JP4680614B2 - Oil reduction device for scroll compressor - Google Patents

Description

  The present invention relates to a scroll compressor, and in particular, not only minimizes the amount of oil that flows out of the compressor, but also effectively cools a drive motor that constitutes the compressor. The present invention relates to a machine oil discharge reduction device.

  In general, a scroll compressor has two scrolls in contact with each other and swivels to change the volume while a plurality of compression chambers formed by the two scrolls move to the center. Gas is sucked and compressed and discharged.

  The scroll compressor is classified into a low pressure type in which the inside of the casing is maintained in a low pressure state that is a suction pressure and a high pressure type in which the inside of the casing is maintained in a high pressure state that is a discharge pressure.

  In the conventional high-pressure scroll compressor, as shown in FIG. 9, a casing 10 provided with a suction pipe 11 and a discharge pipe 12 is fixedly coupled to the inside of the casing 10 at a predetermined vertical interval. The fixed scroll 40 fixedly coupled to the casing 10 so as to be positioned on the upper side of the main frame 20 and the main frame 20, and the fixed scroll 40 so as to be meshed with the fixed scroll 40 so as to be capable of turning. The orbiting scroll 50 positioned between the main frame 20, the Oldham ring 60 positioned between the orbiting scroll 50 and the main frame 20 to prevent the orbiting scroll 50 from rotating, and the main frame 20 and the subframe 30. A drive motor that is fixedly coupled to the casing 10 to generate a drive force, and the drive A rotary shaft 70 for transmitting the driving force of over data to the orbiting scroll 50 was constituted encompass.

  The bottom surface of the casing 10 is filled with oil. The suction pipe 11 and the discharge pipe 12 are positioned in the same direction, and the discharge pipe 12 is positioned below the fixed scroll 40.

  The main frame 20 is formed in a frame body portion 21 having a predetermined shape and has a shaft insertion hole 22 through which the rotary shaft 70 is inserted, and is larger than the inner diameter of the shaft insertion hole 22 following the shaft insertion hole 22. The boss insertion groove 23 formed on the inner diameter, the bearing surface 24 formed on the upper surface of the frame body portion 21 to support the orbiting scroll 50, and the groove on the frame body portion 21 having a predetermined shape, A back pressure space groove 25 that forms a pressure space with the back surface and a flow path groove 26 that is formed on the outer surface of the frame body portion 21 and forms a gas passage with the casing 10 are included.

  The fixed scroll 40 includes a body portion 41 formed in a predetermined shape, a wrap 52 formed in an involute curve shape having a predetermined thickness and height on one surface of the body portion 41, and the center of the body portion 41. A discharge hole 43 penetrating through, a suction port 44 formed on one side of the body portion 41, and a flow channel groove 45 formed on the outer surface of the fixed scroll 40 and through which gas flows together with the casing 10. Contained and configured. A suction pipe 11 provided in the casing 10 is inserted into and coupled to the suction port.

  The orbiting scroll 50 includes a disc portion 51 having a predetermined thickness and area, and a wrap 52 and a disc portion 51 that are formed in an involute curve shape having a predetermined thickness and height on one surface of the disc portion 51. And a boss part 53 formed at the center of the other side.

  In the orbiting scroll 50, the wrap 52 is engaged with the fixed scroll wrap 42, the boss portion 53 is inserted into the boss insertion groove 23 of the main frame 20, and one surface of the inclined plate portion 51 is supported by the bearing surface 24 of the main frame. In this manner, the fixed scroll 40 and the main frame 20 are coupled.

  The rotating shaft 70 is provided with an eccentric portion 71. Further, one side of the rotary shaft 70 is inserted through the shaft insertion hole 22 of the main frame, the eccentric portion 71 is coupled to the boss portion 43 of the orbiting scroll, and the other side is supported by the subframe 30.

  The drive motor includes a stator 80 that is provided with a winding coil C and is fixedly coupled to the inside of the casing 10, and a rotor 90 that is rotatably coupled to the inside of the stator 80. Configured. Further, a gas passage through which gas flows is formed by the outer peripheral surface of the stator 80 and the casing 10.

  An unnamed code B is a bush, 100 is an oil feeder attached to the rotary shaft 70, and 110 is a balance weight.

Hereinafter, the operation of the high-pressure scroll compressor configured as described above will be described.
When power is applied to the scroll compressor, the rotor 90 rotates due to the interaction between the stator 80 and the rotor 90 constituting the drive motor, and the rotational force of the rotor 90 causes the rotating shaft 70 to rotate. And transmitted to the orbiting scroll 50. Next, the rotational force of the rotating shaft 70 is transmitted to the orbiting scroll 50, so that the orbiting scroll 50 coupled to the eccentric portion 71 of the rotating shaft performs a revolving motion with respect to the axis center of the rotating shaft 70. Next, the orbiting scroll 50 starts to orbit while being prevented from rotating by the Oldham ring 60.

  Then, the orbiting scroll 50 is orbited so that the orbiting scroll wrap 52 is engaged with the fixed scroll wrap 42 and the orbiting scroll 50 is engaged with the orbiting scroll wrap 52 and the fixed scroll wrap 42. As the pocket P moves to the center of the fixed scroll 40 and the orbiting scroll 50, the gas is sucked and compressed while the volume is changed, and is discharged through the discharge hole 43 of the fixed scroll.

  At this time, the gas is sucked into the suction port 44 of the fixed scroll immediately through the suction pipe 11, and the gas flowing into the suction port 44 is sucked into the compression pockets P.

  The high-temperature and high-pressure refrigerant gas discharged through the fixed scroll discharge hole 43 passes through the fixed scroll channel groove 45 and the main frame channel groove 26 as shown in FIG. It flows to the lower side of the frame 20. Most of the high-pressure refrigerant gas flowing to the lower side of the main frame 20 is discharged through the discharge pipe 12, and a part of the refrigerant gas passes through the passage between the stator 80 and the casing 90 to drive motor. The refrigerant gas that has moved to the lower side of the drive motor again moves upward through the passage between the stator 80 and the casing 10. In this process, the drive motor is cooled. The refrigerant gas for cooling the drive motor is discharged to the outside through the discharge pipe 12. Next, the high-temperature and high-pressure refrigerant gas discharged through the discharge pipe 12 circulates inside the refrigeration cycle system.

  On the other hand, the oil filled in the bottom surface of the casing 10 passes through an oil feeder 100 coupled to the rotary shaft 70 by the rotation of the rotary shaft 70 and an oil flow path 72 of the rotary shaft fed by the centrifugal force of the rotary shaft 70. It flows through the upper side. The oil that has flowed upward through the oil flow path 72 of the rotating shaft is dispersed in the boss insertion groove 23 of the main frame, and the oil that is dispersed in the boss insertion groove 23 is supplied between the parts in which relative motion occurs. The The oil supplied between the components passes through the shaft insertion hole 22 and is collected on the bottom surface of the casing 10.

  However, in the high-pressure scroll compressor configured as described above, the high-temperature and high-pressure refrigerant gas discharged through the discharge hole 43 of the fixed scroll passes through the inside of the casing 10 and then passes through the discharge pipe 12. After being dispersed through the oil flow path 72 of the rotating shaft in the process of being discharged, a part of the oil recovered on the bottom surface of the casing 10 is mixed with the high-temperature and high-pressure refrigerant gas and immediately escapes through the discharge pipe 12. It is.

  Next, since the oil filled in the casing 10 is excessively discharged into the refrigeration cycle system and the oil in the casing 10 becomes insufficient, the oil supply to each component where relative motion is generated is not smooth. However, there is a disadvantage that the oil is excessively discharged into the refrigeration cycle system to reduce the efficiency of the refrigeration cycle system.

  In addition, a part of the refrigerant gas flows through a passage formed by the outer peripheral surface of the drive motor stator 80 and the inner peripheral surface of the casing 10, so that the drive motor cannot be cooled effectively. There was an inconvenience.

  The present invention has been made in view of the above problems, and not only minimizes the amount of oil that flows out of the compressor to prevent oil shortage inside the compressor, but also provides a compressor. It is an object of the present invention to provide an oil discharge reducing device for a scroll compressor that can improve the efficiency of a refrigeration cycle system that is included.

  Another object of the present invention is to provide an oil discharge reducing device for a scroll compressor that can effectively cool a drive motor constituting the compressor.

  In order to achieve the object according to the present invention described above, in the oil discharge reducing device for a scroll compressor according to the present invention, a casing whose bottom is filled with oil, and a drive motor that is attached to the casing and generates a rotational force A main frame fixedly coupled to the casing, a fixed scroll positioned at a predetermined interval from the main frame, and a swivel positioned between the fixed scroll and the main frame so as to be meshed with the fixed scroll so as to be capable of swiveling motion. In a high-pressure scroll compressor configured to include a scroll, refrigerant guide means for guiding high-pressure refrigerant gas discharged through the discharge hole of the fixed scroll to the rotor side constituting the drive motor, and driving The refrigerant gas that is formed through the motor rotor and guided by the refrigerant guide means flows through the driving mode. Characterized in that when cooling the motor oil that has been included in the refrigerant gas by centrifugal force generated by the rotation of the rotor at the same time is configured to include an oil separating means to be separated.

  In the oil discharge reducing device for a scroll compressor according to the present invention, the refrigerant gas discharged through the discharge hole 43 of the fixed scroll passes through the oil separating means formed through the refrigerant guide means and the rotor 90 of the drive motor. Since the oil is discharged to the discharge pipe 12, the drive motor is effectively cooled by the refrigerant gas mixed with the oil.

  The oil mixed with the refrigerant gas is effectively separated by the rotational force of the rotor 90 while the refrigerant gas mixed with the oil passes through the oil separating means, so that the oil mixed with the refrigerant gas passes through the discharge pipe 12 together with the refrigerant gas. This has the effect of minimizing the amount of oil spilled. In addition, since the oil separated from the refrigerant gas is dispersed in the drive motor and the drive motor is cooled intensively, there is an effect that the cooling efficiency of the drive motor can be further improved.

  Further, the amount of oil mixed with the refrigerant gas discharged into the refrigeration cycle system through the discharge pipe 12 can be minimized, thereby reducing the efficiency of the system due to excessive oil accumulation inside the refrigeration cycle system. In addition to being able to prevent, there is an effect that the reliability of the compressor can be improved by suppressing the shortage of the oil filled in the casing 10 of the compressor.

  Hereinafter, an oil discharge reducing device for a scroll compressor according to the present invention will be described with reference to the drawings.

  In the high-pressure scroll compressor provided with the first embodiment of the high-pressure scroll compressor oil discharge reducing device according to the present invention, as shown in FIG. 1, a casing provided with a suction pipe 11 and a discharge pipe 12. 10, a main frame 20 and a sub frame 30 that are fixedly coupled to the inside of the casing 10 at predetermined intervals, and a fixed scroll 40 that is fixedly coupled to the casing 10 so as to be positioned above the main frame 20. The orbiting scroll 50 positioned between the fixed scroll 40 and the main frame 20 so as to be meshed with the fixed scroll 40 so that the orbiting movement is possible, and the rotation of the orbiting scroll 50 positioned between the orbiting scroll 50 and the main frame 20. To prevent the Oldham ring 60 from being located between the main frame 20 and the subframe 30 A drive motor for fixedly coupled to the casing 10 by generating a driving force, and encompasses a rotation shaft 70 for transmitting the driving force of the driving motor to the orbiting scroll 50.

  The bottom surface of the casing 10 is filled with oil. The suction pipe 11 and the discharge pipe 12 are positioned in the same direction, and the discharge pipe 12 is positioned below the fixed scroll 40.

  The main frame 20 is formed in a frame body portion 21 having a predetermined shape and has a shaft insertion hole 22 through which the rotary shaft 70 is inserted, and is larger than the inner diameter of the shaft insertion hole 22 following the shaft insertion hole 22. The boss insertion groove 23 formed on the inner diameter, the bearing surface 24 formed on the upper surface of the frame body portion 21 to support the orbiting scroll 50, and the groove on the frame body portion 21 having a predetermined shape, And a back pressure space groove 26 that forms a pressure space together with the back surface.

  The fixed scroll 40 includes a body portion 41 formed in a predetermined shape, a wrap 42 formed in an involute curve shape having a predetermined thickness and height on one surface of the body portion 41, and the center of the body portion 41. A discharge hole 43 penetrating through, a suction port 44 formed on one side of the body portion 41, and a flow channel groove 45 formed on the outer surface of the fixed scroll 40 and through which gas flows together with the casing 10. Contained and configured. The suction pipe 11 provided in the casing 10 is inserted into and coupled to the suction port 44.

  The orbiting scroll 50 includes a disc portion 51 having a predetermined thickness and area, and a wrap 52 and a disc portion 51 that are formed in an involute curve shape having a predetermined thickness and height on one surface of the disc portion 51. And a boss part 53 formed at the center of the other side.

  In the orbiting scroll 50, the wrap 52 is engaged with the fixed scroll wrap 42, the boss portion 53 is inserted into the boss insertion groove 23 of the main frame, and one surface of the inclined plate portion 51 is supported by the bearing surface 24 of the main frame. The fixed scroll 40 and the main frame 20 are coupled to each other.

  The rotating shaft 70 is provided with an eccentric portion 71. Further, one side of the rotary shaft 70 is inserted through the shaft insertion hole 22 of the main frame, the eccentric portion 71 is coupled to the boss portion 53 of the orbiting scroll, and the other side is supported by the subframe 30.

  The drive motor includes a stator 80 that is provided with a winding coil C and is fixedly coupled to the inside of the casing 10, and a rotor 90 that is rotatably coupled to the interior of the stator 80. Composed. Further, each passage through which gas flows together with the casing 10 is formed on the outer peripheral surface of the stator 80.

  The drive motor is preferably a synchronous reluctance motor that generates a rotational force by reluctance torque.

  A refrigerant guide means for guiding the high-pressure refrigerant gas discharged through the discharge hole 43 of the fixed scroll to the rotor 90 side of the drive motor is provided. The refrigerant guide means is formed so as to penetrate the rotor 90 and is guided by the refrigerant guide means. An oil separation means for separating the oil contained in the refrigerant gas by the centrifugal force generated by the rotation of the rotor 90 while cooling the drive motor while the refrigerant gas is flowing through is provided.

  The refrigerant guide means is formed through the main frame 20 so that the first passage f1 formed on one side of the fixed scroll 40 and the refrigerant that has passed through the first passage f1 are directed upward of the rotor 90. And a second passage f2.

  The first passage f <b> 1 is preferably a channel groove formed on the outer peripheral surface of the body portion 21 of the fixed scroll and forming a channel with the casing 10. The second passage f2 is formed in a vertical direction on the outer peripheral surface of the main frame 20 so as to communicate with the first passage f1, and in the horizontal direction following the first vertical hole 27. A horizontal hole 28 to be formed and a second vertical hole 29 formed in the vertical direction following the horizontal hole 28 are configured to be included.

  Further, the guide member 120 that guides the refrigerant gas flowing out through the second passage f <b> 2 to the upper side of the rotor 90 is positioned on the lower surface of the main frame 20 and the upper side of the rotor 90. The guide member 120 is formed in a cylindrical shape, and the second vertical hole 29 is positioned inside the guide member 120. The guide member 120 is preferably formed integrally with the main frame 20.

  The oil separating means is a through passage formed through the rotor 90 in the length direction.

  In addition, as shown in FIGS. 2 and 3, the rotor 90 is a cylindrical laminated body in which a plurality of circular thin plates are laminated, and penetrates the laminated body in an arc shape along the circumferential direction. A rotor body 91 having a plurality of formed slots S and having a shaft insertion hole in the center of the laminate, an upper end ring 92 coupled to the upper surface of the rotor body 91, and the rotor And a lower end ring 93 coupled to the lower surface of the body 91. Moreover, the slot S partitions the upper surface of the rotor body 91 into four regions, and a plurality of slots S are respectively formed in the partitioned four regions. The curved direction of these slots S is positioned in the direction opposite to the curved direction of the outer peripheral surface of the rotor body 91. The plurality of slots S allows the rotor 90 to form a magnetic pole when the drive motor is operated.

  The upper end ring 92 and the lower end ring 93 are formed in an annular shape having a predetermined thickness and width.

  In addition, a balance weight 110 is provided to match the rotational balance of the rotating body including the rotation shaft 70 to the upper end ring 92 and the lower end ring 93.

  Further, the through flow passage is formed through the upper end ring 92, and is formed through the plurality of first holes H <b> 1 that communicate with the slot S, each slot S, and the lower end ring 93, and communicates with the slot S. And a plurality of second holes H2.

  Each of the first holes H1 is composed of four, and each of the four first holes H1 is one in each of the slots S positioned in the portion partitioned by the rotor body 91 into four sections. It will be located in each slot S. The first hole H1 is positioned at the center of the slot S.

  Each second hole H2 includes four gas discharge holes h2 and eight oil discharge holes h3. The four gas discharge holes h2 are positioned in one slot S among the slots S respectively positioned in the four sections of the rotor body 91. The eight oil discharge holes h3 are positioned at both ends of the slot S where the gas discharge hole h2 is positioned.

  Further, as shown in FIG. 4, an oil separation membrane 130 is provided on the lower surface of the lower end ring 93 to partition each gas discharge hole h2 and oil discharge hole h3 to prevent mixing of gas and oil. The oil separation membrane 130 is formed in a cylindrical shape having a predetermined length. The oil separation membrane 130 may be formed integrally with the lower end ring 93 or may be separately manufactured and coupled to the lower end ring 93.

  In addition, the first hole H1 formed in the upper end ring 92 and the second hole H2 formed in the lower end ring 93 are overlapped with the balance weight 110 coupled to the upper end ring 92 and the lower end ring 93. Through holes are formed in the balance weight 110 so as to match the positions of the first holes H1 and the second holes H2.

  On the other hand, in another embodiment of the through passage, as shown in FIGS. 5 and 6, the through passage is provided on the inner peripheral surface of the rotor shaft insertion hole h 1 into which the rotary shaft 70 is press-fitted. It consists of a plurality of oil separation grooves 94 formed through in the length direction.

  These oil separation grooves 94 are formed on the inner peripheral surface of the rotor shaft insertion hole h1 at predetermined intervals in the circumferential direction, and have a constant cross section.

  Further, in another modification of the oil separation groove 94, as shown in FIG. 7, the cross section on the inflow side is small, the cross section on the outflow side is large, and the area is sequentially increased.

  Reference numeral B is a bush, 100 is an oil feeder attached to the rotary shaft 70, and H3 is a molding hole.

  The operation of the high pressure scroll compressor oil discharge reducing device according to the present invention will be described below.

  When power is applied to the scroll compressor, the rotor 90 rotates due to the interaction between the stator 80 and the rotor 90 constituting the drive motor, and the rotational force of the rotor 90 causes the rotating shaft 70 to rotate. And transmitted to the orbiting scroll 50. Next, the rotational force of the rotating shaft 70 is transmitted to the orbiting scroll 50, so that the orbiting scroll 50 coupled to the eccentric portion 71 of the rotating shaft performs a revolving motion with respect to the axis center of the rotating shaft 70. Next, the orbiting scroll 50 starts to orbit while being prevented from rotating by the Oldham ring 60.

  Then, the orbiting scroll 50 is orbited so that the orbiting scroll wrap 52 is engaged with the fixed scroll wrap 42 and the orbiting scroll 50 is engaged with the orbiting scroll wrap 52 and the fixed scroll wrap 42. As the pocket P moves to the center of the fixed scroll 40 and the orbiting scroll 50, the gas is sucked and compressed while the volume is changed, and is discharged through the discharge hole 43 of the fixed scroll.

  At this time, the gas is drawn into the suction port 44 of the fixed scroll immediately after passing through the suction pipe 11, and the gas that has flowed into the suction port 44 flows into each compression pocket P.

  On the other hand, when the rotating shaft 70 rotates, the oil filled in the bottom surface of the casing 10 passes through the oil flow path 72 of the rotating shaft by the centrifugal force of the oil feeder 100 coupled to the rotating shaft 70 and the rotating shaft 70. While flowing upward, the oil dispersed in the boss insertion groove 23 of the main frame is supplied between the parts in which relative motion occurs. Part of the oil supplied between the parts is collected on the bottom surface of the casing 10, and part of the oil is mixed with the high-temperature and high-pressure refrigerant gas discharged to the discharge hole 43.

  The high-temperature and high-pressure refrigerant gas discharged through the fixed scroll discharge holes 43 passes through the first passage f1 of the fixed scroll and the second passage f2 of the main frame, as shown in FIG. It flows to the child 90 side. At this time, the refrigerant gas is prevented from spreading inside the casing 10 by the guide member 120 positioned between the main frame 20 and the drive motor.

  Next, the refrigerant gas that has flowed to the rotor 90 side passes through the first hole H1, the slot S, and the second hole H2 that form the through flow path by the suction input generated from the through flow path side by the rotation of the rotor 90. It flows through and flows to the lower side of the drive motor. Next, in the process in which the refrigerant gas passes through the slots S, the oil mixed with the refrigerant gas in each slot S is separated by centrifugal force, and the oil is discharged through the oil discharge hole h3 that constitutes the second hole H2. The refrigerant gas from which the oil has been separated flows through the gas discharge hole h2 to the lower part of the drive motor.

  Hereinafter, the process of separating the oil and the refrigerant gas in each slot S will be described. Since the slot S is formed in an arc shape, the refrigerant gas mixed with the oil while the rotor 90 rotates is in the slot S. The oil mixed with the refrigerant gas by the centrifugal force generated by the rotation of the rotor 90 will fall while gathering at both ends of the slot S along the inner wall of the slot S located outside. Next, the oil dropped to both ends of the slot S flows through the oil discharge holes h3 located at both ends of the slot S to the lower part. Next, the refrigerant gas from which the oil has been separated flows out through the gas discharge hole h2 located on the same line as the first hole H1.

  Next, the oil discharged through the oil discharge hole h3 cools the drive motor while being wound on the winding coil C and the stator 80 by the rotational force of the rotor 90, and the oil that has cooled the drive motor is the casing 10 Collected on the bottom of the.

  Next, the refrigerant gas that has flowed to the lower side of the drive motor through the gas discharge hole h2 is discharged to the upper side of the drive motor through the passage formed by the outer peripheral surface of the stator 80 and the casing 10. 12 is discharged.

  When the oil separation membrane 130 is coupled to the lower end ring 93, the oil separated by the oil separation membrane 130 is mixed with the refrigerant gas flowing through the gas discharge hole h2. To minimize things.

  On the other hand, as another embodiment of the through passage, when a plurality of oil separation grooves 94 are formed on the inner peripheral surface of the shaft insertion hole h1 of the rotor 90, oil separation is performed by centrifugal force due to the rotational force of the rotor 90. The oil mixed with the refrigerant gas flowing into the groove 94 falls to the lower part along the inner wall while gathering on the inner wall of the oil separation groove 94. Next, the oil that falls along the inner wall of the oil separation groove 94 comes to the drive motor side by the rotational force of the rotor 90. When the cross section of the oil separation groove 94 is gradually increased, oil separation is more effectively performed. On the other hand, the refrigerant gas from which the oil has been separated flows through the oil separation groove 94 to the lower side of the drive motor.

1 is a cross-sectional view showing a high-pressure scroll compressor provided with a first embodiment of a scroll compressor oil discharge reducing device according to the present invention. It is the perspective view which decomposed | disassembled and showed the rotor of the drive motor which comprises a high voltage | pressure type scroll compressor. It is the top view which showed the rotor of the drive motor which comprises a high voltage | pressure type scroll compressor. It is the figure which showed the oil separation membrane which comprises the oil discharge reduction apparatus of the scroll compressor which concerns on this invention. It is the front sectional view showing other embodiments of the penetration channel which constitutes the oil discharge reducing device of the scroll compressor concerning the present invention. It is the plane sectional view showing other embodiments of the penetration channel which constitutes the oil discharge reducing device of the scroll compressor concerning the present invention. It is the fragmentary sectional view showing the modification form of a penetration channel. It is sectional drawing of the high-pressure-type scroll compressor which showed the operating state of the oil discharge reduction apparatus of the scroll compressor which concerns on this invention. It is sectional drawing which showed 1st Embodiment of the conventional high-pressure-type scroll compressor. It is sectional drawing which showed the operating state of the conventional high-pressure-type scroll compressor.

Explanation of symbols

10 casing 20 main frame 40 fixed scroll 43 discharge hole 50 orbiting scroll 90 rotor 91 rotor body 92 upper end ring 93 lower end ring 94 oil separation groove f1 first passage f2 second passage h1 shaft insertion hole h2 gas discharge hole h3 Oil discharge hole H1 1st hole H2 2nd hole S slot

Claims (8)

A casing (10) filled with oil on the bottom surface, a drive motor mounted on the casing (10) to generate a rotational force, a main frame (20) fixedly coupled to the casing (10), the main A fixed scroll (40) positioned at a predetermined interval from the frame (20), and a position between the fixed scroll (40) and the main frame (20) that is engaged with the fixed scroll (40) and is capable of orbiting. A swiveling scroll (50)
The rotor (90) constituting the drive motor is a cylindrical laminated body in which a plurality of circular thin plates are laminated, and the plurality of rotors (90) formed through the laminated body in an arc shape along the circumferential direction. A rotor body (91) provided with a slot (S) and a shaft insertion hole in the center of the laminate, and an upper end ring (92) coupled to both sides of the rotor body (91), respectively. And a lower end ring (93),
A plurality of first holes (H1) communicating with the slot (S) are formed through the upper end ring (92), and the lower end ring (93) communicates with the slot (S). A plurality of second holes (H2) to be formed are formed therethrough;
An oil discharge reducing device for a scroll compressor. A refrigerant guide means for guiding the high-pressure refrigerant gas discharged through the discharge hole (43) of the fixed scroll (40) to the rotor side;
The refrigerant guide means includes a first passage (f1) formed on one side of the fixed scroll (40), and the refrigerant that has passed through the first passage (f1) is directed upward of the rotor (90). And including a second passage (f2) formed through the main frame (20).
The oil discharge reducing device for a scroll compressor according to claim 1. The second passage (f2) includes a first vertical hole formed in a vertical direction on the outer peripheral surface of the main frame (20) so as to communicate with the first passage (f1), and the first vertical hole. Subsequently, a horizontal hole formed in the horizontal direction, and a second vertical hole formed in the vertical direction following the horizontal hole,
The oil discharge reduction device for a scroll compressor according to claim 2.   The refrigerant gas flowing through the second passage (f2) is located above the rotor (90) on the lower side of the main frame (20) and above the rotor (90). The oil discharge reducing device for a scroll compressor according to claim 2, further comprising a guide member (120) for guiding. Wherein each first hole (H1), said central oil discharge reducing device of the scroll compressor according to claim 1, wherein the respectively positioned in each slot (S). Said second hole (H2) is provided with gas discharge holes intermediate the respective positions of the slot (S), comprising the oil discharge hole (h3) Rakara positioned at both ends of the slots (S), and characterized in that The oil discharge reducing device for a scroll compressor according to claim 1 . The oil discharge reducing device for a scroll compressor according to claim 6, wherein each of the gas discharge holes (h2) and the first hole (H1) are located on the same line. An oil separation membrane is provided on the lower surface of the lower end ring to partition the gas discharge holes (h2) and the oil discharge holes (h3) to prevent mixing of gas and oil. The oil discharge reducing device for a scroll compressor according to claim 6 .

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