JP2018035750A - Scroll compressor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a scroll compressor having high compression efficiency.SOLUTION: A scroll compressor includes: a casing; a scroll compression mechanism 60; a housing 61; a first back pressure chamber 101 and a second back pressure chamber 102; a discharge valve 35; and a first fixed scroll communication hole 37a and a second fixed scroll communication hole 37b. Here, the discharge valve 35 is provided in a second space S2 to prevent the back flow of compressed refrigerant. Further, the first fixed scroll communication hole 37a and the second fixed scroll communication hole 37b take out one or both of intermediate refrigerant and the compressed refrigerant from the upstream side of the discharge valve 35 and guide them to the first back pressure chamber 101 and the second back pressure chamber 102.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a scroll compressor.

  In recent years, a low-pressure dome type scroll compressor in which a casing is mainly filled with a low-pressure gas refrigerant has been used. As this type of scroll compressor, for example, a compressor having a relief valve for allowing the refrigerant in the compression chamber to escape to the discharge chamber when the refrigerant in the compression chamber becomes higher than the pressure in the discharge chamber is known ( For example, patent document 1 (Unexamined-Japanese-Patent No. 2013-167215).

  By the way, in the conventional low-pressure dome type scroll compressor, with the compression of the gas refrigerant, the movable scroll may be separated from the fixed scroll, and the compression efficiency may not increase.

  An object of the present invention is to provide a scroll compressor having high compression efficiency.

  A scroll compressor according to a first aspect of the present invention includes a casing, a scroll compression mechanism, a housing, a pressing structure, a backflow prevention mechanism, and a lead-out passage. The casing is partitioned into a first space and a second space. The scroll compression mechanism has a movable scroll that forms a compression chamber in combination with a fixed scroll and a fixed scroll. The scroll compression mechanism compresses the refrigerant sucked from the first space in the compression chamber and discharges it to the second space. The housing is attached inside the first space and is used to support the movable scroll. The pressing structure presses the movable scroll against the fixed scroll using one or both of the intermediate refrigerant being compressed in the compression chamber and the compressed refrigerant compressed in the compression chamber. The backflow prevention mechanism is provided in the second space and prevents backflow of the compressed refrigerant. The lead-out passage takes out one or both of the intermediate refrigerant and the compressed refrigerant from the upstream side of the backflow prevention mechanism and guides it to the pressing structure.

  In the scroll compressor according to the first aspect, the intermediate refrigerant and / or the compressed refrigerant is extracted from the upstream side of the backflow prevention mechanism and led out to the pressing structure, and the pressing structure moves the movable scroll from the first space (low pressure space) side. Press against fixed scroll. As a result, separation of the movable scroll and the fixed scroll is prevented, and a highly efficient scroll compressor can be provided.

  The scroll compressor which concerns on the 2nd viewpoint of this invention is a scroll compressor of a 1st viewpoint, Comprising: A backflow prevention mechanism is a check valve provided in the discharge port of a fixed scroll. Further, the inlet of the outlet passage is formed in the fixed scroll.

  In the scroll compressor according to the second aspect, the intermediate refrigerant and / or the compressed refrigerant is taken out from the upstream side of the check valve provided in the scroll compression mechanism and led out to the pressing structure via the fixed scroll. Therefore, in the scroll compressor of the present invention, when the operation is stopped, the compressed refrigerant compressed in the compression chamber is led to the first space before being discharged to the second space. Therefore, the present invention has a structure capable of suppressing the differential pressure between the first space and the second space. Thereby, a highly reliable scroll compressor can be provided.

  The scroll compressor which concerns on the 3rd viewpoint of this invention is a scroll compressor of the 1st viewpoint or the 2nd viewpoint, Comprising: The discharge pipe for discharging the refrigerant | coolant discharged from a compression chamber is further provided. The backflow prevention mechanism is a check valve provided in the discharge pipe. In addition, the outlet passage is formed with an inflow port in the fixed scroll.

  In the scroll compressor according to the third aspect, the intermediate refrigerant and / or the compressed refrigerant is taken out from the upstream side of the check valve provided in the discharge pipe and led out to the pressing structure via the fixed scroll. Therefore, in this scroll compressor, when the operation is stopped, the compressed refrigerant compressed in the compression chamber is led to the first space without staying in the second space, so that the differential pressure between the first space and the second space is reduced. It has a structure that can be suppressed. Thereby, a highly reliable scroll compressor can be provided.

  A scroll compressor according to a fourth aspect of the present invention is the scroll compressor according to the first to third aspects, and includes a floating member that is provided between the housing and the movable scroll and supports the movable scroll in contact therewith. Further prepare. Further, the pressing structure presses the movable scroll against the fixed scroll by pressing the floating member against the movable scroll using one or both of the intermediate refrigerant and the compressed refrigerant.

  In the scroll compressor according to the fourth aspect, the pressing structure presses the floating member against the movable scroll using the intermediate refrigerant and / or the compressed refrigerant. Thereby, the movable scroll is pressed against the fixed scroll. As a result, separation of the movable scroll and the fixed scroll is prevented, and a highly efficient scroll compressor can be provided.

  A scroll compressor according to a fifth aspect of the present invention is the scroll compressor according to the fourth aspect, wherein the pressing structure has a back pressure chamber formed between the housing and the floating member. Further, the lead-out passage leads one or both of the intermediate refrigerant and the compressed refrigerant to the back pressure chamber.

  In the scroll compressor according to the fifth aspect, since the intermediate refrigerant and / or the compressed refrigerant is led to the back pressure chamber formed between the housing and the floating member, the floating member becomes the movable scroll from the first space side. Pressed. Then, the movable scroll is pressed against the fixed scroll from the first space side.

  A scroll compressor according to a sixth aspect of the present invention is the scroll compressor according to the first to third aspects, wherein the pressing structure has a back pressure chamber formed between the housing and the movable scroll. Further, the lead-out passage leads one or both of the intermediate refrigerant and the compressed refrigerant to the back pressure chamber.

  In the scroll compressor according to the sixth aspect, since the intermediate refrigerant and / or the compressed refrigerant is led out to the back pressure chamber formed between the housing and the movable scroll, the movable scroll becomes the fixed scroll from the first space side. Pressed.

  A scroll compressor according to a seventh aspect of the present invention is the scroll compressor according to the first to sixth aspects, wherein a refrigerant having an intermediate pressure between the suction pressure and the discharge pressure is provided in the compression chamber in the first space. It further includes an injection mechanism for introduction.

  The scroll compressor according to the seventh aspect is provided with an injection mechanism for introducing an intermediate-pressure refrigerant into the compression chamber, so that a more efficient scroll compressor can be provided. Further, since the injection mechanism is provided in the first space, overheating of the injection mechanism is suppressed.

  The scroll compressor which concerns on the 8th viewpoint of this invention is a scroll compressor of the 1st viewpoint to the 7th viewpoint, Comprising: The partition member which can partition the inside of a casing into the 1st space and 2nd space from which pressure differs Is further provided.

  In the scroll compressor according to the eighth aspect, the inside of the casing can be partitioned into the first space and the second space having different pressures by the above configuration.

  In the scroll compressor according to the present invention, separation of the movable scroll and the fixed scroll is prevented, and a highly efficient scroll compressor can be provided.

It is a mimetic diagram showing an outline of air harmony device 1 in which scroll compressor 10 concerning a 1st embodiment of the present invention is used. It is a schematic diagram which shows the structure of the longitudinal cross-section of the scroll compressor 10 which concerns on the same embodiment. It is a partial enlarged view which shows typically a part of structure of the longitudinal cross-section of the scroll compression mechanism 60 concerning the embodiment. It is a partial enlarged view which shows typically a part of structure of the housing 61 which concerns on the embodiment. 4 is a partially enlarged view schematically showing a part of the configuration of a longitudinal section of a floating member 65 according to the embodiment. FIG. It is a partially expanded view schematically showing a longitudinal section of another form of the first housing communication hole 62a according to the embodiment. 10 is a partially enlarged view schematically showing a part of the configuration of a vertical cross section of a scroll compression mechanism 60 according to Modification C. FIG. 10 is a partially enlarged view schematically showing a part of the configuration of a vertical cross section of a scroll compression mechanism 60 according to Modification C. FIG.

<First Embodiment>
A scroll compressor 10 according to a first embodiment of the present invention will be described with reference to the drawings. In addition, the scroll compressor 10 which concerns on the following embodiment is only an example of the compressor of this invention, and can be suitably changed in the range which does not deviate from the meaning of this invention.

(1) Outline of Air Conditioner Using Scroll Compressor FIG. 1 is a schematic diagram showing an outline of an air conditioner 1 using a scroll compressor 10 according to the first embodiment of the present invention. Here, the air conditioner dedicated to the cooling operation is shown, but the air conditioner using the scroll compressor 10 may be dedicated to the heating operation, or both the cooling operation and the heating operation can be performed. It may be a thing.

  The air conditioner 1 includes an outdoor unit 2 having a scroll compressor 10, an indoor unit 3, a liquid refrigerant communication pipe 4, and a gas refrigerant communication pipe 5. The outdoor unit 2 mainly includes an accumulator 6, a scroll compressor 10, an outdoor heat exchanger 7, an expansion valve 8, an economizer heat exchanger 9, and an injection valve 26. The indoor unit 3 has an indoor heat exchanger 3a. The liquid refrigerant communication pipe 4 and the gas refrigerant communication pipe 5 connect the outdoor unit 2 and the indoor unit 3, respectively. These devices are connected by a refrigerant pipe as shown in FIG. 1 to form a refrigerant circuit.

  The scroll compressor 10 compresses the refrigerant sucked through the suction pipe 23 in a compression chamber Sc described later, and discharges the compressed refrigerant from the discharge pipe 24. The suction pipe 23 is connected to the indoor heat exchanger 3a, and the discharge pipe 24 is connected to the outdoor heat exchanger 7.

  In the scroll compressor 10, so-called intermediate injection is performed in which a part of the refrigerant flowing from the outdoor heat exchanger 7 toward the expansion valve 8 is supplied to the compression chamber Sc being compressed. Specifically, the refrigerant is supplied to the injection pipe 25 of the scroll compressor 10 through the injection refrigerant supply pipe 27 branched from the pipe connecting the outdoor heat exchanger 7 and the expansion valve 8. At this time, the pressure and flow rate of the refrigerant to be injected are adjusted by an injection valve 26 provided in the injection refrigerant supply pipe 27.

(2) Configuration of Scroll Compressor FIG. 2 is a schematic view showing a configuration of a vertical cross section of the scroll compressor 10 according to the first embodiment of the present invention. FIG. 3 is a partially enlarged view schematically showing a part of the configuration of the vertical cross section of the scroll compression mechanism 60. 4 and 5 are views showing the housing 61 and the floating member 65 shown in FIG. In each drawing, hatching or the like is omitted as appropriate in order to clarify the characteristic part.

  2 and 3, the scroll compressor 10 includes a casing 20, a partition member 28, a scroll compression mechanism 60 including a fixed scroll 30 and a movable scroll 40, a housing 61, a floating member 65, and a drive. A motor 70, a crankshaft 80, and a lower housing 90 are provided.

  Note that FIG. 2 shows cross-sectional views in different directions on the right side and the left side from the center. That is, in FIG. 2, the injection pipe 25 is shown on the left side, and the first fixed scroll communication hole 37a and the first housing communication hole 62a that are the discharge passages for the compressed refrigerant, and the second fixed passage that is the discharge passage for the intermediate refrigerant. Although the scroll communication hole 37b and the second housing communication hole 62b are shown on the right side, these members and the like are actually provided at optimal positions. 2 and 3, the first fixed scroll communication hole 37a and the first housing communication hole 62a, which are compressed refrigerant outlet passages, and the second fixed scroll communication hole 37b and the second housing, which are intermediate refrigerant outlet passages. Although the communication hole 62b is shown in parallel in the cross-sectional direction, any arrangement may be adopted as long as these lead-out passages are formed at different positions.

  Hereinafter, expressions such as “upper” and “lower” may be used in order to describe the positional relationship of the constituent members. Here, the direction of the arrow U in FIG. 2 is called up, and the direction opposite to the arrow U is called down. In the following description, expressions such as “vertical”, “horizontal”, “vertical”, “horizontal” may be used, but the vertical direction is defined as the vertical direction and the vertical direction.

(2-1) Casing The scroll compressor 10 has a vertically long cylindrical casing 20. The casing 20 includes a substantially cylindrical cylindrical member (body portion) 21 that is open at the top and bottom, and an upper lid 22 a and a lower lid 22 b provided at the upper end and the lower end of the cylindrical member 21, respectively. The cylindrical member 21, and the upper lid 22a and the lower lid 22b are fixed by welding so as to keep airtightness.

  The casing 20 houses components of the scroll compressor 10 including a scroll compression mechanism 60, a drive motor 70, a crankshaft 80, and a lower housing 90. The scroll compression mechanism 60 is disposed at the upper part in the cylindrical member 21. An oil sump space So is formed in the lower part of the casing 20. Refrigerating machine oil O for lubricating the scroll compression mechanism 60 and the like is stored in the oil reservoir space So. Further, the inside of the casing 20 is partitioned into a first space S1 and a second space S2 by a partition member 28. Thereby, during the operation of the scroll compressor 10, the first space S1 and the second space S2 have different pressures. Here, the partition member 28 is attached to the upper part of the fixed scroll 30, and the upper part of the casing 20 and the other intermediate part and lower part are partitioned into different spaces.

  A suction pipe 23 is attached to an intermediate portion of the casing 20 so as to penetrate the cylindrical member 21a and communicate with the first space S1. The low-pressure refrigerant in the refrigeration cycle before being compressed by the scroll compression mechanism 60 flows into the first space S1 through the suction pipe 23.

  A discharge pipe 24 is attached to the upper lid 22a of the upper portion of the casing 20 so as to communicate with the second space S2. A high-pressure gas refrigerant in the refrigeration cycle after being compressed by the scroll compression mechanism 60 is discharged from the second space S2 through the discharge pipe 24.

(2-2) Scroll Compression Mechanism The scroll compression mechanism 60 includes a fixed scroll 30 having a discharge port 32a and a movable scroll 40 that forms a compression chamber Sc in combination with the fixed scroll 30. Then, the scroll compression mechanism 60 compresses the refrigerant sucked from the first space S1 in the compression chamber Sc and discharges it to the second space S2.

(2-2-1) Fixed Scroll As shown in FIGS. 2 and 3, the fixed scroll 30 protrudes from a flat fixed end plate 32 and the front surface of the fixed side end plate 32 (the lower surface in FIGS. 2 and 3). A spiral fixed side wrap 33 and an outer edge portion 34 surrounding the fixed side wrap 33 are provided. The fixed side wrap 33 is formed so as to spirally extend from a discharge port 32a, which will be described later, to the outer edge portion 34 (see FIGS. 2 and 3). A suction port (not shown) is provided in the outer edge portion 34 of the fixed scroll 30. The refrigerant flowing from the suction pipe 23 is introduced into the compression chamber Sc of the scroll compression mechanism 60 through the suction port.

  A discharge port 32 a communicating with the compression chamber Sc of the scroll compression mechanism 60 is formed in the center portion of the fixed side end plate 32 so as to penetrate the fixed side end plate 32 in the thickness direction. The discharge port 32a is closed by a discharge valve 35 that functions as a check valve. A discharge chamber 36 is defined between the discharge valve 35 and the compression chamber Sc. The discharge valve 35 is opened when the compressed refrigerant in the discharge chamber 36 has a predetermined pressure or higher, and discharges the compressed refrigerant into the second space S2. As a result, the second space S2 has a pressure atmosphere equivalent to the pressure of the compressed refrigerant discharged from the scroll compression mechanism 60. Further, the discharge chamber 36 is formed with an inlet 36a of a first fixed scroll communication hole 37a described later.

  The fixed scroll 30 is supported on the lower surface (that is, the thrust surface) of the outer edge portion 34 by a support surface 61s of the housing 61 described later. A communication hole is formed in each of the fixed scroll 30 and the housing 61 so as to communicate with the support surface 61s. Specifically, as shown in FIGS. 2 and 3, the fixed scroll 30 is formed with a first fixed scroll communication hole 37a and a second fixed scroll communication hole 37b. The inflow end of the first fixed scroll communication hole 37a is an inflow port 36a that opens to the discharge chamber 36, and the outflow end of the first fixed scroll communication hole 37a continues to the first housing communication hole 62a on the support surface 61s. It is an opening formed at a position. The inflow end of the second fixed scroll communication hole 37b is an opening formed in the upper portion of the compression chamber Sc, and communicates with the compression chamber Sc when the turning angle of the movable scroll 40 falls within a predetermined range. The outflow end of the second fixed scroll communication hole 37b is an opening formed at a position continuous with the second housing communication hole 62b on the support surface 61s.

  The fixed side end plate 32 is formed with an injection passage 31 that opens on the side surface of the fixed side end plate 32 and communicates with the compression chamber Sc. When the pressure of the refrigerant supplied from the injection pipe 25 is higher than the pressure in the compression chamber Sc, the refrigerant is supplied to the compression chamber Sc. On the other hand, when the pressure of the refrigerant supplied from the injection pipe 25 is lower than the pressure of the compression chamber Sc, the reverse flow of the refrigerant is suppressed (blocked) by a check valve (not shown) provided in the injection passage 31. . The injection pipe 25 is attached to the fixed scroll 30 in the first space S1 below the partition member 28. Thus, the injection pipe 25 is prevented from being overheated by being attached to the first space S1 instead of the second space S2.

(2-2-2) Movable Scroll As shown in FIGS. 2 and 3, the movable scroll 40 protrudes from a flat movable side end plate 41 and the front surface of the movable side end plate 41 (upper surface in FIGS. It has a spiral movable wrap 42 and a cylindrical boss 43 that protrudes from the back surface (lower surface in FIGS. 2 and 3) of the movable side end plate 41.

  Here, the fixed side wrap 33 of the fixed scroll 30 and the movable side wrap 42 of the movable scroll 40 are combined so that the lower surface of the fixed side end plate 32 and the upper surface of the movable side end plate 41 face each other. Thereby, the compression chamber Sc is formed between the adjacent fixed side wrap 33 and the movable side wrap 42. Then, when the movable scroll 40 revolves with respect to the fixed scroll 30, the volume of the compression chamber Sc changes periodically. Thereby, the refrigerant sucked from the first space S1 is compressed in the compression chamber Sc.

  The boss portion 43 has a cylindrical shape with the upper end closed. An eccentric portion 81 of a crankshaft 80 described later is inserted into the hollow portion of the boss portion 43. Thereby, the movable scroll 40 and the crankshaft 80 are connected. The boss portion 43 is disposed in the eccentric portion space Sh formed between the movable scroll 40 and the floating member 65. The eccentric part space Sh communicates with the first space S1 and has the same pressure atmosphere as the suction pressure.

  The movable scroll 40 is supported by the floating member 65 via the Oldham coupling 58. The Oldham joint 58 is a member that prevents the movable scroll 40 from rotating and enables revolution.

(2-3) Housing The housing 61 is a member that is press-fitted into the cylindrical member 21 and is fixed below the partition member 28. Specifically, as shown in FIGS. 3 and 4, the housing 61 includes a first housing portion 61 a and a second housing portion 61 b from above. The first housing portion 61a and the second housing portion 61b are members each having a cylindrical portion having a substantially circular or substantially arc-shaped cross section, and both are integrally formed continuously. The inner periphery of the first housing part 61a is larger than the inner periphery of the second housing part 61b. Therefore, the housing 61 has a shape in which the second housing portion 61b extends from the first housing portion 61a. And the floating member 65 is supported by the upper surface of the extension part extended from the 1st housing part 61a of the 2nd housing part 61b contacting the lower surface of the floating member 65 mentioned later. At this time, the first diameter space 101b of the first back pressure chamber 101 and the second diameter of the second back pressure chamber 102 are between the upper surface of the extended portion of the second housing portion 61b and the lower surface of the floating member 65. A space 102b is formed. Details will be described later.

  Further, a part of the upper end surface of the first housing portion 61a is in close contact with the lower surface of the outer edge portion 34 of the fixed scroll 30, and is fixed by a bolt or the like (not shown). That is, a part of the upper end surface of the housing 61 functions as a support surface 61 s that supports the fixed scroll 30. Further, in the support surface 61s, the first housing communication hole 62a and the second housing communication hole 62b are formed so as to be continuous with the first fixed scroll communication hole 37a and the second fixed scroll communication hole 37b, respectively. The housing communication holes 62a and 62b communicate with back pressure chambers 101 and 102, which will be described later.

(2-4) Floating Member The floating member 65 is a member that is provided between the housing 61 and the movable scroll 40 in the first space S <b> 1 and supports the movable scroll 40 in contact therewith. Specifically, as shown in FIGS. 3 and 5, the floating member 65 includes a first floating portion 65 a formed so that the center portion of the upper surface is recessed, and a second floating portion 65 b formed below the first floating portion 65 a. And a third floating portion 65c that connects the first floating portion 65a and the second floating portion 65b. The first floating portion 65a is formed so as to surround the side surface of the eccentric portion space Sh in which the boss portion 43 of the movable scroll 40 is disposed. On the other hand, the first floating part 65a is formed so that the side surface is surrounded by the first housing part 61a. The second floating portion 65b is formed in a cylindrical shape, and a bearing 66 that supports the main shaft 82 of the crankshaft 80 is provided. A main shaft 82 is inserted into the bearing 66, and the main shaft 82 is rotatably supported. The third floating portion 65c is a cylindrical member, and connects the inside of the first floating portion 65a and the outside of the second floating portion 65b. The third floating portion 65c is formed so that the side surface is surrounded by the second housing portion 61b.

  The above-described floating member 65 is disposed so as to be fitted into the housing 61. As a result, the first back pressure chamber 101 and the second back pressure chamber 102 are formed between the floating member 65 and the housing 61. The first back pressure chamber 101 communicates with the discharge chamber 36 via the first fixed scroll communication hole 37a and the first housing communication hole 62a. As a result, the “compressed refrigerant” discharged from the compression chamber Sc is introduced into the first back pressure chamber 101. Further, the second back pressure chamber 102 communicates with the compression chamber Sc via the second fixed scroll communication hole 37b and the second housing communication hole 62b. Then, an “intermediate refrigerant” being compressed in the compression chamber Sc is introduced into the second back pressure chamber 102.

  Specifically, the first back pressure chamber 101 includes the first axial space 101a extending in the axial direction between the inner peripheral surface of the second housing portion 61b and the outer peripheral surface of the third floating portion 65c, and the second housing portion 61b. A first radial space 101b extending in the radial direction is formed between the upper surface and the lower surface of the first floating portion 65a. Here, the first housing communication hole 62a is formed to communicate with the first shaft space 101a. The inner peripheral surface of the second housing portion 61b and the outer peripheral surface of the third floating portion 65c are sealed by an O-ring 64a. The upper surface of the second housing part 61b and the lower surface of the first floating part 65a are sealed by an annular seal member 64c having a C-shaped cross section. The seal member 64c has an opening inside.

  The second back pressure chamber 102 includes a second axial space 102a extending in the axial direction between the inner peripheral surface of the first housing portion 61a and the outer peripheral surface of the first floating portion 65a, and the upper surface of the second housing portion 61b. And a second radial space 102b extending in the radial direction between the lower surface of the first floating portion 65a. Here, the inner peripheral surface of the first housing portion 61a and the outer peripheral surface of the first floating portion 65a are sealed by the O-ring 64b. The upper surface of the second housing part 61b and the lower surface of the first floating part 65a are sealed by an annular seal member 64c having a C-shaped cross section. At this time, the first diameter space 101b and the second diameter space 102b are partitioned by the seal member 64, and the C-shaped seal member 64c is arranged to have an opening on the first diameter space 101b side.

(2-5) Drive motor The drive motor 70 is rotatably accommodated inside the stator 71 with an annular stator 71 fixed to the inner wall surface of the cylindrical member 21 with a slight gap (air gap passage) therebetween. And a rotor 72.

  The rotor 72 is connected to the movable scroll 40 via a crankshaft 80 arranged so as to extend in the vertical direction along the axial center of the cylindrical member 21. As the rotor 72 rotates, the movable scroll 40 revolves with respect to the fixed scroll 30.

(2-6) Crankshaft The crankshaft 80 (drive shaft) is disposed in the cylindrical member 21 and drives the scroll compression mechanism 60. Specifically, the crankshaft 80 transmits the driving force of the driving motor 70 to the movable scroll 40. The crankshaft 80 is disposed so as to extend in the vertical direction along the axial center of the cylindrical member 21, and connects the rotor 72 of the drive motor 70 and the movable scroll 40 of the scroll compression mechanism 60.

  The crankshaft 80 includes a main shaft 82 whose center axis coincides with the axis of the cylindrical member 21, and an eccentric portion 81 that is eccentric with respect to the axis of the cylindrical member 21. The eccentric portion 81 is inserted into the boss portion 43 of the movable scroll 40 as described above. The main shaft 82 is rotatably supported by the bearing 66 of the floating member 65 and the lower bearing 91. The main shaft 82 is connected to the rotor 72 of the drive motor 70 between the floating member 65 and the lower housing 90.

  An oil supply path 83 for supplying the refrigerator oil O to the scroll compression mechanism 60 and the like is formed inside the crankshaft 80. The lower end of the main shaft 82 is located in an oil sump space So formed in the lower part of the casing 20, and the refrigerating machine oil O in the oil sump space So is supplied to the scroll compression mechanism 60 and the like through the oil supply path 83.

(2-7) Lower Housing The lower housing 90 is provided in the lower part in the cylindrical member 21 and supports the crankshaft 80. Specifically, the lower housing 90 has a lower bearing 91 on the lower end side of the crankshaft 80. Thereby, the main shaft 82 of the crankshaft 80 is rotatably supported. Note that an oil pickup communicating with the oil supply path 83 of the crankshaft 80 is fixed to the lower housing 90.

(3) Operation of the scroll compressor (3-1) Compression of refrigerant The operation of the scroll compressor 10 described above will be described.

  First, the drive motor 70 is activated. Thereby, the rotor 72 rotates with respect to the stator 71, and the crankshaft 80 to which the rotor 72 is fixed rotates. When the crankshaft 80 rotates, the movable scroll 40 connected to the crankshaft 80 revolves with respect to the fixed scroll 30. At this time, the low-pressure gas refrigerant in the refrigeration cycle is introduced into the first space S <b> 1 inside the casing 20 through the suction pipe 23. The gas refrigerant introduced into the first space S1 is sucked into the compression chamber Sc from the suction port of the fixed scroll 30. Then, as the movable scroll 40 revolves, the first space S1 and the compression chamber Sc are not in communication. As the volume of the compression chamber Sc decreases, the pressure inside the compression chamber Sc increases.

  The gas refrigerant in the compression chamber Sc is compressed as the volume of the compression chamber Sc decreases, and finally becomes a high-pressure gas refrigerant. The high-pressure gas refrigerant is discharged from the compression chamber Sc to the discharge chamber 36, and pushes up the discharge valve 35 to flow into the second space S2. Then, the high-pressure gas refrigerant is discharged to the outside of the casing 20 through the discharge pipe 24. The second space S2 is maintained in a high pressure state by the check valve provided in the discharge valve 35.

(3-2) Pressing by Back Pressure In the scroll compressor 10 described above, a high-pressure gas refrigerant is discharged from the compression chamber Sc to the discharge chamber 36. At this time, since the discharge chamber 36 is provided with the inflow port 36a of the first fixed scroll communication hole 37a, a part of the compressed refrigerant compressed in the compression chamber Sc is in the first fixed scroll communication hole 37a and the first fixed scroll communication hole 37a. It is led out to the first back pressure chamber 101 through the housing communication hole 62a. As a result, pressure is applied to the floating member 65 upward. The floating member 65 applies pressure upward to the movable scroll 40. As a result, the movable scroll 40 is pressed against the fixed scroll 30.

  In the scroll compressor 10 described above, the compression chamber Sc and the second fixed scroll communication hole 37b are intermittently communicated with each other as the movable scroll 40 turns. Therefore, part of the intermediate refrigerant that is being compressed in the compression chamber Sc is led out to the second back pressure chamber 102 via the second fixed scroll communication hole 37b and the second housing communication hole 62b. As a result, pressure is applied to the floating member 65 upward. The floating member 65 applies pressure upward to the movable scroll 40. As a result, the movable scroll 40 is pressed against the fixed scroll 30.

(4) Features (4-1)
As described above, the scroll compressor 10 according to the present embodiment includes the casing 20, the scroll compression mechanism 60, the housing 61, the first back pressure chamber 101 and the second back pressure chamber 102 (pressing structure), A discharge valve 35 (backflow prevention mechanism), a first fixed scroll communication hole 37a and a second fixed scroll communication hole 37b (lead-out passage) are provided. The inside of the casing 20 is partitioned into a first space S1 and a second space S2. The scroll compression mechanism 60 includes a fixed scroll 30 and a movable scroll 40 that forms a compression chamber Sc in combination with the fixed scroll 30. Then, the scroll compressor 10 compresses the refrigerant sucked from the first space S1 in the compression chamber Sc and discharges it to the second space S2. The housing 61 is attached inside the first space S <b> 1 and is used for supporting the movable scroll 40. The first back pressure chamber 101 and the second back pressure chamber 102 use the movable scroll 40 using one or both of an intermediate refrigerant being compressed in the compression chamber Sc and a compressed refrigerant discharged from the compression chamber Sc. Is pressed against the fixed scroll 30. The discharge valve 35 is provided in the second space S2, and prevents the backflow of the compressed refrigerant. The first fixed scroll communication hole 37a and the second fixed scroll communication hole 37b take out one or both of the intermediate refrigerant and the compressed refrigerant from the upstream side with respect to the discharge valve 35 (backflow prevention mechanism), and the first back pressure It leads to the chamber 101 and the second back pressure chamber 102.

  Therefore, in the scroll compressor 10 according to this embodiment, the intermediate refrigerant (intermediate pressure refrigerant) and / or the compressed refrigerant (high pressure refrigerant) is taken out from the upstream side of the discharge valve 35 (backflow prevention mechanism) and the first back pressure is obtained. To the chamber 101 and the second back pressure chamber 102 (pressing structure), and the first back pressure chamber 101 and the second back pressure chamber 102 move the movable scroll 40 to the fixed scroll 30 from the first space S1 (low pressure space) side. Press. As a result, separation of the movable scroll 40 and the fixed scroll 30 is prevented, and the highly efficient scroll compressor 10 can be provided.

  In the scroll compressor 10 according to the present embodiment, when the operation is stopped, the compressed refrigerant compressed in the compression chamber Sc is led out to the first space S1 before flowing out downstream from the discharge valve 35 (backflow prevention mechanism). Is done. Here, since the discharge valve 35 (backflow prevention mechanism) is provided in the second space S2, it has a structure capable of suppressing the differential pressure between the first space S1 and the second space S2. Thereby, a highly reliable scroll compressor can be provided.

  Supplementally, in the scroll compressor 10 in which the discharge valve 35 (backflow prevention mechanism) is provided at the discharge port 32a, a differential pressure is generated between the first space S1 and the second space S2 inside the scroll compression mechanism 60 when the operation is stopped. Become. If the state in which such differential pressure occurs is prolonged, problems such as shortening of the life of the seal member between various members and occurrence of liquid compression upon restarting occur. With the structure of the scroll compressor 10 according to the present embodiment, before the operation is stopped, the compressed refrigerant compressed in the compression chamber Sc flows out into the second space S2 downstream of the discharge valve 35 (backflow prevention mechanism). Therefore, it is possible to suppress the occurrence of a differential pressure between the scroll compression mechanism 60 and the second space S2.

(4-2)
Further, the scroll compressor 10 according to the present embodiment has a floating member 65 between the housing 61 and the movable scroll 40 that supports the movable scroll 40 in contact therewith. The first back pressure chamber 101 and the second back pressure chamber 102 press the floating member 65 against the movable scroll 40 using either one or both of the intermediate refrigerant and the compressed refrigerant, thereby fixing the movable scroll 40 to the fixed scroll 30. Press on.

  Here, a pressing force can be applied to the movable scroll 40 with a simple structure by using the floating member 65 separate from the housing 61. Supplementally, in a structure in which the back pressure chamber is formed in the housing 61 and the movable scroll 40 is pushed up, it may be difficult to form an optimally shaped back pressure chamber due to restrictions on the installation space of the Oldham coupling 58 and the like. is there. On the other hand, in the configuration of the scroll compressor 10 according to the present embodiment, the back pressure chamber can be formed with a high degree of freedom by using the floating member 65. As a result, the movable scroll 40 can be pressed against the fixed scroll 30 with an optimal pressing force.

(4-3)
Further, the scroll compressor 10 according to the present embodiment includes an injection pipe 25 (injection mechanism) in the first space S1 for introducing a refrigerant having an intermediate pressure between the suction pressure and the discharge pressure into the compression chamber Sc. . With such a configuration, so-called intermediate injection can be performed, and a highly efficient scroll compressor 10 can be provided. Moreover, since the injection piping 25 is provided in the first space S1, overheating of the injection piping 25 is suppressed.

  In the conventional low-pressure dome-type scroll compressor, if the fixed scroll is pressed against the movable scroll from above (second space S2), the fixed scroll moves in the axial direction, making it difficult to install the injection mechanism. On the other hand, in the configuration of the scroll compressor 10 according to the present embodiment, since the movable scroll 40 is pressed against the fixed scroll 30 from below (first space S1), the fixed scroll 30 may be moved in the axial direction. Absent. As a result, it is possible to provide the scroll compressor 19 in which the injection pipe 25 can be easily installed and the compression efficiency can be further increased.

(4-4)
Moreover, since the scroll compressor 10 according to the present embodiment includes the partition member 28, the inside of the casing 20 can be easily partitioned into the first space S1 and the second space S2 having different pressures.

(4-5)
Further, in the scroll compressor 10 according to the present embodiment, the first back pressure chamber 101 is formed in the radial direction, continuous with the first axial space 101a formed in the axial direction, and the first axial space 101a. A first diameter space 101b is provided. 2 and 3 described above, the first housing communication hole 62a is formed to communicate with the first shaft space 101a, so that the first housing communication hole 62a can be easily processed. On the other hand, the form of the first housing communication hole 62a is not limited to this, and the hole may be bent in the middle as shown in FIG. 6 to communicate with the first diameter space 101b. In the form communicating with the first diameter space 101b, the first housing communication hole 62a does not interfere with the space for installing the O-ring 64a and the like formed between the second housing portion 61b and the third floating portion 65c. The thickness of the second housing part 61b can be reduced.

(4-6)
In the scroll compressor 10 according to the present embodiment, the compressed refrigerant is introduced into the first back pressure chamber 101 and the intermediate refrigerant is led into the second back pressure chamber 102. Here, since the first back pressure chamber 101 is formed inside the second back pressure chamber 102, the pressure distribution of the entire back pressure chamber is directed toward the center in the radial direction during the operation of the scroll compressor 10. Configured to be high. On the other hand, during the operation of the scroll compressor 10, the pressure in the compression chamber Sc increases toward the center in the radial direction. Therefore, the scroll compressor 10 according to the present embodiment is configured such that the pressure in the back pressure chamber increases according to the pressure distribution in the compression chamber Sc during operation. With such a configuration, the movable scroll 40 can be pressed against the fixed scroll 30 with an optimal pressing force.

(5) Modification (5-1) Modification A
In the above description, the first space S1 and the second space 62 are partitioned by the partition member 28, but the configuration of the scroll compressor 10 according to the present embodiment is not limited to this. For example, the first space S <b> 1 and the second space S <b> 2 may be formed by fitting a part of the constituent members of the fixed scroll 30 along the inner wall of the casing 20.

(5-2) Modification B
In the above description, the first back pressure chamber 101 into which the compressed refrigerant is introduced and the second back pressure chamber 102 into which the intermediate refrigerant is introduced are configured. However, the configuration of the scroll compressor 10 according to the present embodiment is as follows. However, it is not limited to this. For example, an intermediate refrigerant may be introduced into the first back pressure chamber 101 and a compressed refrigerant may be introduced into the second back pressure chamber 102. Further, the number of back pressure chambers may not be two. For example, it is possible to adopt a configuration in which a single back pressure chamber is provided and a compressed refrigerant and an intermediate refrigerant are introduced into the back pressure chamber.

(5-3) Modification C
In the above description, the discharge valve 35 functioning as a check valve is provided in the discharge port 32a of the fixed scroll 30 and the inflow port 36a is formed in the fixed scroll 30. However, the scroll compression according to this embodiment is described. The configuration of the machine 10 is not limited to this.

  For example, the scroll compressor 10 according to the present embodiment may have a configuration in which a check valve 24a is simply provided in the discharge pipe 24 as shown in FIG. That is, regardless of whether or not the discharge valve 35 is provided at the discharge port 32 a of the fixed scroll 30, the check pipe 24 a is provided in the discharge pipe 24, and the first fixed scroll communication hole 37 a is provided at a predetermined position of the fixed scroll 30. If this is the case, when the operation is stopped, the compressed refrigerant compressed in the compression chamber Sc is led out to the first space S1 before flowing out downstream of the check valve 24a (backflow prevention mechanism) of the discharge pipe 24. Further, it is possible to suppress the occurrence of a differential pressure between the scroll compression mechanism 60 and the second space S2.

  In this case, the discharge chamber 36 may not be provided with the inlet 36a of the first fixed scroll communication hole 37a. For example, as shown in FIG. 8, a configuration in which the inlet 34a of the first fixed scroll communication hole 37a is provided on the upper surface of the fixed scroll may be employed. In short, in the invention according to the present embodiment, the place where the first fixed scroll communication hole 37a is formed can be provided at any place without changing the gist of the invention.

(5-4) Modification D
In the above description, the floating member 65 is provided between the housing 61 and the movable scroll 40, and the first back pressure chamber 101 and the second back pressure chamber 102 are formed between the housing 61 and the floating member 65. However, the configuration of the scroll compressor 10 according to the present embodiment is not limited to this. That is, in the scroll compressor 10 according to this embodiment, the communication hole formed in the fixed scroll takes out one or both of the intermediate refrigerant and the compressed refrigerant from the upstream side of the discharge valve 35 (backflow prevention mechanism). Any configuration can be adopted as long as the configuration leads to the back pressure chamber. For example, the scroll compressor 10 according to this embodiment may have a back pressure chamber between the housing 61 and the movable scroll 40. In this case, the floating member 65 becomes unnecessary.

10 Scroll compressor 20 Casing 24 Discharge pipe 24a Check valve (backflow prevention mechanism)
25 Injection piping (injection mechanism)
28 Partition member 30 Fixed scroll 32a Discharge port 34a Inlet port 35 Discharge valve (backflow prevention mechanism)
36a Inflow port 37a First fixed scroll communication hole (lead-out passage)
37b Second fixed scroll communication hole (lead-out passage)
40 movable scroll 60 scroll compression mechanism 61 housing 61a first housing part 61b second housing part 62a first housing communication hole 62b second housing communication hole 65 floating member 65a first floating part 65b second floating part 65c third floating part 101 1st back pressure chamber (pressing structure)
101a First shaft space 101b First diameter space 102 Second back pressure chamber (pressing structure)
102a Second shaft space 102b Second diameter space S1 First space S2 Second space Sc Compression chamber

JP2013-167215A

Claims (8)

A casing (20) whose interior is partitioned into a first space (S1) and a second space (S2);
A fixed scroll (30) and a movable scroll (40) which forms a compression chamber (Sc) in combination with the fixed scroll, and compresses the refrigerant sucked from the first space in the compression chamber and A scroll compression mechanism (60) for discharging into the space;
A housing (61) mounted in the first space and supporting the movable scroll;
A pressing structure (101, 102) for pressing the movable scroll against the fixed scroll using either one or both of an intermediate refrigerant being compressed in the compression chamber and a compressed refrigerant compressed in the compression chamber;
A backflow prevention mechanism (35, 24a) provided in the second space for preventing backflow of the compressed refrigerant;
A lead-out passage (37a, 37b) for taking out one or both of the intermediate refrigerant and the compressed refrigerant from the upstream side of the backflow prevention mechanism and leading out to the pressing structure;
A scroll compressor (10) comprising: The backflow prevention mechanism is a check valve provided at the discharge port (32a) of the fixed scroll,
In the lead-out passage, inflow ports (36a, 34a) are formed in the fixed scroll,
The scroll compressor according to claim 1. A discharge pipe (24) for discharging the refrigerant discharged from the compression chamber;
The backflow prevention mechanism is a check valve (24a) provided in the discharge pipe;
In the lead-out passage, inflow ports (36a, 34a) are formed in the fixed scroll,
The scroll compressor according to claim 1 or 2. A floating member (65) provided between the housing and the movable scroll and supporting the movable scroll in contact with the movable scroll;
The pressing structure presses the movable scroll against the fixed scroll by pressing the floating member against the movable scroll using one or both of the intermediate refrigerant and the compressed refrigerant.
The scroll compressor according to any one of claims 1 to 3. The pressing structure has a back pressure chamber (101, 102) formed between the housing and the floating member,
The outlet passage leads out one or both of the intermediate refrigerant and the compressed refrigerant to the back pressure chamber;
The scroll compressor according to claim 4. The pressing structure has a back pressure chamber formed between the housing and the movable scroll,
The outlet passage leads out one or both of the intermediate refrigerant and the compressed refrigerant to the back pressure chamber.
The scroll compressor according to any one of claims 1 to 3. The first space further includes an injection mechanism (25) for introducing a refrigerant having an intermediate pressure between a suction pressure and a discharge pressure into the compression chamber.
The scroll compressor according to any one of claims 1 to 6. A partition member (28) capable of partitioning the inside of the casing into a first space and a second space having different pressures;
A scroll compressor given in any 1 paragraph of Claims 1-7.

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