KR20040098395A - Scroll compressor - Google Patents

Abstract

PURPOSE: A scroll compressor is provided to hold axial load and to function as an existing Oldham's coupling by integrating the Oldham's coupling for repressing rotation of an orbiting scroll revolving in a fixed scroll through the rotation of a driving shaft and a thrust bearing unit. CONSTITUTION: A scroll compressor is composed of a closed container being an outer case; a driving motor fixed in the closed container and driven by electrical actions of a stator and a rotor; a driving shaft rotated by the driving motor; a main frame fixed in the closed container to support the driving shaft; an orbiting scroll positioned on the main frame and orbited by an eccentric unit formed at the upper end of the driving shaft; a fixed scroll combined to the upside of the orbiting scroll and engaged with the orbiting scroll to compress refrigerant; and a thrust bearing(60) installed between the orbiting scroll and the main frame to support axial load and composed of upper and lower keys(62,64) formed at the upper and lower sides to prevent rotation of the orbiting scroll and at least one oil hole(66) for smoothly flowing in the oil supplied from the inside of the main frame to form an oil level.

Description

Scroll compressor

The present invention relates to a scroll compressor, and more particularly, in the fixed scroll through the rotation of the drive shaft and the thrust bearing portion formed on the top of the conventional main frame to support the load acting in the axial direction of the compressor among the components of the scroll compressor. The thrust bearing integrated with the old dam ring while simultaneously supporting the axial load while supporting the axial load can be performed by integrally constructing an old dam ring that suppresses the rotating motion of the rotating scroll which rotates (orbit). By forming a plurality of oil holes in the thrust bearing, even if the axial gap of the thrust bearing decreases due to the axial load, the oil is smoothly supplied to the upper and lower surfaces of the bearing so that the thrust bearing as well as the main frame or One scroll compression to prevent turning scrolls from wear It is about the flag.

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 turning 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 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 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 (orbit) movement of the swing scroll 7. As described above, the high pressure gaseous refrigerant is compressed into the high pressure gaseous refrigerant in the compression chamber P in which the volume is changed, and the gaseous refrigerant compressed to the 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.

However, in the conventional scroll compressor, as shown in FIG. 3 to support the load acting from the axial direction, a thrust bearing portion 5b is integrally formed on the upper end of the main frame 5, and such a thrust bearing In order to give the part 5b stiffness to withstand the load acting from the axial direction, troublesome problems such as a separate heat treatment operation to increase the strength of the material to the thrust bearing part 5b are required. there was.

In addition, since the old dam ring 6 is located outside the thrust bearing portion 5b, there is a limit in increasing the outer diameter of the thrust bearing portion 5b, and the turning scroll 7 is in the thrust bearing portion 5b. Since the possibility of inclination increases, there is also a big problem that the thrust bearing portion 5b or the swinging scroll 7 is worn, causing abnormal noise and vibration in the scroll compressor.

In addition, when the axial load acts on the thrust bearing portion 5b and the old dam ring 6 as described above, the old dam ring 6 is pressed into the thrust bearing portion 5b and the all thrust bearing portion 5b and the oall ring. As the gap between the dam rings 6 is narrowed, the oil supplied from the inside of the main frame 5 by the rotation of the drive shaft 3 is not smoothly supplied to the upper and lower surfaces of the bearing part 5b, thereby preventing the old dam ring ( 6) during the straight reciprocating motion, the thrust bearing part 5b as well as the old dam ring 6 reciprocating linearly on the top surface of the thrust bearing part 5b are also worn, causing abnormal noise and vibration in the scroll compressor. There was also a big problem.

The present invention has been made in order to solve the above problems, the fixed scroll through the rotation of the drive shaft and the thrust bearing portion formed on the top of the conventional main frame to support the load acting in the axial direction of the compressor among the components of the scroll compressor The object is to be able to perform the role of the conventional Oldham ring while supporting the axial load by integrally configuring the Oldham ring to suppress the rotational motion of the orbiting scroll in the swing (orbit) movement within.

In addition, by forming a plurality of oil holes in the thrust bearing integrated with the old dam ring, even if the axial gap between the thrust bearing and the main frame and the turning scroll due to the axial load is reduced, the oil to the top / bottom of the bearing Another object of the present invention is to prevent the wear of the main frame or the turning scroll, as well as the thrust bearing, by allowing the supply to be performed smoothly.

The object of the present invention is the rotational movement of a rotating scroll which rotates in a fixed scroll through the rotation of a drive shaft and a thrust bearing portion formed at an upper end of the main frame so as to support a load acting in the axial direction of the compressor. It can be solved by the scroll compressor of the present invention configured to integrally constitute the Oldham ring to suppress the, and formed by forming a plurality of oil holes in the thrust bearing surface integrated with the Olddam ring, in detail with reference to the accompanying drawings. Explain.

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.

Figure 3 is a combined state of the main frame and the swinging scroll and Oldham ring of the components of the conventional scroll compressor.

4 is a cross-sectional view of the scroll compressor of the present invention.

5 is a perspective view of a thrust bearing applied to the present invention.

Figure 6 is a first embodiment of a thrust bearing in accordance with the present invention.

7 shows a second embodiment of a thrust bearing according to the invention.

8 shows a third embodiment of a thrust bearing according to the 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. Main Frame 5a. Keyway

5b. Thrust Bearing Part 6. Old Daming

7. Swivel Scroll 7c. Keyway

8. Fixed scroll 9. Discharge port

10. Check valve 11. Discharge chamber

12. Upper diaphragm 14. Discharge tube

15. Airtight Container 60. Thrust Bearing

62. Upper key 64. Lower key

66, 66a. Oil hole

Figure 4 is a cross-sectional view of the scroll compressor of the present invention, Figure 5 is a perspective view of a thrust bearing applied to the present invention, Figure 6 is an embodiment showing a first embodiment of the thrust bearing according to 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 closed container (15) and driven through the electrical action of the stator (2a) and the rotor (2b); A drive shaft 3 rotated by the drive motor 2; A main frame (5) fixed in the sealed container (15) to support the drive shaft (3); A swing scroll (7) positioned above the main frame (5) and driven by an eccentric portion (3a) formed at an upper end of the drive shaft (3) to pivot; A fixed scroll (8) coupled to an upper side of the swing scroll (7) to engage the swing scroll (7) to compress the refrigerant; The upper and lower keys 62 and 64 are provided on the upper and lower surfaces of the swing scroll 7 and the main frame 5 so as to support the axial load while preventing the rotation of the swing scroll 7. And a thrust bearing 60 formed through at least one oil hole 66 so that oil supplied from the main frame 5 flows smoothly to form an oil surface.

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

The scroll compressor of the present invention, while supporting the load acting from the axial direction to perform the role of the conventional Oldham ring (6), at the same time, the thrust bearing 60 and the main frame (5) due to the axial load and Even if the axial gap between the turning scrolls 7 becomes small, in order to smoothly supply oil to the upper and lower surfaces of the bearing 60, the conventional main frame 5 can support the load acting in the axial direction of the compressor. The all-dam ring 6 which suppresses the rotation of the turning scroll 7 which makes the turning (orbiting) movement in the fixed scroll 8 through the rotation of the thrust bearing part 5b and the drive shaft 3 formed at the upper end) At the same time, a plurality of oil holes 66 are formed in the thrust bearing 60 integrated with the old dam ring 6, and 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.

The scroll compressor of the present invention, as shown in Figure 4, the 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 main frame 5 supporting the drive shaft 3; A rotating scroll 7 fixed to the eccentric portion 3a of the drive shaft 3 and positioned above the main frame 5, and a fixed scroll 8 engaged with the turning scroll 7 to compress the refrigerant. A compressed scroll portion; The upper and lower keys 62 and 64 are provided on the upper and lower surfaces of the swing scroll 7 and the main frame 5 so as to support the axial load while preventing the rotation of the swing scroll 7. And a thrust bearing 60 formed through at least one oil hole 66 so that oil supplied from the main frame 5 flows smoothly to form an oil surface.

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 thrust bearing 60 and the main frame 5 due to the action of the axial load can be performed while supporting the load acting from the axial direction and performing the role of the conventional old dam ring 6. ) And the main frame so as to support the load acting in the axial direction of the compressor so that oil supply is smoothly made to the upper and lower surfaces of the bearing 60 even if the axial gap between the rotating scroll 7 and the turning scroll 7 becomes small. (5) Rotation in the fixed scroll 8 through rotation of the thrust bearing portion 5b formed on the upper end and the drive shaft 3 (idle rotation) A plurality of oil holes 66 are formed in the thrust bearing 60 integrated with the old wall ring 6 while integrally configuring the old wall ring 6 which suppresses the rotation of the swinging scroll 7 that moves. Only the thrust bearing 60 structure formed and configured will be described in detail.

The thrust bearing 60 structure applied to the scroll compressor of the present invention, as shown in Figure 5, is formed integrally on the top of the conventional main frame 5 by using a bearing material separate from the main frame 5 material. It is formed in the form of a circular ring integrating the thrust bearing portion 5b and the old dam ring 6 which prevents the rotation of the swing scroll 7. The swing scroll 7 is formed on the top and bottom surfaces of the thrust bearing 60. The thrust bearing 60 is inserted into the key grooves 7c and 5a formed on the bottom surface and the upper surface of the main frame 5, and the thrust bearing 60 linearly reciprocates in the left and right directions with respect to the pivoting scroll 7. A plurality of upper keys 62 and lower keys 64 are formed in the fixed scroll 8 to allow the pivoting scroll 7 to swing (orbit).

At this time, although the upper key 62 and the lower key 64 formed on the upper and lower surfaces of the thrust bearing 60 are formed at right angles to each other, in the case of the upper key 62 and the lower key 64 described above. Note that it does not necessarily need to protrude in the perpendicular direction.

In addition, at a predetermined position of the thrust bearing 60, oil supplied from the inside of the main frame 5 smoothly flows on the upper and lower surfaces of the bearing 60 to form oil surfaces on the upper and lower surfaces of the bearing 60. A plurality of oil holes 66 are formed so that the oil holes 66 may be formed in a circular shape having a predetermined diameter along the circumferential direction of the thrust bearing as shown in FIGS. 5 and 6. .

In the case of the thrust bearing 60 structure described above, the main frame 5 includes the upper and lower keys 62 and 64 protruding from the upper and lower surfaces of the scroll compressor of the present invention, that is, the thrust bearing 60. A scroll compressor of the type in which the thrust bearing 60 is installed between the main frame 5 and the pivoting scroll 7 by being inserted into a key groove 5a, 7c formed on an upper surface and a bottom of the pivoting scroll 7. In addition, in addition to the upper and lower keys 62, 64 are formed on the upper and lower surfaces of the turning scroll 7 in a state in which a thrust bearing portion 5b is generally formed on the upper side of the main frame 5. In the upper surface of the swing scroll 7 by the lower key 64 of the rotation is prevented from rotating the linear reciprocating movement, by the upper key 62 of the swing scroll 7 directly coupled to the fixed scroll (8) The pivoting scroll 7 is straight at the bottom of the fixed scroll 8 A scroll compressor of the type in which the swing scroll 7 swings (orbits) in the fixed scroll 8 through a reciprocating motion, or the fixed scroll 8 and the swing scroll 7 are installed opposite to each other. The circular oil hole 66 formed in the circumferential direction of the thrust bearing 60 applied to the present invention is also applied to a scroll compressor of the type in which the pivoting scroll 7 pivots on the fixed scroll 8. Note that it can be used.

In addition, the operation of the scroll compressor of the present invention is operated in the same process as the conventional scroll compressor (a state in which the turning scroll 7 compresses the refrigerant sucked through the swinging (orbital) movement in the fixed scroll 8) to the refrigerant. Because of the compression, this also the description of the operation of the scroll compressor of the present invention will be omitted.

7 and 8 are exemplary views showing the second and third embodiments of the thrust bearing according to the present invention. As shown in FIGS. 7 and 8, the oil supplied from the inside of the main frame 5 is A plurality of oil holes 66a having a long hole shape are formed along the circumferential direction of the thrust bearing 60 so as to smoothly flow into the upper and lower surfaces of the bearing 60.

As the oil supplied from the inside of the main frame 5 is smoothly supplied to the upper and lower surfaces of the thrust bearing 60 through the configuration of the embodiments described above, according to the linear reciprocating motion of the thrust bearing 60. The thrust bearing 60, of course, has a feature that can prevent the main frame 5 or the swinging scroll 7 to be worn.

The scroll compressor of the present invention is pivoted in a fixed scroll through rotation of a drive shaft and a thrust bearing part formed on an upper end of a conventional main frame so as to support a load acting in the axial direction of the compressor among components of a conventional scroll compressor. By integrally configuring the old dam ring to suppress the rotational movement of the rotating scroll to exercise, there is an excellent effect that can perform the role of conventional old dam ring while supporting the axial load.

In addition, by forming a plurality of oil holes in the thrust bearing integrated with the old dam ring, even if the axial gap between the thrust bearing and the main frame and the turning scroll due to the axial load is reduced, the oil to the top / bottom of the bearing By providing a smooth supply, there is an excellent effect that can prevent the wear of the main frame or the rotating scroll, as well as the thrust bearing.

In addition, since oil is supplied to the upper and lower surfaces of the thrust bearing through the oil hole formed in the thrust bearing as described above, oil is formed on the upper and lower surfaces of the bearing. In addition to the sealing effect by the oil surface formed on the upper and lower surfaces of the bearing, the thrust bearing including the oil surface formed on the upper and lower surfaces of the bearing in an axial direction can support a larger load than the conventional one. There is also an excellent effect.

Claims (3)

An airtight container which is an outer case; A drive motor fixed in the closed container and driven through an electrical action of a stator and a rotor; A drive shaft rotated by the drive motor; A main frame fixed in the sealed container to support the drive shaft; A pivoting scroll positioned above the main frame and driven by an eccentric portion formed at an upper end of the driving shaft to pivot; A fixed scroll coupled to an upper side of the swing scroll to engage the swing scroll to compress the refrigerant; It is installed between the pivoting scroll and the main frame to support the axial load while the upper and lower keys are formed on the top / bottom to prevent the rotation of the pivoting scroll, the oil supplied from the inside of the main frame is smoothly introduced And a thrust bearing formed by passing at least one oil hole so as to form an oil surface. The scroll compressor according to claim 1, wherein a plurality of oil holes are formed in a circular shape along the circumferential direction of the thrust bearing. The scroll compressor according to claim 1, wherein the oil holes are formed in plural in the form of long holes along the circumferential direction of the thrust bearing.