KR100557053B1 - Scroll compressor - Google Patents

Abstract

The present invention relates to a scroll compressor, which forms an oil groove at a predetermined position on the upper side of the main frame on which the Old Daming, the anti-rotation mechanism of the revolving scroll, among the components of the scroll compressor is seated, from the inside of the main frame through the rotation of the drive shaft. The oil supplied is confined in the oil groove formed at the top of the main frame to reduce the friction force between the old dam ring and the main frame during initial startup of the compressor, thereby preventing the old dam ring or the main frame from being worn, and the smooth compression action. It has an excellent effect of making it happen.

In addition, there is also an excellent effect that can significantly reduce the abnormal noise and vibration of the compressor due to the frictional force between the old dam ring and the main frame.

Scroll compressor, main frame, oil groove, oil level

Description

Scroll compressor

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 an exploded perspective view of a pivoting scroll and olddaming, the main frame of the components of a conventional scroll compressor.

Figure 4 is a perspective cross-sectional view showing an exploded state of the fixed scroll and swing scroll, Oldham ring, main frame according to the invention.

5 is a cross sectional view of a fixed scroll and swinging scroll, an Oldham ring, a main frame according to the present invention;

Explanation of symbols on the main parts of the drawings

1. Suction line 2. Drive motor

3. Drive shaft 3a. Drive shaft eccentric

5, 15. Main Frame 15a. Keyway

6, 16. Oldhamling 16a. Upper key

16b. Subkey 7. Swivel Scroll

7c. Keyway 8. Fixed Scroll

9. Outlet port 10. Check valve

11.Discharge chamber 12. Upper diaphragm

14. Discharge tube 15. Case

20. Oil groove

The present invention relates to a scroll compressor, and more particularly, oil is trapped at an upper end of a main frame on which an old dam ring, which is an anti-rotation mechanism of a revolving scroll, of the components of the scroll compressor is mounted. The present invention relates to a scroll compressor in which an oil groove is formed at a predetermined position on an upper end of the main frame so as to reduce frictional force of the liver and thereby reduce noise and vibration of the compressor.

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 case 15; A suction pipe 1 and a suction chamber 4 for allowing fluid (refrigerant) to flow from the outside; A drive motor 2 fixed in the case 15 and comprising a stator 2a and a rotor 2b; A drive shaft 3 rotated by the drive motor 2; And a drive shaft eccentric portion 3a provided eccentrically at the center of the drive shaft 3 on the top 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 refrigerant gas 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 main frame 5; 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 discharge port (9) for discharging the high-pressure refrigerant gas compressed by 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 gas discharged through the discharge port (9); An upper diaphragm coupled to a rear surface of the fixed scroll 8 and partitioning the case 15 into an intake chamber 4 through which low-pressure refrigerant gas is sucked and a discharge chamber 11 through which high-pressure refrigerant gas is discharged and accumulated. 12; It is coupled to the discharge chamber 11 is composed of a discharge pipe 14 for discharging the high-pressure refrigerant gas. 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 configuration, the drive shaft 3 inserted 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 surface 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 in the longitudinal direction is performed, and in the case of the old dam ring 6, the upper surface of the main frame 5 extends from the upper surface of the main frame 5 in the longitudinal direction of the lower key 6b of the old dam ring 6. By performing a linear reciprocating motion in the formed keyway 5a, only the pivoting (idle) motion is made in the pivoting scroll 7 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-temperature low-pressure gas phase refrigerant flowing through the evaporator (not shown) of the refrigeration cycle equipment flows into the chamber P, the low-temperature, low-pressure gas phase refrigerant flows in accordance with the turning (idle) motion of the turning scroll 7. As shown in FIG. 2, the gaseous refrigerant of a high temperature and 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. Will be.

As such, the high temperature and high pressure gaseous 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.

However, in the initial start-up of a conventional scroll compressor, a thrust bearing formed at the top of the main frame so that oil flows from the inside of the main frame 5 through the rotation of the drive shaft 3 to support the load applied from the top, that is, the axial direction. Since it does not stay in the portion 5b (see FIG. 3), the linear reciprocating motion of the old dam ring 6 according to the swinging motion of the swinging scroll 7 during the initial startup of the compressor as described above, that is, of the main frame 5 As the frictional force between the Old Daming 6 and the main frame 5 linearly reciprocating at the upper end of the thrust bearing part 5b was greatly increased, there was a big problem that abnormal noise and vibration occurred in the compressor.

In addition, as the above-mentioned old wall ring (6) or the main frame (5) is worn as the friction force between the old wall ring (6) and the main frame (5) increases, the smooth between the turning scroll (7) and the fixed scroll (8). There was also a big problem that the compression did not work.

The present invention has been made in order to solve the above problems, by forming an oil groove in the upper predetermined position of the main frame on which the Old Daming, which is the anti-rotation mechanism of the swinging scroll of the components of the scroll compressor, the main shaft through the rotation of the drive shaft The oil supplied from the inside of the frame is confined in the oil groove formed on the top of the main frame to prevent the old dam ring or the main frame from being worn by lowering the friction force between the old dam ring and the main frame during initial startup of the compressor. The purpose is to ensure a smooth compression.

In addition, there is another object to greatly reduce the abnormal noise and vibration of the compressor due to the frictional force between the Oldham ring and the main frame.

The object of the present invention is to lock the oil on the top of the main frame on which the old dam ring, the anti-rotation mechanism of the revolving scroll, to reduce the frictional force between the old dam ring and the main frame during the initial startup of the compressor, resulting in noise and vibration of the compressor. The bar can be solved by the scroll compressor of the present invention in which an oil groove is formed at a predetermined position on the upper side of the main frame so as to reduce the pressure.

4 is a perspective cross-sectional view illustrating an exploded state of the fixed scroll and the swinging scroll, the old dam ring, and the main frame according to the present invention, and FIG. 5 is a combined sectional view of the fixed scroll and the turning scroll, the old dam ring, and the main frame according to the present invention.

The scroll compressor of the present invention, the case 15; A drive motor 2 fixed in the case 15 and comprising 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); A thrust bearing portion for preventing rotation of the pivoting scroll 7 and supporting a load acting in the axial direction, and an up / down key for allowing the pivoting scroll 7 to pivot in the fixed scroll 8 ( An olddam ring 16 including 16a) and 16b; A main frame 15 supporting the old dam ring 16 and the revolving scroll 7 and having a key groove 15 a formed at an upper end thereof so as to be engaged with the lower key 16 b of the old dam ring 16; The oil supplied from the inside of the main frame 15 is confined through the rotation of the drive shaft 3 so that the friction force between the thrust bearing part and the main frame 15 and the lower key 16b and the key groove at the initial start of the compressor. And an oil groove 20 formed at a predetermined position on the top of the main frame 15 so as to lower the friction force between the portions 15a.

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

In the scroll compressor of the present invention, the oil supplied from the inside of the main frame 15 through the rotation of the drive shaft 3 is confined to the upper end of the main frame 15 so that the old dam ring 16 and the main at the initial start of the compressor. The friction force between the frames 15 is reduced to prevent the olddam ring 16 or the main frame 15 from being worn, and the predetermined position at the upper end of the main frame 15, that is, the radial direction, can be smoothly compressed. As a configuration in which the oil groove 20 is formed, the present invention will be described in detail. The same reference numerals will be applied to the same configurations as those of the present invention and the conventional art described above.

A scroll compressor according to the present invention, as shown in Figures 1 and 4, the case 15; A drive motor 2 fixed in the case 15 and comprising 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 (16) for supporting rotation prevention and axial load of the swing scroll (7) and allowing the swing scroll (7) to pivot within the fixed scroll (8); A main frame (15) for supporting the old dam ring (16) and the revolving scroll (7); The main frame is confined by the oil supplied from the inside of the main frame 15 through the rotation of the drive shaft 3 so that the friction force between the old dam ring 16 and the main frame 15 may be reduced during initial startup of the compressor. 15, an oil groove 20 formed at a predetermined position on the upper end thereof.

At this time, the main frame 15 is a state in which the thrust bearing portion 5b for supporting the load acting from the axial direction of the compressor in the structure of the conventional main frame 5 is removed as shown in FIG. As a structure, the upper surface of the main frame 15 forms a flat plane, and the Oldham ring 16 is seated on the upper end of the main frame 15 so that the linear reciprocating motion can be performed. The key groove 15a of a predetermined length is formed on the upper end of the main frame 15 corresponding to the 16b.

In addition, the oil groove 20 formed at a predetermined position on the top of the main frame 15 is formed in an arc shape along the upper radial direction of the main frame 15, and the key groove 15a formed on the top of the main frame 15. It is formed in an interconnected form.

In addition, the old dam ring 16 has a main frame for supporting a load acting in an axial direction with the old dam ring 6 for preventing the rotating scroll 7 from rotating among the components of the conventional scroll compressor shown in FIG. 3. (5) The thrust bearing portion 5b formed at the upper end is integrally formed (see FIG. 4), and in the case of the old dam ring 16 applied to the present invention, the same as that of the conventional scroll wheel 7 It is installed between the pivoting scroll 7 and the main frame 15 from which the thrust bearing part 5b has been removed to prevent the rotation, and the old dam ring 16 is moved forward / backward based on the pivoting scroll 7. And a key groove formed in the pivoting scroll 7 and the main frame 15 to allow the pivoting scroll 7 to swing (orbit) in the fixed scroll 8 while linearly reciprocating in a left / right direction. (7c) the upper key 16a and the lower and upper and lower surfaces of the Oldham ring 16 corresponding to 15a. A large number of bookies 16b are formed.

In the case of the main frame 15 and the Oldham ring 16 structure described above, it is noted that the present invention can be applied not only to the low pressure scroll compressor of the present invention but also to the high pressure scroll compressor.

In addition, the operation process of the scroll compressor to which the present invention is applied is operated in the same process as the conventional scroll compressor (a state in which the rotating scroll 7 compresses the refrigerant sucked through the rotating (idle) movement in the fixed scroll 8). Since the refrigerant is compressed (see FIG. 2), the detailed description of the present invention will omit the overall operation description of the scroll compressor, and the compressor in the state where oil is filled in the oil groove 20 on the top of the main frame 15. Only the interaction relationship between the old dam ring 16 and the main frame 15 in the initial startup will be described.

As described above, when the compressor is initially started while the oil groove 20 formed at the top of the main frame 15 is filled with oil, the old dam ring 16 is rotated by the pivoting motion of the swing scroll 7. 15) when the straight reciprocating motion is made at the upper end between the old dam ring 16 and the main frame 15 which linearly reciprocate the upper end of the main frame 15 by lubricating oil filled in the oil groove 20. The frictional force is lowered, so that the straight reciprocating motion of the Oldham ring 16 is made smoothly at the top of the main frame 15.

Further, when the smooth straight reciprocation of the old dam ring 16 is made at the top of the main frame 15 by the lubrication of the oil, it is coupled to the key groove 15a and the key groove 15a formed at the top of the main frame 15. The oil is also supplied between the lower keys 16b of the old dam ring 16 so that the lower key 16b of the old dam ring 16 linearly reciprocates in the key groove 15a through lubrication of the supplied oil. You will have a smooth reciprocating motion.

The scroll compressor described above locks the oil supplied from the inside of the main frame 15 through the rotation of the drive shaft 3 in the oil groove 20 formed at the upper end of the main frame 15 to initially start the compressor. By lowering the friction force between the old wall ring 16 and the main frame 15 is characterized in that the old wall ring 16 or the main frame 15 can be prevented from being worn.

The scroll compressor of the present invention forms an oil groove at a predetermined position on the upper side of the main frame on which the Old Daming, which is a rotating prevention mechanism of the rotating scroll, of the components of the scroll compressor, and is supplied from the inside of the main frame through the rotation of the drive shaft. Is trapped in the oil groove formed on the top of the main frame to reduce the friction between the old dam ring and the main frame during initial startup of the compressor to prevent the old dam ring or the main frame from being worn, and to achieve a smooth compression. Excellent effect

In addition, there is also an excellent effect that can significantly reduce the abnormal noise and vibration of the compressor due to the frictional force between the old dam ring and the main frame.

Claims (3)

A case; A drive motor fixed in the case and comprising 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 all-dam ring including a thrust bearing portion for preventing rotation of the swing scroll and supporting a load acting in an axial direction, and an up / down key for allowing the swing scroll to swing within the fixed scroll; A main frame supporting the old dam ring and the revolving scroll and having a key groove formed at an upper end thereof so as to be coupled to a lower key of the old dam ring; The upper part of the main frame may lock the oil supplied from the inside of the main frame through rotation of the drive shaft so that the friction force between the thrust bearing part and the main frame and the friction force between the lower key and the key groove may be reduced during initial startup of the compressor. An oil groove formed in a predetermined position; Scroll compressor comprising a. The scroll compressor according to claim 1, wherein the oil groove is formed at least one in an arc shape along the upper radial direction of the main frame. The scroll compressor according to claim 1 or 2, wherein the oil grooves are interconnected with key grooves formed on the top of the main frame.

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