KR102392655B1 - Compressor having seperated oil retrun flow path and refrigerant flow path - Google Patents

Abstract

The present invention relates to a compressor capable of reducing oil shortage caused by delay in oil recovery by separating an oil recovery flow path and a refrigerant flow path.
The compressor according to the present invention includes a flow guide for guiding the coolant through the space between the insulators of the stator, and provides a structure capable of blocking the coolant discharged from the compression unit from flowing into the oil recovery passage. The flow guide includes an inner wall portion and an outer wall portion, and the outer wall portion is formed to overlap the insulator outer plate, thereby improving the airtightness of the refrigerant passage.

Description

A compressor that separates the refrigerant discharge path and the oil return path {COMPRESSOR HAVING SEPERATED OIL RETRUN FLOW PATH AND REFRIGERANT FLOW PATH}

The present invention relates to a compressor in which a discharge passage of a refrigerant and a return passage of oil can be separated.

In general, a compressor is applied to a vapor compression type refrigeration cycle such as a refrigerator or an air conditioner.

The compressor may be classified into a reciprocating type, a rotary type, a scroll type, etc. according to a method of compressing the refrigerant.

In the reciprocating compressor, the piston driving part moves the piston in a straight line to compress the refrigerant.

The rotary compressor compresses the refrigerant using a rolling piston that rotates eccentrically in the compression space of a cylinder and a vane that comes into contact with the rolling piston and divides the compression space of the cylinder into a suction chamber and a discharge chamber.

In the scroll compressor, a fixed scroll is fixed in the inner space of an airtight container, and the orbiting scroll is engaged with the fixed scroll to perform a turning motion. It is a compressor in which a pair of compression chambers are continuously formed.

Scroll compressors are widely used for refrigerant compression in air conditioners because of the advantages of obtaining a relatively high compression ratio compared to other types of compressors and obtaining a stable torque by smoothly connecting refrigerant suction, compression, and discharge strokes.

On the other hand, the compressor may be divided into an upper compression type or a lower compression type according to the positions of the driving motor and the compression unit. The upper compression type is a method in which the compression unit is located above the drive motor, and the lower compression type is a method in which the compression unit is located below the drive motor. In particular, in the case of the lower compression type, the refrigerant discharged to the inner space of the casing moves to the discharge pipe located at the upper portion of the casing, whereas the oil is, conversely, returned to the oil storage space provided at the lower side of the compression unit. There is a risk of being discharged to the outside or being pushed by the pressure of the refrigerant to stagnate on the upper side of the drive motor.

The present invention uses a high-pressure, lower-compression scroll compressor (hereinafter abbreviated as a lower-compression scroll compressor) as an example of a technology for reducing oil leakage by separating a passage through which oil is recovered and a passage through which refrigerant is discharged inside a casing. Explain.

1 is a cross-sectional view showing an example of a conventional lower compression scroll compressor.

As shown in this figure, in the conventional lower compression scroll compressor, the driving motor 2 is provided in the inner space of the casing 1 and has a stator and a rotor, and a compression unit provided below the driving motor 2 . (3), it includes a rotating shaft (5) for transmitting the rotational force of the driving motor (2) to the compression unit (3). A refrigerant discharge pipe 16 is installed at an upper portion of the casing 1 .

In the inner peripheral surface of the casing (1) and the outer peripheral surface of the driving motor (2), or inside the driving motor (2), the refrigerant discharged from the compression unit (3) is guided to move in the direction of the refrigerant discharge pipe (16) At the same time, a flow path Pm is formed to guide the oil separated from the refrigerant in the space above the driving motor 2 to be recovered to the oil storage space V3 below the compression unit 3 .

In the conventional lower compression scroll compressor as described above, the refrigerant and oil discharged from the compression unit 3 move upwards of the driving motor 2 through the flow path Pm provided in the driving motor 2 . Then, it is discharged to the outside of the compressor through the refrigerant discharge pipe 16 .

At this time, the oil separated from the refrigerant between the driving motor 2 and the compression unit 3 moves to the oil storage space V3 through the flow path Pc provided in the compression unit 3, while the driving motor 2 ), the oil separated from the refrigerant moves to the oil storage space V3 below the compressor through the flow path Pm provided in the driving motor 2 and the flow path Pc provided in the compression unit 3 . will do

However, in the conventional lower compression scroll compressor as described above, as the refrigerant and oil move together through the flow path Pm provided in the drive motor 2 , the drive motor 2 moves from the upper side to the lower side. The oil may be mixed with the refrigerant discharged from the compression unit 3 and discharged to the outside of the compressor together with the refrigerant.

Alternatively, the oil may not pass through the flow path Pm of the driving motor 2 due to the high-pressure refrigerant and may be stagnated in the space above the driving motor 2 . Then, as the amount of oil recovered to the storage space V3 is rapidly reduced, the amount of oil supplied to the compression unit 3 is decreased, causing friction loss or wear of the compression unit.

In addition, the oil supplied to the compression unit 3 through the oil passage of the rotary shaft 5 to lubricate the compression unit 3 and the oil flowing into the space between the drive motor 2 and the compression unit 3 is There is also a problem in that the refrigerant discharged from the compression unit 3 is mixed with the refrigerant and moved to the upper side of the driving motor 2 along with the refrigerant and discharged to the outside of the compressor, further exacerbating the shortage of oil in the compressor.

An object of the present invention is to provide a scroll compressor capable of smoothly recovering oil to a storage space by separating a refrigerant passage and an oil return passage in a casing.

Another object of the present invention is to provide a scroll compressor that lubricates a compression unit and prevents oil flowing into a space between the compression unit and a driving motor from mixing with refrigerant discharged from the compression unit, thereby allowing oil to be smoothly recovered.

A scroll compressor according to an embodiment of the present invention includes a flow path guide between the driving motor and the compression unit, and guides the refrigerant discharged from the compression unit into the flow path guide, thereby separating the oil recovery path and the refrigerant path. provide structure.

The flow guide is formed to overlap and surface contact with the insulator of the driving motor to provide a structure capable of blocking the refrigerant discharged from the compression unit from flowing into the oil recovery passage.

The compressor according to the present invention provides a structure in which the refrigerant discharged from the compression unit moves to the refrigerant discharge pipe through the refrigerant passage, and the oil separated from the upper side of the driving motor can smoothly move to the oil storage space through the oil passage. . Accordingly, the flow path through which the refrigerant is discharged and the flow path through which the oil is recovered are separated, so that the flow of oil is not hindered by the refrigerant. As a result, oil can be smoothly returned to the oil storage space, thereby preventing oil shortage during compressor operation.

In addition, the compressor according to the present invention lubricates the compression unit and prevents the oil flowing out from mixing with the refrigerant discharged from the compression unit, as well as recovering the oil to the storage space through a separate recovery passage, so that the oil is discharged out of the compressor together with the refrigerant have the effect of preventing it from happening.

1 is a cross-sectional view for explaining the flow of a refrigerant and oil of a conventional compressor.
2 is a longitudinal cross-sectional view for explaining the structure of the scroll compressor according to the first embodiment of the present invention.
3 is a perspective view illustrating a flow path guide of the scroll compressor according to the first embodiment of the present invention.
4 is a view for explaining a refrigerant passage and an oil recovery passage of the scroll compressor according to the first embodiment of the present invention.
5 is a view for explaining a refrigerant passage and an oil recovery passage of a scroll compressor according to a second embodiment of the present invention.
6 is a view for explaining a refrigerant passage and an oil recovery passage of a scroll compressor according to a third embodiment of the present invention.
7 is a view for explaining a refrigerant passage and an oil recovery passage of a scroll compressor according to a fourth embodiment of the present invention.
8 is a view for explaining a refrigerant passage and an oil recovery passage of a scroll compressor according to a fifth embodiment of the present invention.

Hereinafter, a compressor with improved lubrication performance according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a longitudinal cross-sectional view for explaining the structure of the scroll compressor according to the first embodiment of the present invention.

The scroll compressor of the illustrated embodiment corresponds to a hermetic compressor in which a driving motor and a compression unit are installed together in a sealed casing, and since the compression unit is located below the driving motor, it corresponds to a lower compression type compressor.

The scroll compressor according to the present embodiment includes a casing 210 that seals an internal space, a driving motor 220 disposed above the internal space, a compression unit 200 disposed below the driving motor, and the and a rotating shaft 226 for transmitting the rotational force of the driving motor 220 to the compression unit 200 .

Hereinafter, each configuration will be described in more detail.

[Casing (210)]

The casing 210 serves to seal the inner space, and for this purpose, it may be formed in a cylindrical shape in which the upper part and the lower part are closed.

The casing 210 includes a cylindrical shell 211 corresponding to the middle portion, an upper shell 212 coupled to an upper portion of the cylindrical shell 211, and a lower shell 214 coupled to the lower portion of the cylindrical shell 211. include

The inner space of the casing 210 is a lower portion of the upper shell 212 and an upper side of the driving motor 220, a first space V1, and a second space between the driving motor 220 and the compression unit 200 ( V2), a third space V3 corresponding to the lower portion of the fixed scroll 250 and the interior of the discharge cover 270, and a fourth space below the discharge cover 270 and corresponding to the upper portion of the lower shell 214 (V4) can be distinguished.

A refrigerant discharge pipe 216 is installed in the upper shell 212 . The inlet of the refrigerant discharge pipe 216 is disposed in the first space (V1).

The refrigerant compressed in the compression unit 200 is discharged into the second space V2, and the refrigerant discharged into the second space V2 passes through the driving motor 220 and moves to the first space V1, It is discharged through the refrigerant discharge pipe 216 disposed in the first space (V1).

At this time, it is preferable to prevent the oil from flowing out through the refrigerant discharge pipe 216 together with the refrigerant. This is because, when the oil to be circulated inside the compressor flows out through the refrigerant discharge pipe 216 , the amount of oil circulating inside the compressor decreases, thereby reducing lubrication and cooling effects.

For this, an oil separator (not shown) for separating oil may be connected to the refrigerant discharge pipe 216 .

The fourth space V4 below the lower shell 214 serves as an oil storage space for storing oil. In other words, the fourth space V4 functions as an oil chamber for temporarily storing oil supplied to a lubrication required section to which oil is to be supplied inside the compressor. During the operation of the compressor, the oil stored in the fourth space V4 is supplied to the section requiring refueling and is circulated, and when the compressor is stopped, the oil is collected in the fourth space V3.

On the other hand, a refrigerant suction pipe 218, which is a passage through which the refrigerant to be compressed is introduced, is installed on the side surface of the cylindrical shell 211 . The refrigerant suction pipe 218 passes through the side surface of the fixed scroll 250 and is connected to the compression chamber S1.

The refrigerant introduced through the refrigerant suction pipe 218 has a relatively lower pressure than that of the refrigerant discharged through the refrigerant discharge pipe 216 . Hereinafter, the pressure of the refrigerant introduced through the refrigerant suction pipe 218 is referred to as a low pressure, the refrigerant discharged through the refrigerant discharge pipe 216 is referred to as a high pressure, and the pressure between them is referred to as an intermediate pressure.

[Drive motor (220)]

The compressor according to the present embodiment is a lower compression type, and a driving motor 220 for driving the compression unit 200 is disposed on the upper side in the inner space of the casing 210 . Of course, in the case of the upper compression type compressor, the driving motor is disposed on the lower side in the inner space of the casing 210 .

The driving motor 220 includes a stator and a rotor 224 . The stator is formed in a cylindrical shape so that the outer circumferential surface of the stator is fixed to the inner surface of the casing 210 . The stator includes an iron core 222 formed in a substantially annular shape and stacked with a plurality of sheets, and a coil 222a wound around the iron core 222 . In addition, an insulator 223 for insulating the coil 222a and the iron core 222 is provided in the stator.

The stator has a plurality of slots formed along the circumferential direction on its inner circumferential surface, and a coil 222a is wound in the slots.

An oil return passage 212a may be provided on the outer circumferential surface of the stator.

The oil return passage 212a provides a path through which the refrigerant separated in the first space V1 passes through the driving motor 220 and moves to the oil storage space. The rotor 224 rotates inside the stator to generate rotational power. The rotational power generated by the rotor 224 is transmitted to the compression unit 200 through the rotation shaft 225 . The rotating shaft 225 is coupled to the rotor 224 and rotates integrally with the rotor 224 .

[Compression unit 200]

The compression unit 200 includes a main frame 230 , a fixed scroll 250 , an orbiting scroll 240 , and a discharge cover 270 .

[Main Frame (230)]

The main frame 230 forms an upper portion of the compression unit 200 , and faces a lower portion of the driving motor 220 .

The main frame 230 includes a frame end plate part 232 and a frame side wall part 231 .

The frame head plate part 232 is formed in a substantially circular shape and has a frame bearing part 232a in the center. The frame bearing portion 232a is a portion through which the rotation shaft passes. The frame bearing part 232a may be formed to protrude from the upper surface of the frame head plate part 232 toward the driving motor 220 , and is rotatably coupled to the main bearing part MB of the rotation shaft 226 .

The frame side wall portion 231 extends toward the fixed scroll, and the lower end thereof is coupled to the fixed scroll 250 . In addition, the outer peripheral portion of the frame side wall portion 231 is coupled to the cylindrical shell 211 of the casing (210).

The frame side wall portion 231 includes a frame discharge hole 231a penetrating the inside thereof in the axial direction (longitudinal direction). The frame discharge hole 231a provides a passage through which the compressed refrigerant can move from the third space V3 to the second space V2. The frame discharge hole 231a is connected to the fixed scroll discharge hole 256b provided in the fixed scroll 250 .

The main frame 230 is coupled to the fixed scroll 250 , and the orbiting scroll 240 is pivotably disposed between the main frame 230 and the fixed scroll 250 .

A back pressure chamber S2 is formed between the bottom surface of the main frame 230 and the orbiting scroll 240 . The back pressure chamber S2 includes an intermediate pressure region having a pressure between a low pressure and a high pressure. The orbiting scroll 240 is brought into close contact with the fixed scroll 250 by the pressure of the back pressure chamber S2 .

An Oldham's ring 150 is provided between the main frame 230 and the orbiting scroll 240 . The Oldham ring 150 serves to cause the orbiting scroll 240 to only rotate without rotating.

[Fixed Scroll (250)]

The fixed scroll 250 includes a fixed head plate part 254 , a fixed scroll side wall part 255 , a fixed wrap 251 , and a fixed scroll bearing part 252 .

The fixed end plate 254 has a substantially circular shape. The fixed end plate 254 is provided with a discharge port 253 for discharging the refrigerant compressed in the compression chamber (S1).

The fixed scroll sidewall 255 extends from the outer periphery of the fixed end plate 254 toward the main frame and is connected to the main frame sidewall 231 .

The fixing wrap 251 is formed to protrude toward the upper side of the fixing end plate 254 . The fixed wrap 251 engages with the orbiting wrap 241 of the orbiting scroll 240 to form a compression chamber S1.

The fixed scroll bearing part 252 is formed in the center of the fixed head plate part 254 and is a part through which the rotation shaft 225 passes.

On the other hand, a discharge cover 270 that accommodates the refrigerant discharged from the compression chamber and partitions the third space V3 is coupled to the lower surface of the fixed scroll 250 .

The fixed scroll sidewall 255 includes the fixed scroll discharge hole 256b connected to the frame discharge hole 231a described above. The frame discharge hole 231a and the fixed scroll discharge hole 256b allow the refrigerant discharged from the compression chamber S1 to the third space V3, which is the inner space of the discharge cover 270, to flow into the second space V2. play a role in enabling

The fixed scroll bearing part 252 may be formed to protrude from the lower surface of the fixed head plate part 254 toward the oil storage space V4. In this case, the lower end of the fixed scroll bearing unit 252 may be bent toward the center so that the lower end supports the lower end of the sub bearing unit SB of the rotating shaft 226 to form a thrust bearing surface.

[Discharge cover (270)]

The discharge cover 270 serves to prevent the refrigerant discharged from the discharge port 253 provided in the fixed end plate 254 from being mixed with the oil stored in the fourth space V4. The discharge cover 270 is coupled to seal the space between it and the bottom surface of the fixed scroll 250 .

The discharge cover 270 has a through hole 276 through which the oil feeder 271 passes. The oil feeder 271 is coupled to the sub-bearing part SB of the rotating shaft 226 and is immersed in oil stored in the oil storage space of the casing 210 .

[Orbiting Scroll (240)]

The orbiting scroll 240 is disposed between the main frame 230 and the fixed scroll 250 , and is coupled to the eccentric portion EC of the rotation shaft 226 . The orbiting scroll 240 rotates by rotation of the rotating shaft 226 .

The orbiting scroll 240 includes a turning head plate part 245 , a turning wrap 241 , and a rotation shaft coupling part 242 .

The orbiting head plate part 245 has a substantially circular shape and faces the fixed head plate part 245 .

The orbiting wrap 241 protrudes from the bottom surface of the turning end plate 245 toward the fixed end plate 245 to be engaged with the fixed wrap 251 . The lower surface of the orbiting wrap 241 is in close contact with the upper surface of the fixed end plate 254 .

The rotating shaft coupling part 242 is disposed in the center of the rotating head plate part 245 and is rotatably coupled to the eccentric part EC of the rotating shaft. The rotation shaft coupling part 242 is formed to have a height overlapping with the orbit wrap 241 and is connected to the orbit wrap 241 . The rotation shaft coupling portion 242 is connected to the orbital wrap 241 and also serves to form the compression chamber S1 together with the fixed wrap 251 in the compression process.

When the refrigerant is compressed, the repulsive force of the refrigerant is applied to the fixed wrap 251 and the orbiting wrap 241, and as a reaction force therefor, a compressive force is applied between the rotating shaft coupling part 242 and the eccentric part EC.

The scroll compressor according to the embodiment of the present invention has a structure in which the eccentric portion EC of the rotating shaft 226 passes through the orbiting head plate 245 of the orbiting scroll 240 and overlaps with the orbiting wrap 241 in a radial direction. have In this structure, the repulsive force and compressive force of the refrigerant are applied in the same plane with respect to the turning head plate part 245 . Accordingly, since the repulsive force and the compressive force of the refrigerant cancel each other out, it is possible to reduce the inclination of the orbiting scroll 240 .

[Rotation shaft 226]

It serves to transmit the rotational force of the driving motor 220 of the rotating shaft 226 to the compression unit 200 and to provide a flow path through which oil is supplied.

The upper portion of the rotary shaft 226 is integrally coupled to the rotor 224 of the driving motor 220 , and the lower portion of the rotary shaft 226 is rotatably coupled to the compression unit 200 .

The rotating shaft 226 has a main bearing part MB, a sub bearing part SB, an eccentric part EC, an oil supply passage 226a, an oil supply hole H1, H2, H3, H4, H5, and , and oil supply grooves (G1, G2).

The oil supply passage 226a is provided at the center of the rotation shaft in the axial direction. The oil supply passage 226a provides a path through which the oil stored in the oil storage space V4 can move upward.

The main bearing part MB is coupled to the frame bearing part 232a of the main frame 230 . The sub bearing part SB is coupled to the fixed scroll bearing part 252 of the fixed scroll 250 . The eccentric part EC is disposed between the main bearing part MB and the sub bearing part SB, and is coupled to the rotation shaft coupling part 242 of the orbiting scroll 240 .

The main bearing part MB, the sub bearing part SB, and the eccentric part EC all have a circular cross section. The diameter of each part may be set differently.

The axial center of the sub bearing part SB coincides with the axial center of the main bearing part MB, and the axial center of the eccentric part EC is formed to be eccentric with respect to the axial center of the main bearing part MB. . In other words, the main bearing part MB and the sub bearing part SB are formed on the same axis to have the same axial center, and the eccentric part EC is circular at an eccentric position with respect to the axial center of the main bearing part MB. is formed by the cross section of

The eccentric part EC may have an outer diameter smaller than the outer diameter of the main bearing part MB and larger than the outer diameter of the sub bearing part SB. This is to improve assembly when the rotary shaft 226 is coupled to the compression unit 200 .

The oil supply passage 226a is provided inside the rotation shaft 226 to provide a path for supplying the oil stored in the oil storage space V4 to the bearing portions MB and SB and the eccentric portion EC. The bearing parts MB and SB and the eccentric part EC are for reducing frictional force by supplying oil to parts that are in friction with the compression part 200 when the rotating shaft 226 rotates. If oil is supplied to the friction area, frictional force is reduced, which has the effect of reducing power loss. Also, the oil has the effect of cooling the friction area.

The oil supply passage 226a is provided in the axial direction inside the rotation shaft 226, and the oil supply required section (bearing part, eccentric part, etc.) requiring oil supply is the outer peripheral surface of the rotation shaft. Accordingly, a refueling hole connected to the oil supply passage 226a is formed through the outer circumferential surface of the rotating shaft in the oil supply required section.

Specifically, the oil supply hole includes a first oil supply hole formed to penetrate the outer peripheral surface of the main bearing part MB, a second oil supply hole H2 formed to penetrate the outer peripheral surface of the eccentric part EC, and a sub bearing part SB. It may include a third oil supply hole (H3) formed to penetrate the outer peripheral surface of the.

The oil supply groove is for supplying oil evenly to the oil supply required section (bearing part, eccentric part), and may be provided in the form of a concave groove on the outer peripheral surface of the oil supply required section.

As a result, the oil guided upward through the oil supply passage 226a is discharged through the first oil supply hole, is supplied to the outer peripheral surface of the main bearing unit MB, and is discharged through the second oil supply hole H2, It is supplied to the outer peripheral surface of the core part EC, is discharged through the third oil supply hole H3, and is supplied to the outer peripheral surface of the sub bearing part SB in the vertical direction.

In addition, the oil guided through the oil supply passage 226a is discharged through the fourth oil supply hole H4 and is supplied to the upper surface of the orbiting scroll 240 , and is discharged through the fifth oil supply hole H5 to the orbiting scroll. It may be supplied between 240 and the fixed scroll 250 . The oil supplied into the compression chamber has the effect of improving the airtightness of the compression chamber.

In addition, an oil feeder 271 for pumping oil stored in the fourth space V4 may be coupled to the lower end of the rotation shaft 226 , that is, the lower end of the sub bearing part SB.

The oil feeder 271 includes an oil supply pipe 273 that is inserted into and coupled to the oil supply passage 226a of the rotating shaft 226, and an oil suction member such as a propeller that is inserted into the oil supply pipe 273 to suck oil ( 274) can be achieved.

Here, the oil supply pipe 273 is installed to pass through the through hole 276 of the discharge cover 270 to be submerged in the oil storage space V4.

Also, although not shown in the drawings, a trochoid pump (not shown) may be coupled to the sub bearing part SB to forcibly pump the oil filled in the oil storage space V4 to the upper side instead of the oil feeder 271 . there is.

A balance weight 227 for suppressing noise and vibration may be coupled to the rotation shaft 226 . For reference, the balance weight 227 may be provided between the driving motor 220 and the compression unit 200 , that is, in the second space V2 .

Next, an operation process of the scroll compressor according to an embodiment of the present invention will be described.

When power is applied to the driving motor 220 , the rotating shaft 226 integrally coupled with the rotor 224 of the driving motor 220 rotates. Then, the compression chamber S1 formed between the orbiting wrap 241 and the fixed wrap 251 moves while changing the volume while the orbiting scroll 240 eccentrically coupled to the rotation shaft 226 performs a pivoting motion. At this time, the compression chamber (S1) may be continuously formed in several stages while gradually decreasing in volume in the central direction.

Due to the orbiting motion of the orbiting scroll 240 , the refrigerant is compressed while moving and discharged into the third space V3 through the outlet 253 of the fixed scroll 250 .

The high-pressure refrigerant discharged into the third space V3 is transferred to the second space V2 through the fixed scroll discharge hole 256b and the frame discharge hole 231a formed to be connected to the fixed scroll 250 and the main frame 230 with each other. is discharged with The refrigerant discharged to the second space V2 passes through the driving motor 200 and rises to the first space V1, and then in the first space V1 through the refrigerant discharge pipe 216 to the outside of the casing 210. is emitted as

The present invention is characterized in that the flow guide 300 is provided in the second space V2. The flow guide 300 guides the refrigerant discharged from the compression unit to the space between the insulators 223 so that the refrigerant discharged from the compression unit rises through the core hole of the stator.

In addition, the flow guide 300 serves to block the refrigerant discharged from the compression unit from flowing into the oil return passage 212a between the drive motor and the casing, thereby separating the oil return passage and the refrigerant passage. do.

3 is a perspective view illustrating a flow path guide of the scroll compressor according to the first embodiment of the present invention, and FIG. 4 is a view for explaining a refrigerant flow path and an oil recovery flow path of the scroll compressor according to the first embodiment of the present invention.

3 and 4, the flow guide 300 of the scroll compressor according to the first embodiment of the present invention includes a bottom portion 302 that is in close contact with the upper surface of the main frame and an outer wall portion provided along the outside of the bottom portion. (304) and an inner wall portion (306) provided along the inner side of the bottom portion.

The bottom portion 302 is formed in an annular shape to overlap the frame discharge hole 231a provided on the upper surface of the main frame.

In addition, the bottom portion 302 has a through hole 301 communicating with the frame discharge hole 231a.

The outer wall portion 304 of the flow guide 300 is preferably formed at a height that can overlap the insulator outer plate 223a.

In addition, the inner wall portion 306 of the flow guide 300 is preferably formed so that the upper end faces the insulator inner plate (223b).

In addition, the inner wall portion 306 is disposed to surround the outer periphery of the weight balance (227).

The insulator 223 provided above and below the stator of the fixed motor includes an inner plate 223b close to the rotation shaft and an outer plate 223a close to the casing.

According to the present invention, the flow guide 300 seals the space between the inner plate 223b and the outer plate 223a of the insulator 223 , so that the refrigerant is transferred to the core between the inner plate 223b and the outer plate 223a of the insulator 223 . It is designed to move through the hall (not shown).

This structure blocks the refrigerant discharged through the frame discharge hole 231a from flowing into the oil return passage 212a, and has the effect of smoothly recovering oil.

In order to more reliably block the refrigerant discharged from the frame discharge hole 231a from flowing into the oil return passage 212a, the outer wall portion 304 of the passage guide 300 is connected to the insulator outer plate 223a as shown. It is advisable to have them interview you.

5 is a view for explaining a refrigerant passage and an oil recovery passage of a scroll compressor according to a second embodiment of the present invention.

The scroll compressor according to the second embodiment of the present invention further includes a sealing member 304b in the flow path guide 300 to further improve the airtightness of the refrigerant flow path.

As shown, the outer wall portion 304 of the flow guide 300 has a section overlapping the outer wall 223a of the insulator 223 . In other words, the outer wall portion 304 of the flow guide 300 overlaps the outer surface of the insulator outer wall 223a. A sealing groove 304a is provided on the inner surface of the outer wall portion 304, and a sealing member 304b is inserted into the sealing groove 304a so that the sealing member 304b is formed between the flow path guide outer wall portion 304 and the insulator outer wall ( 223a) to be sealed.

This structure has the effect of ensuring the airtightness of the sealing member 304b regardless of the protrusions or grooves even if there are grooves or protrusions between the outer walls of the insulator 223a.

6 is a view for explaining a refrigerant passage and an oil recovery passage of a scroll compressor according to a third embodiment of the present invention.

In the scroll compressor according to the third embodiment of the present invention, the outer wall portion 304 of the flow guide 300 is in close contact with the lower surface of the iron core 222 .

In other words, since the outer wall portion 304 completely surrounds the insulator outer wall 223a and is in close contact with the iron core, the refrigerant discharged through the frame discharge hole 231a is prevented from flowing out to the outside. At this time, in order to improve airtightness, a sealing member 304b may be provided between the iron core and the outer wall portion 304 .

In the case of the third embodiment, as in the second embodiment, airtightness can be secured even if protrusions or grooves are provided on the outer wall of the insulator 223a, and furthermore, airtightness can be secured even when a cut section of the outer wall of the insulator 223a occurs. .

7 is a view for explaining a refrigerant passage and an oil recovery passage of a scroll compressor according to a fourth embodiment of the present invention, and FIG. 8 is a diagram illustrating a refrigerant passage and an oil recovery passage of the scroll compressor according to the fifth embodiment of the present invention. It is a drawing for explanation.

When the insulator outer plate 223a has a step 223a_1 as in the fourth and fifth embodiments, the outer wall portion of the flow guide 300 also has a step 304_3 corresponding thereto, or a double wall 304_1, 304_2) is shown.

7, the outer wall portion of the flow guide 300 is formed as double walls 304_1 and 304_2, and the sealing member 304b having a U-shaped cross section is coupled to the upper end of the inner outer wall 304_4. there is.

Alternatively, as shown in FIG. 8 , the step surface 304_3 may be provided on the outer wall portion 304 of the flow path guide 300 to make surface contact with the step of the insulator outer plate. At this time, the sealing member 304b may be inserted into the inner surface of the outer wall portion 304 of the flow path guide 300 to further improve airtightness.

It is to be understood that the foregoing embodiments are illustrative in all respects and not restrictive, and the scope of the present invention will be indicated by the appended claims rather than the foregoing detailed description.

100: scroll compressor
200: compression unit 210: casing
220: drive motor 226: rotation shaft
MB main bearing part SB: sub bearing part
EC: eccentric 230: main frame
240: orbiting scroll 241: orbiting wrap
250: fixed scroll 251: fixed wrap
270: discharge cover 271: oil feeder
300: euro guide 303: bottom
304: outer wall portion 306: inner wall portion

Claims (12)

a casing having an inner space;
a driving motor having a stator fixed to the inside of the casing and a rotor rotatably provided inside the stator;
a compression unit provided on one side of the driving motor and having a discharge hole to discharge the compressed refrigerant into the inner space of the casing;
a rotating shaft that transmits a driving force from the driving motor to the compression unit; and
and a passage guide installed between the driving motor and the compression unit to guide the refrigerant discharged from the discharge hole to the space between the insulators provided in the stator; and
The euro guide
An annular bottom portion having a shape overlapping the discharge hole provided on the upper surface of the compression portion,
an inner wall portion protruding from the inner surface of the bottom portion toward the driving motor;
an outer wall portion protruding from the outer surface of the bottom portion toward the driving motor;
and a through hole provided in the bottom portion to communicate with the discharge hole,
The outer wall portion overlaps the insulator outer plate of the stator,
The outer plate is provided with a step,
The scroll compressor is formed with a double wall corresponding to the step of the outer wall portion.
delete delete The method of claim 1,
The upper end of the inner wall
in contact with the lower end of the insulator inner plate of the stator
scroll compressor.
a casing having an inner space;
a driving motor having a stator fixed to the inside of the casing and a rotor rotatably provided inside the stator;
a compression unit provided on one side of the driving motor and having a discharge hole to discharge the compressed refrigerant into the inner space of the casing;
a rotating shaft that transmits a driving force from the driving motor to the compression unit; and
and a passage guide installed between the driving motor and the compression unit to guide the refrigerant discharged from the discharge hole to the space between the insulators provided in the stator; and
The euro guide
An annular bottom portion having a shape overlapping the discharge hole provided on the upper surface of the compression portion,
an inner wall portion protruding from the inner surface of the bottom portion toward the driving motor;
an outer wall portion protruding from the outer surface of the bottom portion toward the driving motor;
and a through hole provided in the bottom portion to communicate with the discharge hole,
The outer wall portion overlaps the insulator outer plate of the stator,
The upper end of the inner wall portion is in contact with the lower end of the insulator inner plate of the stator,
Further comprising a sealing member between the outer wall portion and the outer plate
scroll compressor.
6. The method of claim 5,
The outer plate is provided with a step,
The outer wall portion is formed as a double wall corresponding to the step
scroll compressor.
a casing having an inner space;
A stator comprising an iron core fixed inside the casing and forming an oil recovery passage between the casing, an insulator disposed above and below the iron core and having inner and outer walls, and a coil wound around the iron core and the insulator. ;
a rotor rotatably provided inside the stator;
a compression unit fixed to the inside of the casing, forming an oil recovery passage between the casing and the casing, and having a discharge hole to discharge the compressed refrigerant into the inner space of the casing;
a rotating shaft that transmits a driving force from the rotor to the compression unit; and
a driving motor having the stator and the rotor, and a flow guide installed between the compression unit and guiding the refrigerant discharged from the discharge hole into a space between the inner wall and the outer wall of the insulator; and
The euro guide is
An annular bottom part having a shape overlapping the discharge hole provided on the upper surface of the compression part;
an inner wall portion protruding from the inner surface of the bottom portion toward the driving motor;
an outer wall portion protruding from the outer surface of the bottom portion toward the driving motor;
and a through hole provided in the bottom portion to communicate with the discharge hole,
The outer wall portion overlaps the insulator outer plate,
The outer plate is provided with a step,
The outer wall portion is formed as a double wall corresponding to the step
scroll compressor.
delete delete 8. The method of claim 7,
The upper end of the inner wall
in contact with the lower end of the insulator inner plate
scroll compressor.
a casing having an inner space;
A stator comprising an iron core fixed inside the casing and forming an oil recovery passage between the casing, an insulator disposed above and below the iron core and having inner and outer walls, and a coil wound around the iron core and the insulator. ;
a rotor rotatably provided inside the stator;
a compression unit fixed to the inside of the casing, forming an oil recovery passage between the casing and the casing, and having a discharge hole to discharge the compressed refrigerant into the inner space of the casing;
a rotating shaft that transmits a driving force from the rotor to the compression unit; and
a drive motor having the stator and the rotor, and a flow guide installed between the compression unit and guiding the refrigerant discharged from the discharge hole to a space between the inner wall and the outer wall of the insulator;
The euro guide is
An annular bottom portion having a shape overlapping the discharge hole provided on the upper surface of the compression portion,
an inner wall portion protruding from the inner surface of the bottom portion toward the driving motor;
an outer wall portion protruding from the outer surface of the bottom portion toward the driving motor;
and a through hole provided in the bottom portion to communicate with the discharge hole,
The outer wall portion overlaps the insulator outer plate,
Further comprising a sealing member between the outer wall portion and the outer plate
scroll compressor.
12. The method of claim 11,
The outer plate is provided with a step,
The outer wall portion is formed as a double wall corresponding to the step
scroll compressor.

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