a predetermined space with the lower surface of the piston 121 while being perpendicular to the bypass hole 132, and acts from the bypass hole 132 during normal operation. A high-pressure refrigerant gas flows into a predetermined space at the lower end of the vacuum preventing device mounting groove 130 through the flow groove 125 of the piston 121, so that the gap 121 makes the piston 121 equilibrium by the refrigerant pressure. 133; The stopper 123 includes a fixing pin groove 134 formed perpendicularly to a predetermined position behind the stopper 123 to fix the fixing pin 124 for preventing the departure.

Referring to the coupling process of the vacuum prevention device 120 configured as described above, first, the flow groove 125 in the circumferential surface in the vacuum prevention device mounting groove 130 formed at a predetermined depth of the fixed scroll (8) Insert the formed piston 121, insert the stopper 123 bound with the spring 122 to the rear of the piston 121, and the fixing pin 124 to the rear of the stopper 123 to mount the vacuum prevention device By inserting and fixing the predetermined position of the groove 130, that is, the fixing pin groove 134 formed at the predetermined position behind the stopper 123, the coupling process of the vacuum preventing device 120 is terminated.

Normal operation state in the state in which the vacuum prevention apparatus 120 is coupled as described above, and the operating state of the vacuum prevention apparatus 120 when the suction pressure of the compressor drops below the set suction pressure condition by the pump-down operation or the abnormal operation. When described as follows.

7 is a view showing a state of operation of the vacuum preventing device applied to the present invention in normal operation, Figure 8 is applied to the present invention when the suction pressure of the compressor drops below the set suction pressure conditions by the pump down operation or abnormal operation. The operation state diagram of the vacuum preventing device is shown.

First, since the refrigerant pressure of the compression chamber P having an intermediate pressure is larger than the elastic force of the spring 122 in the normal operation, the spring 122 is compressed while the piston 121 is pressed by the refrigerant pressure, As shown in FIG. 7, the bypass hole 132 formed at the upper end of the vacuum preventing device mounting groove 130 is blocked by the piston 121.

Furthermore, in the state where the piston 121 pressurized by the refrigerant pressure blocks the bypass hole 132 of the vacuum preventing device mounting groove 130 as described above, the refrigerant gas of the high pressure through the bypass hole 132. The piston 121 acts on the piston 121. At this time, the circumferential surface of the piston 121, that is, the piston 121 pressurized by the refrigerant pressure and the flow groove at a predetermined position corresponding to the bypass hole 132 125 is formed, when the high-pressure refrigerant gas acts on the piston 121 through the bypass hole 132 as described above, the high-pressure refrigerant gas to the flow groove 125 of the piston 121 While the piston 121 flows into the gap groove 133 formed at the lower end of the vacuum preventing device mounting groove 130 to form a predetermined space with the lower surface of the piston 121, the piston 121 is formed in an up and down equilibrium by the introduced refrigerant pressure. Blocking the bypass hole 132, the refrigerant gas in the high pressure portion A low-pressure portion is no longer bypassed.

On the other hand, when the suction pressure of the compressor is lower than the set suction pressure condition due to the pump-down operation or the abnormal operation and is very low, the refrigerant pressure of the compression chamber P having the intermediate pressure is smaller than the elastic force of the spring 122, As the piston 122 is pressurized by the pressure and the spring 122 is elastically restored, the piston 121 is moved to its original position as shown in FIG. 8, and the by-pass was blocked by the piston 121. As the pass hole 132 is opened, the refrigerant gas of the high pressure part flows into the vacuum prevention device mounting groove 130 through the bypass hole 132, and then flows to the low pressure part through the hollow stopper to prevent high vacuum. .

In the case of the present invention through the above-described action, it is possible to prevent the phenomenon that the piston is pinched in the vacuum preventing device mounting groove by the high pressure of the conventional refrigerant gas.

The scroll compressor of the present invention is a vacuum prevention device for preventing high vacuum of the low pressure part by flowing the refrigerant gas of the high pressure part to the low pressure part when the suction pressure of the compressor is lowered below the set suction pressure condition by the pump down operation or the abnormal operation. By improving the structure of the refrigerant, the high-pressure refrigerant gas acting from the bypass hole during the normal operation flows into the gap groove in the mounting groove formed to form a predetermined space with the lower surface of the piston through the flow groove of the piston of the vacuum preventing device refrigerant The piston is balanced up and down by pressure, and the piston is pressed by the high-pressure refrigerant gas as in the prior art, so that the piston can be smoothly linearly moved inside the vacuum prevention device mounting groove without being caught in the vacuum prevention device mounting groove.

In addition, even if the suction pressure of the compressor is lower than the set suction pressure condition by the pump down operation or the abnormal operation, and the piston is moved to the original position by the spring force, the high-pressure refrigerant gas acting from the bypass hole in the normal operation is Since the piston flows into the gap groove in the mounting groove formed to form a predetermined space with the lower surface of the piston through the flow groove of the piston among the vacuum prevention devices, the piston is in a state of being in an up and down equilibrium by the refrigerant pressure. Since it is smoothly moved to its original position without being caught by the prevention device mounting groove, it is possible to prevent abrasion caused by friction between the conventional piston and the vacuum prevention device mounting groove, and in particular, the compressor according to the prevention of wear between the piston and the vacuum prevention device mounting groove. There is also an excellent effect that works smoothly.

Claims (2)

An airtight container which is an outer case; A drive motor fixed in the closed container and composed of a stator and a rotor; A drive shaft rotated by the drive motor; A swing scroll and a fixed scroll for compressing the sucked refrigerant while the swing wrap pivots in the fixed wrap through rotation of the drive shaft; An old dam ring preventing rotation of the swing scroll and allowing the swing scroll to swing within the fixed scroll; A main frame supporting the old dam ring and the pivoting scroll; A vacuum prevention device mounting groove formed to communicate with the suction pressure side of the fixed scroll, a bypass hole formed to communicate with the discharge pressure side from the vacuum prevention device mounting groove, and a compression chamber having an intermediate pressure from the vacuum prevention device mounting groove. A through hole formed so as to correspond to a piston linearly moving in the vacuum prevention device mounting groove to open and close the bypass hole according to a differential pressure between an intermediate pressure and a suction pressure, and a bypass hole closed by the piston. A vacuum prevention device including a flow groove formed on an outer circumferential surface of the piston, a spring positioned on the suction pressure side of the piston to support the piston, and a stopper preventing the piston and the spring from being separated from the vacuum prevention device mounting groove; Scroll compressor comprising a. The gap groove of a predetermined depth is further provided on the opposite side wall of the vacuum prevention device mounting groove in which the bypass hole is formed, so that the refrigerant of the discharge pressure is more smoothly supplied to the flow groove to achieve the vertical balance of the piston. Scroll compressor, characterized in that formed.