JP2011043067A - Scroll compressor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce a scroll compressor in size along the axial direction. <P>SOLUTION: The scroll compressor 10 forms, in the back face 34a of a fixed scroll 34 meshed with a movable scroll 36, a circular recess 72 facing the separation chamber 44 of a rear housing 14, and an oil separation pipe 50 having a cylindrical part and a body part is mounted in the circular recess. The oil separation pipe 50 is held with the cylindrical part inserted in the separation chamber 44 and with the body part caught between the fixed scroll 34 and the rear housing 14 when fitting the fixed scroll 34 to the rear housing 14. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a scroll type compressor that has a fixed scroll and a movable scroll that are meshed with each other to form a compression chamber, and compresses fluid by turning the movable scroll.

  Conventionally, a fixed scroll having a fixed plate and a spiral fixed wrap upright on the fixed plate, and a movable scroll arranged so that the movable plate and a spiral movable wrap upright on the movable plate are engaged with the fixed wrap. And a compression chamber formed between the fixed scroll and each wrap of the movable scroll and the fixed plate and the movable plate by rotating the movable scroll through an eccentric drive pin. A scroll type compressor is known in which a fluid is compressed by gradually moving to a central part.

  The present applicant has provided a separation chamber for separating the above-described fluid and the lubricating oil contained in the fluid between the back surface of the fixed scroll and the housing, and a scroll type compression in which a separation member is provided in the separation chamber. Has been proposed (see Patent Document 1).

JP 2007-9772 A

  The present invention has been made in connection with the above proposal, and an object thereof is to provide a scroll type compressor that can be miniaturized along the axial direction.

In order to achieve the above-mentioned object, the present invention provides a discharge chamber formed between a fixed scroll and a housing, into which a compressed fluid is led out under a turning action of a movable scroll meshed with the fixed scroll, In a scroll compressor comprising a separation chamber that communicates with the discharge chamber and separates the lubricating oil contained in the fluid, and an oil storage chamber that communicates with the separation chamber and stores the lubricating oil.
A main body part sandwiched between the fixed scroll and the housing; and a pipe part connected to the main body part and inserted into the housing to distribute the fluid and the lubricating oil in the separation chamber. An oil separating member;
With
An end portion of the tube portion on the main body side is provided on the fixed scroll side with respect to a joint surface between the fixed scroll and the housing.

  According to the present invention, the oil separating member includes a main body portion sandwiched between the fixed scroll and the housing, and a pipe portion connected to the main body portion and inserted into the housing, and the main body portion side The end portion of the tube portion is provided on the fixed scroll side with respect to the joint surface between the fixed scroll and the housing. The oil separation member separates the fluid and the lubricating oil in a separation chamber communicating with the discharge chamber, and distributes the lubricating oil to the oil storage chamber.

  Therefore, by setting the end portion of the tube portion to the fixed scroll side with respect to the joint surface, the protruding amount (length) of the tube portion inserted into the housing can be suppressed, and the tube portion can be made to have a desired length. Therefore, the housing can be reduced in size along the axial direction, and accordingly, the scroll compressor can be reduced in size along the axial direction.

  The separation chamber may be configured by a first space provided between the main body portion and the tube portion in the oil separation member, and a second space formed in the housing and communicating with the first space. Thus, in addition to the second space formed in the housing, the first space can be provided on the oil separation member side, and the separation chamber can be configured from the first space and the second space. The longitudinal dimension of the second space can be suppressed, and the longitudinal dimension of the housing can be reduced accordingly.

  Further, the main body may be formed with an introduction passage through which the discharge chamber and the separation chamber are communicated to introduce fluid from the discharge chamber to the separation chamber.

  Furthermore, it is preferable to provide a capturing means for capturing the lubricating oil at the joint surface between the first space in the fixed scroll and the second space in the housing. Accordingly, the lubricating oil can be easily captured by providing the capturing means between the first space and the second space, and the fixed scroll is compared with the case where the capturing means is provided separately. In addition, the processing man-hours and assembly man-hours for the housing can be reduced.

  According to the present invention, the following effects can be obtained.

  In other words, the pipe, which is composed of a main body portion sandwiched between the fixed scroll and the housing, and a pipe portion connected to the main body portion and inserted into the housing, the oil separating member being on the main body side. By providing the end of the portion on the fixed scroll side with respect to the joint surface between the fixed scroll and the housing, the protruding amount (length) of the tube portion inserted into the housing can be suppressed. Moreover, since the tube portion can be formed with a desired length, the housing can be reduced in size along the axial direction, and accordingly, the scroll compressor can be reduced in size along the axial direction. .

1 is an overall longitudinal sectional view of a scroll compressor according to an embodiment of the present invention. It is a top view of the rear housing seen from the joint surface side. It is an expanded sectional view of the oil separation pipe vicinity shown in FIG. It is the top view which looked at the fixed scroll in the scroll compressor of Drawing 1 from the fixed side spiral wall side. It is a top view of this fixed scroll seen from the back side of the fixed scroll. FIG. 5 is an exploded perspective view showing a state where an oil separation pipe is detached from the fixed scroll of FIG. 4. It is a top view of the fixed scroll with which the oil separation pipe which concerns on a modification is mounted | worn. 8A to 8C are enlarged cross-sectional views showing the vicinity of a connection portion between the main body of the oil separation pipe and the rear housing.

  A preferred embodiment of a scroll compressor according to the present invention will be described in detail below with reference to the accompanying drawings.

  In FIG. 1, reference numeral 10 indicates a scroll compressor according to an embodiment of the present invention.

  As shown in FIG. 1, the scroll compressor 10 includes a front housing 12 formed in a cup shape, and a rear housing (housing) 14 connected to the front housing 12. In the rear housing 14, for example, a suction port (not shown) for introducing a fluid made of a refrigerant gas or the like into the interior, and a compressed fluid obtained by compressing the fluid by the scroll compressor 10, for example, a refrigerant circulation A discharge port (not shown) for discharging to the system is provided.

  The rear housing 14 is provided with a plurality of attachment portions 16 for attaching the scroll compressor 10 to, for example, an engine or an external device.

  A shaft portion 20 of the rotary shaft 18 is inserted into the front housing 12, and the shaft portion 20 is rotatably supported via a first bearing 22 held by the front housing 12.

  Further, the rotary shaft 18 is provided with a support portion 24 whose diameter is increased with respect to the shaft portion 20, and the support portion 24 is rotatably supported by inserting an outer peripheral surface of the support portion 24 into the second bearing 26. . That is, the rotating shaft 18 is rotatably supported by the first and second bearings 22 and 26. A pin 28 eccentric to the axis is fixed to the end surface of the support portion 24.

  Further, the front housing 12 is connected via a plurality of fastening bolts 30 so as to close the opening of the rear housing 14.

  Further, a thrust bearing 32 is provided between the end surface of the front housing 12 and the end surface of the movable scroll 36, and the turning of the movable scroll 36 is permitted via the thrust bearing 32 and is given to the movable scroll 36. The axial thrust force is received.

  On the other hand, a fixed scroll 34 and a movable scroll 36 that turns with respect to the fixed scroll 34 are inserted into the rear housing 14 from the opened one end side.

  As shown in FIG. 2, a joining surface 38 is formed inside the rear housing 14 to which the fixed scroll 34 abuts and is fixed. The joining surface 38 includes the fixed scroll 34, the movable scroll 36, and the like. A first discharge chamber 42 into which a fluid compressed in a compression chamber 40 (see FIG. 1) composed of the fluid is introduced, and separation for separating the lubricating oil contained in the fluid in communication with the first discharge chamber 42 A chamber (second space) 44, a first oil storage chamber 46 in which the lubricating oil separated in the separation chamber 44 is stored, and a first discharge chamber 48 into which a fluid is introduced after the lubricating oil is separated. It is formed. The first discharge chamber 42, the separation chamber 44, the first oil storage chamber 46, and the first discharge chamber 48 are each formed to be recessed by a predetermined depth with respect to the joint surface 38.

  The separation chamber 44 is formed so that an oil separation pipe (oil separation member) 50 (described later) provided between the fixed scroll 34 and the fixed scroll 34 can be inserted when the fixed scroll 34 is assembled to the rear housing 14.

  Further, as shown in FIG. 3, the separation chamber 44 is formed with a lead-out passage 52 in the vicinity of the bottom portion separated from the joint surface 38 of the rear housing 14, and the lead-out passage 52 is formed with respect to the axis of the separation chamber 44. Are inclined at a predetermined angle and extend toward the end face. The lead-out passage 52 communicates with a discharge groove 54 provided on the joint surface 38 of the rear housing 14 and communicates with the first oil storage chamber 46 through the discharge groove 54 (see FIG. 2). That is, the oil separated inside the separation chamber 44 flows to the first oil storage chamber 46 through the outlet passage 52 and the discharge groove 54.

  The fixed scroll 34 includes a fixed side substrate portion 56 connected to the rear housing 14 and a fixed side spiral wall 58 erected in a spiral shape from the fixed side substrate portion 56 to the movable scroll 36 side.

  As shown in FIG. 4, a tube 62 is provided at a lower portion of the fixed-side spiral wall 58 so as to penetrate the fixed-side spiral wall 58, and the tube 62 has a predetermined length along the axial direction. And provided substantially parallel to the axis of the fixed scroll 34.

  One end of the tube 62 passes through the fixed-side substrate portion 56, communicates with the first oil storage chamber 46 of the rear housing 14 connected to the fixed scroll 34, and the other end is on the outer peripheral side of the fixed-side spiral wall 58. It opens at and communicates with the low pressure side. That is, the tube 62 communicates the first oil storage chamber 46 in which lubricating oil is stored with the low pressure side. In addition, a set of protective walls 64 are formed on the outer peripheral surface of the fixed spiral wall 58 so as to stand radially outward from both sides of the tube 62. Then, lubricating oil (for example, oil) is discharged from the first oil storage chamber 46 of the rear housing 14 and the second oil storage chamber 74 side of the fixed scroll 34 to the low pressure side through the tube 62, and the lubricating oil is fixed to the fixed-side spiral wall 58. Along the axial direction.

  On the other hand, the back surface 34 a of the fixed-side substrate portion 56 is provided so as to come into contact with the joint surface 38 of the rear housing 14 and is fixed by a plurality of bolts 66. A lead-out hole 68 communicating with the second discharge chamber 70 formed between the compression chamber 40 and the rear housing 14 is formed in a substantially central portion of the back surface 34a.

  Further, as shown in FIGS. 5 and 6, the second discharge chamber 70 into which the fluid compressed in the compression chamber 40 is introduced into the back surface 34 a of the fixed scroll 34 and the second scroll is introduced. The lubricating oil is separated from the discharge chamber 70 in a circular recess 72 in which an oil separation pipe 50 to be described later is mounted, a second oil storage chamber 74 in which the lubricating oil separated by the oil separation pipe 50 is stored. A second discharge chamber 76 into which a fluid is introduced later is formed.

  The second discharge chamber 70 is formed to be recessed by a predetermined depth with respect to the back surface 34 a of the fixed scroll 34, is formed so as to face the first discharge chamber 42 of the rear housing 14, and communicates with the outlet hole 68. Yes.

  A discharge valve (not shown) and a retainer 80 are inserted into the second discharge chamber 70. One end of the discharge valve is disposed at a position facing the lead-out hole 68, and the other end is fixed together with a retainer 80 on a straight line spaced from the lead-out hole 68 by a bolt. The discharge valve closes the outlet hole 68 and bends and opens when the fluid compressed in the compression chamber 40 described later reaches a predetermined pressure.

  That is, the discharge valve is seated so as to close the outlet hole 68, and the discharge valve is separated from the outlet hole 68 by the pressure of the compressed fluid introduced into the outlet hole 68. It is supplied to the discharge chamber 70.

  The circular recess 72 is provided so as to be between the second discharge chamber 70 and the second discharge chamber 76, and is disposed so as to face the separation chamber 44 when the fixed scroll 34 is assembled to the rear housing 14. . The circular concave portion 72 is formed with substantially the same depth as the second discharge chamber 70 and the second discharge chamber 76, and a concave groove 84 is formed in which the bottom portion separated from the back surface 34a of the fixed scroll 34 is further depressed by one step. It extends toward the second discharge chamber 76 side.

  As shown in FIGS. 3, 5 and 6, the oil separation pipe 50 provided in the circular recess 72 includes a main body portion 86 and a cylindrical portion 88 provided in the center of the main body portion 86. The main body portion 86 is formed in an annular shape on the outer peripheral side of the cylindrical portion 88 so as to be spaced apart by a predetermined distance in the radially outward direction, and has a predetermined height along the axial direction. The main body 86 is sandwiched and held in a state in which one side surface is attached to the circular recess 72 of the fixed scroll 34 and the other side surface is in contact with the joint surface 38 of the rear housing 14. Is done.

  An annular recess (first space) 90 provided between the main body portion 86 and the cylindrical portion 88 is separated from the separation chamber 44 when the oil separation pipe 50 is held between the fixed scroll 34 and the rear housing 14. The inner circumferential surface 44a of the separation chamber 44 and the inner circumferential surface 86a of the main body 86 are formed so as to be substantially flush with each other.

  The main body 86 is formed with first and second introduction passages 92 and 94 cut out so as to communicate the inside and the outside of the main body 86, and the first and second introduction passages 92 and 94, Through 94, the fluid in the first discharge chamber 42 is introduced into the interior of the separation chamber 44 described later. The first and second introduction passages 92 and 94 are formed at a predetermined interval so as to be substantially orthogonal to each other, and are formed so as to be tangential to the outer peripheral surface of the cylindrical portion 88 (FIG. 5). reference).

  On the other hand, a passage 95 penetrating in the axial direction is formed inside the cylindrical portion 88, and the cylindrical portion 88 is inserted into the separation chamber 44 of the rear housing 14. A clearance having a predetermined interval is provided between the cylindrical portion 88 and the inner peripheral surface 44 a of the separation chamber 44. That is, after the fluid introduced into the separation chamber 44 from the first and second discharge chambers 42 and 70 flows to the bottom side through the clearance, the oil separation pipe 50 is passed through the passage 95 of the cylindrical portion 88. It flows to the main body 86 side and is led out to the first discharge chamber 48 through the concave groove 84.

  The second discharge chamber 76 is provided with an open valve (not shown) for discharging the fluid in the second discharge chamber 76 to the outside through a valve hole (not shown), and the pressure of the fluid in the second discharge chamber 76 is reduced. When the pressure exceeds a predetermined value set in advance, the open valve is opened, and the fluid is discharged to the outside, and the pressure in the second discharge chamber 76 is reduced to a desired pressure value. As a result, the open valve is closed, the communication between the second discharge chamber 76 and the outside is cut off, and the pressure in the second discharge chamber 76 is maintained at a desired pressure value. The second oil storage chamber 74 is provided on the lower side of the back surface 34 a of the fixed scroll 34.

  Note that, between the second discharge chamber 70 and the second oil storage chamber 74, between the second discharge chamber 70 and the second discharge chamber 76, and between the second oil storage chamber 74 and the second discharge chamber 76, respectively. In addition to being separated by the boundary wall 96, the circular recess 72 is formed by notching a part of the boundary wall 96 between the second discharge chamber 70 and the second discharge chamber 76.

  The main body 86 may be fixed to the fixed scroll 34 with a fixing bolt 98 as in the oil separation pipe 50a shown in FIG. The means for positioning and fixing the oil separation pipe 50 with respect to the fixed scroll 34 is not limited to the fixing bolt 98 described above, and may be performed via the positioning pin 28 or the like. The circular recess 72 and the main body 86 may be fitted to each other, or the main body 86 may be press-fitted into the circular recess 72.

  That is, the oil separation pipe 50 may be fixed by any means as long as it is a means that can be fixed in a state in which the rotation with respect to the fixed scroll 34 is restricted.

  The movable scroll 36 includes a movable-side substrate unit 100 and a movable-side spiral wall 102 that is erected in a spiral shape from the movable-side substrate unit 100 toward the fixed scroll 34 and meshes with the fixed-side spiral wall 58. A compression chamber 40 is formed by the fixed-side substrate portion 56 and the fixed-side spiral wall 58 in the fixed scroll 34 and the movable-side substrate portion 100 and the movable-side spiral wall 102 in the movable scroll 36.

  In order to seal the compression chamber 40, sealing members 104a, 104a are respectively slidably in contact with the movable side substrate portion 100 and the fixed side substrate portion 56 at the ends of the fixed side spiral wall 58 and the movable side spiral wall 102, respectively. 104b is attached.

  A mounting hole 106 opened toward the second bearing 26 side is formed in the movable side substrate portion 100, and a bush 110 is rotatably supported in the mounting hole 106 via a swivel bearing 108. The bush 110 is formed with a hole portion that is eccentric with respect to the axis thereof, and the pin 28 of the support portion 24 is inserted into the hole portion.

  The scroll compressor 10 according to the embodiment of the present invention is basically configured as described above. Next, the operation, action, and effect thereof will be described.

  For example, when a rotational force is transmitted to the rotary shaft 18 under the action of an electromagnetic clutch (not shown), the support portion 24 rotates via the first and second bearings 22 and 26, thereby being fixed to the support portion 24. The pin 28 is rotated in a state of being eccentric with respect to the axis of the rotary shaft 18.

  Then, the bush 110 rotates via the pin 28 and turns with respect to the fixed scroll 34 while the movable scroll 36 is restrained from rotating.

  As a result, the compression chamber 40 formed between the fixed scroll 34 and the movable scroll 36 is gradually displaced from the outer peripheral portion to the central portion, and in the compression chamber 40 under the sealing action of the seal members 104a and 104b. The fluid is gradually compressed. Then, the compressed fluid is led out to the first and second discharge chambers 42 and 70 by separating the discharge valve (not shown) from the lead-out hole 68 under the pressure action.

  Next, the fluid is introduced from the first and second discharge chambers 42 and 70 into the separation chamber 44 through the first and second introduction passages 92 and 94. At this time, since the fluid is introduced in a tangential direction with respect to the inner peripheral surface 44a of the separation chamber 44, the inside of the clearance between the cylindrical portion 88 of the oil separation pipe 50 and the inner peripheral surface 44a is the inner peripheral surface. It circulates while turning along the surface 44a. Thereby, the lubricating oil contained in the fluid is centrifuged from the fluid by the centrifugal force generated by the swirling flow of the fluid and separated to the inner peripheral surface 44a side.

  The fluid from which the lubricating oil has been separated flows from the clearance between the separation chamber 44 and the cylindrical portion 88 to the main body portion 86 side through the passage 95 of the oil separation pipe 50, and once the concave groove 84 of the fixed scroll 34. And then introduced into the first and second discharge chambers 48 and 76 of the rear housing 14. As a result, the fluid is discharged to a refrigerant circulation system (not shown) through a discharge port (not shown) communicating with the discharge chamber.

  On the other hand, the lubricating oil separated from the fluid flows along the inner peripheral surface 44 a of the separation chamber 44, then flows to the joining surface 38 side through the lead-out passage 52, and the first and second oil storage chambers through the discharge groove 54. 46 and 74 are introduced and stored.

  Finally, the lubricating oil stored in the first and second oil storage chambers 46 and 74 is discharged to the outer peripheral surface of the fixed spiral wall 58 in the fixed scroll 34 through the tube 62, and the movable scroll 36 is moved along the outer peripheral surface. Circulate to the side. At this time, the sliding surface of the movable scroll 36 is supplied to the sliding surface between the movable substrate portion 100 and the fixed spiral wall 58, and the sliding surface is lubricated.

  Further, as shown in FIG. 8A, the inner peripheral surface 86a of the main body 86 in the oil separation pipe 50 and the inner peripheral surface 44a of the separation chamber 44 are offset in the radial direction, for example, the inner peripheral surface of the separation chamber 44 By forming 44 a so as to protrude radially inward with respect to the inner peripheral surface 86 a of the main body 86, the stepped portion 112 is provided at the joint portion between the main body 86 and the separation chamber 44. Thereby, when the lubricating oil separated from the fluid introduced into the annular recess 90 flows toward the separation chamber 44 along the inner peripheral surface of the annular recess 90, it is preferably captured by the step portion 112. It becomes.

  That is, it becomes possible to easily and suitably capture the separated lubricating oil by changing the shapes of the oil separation pipe 50 and the separation chamber 44.

  Note that the means for capturing the lubricating oil is not limited to the above-described configuration. For example, as shown in FIG. 8B, the section on the inner peripheral surface 86 a side at the end of the main body 86 is triangular. A chamfered portion 114a that is notched is formed in an annular shape, and another chamfered portion 114b having a triangular cross section facing the chamfered portion 114a is annularly formed on the inner peripheral surface 44a side at the opening end of the separation chamber 44. You may make it form in. In this case, the chamfered portions 114a and 114b are not limited to being provided in both the oil separation pipe 50 and the rear housing 14, and may be provided in only one of them. As a result, the lubricating oil can be easily and suitably captured in the recesses formed by the two chamfered portions 114 a and 114 b and recessed from the inner peripheral surfaces 86 a and 44 a of the main body portion 86 and the separation chamber 44.

  Further, as shown in FIG. 8C, for example, a plate material 116 is sandwiched between the main body 86 of the oil separation pipe 50 and the rear housing 14, and the plate material 116 is connected to the inner periphery of the main body 86 and the separation chamber 44. By slightly projecting in the radially inward direction with respect to the surfaces 86a and 44a, the lubricating oil can be suitably captured at the projecting portion of the plate material 116.

  As described above, in the present embodiment, in the oil separation pipe 50, the annular recess 90 is provided between the main body portion 86 and the cylindrical portion 88, and the annular recess 90 is communicated with the separation chamber 44 of the rear housing 14. Therefore, the separation chamber 44 provided in the rear housing 14 can be extended to the fixed scroll 34 side by the annular recess 90.

  Therefore, the amount of protrusion of the cylindrical portion 88 toward the rear housing 14 can be suppressed, and the separation chamber 44 can be easily assembled by assembling the oil separation pipe 50 having the annular recess 90 on the back surface of the fixed scroll 34. Can be extended to the fixed scroll 34 side. As a result, the longitudinal dimension of the separation chamber 44 can be sufficiently ensured without increasing the longitudinal dimension of the rear housing 14, and accordingly, the longitudinal dimension of the scroll compressor 10 including the rear housing 14 is increased. Miniaturization can be measured.

  Further, by changing the shape of only the oil separation pipe 50, it is possible to ensure the longitudinal dimension of the separation chamber 44, and it is not necessary to change the shape of the rear housing 14, so that the number of processing steps for the rear housing 14 is increased. It is also possible to reduce the number of man-hours when assembling the rear housing 14, the oil separation pipe 50, and the fixed scroll 34.

  That is, since the longitudinal dimension of the separation chamber 44 can be freely adjusted by changing the shape of the oil separation pipe 50, for example, the oil separation pipe 50 is also used in scroll compressors having different performance and characteristics. It is possible to easily change the separation characteristics of the lubricating oil by a simple operation of replacement.

  Furthermore, by providing the first and second introduction passages 92 and 94 in the main body portion 86 of the oil separation pipe 50, the fluid in the first and second discharge chambers 42 and 70 is suitably introduced into the separation chamber 44. Therefore, as compared with the case where a means for guiding the fluid to the separation chamber 44 is provided separately, the processing man-hour can be reduced and the assembling man-hour can also be reduced. Further, since the shape of the introduction passage can be easily changed by changing the shape of only the oil separation pipe 50, for example, the oil separation pipe 50 is replaced even in a scroll compressor having different performance and characteristics. This makes it easy to adjust the separation characteristics of the lubricating oil.

  Furthermore, the lubricating oil can be easily captured by providing an oil capturing means for capturing the separated lubricating oil contained in the fluid between the end of the oil separation pipe 50 and the end of the separation chamber 44. Therefore, as compared with the case where the oil catching means is provided separately, it is possible to reduce the processing man-hours and the assembling man-hours.

  The scroll compressor according to the present invention is not limited to the above-described embodiment, and can of course have various configurations without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 10 ... Scroll type compressor 12 ... Front housing 14 ... Rear housing 18 ... Rotating shaft 32 ... Thrust bearing 34 ... Fixed scroll 36 ... Movable scroll 40 ... Compression chamber 42 ... First discharge chamber 44 ... Separation chamber 46 ... First oil storage chamber 48 ... first discharge chamber 50, 50a ... oil separation pipe 56 ... fixed side substrate portion 58 ... fixed side spiral wall 68 ... leading hole 70 ... second discharge chamber 72 ... circular recess 74 ... second oil storage chamber 76 ... second discharge Chamber 86 ... Main body part 88 ... Cylindrical part 90 ... Annular recess 100 ... Movable side substrate part 102 ... Movable side spiral wall 104a, 104b ... Sealing member

Claims (4)

A discharge chamber formed between the fixed scroll and the housing and from which a fluid compressed under the swirling action of the movable scroll meshed with the fixed scroll is led out, and is contained in the fluid in communication with the discharge chamber. In a scroll compressor comprising a separation chamber that separates the lubricating oil, and an oil storage chamber that communicates with the separation chamber and stores the lubricating oil.
A main body part sandwiched between the fixed scroll and the housing; and a pipe part connected to the main body part and inserted into the housing to distribute the fluid and the lubricating oil in the separation chamber. An oil separating member;
With
The scroll type compressor, wherein an end portion of the tube portion on the main body portion side is provided on the fixed scroll side with respect to a joint surface between the fixed scroll and the housing. The scroll compressor according to claim 1, wherein
The separation chamber includes a first space provided between the main body portion and the tube portion in the oil separation member, and a second space formed in the housing and communicating with the first space. A scroll compressor characterized by that. In the scroll compressor according to claim 1 or 2,
The scroll compressor characterized in that the main body is formed with an introduction passage for communicating the discharge chamber and the separation chamber and introducing the fluid from the discharge chamber to the separation chamber. In the scroll compressor according to any one of claims 1 to 3,
A scroll compressor characterized in that a capture means for capturing the lubricating oil is provided on a joint surface between the first space in the fixed scroll and the second space in the housing.

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