JP2013024153A - Hermetic type compressor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hermetic type compressor capable of introducing oil discharged from a drain oil pipe into the stator cut without fail, making the oil smoothly flow down to oil sump, and preventing the oil loss without enlarging diameter of a housing and a stator cut, and while suppressing flow path pressure loss.SOLUTION: In the hermetic type compressor which makes the oil for lubricating a lubricated region of compression mechanism return to the oil sump via the oil drain hole and a drain oil pipe 48 arranged in a supporting member 31 of the compression mechanism, the lower end of the drain oil pipe 48 is opened in a position facing a stator cut 5B arranged in a perimeter of a stator 5 lower than a stator coil end 5A of a motor and upper than the upper end of the stator 5, and the lower part of the drain oil pipe 48 is curved toward the perimeter side of the stator 5 with the outer diameter D of the drain oil pipe 48 larger than diameter direction width L of the stator cut 5B.

Description

  The present invention relates to a hermetic compressor in which a motor is built in a hermetic housing and a compression mechanism is provided on the motor.

  In a hermetic compressor in which a motor is installed at an intermediate position of the hermetic housing and a compression mechanism that is driven via a rotating shaft is disposed on the motor, the lubricating oil filled in the oil reservoir at the bottom of the hermetic housing is removed. Oil is supplied to a required lubrication portion of the compression mechanism through an oil supply pump and an oil supply hole in the rotary shaft, and the oil lubricated to the portion is returned to an oil reservoir through an oil discharge hole provided in a support member of the compression mechanism. I have to. In such a hermetic compressor, oil that lubricates a required lubrication site, is discharged from the oil drain hole, and flows down to the oil reservoir is wound up by the refrigerant gas flow, and is sucked into the compression mechanism together with the refrigerant gas and compressed. Then, it is discharged to the outside of the compressor. When this oil rising phenomenon is remarkable, the lubricating oil in the oil reservoir becomes insufficient, and problems such as the compressor becoming poorly lubricated and the system efficiency being lowered occur.

  Then, after lubricating a required lubrication site | part, the guide plate was installed by welding etc. with respect to the airtight housing so that the flow path of the oil discharged | emitted from an oil drain hole and flowing down may be covered (for example, refer patent document 1) ) Or one end of the oil drain pipe connected to the oil drain hole and its lower end extended to the upper part of the oil reservoir, or one extended to the upper part of the stator cut position provided on the stator outer periphery of the motor ( For example, Patent Documents 2 and 3) are proposed, and the contact between the oil discharged from the oil discharge hole and the refrigerant gas is suppressed, and the oil rise is reduced.

JP 2000-291552 A JP 2005-273463 A Japanese Patent Application Laid-Open No. 7-1558569

  However, as shown in Patent Document 1, in the case where the guide plate is provided, a gap is easily formed between the support member provided with the oil drain hole and the guide plate, and the oil is wound up from there. Since oil rising cannot be sufficiently suppressed and the guide plate needs to be welded to the hermetic housing, there is a problem in that assemblability is lowered. Further, as shown in Patent Document 2, when the lower end of the oil drain pipe is extended to the upper part of the oil sump, the oil drain pipe needs to be extended downward through a stator cut provided on the outer periphery of the stator. When the stator cut is made large to pass the oil pipe, the motor efficiency is lowered, and when the sealed housing is made large, there is a problem that the compressor is enlarged.

  Furthermore, as shown in Patent Document 3, in the case where the lower end of the oil drain pipe is extended to the upper portion of the stator cut, the oil flowing out from the lower end of the oil drain pipe is reliably introduced into the stator cut. It is necessary to increase the directivity of the oil that flows out by increasing the cut or narrowing the drain oil pipe, and to reliably introduce the oil into the stator cut. In addition, there were problems such as difficulty in introducing oil into the stator cut.

  The present invention has been made in view of such circumstances, and it is possible to reliably remove oil discharged from an oil drain pipe without increasing the housing diameter or stator cut and suppressing flow path pressure loss. It is an object of the present invention to provide a hermetic compressor that can be smoothly introduced into an oil sump and can be prevented from rising.

In order to solve the above problems, the hermetic compressor of the present invention employs the following means.
That is, in the hermetic compressor according to the present invention, a motor is built in the hermetic housing, and a compression mechanism that is driven by the motor via a rotating shaft is provided on the upper part of the hermetic compressor. The filled lubricating oil is supplied to a required lubricating portion of the compression mechanism via an oil supply pump and an oil supply hole in the rotary shaft, and the oil that has lubricated the portion is provided on a support member of the compression mechanism. A hermetic compressor configured to return to the oil reservoir through a hole and an oil drain pipe, wherein the oil drain pipe has a lower end below the stator coil end of the motor and an upper end of the stator. The upper part is opened at a position facing the stator cut provided on the outer periphery of the stator, and the lower part of the oil drainage pipe is curved toward the outer peripheral side of the stator. Together, the outer diameter of the exhaust oil pipe, characterized in that it is larger than the radial width of the stator cutting.

  According to the present invention, there is provided a hermetic compressor in which oil that has lubricated a lubrication site of a compression mechanism is returned to an oil sump via a drain hole and a drain pipe provided in a support member of the compression mechanism. The lower end of the oil drainage pipe is opened at a position facing the stator cut provided on the outer periphery of the stator below the stator coil end of the motor and above the stator upper end. Since the lower part is curved toward the outer peripheral side of the stator and the outer diameter of the oil drain pipe is larger than the radial width of the stator cut, the oil that lubricates the lubrication part of the compression mechanism is supported by the support member. The oil is removed from the oil drain hole provided in the pipe to the oil drain pipe, and the oil pressure pipe whose outer diameter is larger than the radial width of the stator cut suppresses the flow pressure pressure loss, while the stator at the lower part of the pipe. Allowed to flow toward the centrifugal direction by the site being curved toward the peripheral side, it can be placed reliably guided to the stator inner cutting opposite from the lower end opening. Therefore, without increasing the housing diameter or stator cut width and suppressing flow path pressure loss in the oil drainage passage, the oil flowing out from the oil drainage pipe is surely introduced into the stator cut to smoothly collect the oil. The oil can be prevented from rising from the hermetic compressor.

  Further, the hermetic compressor according to the present invention is the above hermetic compressor, wherein the drain oil pipe is inserted into a downward pipe that intersects the drain hole provided radially outward in the support member. The upper end of the hole is inserted and installed, and oil discharged from the drain hole can be introduced into the drain pipe through a lateral hole or notch provided on the outer peripheral surface of the drain pipe upper end. It is characterized by being.

  According to the present invention, the oil drain pipe is inserted and installed in the downward pipe insertion hole intersecting with the oil drain hole provided radially outward in the support member, and the oil pipe upper end. Since the oil discharged from the oil drainage hole can be introduced to the oil drainage pipe through the horizontal hole or notch provided on the outer peripheral surface of the oil pipe, the upper end of the oil drainage pipe intersects the oil drainage hole. By inserting into the pipe insertion hole facing downward, the horizontal hole or notch provided on the outer peripheral surface of the upper end of the oil drainage pipe communicates with the oil drainage hole, and the oil lubricated the lubrication part of the compression mechanism is transferred to the stator cut. An oil drainage path that leads to Therefore, it is not necessary to block the outer end portion of the oil drain hole, the formation of the oil drain path can be facilitated, and the oil winding by the refrigerant gas can be reliably suppressed.

  Furthermore, the hermetic compressor according to the present invention is any one of the hermetic compressors described above, wherein the lower end opening of the oil drainage pipe is cut obliquely so as to open along the inner peripheral surface of the hermetic housing. It is characterized by.

  According to the present invention, the lower end opening of the oil drain pipe is cut obliquely so as to open along the inner peripheral surface of the sealed housing, so that the lower end opening of the oil drain pipe is connected to the inner peripheral surface of the sealed housing. It is possible to open long in the direction substantially parallel to the bottom. As a result, the directivity of the oil flowing out from the lower end opening of the oil drain pipe toward the stator cut can be increased, and the oil can be more reliably introduced into the stator cut.

  In the hermetic compressor according to the present invention, a motor is built in the hermetic housing, and a compression mechanism that is driven by the motor via a rotating shaft is provided on the upper part of the hermetic compressor. The filled lubricating oil is supplied to a required lubricating portion of the compression mechanism via an oil supply pump and an oil supply hole in the rotary shaft, and the oil that has lubricated the portion is provided on a support member of the compression mechanism. A hermetic compressor configured to return to the oil sump via a hole and an oil drain pipe, wherein the oil drain pipe and the oil drain hole provided radially outward of the support member; The upper end of the pipe is inserted into a downwardly-intersecting pipe insertion hole, and the oil discharged from the oil discharge hole through the lateral hole or notch provided on the outer peripheral surface of the oil discharge pipe upper end is Excretion Characterized in that it is capable introduced into the pipe side.

  According to the present invention, a hermetic compressor is configured to return oil that has lubricated a required lubrication site of a compression mechanism to an oil sump via an oil drain hole and a drain pipe provided in a support member of the compression mechanism. The oil drainage pipe is inserted and installed in a downward pipe insertion hole that intersects the oil drainage hole provided radially outward in the support member. The oil discharged from the oil drain hole through the horizontal hole or notch provided on the outer peripheral surface can be introduced to the oil drain pipe side, so the upper end of the oil drain pipe crosses the oil drain hole downward By inserting into the pipe insertion hole, the lateral hole or notch provided in the outer peripheral surface of the upper end of the oil drainage pipe communicates with the oil drainage hole, and the oil lubricated the lubrication part of the compression mechanism is transferred to the stator cut. It can form a leading oil drainage pathTherefore, it is not necessary to block the outer end portion of the oil drain hole, the formation of the oil drain path can be facilitated, and the oil winding by the refrigerant gas can be reliably suppressed.

  Furthermore, the hermetic compressor according to the present invention is characterized in that, in any of the hermetic compressors described above, the oil drainage pipe is inserted and installed at the upper end portion thereof into the pipe insertion hole.

  According to the present invention, since the upper end portion of the oil drainage pipe is press-fitted and installed in the pipe insertion hole, the oil drainage pipe is located between the pipe insertion hole and the oil drainage hole to the outer end portion from the oil drainage pipe. The oil leakage gap can be eliminated. This eliminates oil leakage from the oil drain hole and pipe insertion hole, effectively guides the oil to the oil reservoir, suppresses oil rise, and reliably prevents the oil drain pipe from dropping off. can do.

  Furthermore, the hermetic compressor of the present invention is the above-described hermetic compressor, wherein the oil drainage pipe is integrally provided with a mounting plate below the upper end portion that is inserted and installed in the pipe insertion hole. The oil drainage pipe is inserted and installed so as to close the pipe insertion hole with respect to the support member via the mounting plate.

  According to the present invention, the oil drainage pipe is integrally provided with a mounting plate below the upper end where the oil drainage pipe is inserted and installed in the pipe insertion hole, and the oil drainage pipe is inserted into the support member via the mounting plate. The mounting plate is inserted and installed so as to close the hole, so that the upper end portion of the drainage pipe with which the mounting plate is integrally provided is inserted into the pipe insertion hole, and the drainage pipe is installed in the support member. The pipe insertion hole can be sealed so as not to leak oil. Therefore, oil leakage from the pipe insertion hole can be eliminated, the oil can be effectively guided to the oil reservoir, oil rising can be suppressed, and the oil drain pipe can be prevented from falling off.

  Furthermore, the hermetic compressor according to the present invention is the above-described hermetic compressor, wherein the mounting plate is fixed to the support member with screws and is provided in the oil drain hole and the oil drain pipe in that state. The oil drainage pipe is integrated in advance so that the position of the horizontal hole or notch and the direction of the oil drainage pipe are set to a predetermined position and direction.

  According to the present invention, the mounting plate is fixed to the support member with screws, and in this state, the positions of the oil drain holes and the side holes or notches provided in the oil drain pipe and the direction of the oil drain pipe are predetermined. Since it is integrated with the oil drain pipe in advance so as to be set in the position and direction, the oil drain pipe with the mounting plate assembled integrally is inserted into the pipe insertion hole, and the mounting plate is fixed to the support member with screws. Only by doing this, the positions of the oil drain holes and the side holes or notches provided in the oil drain pipe and the direction of the oil drain pipe can be set to predetermined positions and directions. As a result, the assembly of the oil drain pipe can be facilitated and the assembly accuracy can be improved, and the oil can be more reliably introduced into the stator cut.

  Furthermore, the hermetic compressor according to the present invention is the above-described hermetic compressor, wherein the oil drainage pipe is a step whose diameter is reduced at a position below the upper end portion inserted and installed in the pipe insertion hole. The mounting plate is joined to the stepped portion.

  According to the present invention, the oil drainage pipe is a stepped pipe having a reduced diameter at a position below the upper end portion inserted and installed in the pipe insertion hole, and the mounting plate is joined to the stepped portion. The mounting plate can be simply assembled by brazing or adhering to a specified position of the drainage pipe using the stepped portion of the pipe, and can be assembled together. Therefore, it is possible to facilitate the manufacture and assembly of the drainage pipe with the mounting plate, and to improve the assembly of the hermetic compressor.

  According to the hermetic compressor of the present invention, the oil that has lubricated the lubrication part of the compression mechanism is guided from the oil drain hole provided in the support member to the oil drain pipe, and the outer diameter is larger than the radial width of the stator cut. The oil drainage pipe is used to suppress the flow path pressure loss, and the pipe is made to flow out in the centrifugal direction by the curved portion toward the outer periphery of the stator at the lower part of the pipe. Therefore, oil flowing out from the oil drain pipe is surely introduced into the stator cut without increasing the housing diameter and stator cut width and suppressing flow path pressure loss in the oil drain path. As a result, the oil can flow smoothly into the oil reservoir, and oil rising from the hermetic compressor can be prevented.

  Further, according to the hermetic compressor of the present invention, by inserting the upper end portion of the oil drain pipe into the downward pipe insertion hole intersecting with the oil drain hole, the horizontal hole provided in the outer peripheral surface of the oil drain pipe upper end portion Alternatively, it is possible to connect the notch and the oil drain hole to form an oil drain path that guides the oil that has lubricated the lubrication part of the compression mechanism to the stator cut, so there is no need to block the outer end of the oil drain hole. In addition to facilitating the formation of the oil drainage path, it is possible to reliably prevent oil from being rolled up by the refrigerant gas.

1 is a longitudinal sectional view of a hermetic compressor according to a first embodiment of the present invention. It is an A arrow directional view of the hermetic compressor shown in FIG. It is a B arrow view of the hermetic compressor shown in FIG. It is a block diagram of the oil-drain pipe installation part of the hermetic compressor shown in FIG. It is a block diagram of the connection part of the oil drainage hole and oil drainage pipe of the hermetic compressor concerning a 2nd embodiment of the present invention. It is a partial block diagram of the modified examples (A) and (B) of the connection part of the oil drain hole and the oil drain pipe shown in FIG. It is a block diagram of the drainage pipe installation part which concerns on 3rd Embodiment of this invention. FIG. 8 is a front view (A), a left side view (B), a right side view (C), and a plan view (D) of the oil drainage pipe assembly shown in FIG. 7. It is a block diagram of the waste oil pipe installation part which concerns on 4th Embodiment of this invention.

Embodiments according to the present invention will be described below with reference to the drawings.
[First Embodiment]
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. 1 to 4.
1 is a longitudinal sectional view of a hermetic compressor according to the first embodiment of the present invention. FIG. 2 is a view as viewed from an arrow A, FIG. 3 is a view as viewed from an arrow B, FIG. Is a configuration diagram of the oil drain pipe installation portion. In this embodiment, for convenience, an example of a hermetic multistage compressor (sealed compressor) 1 that uses a rotary compression mechanism as the low-stage compression mechanism 2 and a scroll compression mechanism as the high-stage compression mechanism 3 will be described. As will be described, the hermetic compressor does not have to be a multistage compressor, but may be a single stage compressor, and the compression mechanism is also limited to the rotary and scroll type compression mechanisms described above. Of course, it is not done.

  The hermetic multistage compressor 1 includes a hermetic housing 10. A motor 4 including a stator 5 and a rotor 6 is fixedly installed at a substantially central portion in the hermetic housing 10, and a rotating shaft (crank shaft) 7 is integrally coupled to the rotor 6. A low-stage rotary compression mechanism 2 is installed below the motor 4. The low-stage rotary compression mechanism 2 includes a cylinder chamber 20, a cylinder main body 21 fixedly installed in the hermetic housing 10, and an upper bearing fixedly installed above and below the cylinder main body 21 to seal the upper and lower portions of the cylinder chamber 20. 22 and the lower bearing 23, a rotor 24 that is fitted to the crank portion 7A of the rotating shaft 7 and rotates on the inner peripheral surface of the cylinder chamber 20, and the inside of the cylinder chamber 20 is divided into a suction side and a discharge side (not shown). A blade, a blade pressing spring, and the like.

  The low-stage-side rotary compression mechanism 2 itself may be a known one. A low-pressure refrigerant gas (working gas) is sucked into the cylinder chamber 20 through the suction pipe 25, and this refrigerant gas is intermediated by the rotation of the rotor 24. After being compressed to a pressure, it is discharged into discharge chambers 26A and 26B, merged in discharge chamber 26A, and then discharged into sealed housing 2. The intermediate-pressure refrigerant gas flows through the gas passage hole 6A provided in the rotor 6 of the motor 4 and flows into the upper space of the motor 4, and is further sucked into the high-stage scroll compression mechanism 3 to be two-stage. It is designed to be compressed.

  The high-stage scroll compression mechanism 3 is installed on the upper part of the motor 4, and is provided with a bearing 30 that supports the rotating shaft 7, and a support member 31 (both a frame member and a bearing member) that is fixedly installed in the hermetic housing 10. It is supposed to be incorporated above. The support member 31 is fixedly installed at a plurality of locations (for example, three locations) on the circumference with respect to the sealed housing 10 by plug welding or the like, and the outer peripheral surface thereof is between the inner peripheral surface of the sealed housing 10. Thus, a notch 31A (see FIG. 3) constituting the refrigerant gas suction passage is formed.

  The high-stage scroll compression mechanism 3 includes spiral wraps 32B and 33B standing on end plates 32A and 33A, respectively, and the spiral wraps 32B and 33B are engaged with each other and assembled on the support member 31. The fixed scroll member 32 and the orbiting scroll member 33 constituting the pair of compression chambers 34, and the orbiting scroll member 33 and the eccentric pin 7B provided at the shaft end of the rotary shaft 7 are coupled via a drive bush, an orbiting bearing and the like. The orbiting scroll member 33 is provided between the orbiting scroll member 33 and the support member 31 for revolving orbiting around the fixed scroll member 32, and the orbiting scroll member 33 is revolved while preventing its rotation. A rotation prevention mechanism 36 such as an Oldham ring to be rotated and a back surface of the fixed scroll member 32 are provided. And off valve 40, it is fixedly installed on the rear surface of the fixed scroll member 32, and a discharge cover 42 or the like for forming the discharge chamber 41 between the fixed scroll member 32.

  The high-stage scroll compression mechanism 3 itself may be a known one, and the intermediate-pressure refrigerant gas compressed by the low-stage rotary compression mechanism 2 and discharged into the sealed housing 10 is sucked into the compression chamber 34, The rotary scroll member 33 is configured to be compressed to the discharge pressure (high pressure) by the revolving orbit drive and then discharged to the discharge chamber 41 through the discharge valve 40. The high-pressure refrigerant gas is discharged from the discharge chamber 41 through the discharge pipe 43 to the outside of the compressor, that is, to the refrigeration cycle side.

  A known positive displacement oil pump 11 is incorporated between the lowermost end portion of the rotating shaft 7 and the lower bearing 23 of the low-stage rotary compression mechanism 2. This positive displacement oil pump 11 pumps up lubricating oil (hereinafter also referred to simply as oil) 13 filled in an oil reservoir 12 formed at the bottom of the hermetic housing 10 and is provided in the rotary shaft 7. The lubricating oil 13 is forcibly supplied to a required lubricating portion such as a bearing portion of the low-stage-side rotary compression mechanism 2 and the high-stage-side scroll compression mechanism 3 through the provided oil supply hole 14.

  Further, the high-stage scroll compression mechanism 3 is provided with an oil discharge path for returning oil that has lubricated a required lubrication site such as a bearing portion to the oil reservoir 12 at the bottom of the sealed housing 10. This oil drainage path accommodates the orbiting boss portion 35 of the orbiting scroll member 33, the space portion 45 of the support member 31 where the oil that has lubricated the required lubrication site, and the outer peripheral portion of the space portion 45 and the support member 31. And an oil drain pipe 48 inserted and installed in a downward pipe insertion hole 47 intersecting with the oil drain hole 46.

  As shown in FIG. 4, the oil drain pipe 48 extends downward from the lower surface of the support member 31, and the lower end thereof is disposed below the high stage side scroll compression mechanism 3. It is configured to be disposed in a range H below 5A and above the upper end of the stator 5. Further, the oil drain pipe 48 has a lower portion smoothly curved toward the outer peripheral side of the stator 5 and a plurality of stator cuts 5B (FIG. 1) having lower end openings provided on the outer periphery of the stator 5. It is configured to be opened at a position opposite to one of the reference). Furthermore, the outer diameter D of the oil drainage pipe 48 is made larger than the radial width L of the stator cut 5B, so that the pressure loss in the oil drainage path is reduced and the oil can be drained smoothly. .

  In the present invention, the fact that the lower portion of the oil drainage pipe 48 is smoothly curved toward the outer peripheral side of the stator 5 means that the lower portion is not only smoothly curved in an arc shape. Is bent toward the outer peripheral side, and the lower part is bent smoothly as a whole.

With the configuration described above, according to the present embodiment, the following operational effects can be obtained.
The low-pressure refrigerant gas directly sucked into the cylinder chamber 20 of the low-stage rotary compression mechanism 2 through the suction pipe 25 is compressed to an intermediate pressure by the rotation of the rotor 24 and then discharged to the discharge chambers 26A and 26B. . The intermediate-pressure refrigerant gas is merged in the discharge chamber 26 </ b> A and discharged into the lower space of the electric motor 4, and then flows through the gas passage hole 6 </ b> A provided in the rotor 6 of the motor 4 and the upper portion of the motor 4. Flowed into space.

  The intermediate-pressure refrigerant gas that has flowed into the upper space of the motor 4 passes through the notch portion 31 </ b> A provided on the outer peripheral surface of the support member 31 that constitutes the high-stage scroll compression mechanism 3. Are sucked into the compression chamber 34. The intermediate-pressure refrigerant gas is compressed into a high pressure by the high-stage scroll compression mechanism 3 and then discharged into the discharge chamber 41 from the discharge valve 40, and the outside of the compressor, that is, the refrigeration through the discharge pipe 43. It is sent to the cycle side.

  During the two-stage compression process, the lubricating oil 13 supplied to the lubricating part of the low-stage rotary compression mechanism 2 by the oil supply pump 11 through the oil supply hole 14 is lubricated to a required lubricating part, and a part of the lubricating oil 13 is oil. It flows down to the reservoir 12 and the other part dissolves in the refrigerant gas and is discharged into the lower space of the motor 4 together with the intermediate-pressure refrigerant gas, where it is separated and flows down to the oil reservoir 12. On the other hand, the lubricating oil 13 supplied to the lubrication site of the high-stage scroll compression mechanism 3 through the lubrication hole 14 is lubricated to the required lubrication site, and then partially dissolved in the refrigerant gas, so that the discharged gas is directly discharged. At the same time, it is sent out to the refrigeration cycle side, but most of it is collected in the space 45 of the support member 31.

  The lubricating oil 13 collected in the space 45 passes through a drain hole 46 and a drain pipe 48 communicated with the space 45, and the stator cut 5B of the motor 4 from the lower end opening of the drain pipe 48. Then, the air is introduced into the oil reservoir 12 at the bottom of the sealed housing 10 through the stator cut 5B. As a result, oil rising from the hermetic compressor 1 to the refrigeration cycle side can be reduced, system efficiency can be improved, and lack of lubricating oil in the compressor 1 can be eliminated.

  Further, in the present embodiment, the oil lubricated at the required lubrication site of the high-stage scroll compression mechanism 3 is returned to the oil reservoir 12 through the oil drain hole 46 and the oil drain pipe 48 so that the oil cannot be taken up by the refrigerant gas. However, the lower end of the oil drainage pipe 48 is disposed between the range H below the stator coil end 5A of the motor 4 and above the upper end of the stator 5, and is provided on the outer periphery of the stator 5. The lower portion of the oil drain pipe 48 is smoothly curved toward the outer peripheral side of the stator 5 and the outer diameter D of the oil drain pipe 48 is set to the diameter of the stator cut 5B. It is larger than the direction width L.

  For this reason, the oil which lubricated the required lubrication site | part of the high stage side scroll compression mechanism 3 is guide | induced to the oil drain hole 46 and the oil drain pipe 48 from the space part 45 provided in the supporting member 31, and the diameter of the stator cut 5B Outflow in a centrifugal direction by a portion curved toward the outer peripheral side of the stator 5 at the lower part of the oil drain pipe 48 while suppressing flow pressure pressure loss by the oil drain pipe 48 having an outer diameter D larger than the direction width L. And can be reliably introduced into the opposite stator cut 5B from the lower end opening. Therefore, the oil flowing out from the oil drain pipe 48 is surely supplied to the stator cut 5B without increasing the outer diameter of the hermetic housing 10 and the width L of the stator cut 5B, and suppressing the flow path pressure loss in the oil drain path. It can be introduced and smoothly flow down to the oil sump 12 and oil rising from the hermetic compressor 1 can be prevented.

[Second Embodiment]
Next, a second embodiment of the present invention will be described with reference to FIGS.
The present embodiment differs from the first embodiment described above in the installation structure of the oil drain pipe 48. Since other points are the same as those in the first embodiment, description thereof will be omitted.
In the present embodiment, the upper end portion of the oil drain pipe 48 is press-fitted into the downward pipe insertion hole 47 intersecting with the oil drain hole 46 (including light press fitting), and the oil drain pipe 48 is fixedly installed in the pipe insertion hole 47. At the same time, a lateral hole 49 provided on the outer peripheral surface of the upper end portion of the oil draining pipe 48 is communicated with the oil draining hole 46, and oil discharged from the oil draining hole 46 is introduced into the oil draining pipe 48 through the lateral hole 49. It can be introduced.

  In addition, in this embodiment, it is set as the structure which provided the horizontal hole 49 in the outer peripheral surface of the upper end part of the oil exhaust pipe 48, but it replaces with this horizontal hole 49, and as shown to FIG. 6 (A) and (B), It is good also as a structure which provided the notches 50A and 50B which cut a part of the side facing the oil drain hole 46 of the upper end part of the oil drain pipe 48 in the shape of a rectangle or a triangle.

  As described above, the upper end portion of the oil drain pipe 48 is inserted and installed in the downward pipe insertion hole 47 intersecting the oil drain hole 46 provided in the support member 31 in the radially outward direction. By adopting a configuration in which oil discharged from the oil drain hole 46 through the horizontal hole 49 or the notches 50A and 50B provided in the upper end portion can be introduced to the oil drain pipe 48 side, Is inserted into a downward pipe insertion hole 47 intersecting the oil drain hole 46, and the horizontal hole 49 or notches 50A and 50B provided in the outer peripheral surface of the upper end of the oil drain pipe 48 are communicated with the oil drain hole 46. By doing so, it is possible to form an oil drainage path that guides the oil that has lubricated the lubrication site of the high-stage scroll compression mechanism 3 to the stator cut 5B. For this reason, it is not necessary to block the outer end portion of the oil drain hole 46, the formation of the oil drain path can be facilitated, and the winding of oil by the refrigerant gas can be reliably suppressed.

  Further, since the upper end portion of the oil drainage pipe 48 is inserted and installed in the pipe insertion hole 47 by press-fitting, the end portion outside the oil drainage pipe 48 between the oil drainage pipe 48 and the pipe insertion hole 47 and the oil drainage hole 46. It is possible to eliminate the oil leakage gap. Accordingly, oil leakage from the oil drain hole 46 and the pipe insertion hole 47 can be eliminated, the oil can be effectively guided to the oil reservoir 12, oil rising can be suppressed, and the oil drain pipe 48 can be supported. The falling off from the member 31 can be reliably prevented.

[Third Embodiment]
Next, a third embodiment of the present invention will be described with reference to FIGS.
The present embodiment differs from the first and second embodiments described above in the attachment structure of the oil drain pipe 48A. Since other points are the same as those in the first and second embodiments, description thereof will be omitted.
In the present embodiment, a stepped portion 51 whose outer diameter is reduced in a tapered shape is provided at a lower position of the upper end portion where the oil drain pipe 48A is inserted and installed in the pipe insertion hole 47, and the diameter of the upper end portion is slightly increased. The stepped oil drain pipe 48A is thickened, and the mounting plate 52 is integrally joined to the stepped portion 51 by brazing or bonding.

  The stepped oil drain pipe assembly (oil drain pipe) 48 A is inserted and installed in the pipe insertion hole 47 via the mounting plate 52, and the mounting plate 52 is further supported by the support member 31 via the bolt 53. It is set as the structure fixed with a screw. Further, as shown in FIG. 7, the mounting plate 52 has a bolt hole 54 and is provided in the oil drain hole 46 and the oil drain pipe 48 </ b> A in a state of being screwed and fixed to the support member 31 via the bolt 53. The oil drain pipe 48A is previously integrated with the oil drain pipe 48A by brazing or bonding so that the positions of the horizontal holes 49 or the cutouts 50A and 50B and the bending direction of the oil drain pipe 48A are set to predetermined positions and directions. It is configured.

  As described above, the attachment plate 52 is integrally provided below the upper end portion of the oil drain pipe 48A inserted and installed in the pipe insertion hole 47, and the oil drain pipe 48A is attached to the support member 31 by the attachment plate 52. Since the pipe insertion hole 47 is inserted and installed, the upper end portion of the oil drain pipe 48A integrally provided with the mounting plate 52 is inserted into the pipe insertion hole 47, and the oil drain pipe 48A is inserted into the support member 31. The pipe insertion hole 47 can be sealed with the mounting plate 52 so as not to leak oil. Therefore, oil leakage from the pipe insertion hole 47 can be eliminated, oil can be effectively guided to the oil reservoir 12, oil rising can be suppressed, and the oil drain pipe 48A can be prevented from falling off. .

  In addition, the mounting plate 52 is fixed to the support member 31 with bolts 53 with screws 53, and the positions of the oil drain holes 46 and the horizontal holes 49 or notches 50A and 50B provided in the oil drain pipe 48A and The oil drain pipe 48A is previously integrated with the oil drain pipe 48A so that the bending direction of the oil drain pipe 48A is set to a predetermined position and direction. For this reason, the oil drain hole 46 and the oil drain pipe 48A can be obtained simply by inserting the oil drain pipe 48A in which the mounting plate 52 is integrally assembled into the pipe insertion hole 47 and screwing and fixing the mounting plate 52 to the support member 31. The position of the horizontal hole 49 or the notches 50A and 50B provided in the direction of the oil drain pipe 48A and the direction of the oil drain pipe 48A can be set to a predetermined position and direction. Therefore, the assembly of the oil drain pipe 48A can be facilitated and the assembly accuracy can be improved, and the oil can be more reliably introduced into the stator cut 5B.

  Further, in this embodiment, the oil drain pipe 48A is a stepped oil drain pipe 48A whose diameter is reduced at a position below the upper end portion inserted and installed in the pipe insertion hole 47, and the mounting plate 51 is attached to the stepped portion 51. 52, the mounting plate 52 is simply joined to the specified position of the oil drainage pipe 48A using the stepped portion 51 of the pipe by brazing or bonding, and assembled together. Can do. Therefore, it is possible to facilitate the manufacture and assembly of the drain oil pipe 48A with the mounting plate 52, and to improve the assemblability of the hermetic compressor 1.

[Fourth Embodiment]
Next, a fourth embodiment of the present invention will be described with reference to FIG.
The present embodiment differs from the first to third embodiments described above in the configuration of the oil drain pipe 48B. Since other points are the same as those in the first to third embodiments, the description thereof will be omitted.
In the present embodiment, as shown in FIG. 9, the lower end opening 48 </ b> C through which oil flows out toward the stator cut 5 </ b> B of the oil drain pipe 48 </ b> B opens along the inner peripheral surface of the hermetic housing 10. It is configured to be cut diagonally.

  In this manner, the lower end opening 48C of the oil drainage pipe 48B is hermetically cut so as to open along the inner peripheral surface of the hermetic housing 10, whereby the lower end opening 48C of the oil drainage pipe 48B is hermetically sealed. The housing 10 can be opened long in a downward direction substantially parallel to the inner peripheral surface of the housing 10. For this reason, the directivity of the oil flowing out from the lower end opening 48C of the oil drain pipe 48B toward the stator cut 5B can be improved, and the oil can be more reliably guided into the stator cut 5B.

  In addition, this invention is not limited to the invention concerning the said embodiment, In the range which does not deviate from the summary, it can change suitably. For example, in a hermetic compressor to which the present invention is applied, a compression mechanism is provided in the upper part of the motor in the hermetic housing, and the lubricating oil filled in the oil reservoir at the bottom of the hermetic housing is supplied to the oil pump and the oil hole. As long as the oil is supplied to the compression mechanism through the oil, and after lubricating the required lubrication part, it can be applied regardless of the type of the compression mechanism, regardless of whether it is a single stage or multiple stages. .

1 Hermetic multistage compressor (hermetic compressor)
2 Low stage side compression mechanism 3 High stage side compression mechanism 4 Motor 5 Stator 5A Stator coil end 5B Stator cut 7 Rotating shaft (Crankshaft)
10 Sealed housing 11 Oil supply pump 12 Oil reservoir 13 Lubricating oil (oil)
14 Oil supply hole 31 Support member 46 Oil drain hole 47 Pipe insertion hole 48, 48A, 48B Oil drain pipe 48C Lower end opening 49 Side hole 50A, 50B Notch 51 Stepped portion 52 Mounting plate 53 Bolt D Outer diameter L of oil drain pipe Stator cut radial width

Claims (8)

A motor is built in the hermetic housing, and a compression mechanism that is driven by the motor via a rotating shaft is provided at the top, and lubricating oil filled in an oil reservoir at the bottom of the hermetic housing is supplied to the oil supply pump and the rotating shaft. Oil is supplied to a required lubricating portion of the compression mechanism through an oil supply hole therein, and oil that has lubricated the portion is supplied to the oil reservoir through an oil discharge hole and a drain pipe provided in a support member of the compression mechanism. It is a hermetic compressor that is made to return,
The oil drainage pipe is opened at a position facing the stator cut provided on the outer periphery of the stator below the stator coil end of the motor and above the stator upper end.
A closed type characterized in that a lower portion of the oil drain pipe is curved toward the outer peripheral side of the stator, and an outer diameter of the oil drain pipe is made larger than a radial width of the stator cut. Compressor. The oil drainage pipe has its upper end inserted and installed in a downward pipe insertion hole that intersects the oil drainage hole provided radially outward on the support member,
The oil discharged from the oil drain hole through a lateral hole or notch provided in the outer peripheral surface of the upper end portion of the oil drain pipe can be introduced into the oil drain pipe side. The hermetic compressor according to 1.   3. The hermetic compressor according to claim 1, wherein a lower end opening of the oil drain pipe is cut obliquely so as to open along an inner peripheral surface of the hermetic housing. A motor is built in the hermetic housing, and a compression mechanism that is driven by the motor via a rotating shaft is provided at the top, and lubricating oil filled in an oil reservoir at the bottom of the hermetic housing is supplied to the oil supply pump and the rotating shaft. Oil is supplied to a required lubricating portion of the compression mechanism through an oil supply hole therein, and oil that has lubricated the portion is supplied to the oil reservoir through an oil discharge hole and a drain pipe provided in a support member of the compression mechanism. A hermetic compressor that is being returned,
The oil drainage pipe has its upper end inserted and installed in a downward pipe insertion hole that intersects the oil drainage hole provided radially outward in the support member,
Sealed type characterized in that oil discharged from the oil drain hole can be introduced to the oil drain pipe side through a lateral hole or notch provided in the outer peripheral surface of the oil drain pipe upper end. Compressor.   The hermetic compressor according to any one of claims 2 to 4, wherein an upper end portion of the oil drain pipe is inserted and installed in the pipe insertion hole by press fitting. The drainage pipe is integrally provided with a mounting plate at a lower position of the upper end portion inserted and installed in the pipe insertion hole,
5. The hermetic compression according to claim 2, wherein the oil drainage pipe is inserted and installed through the mounting plate so as to close the pipe insertion hole with respect to the support member. Machine.   The mounting plate is screwed and fixed to the support member, and in this state, the positions of the drain holes and the side holes or notches provided in the drain pipe and the direction of the drain pipe are predetermined. The hermetic compressor according to claim 6, wherein the hermetic compressor is integrated with the oil drain pipe in advance so as to be set in a position and a direction. The drainage pipe is a stepped pipe having a reduced diameter at a position below the upper end portion inserted and installed in the pipe insertion hole, and the mounting plate is joined to the stepped portion. The hermetic compressor according to claim 6 or 7.

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