The present invention relates to a scroll compressor. More specifically, the present invention relates to a scroll compressor in which a floating member presses a movable scroll against a fixed scroll.
Patent Literature 1 (JP 2000-337276A) discloses a known scroll compressor in which a floating member (corresponding to a compliant frame in Patent Literature 1) presses a movable scroll against a fixed scroll to reduce a leakage loss of a refrigerant from spiral distal ends of the scrolls.
In the scroll compressor disclosed in Patent Literature 1 (JP 2000-337276A), an upper clearance between an outer peripheral side face of a floating member and an inner peripheral side face of a housing is equal in width to a lower clearance between the outer peripheral side face of the floating member and the inner peripheral side face of the housing. Due to this structure, the scroll compressor operates with a high degree of efficiency without a leakage loss. Also, due to the structure, the scroll compressor operates without partial contact at a movable scroll hearing and a main bearing.
According to the scroll compressor disclosed in Patent Literature 1 (JP 2000-337276 A), the outer peripheral side face of the floating member is opposed to the inner peripheral side face of the housing. Therefore, the outer peripheral side face of the floating member requires highly accurate processing for preventing partial contact of the floating member with the housing. With regard to the partial contact of the floating member with the housing, for example, strain in assembling the floating member also needs to be taken into consideration in addition to the processing accuracy for the floating member, which may cause an increase in number of man-hours for assembly and manufacture.
The present invention provides a scroll compressor in which a floating member presses a movable scroll against a fixed scroll, the scroll compressor being capable of reducing inclination of the floating member and being capable of reducing the number of man-hours for assembly and manufacture.
According to a first aspect of the present invention, a scroll compressor includes a compression mechanism, a motor, a drive shaft, a casing, a housing, and a floating member. The compression mechanism includes a fixed scroll and a movable scroll. The fixed scroll includes a fixed-side wrap having a spiral shape. The movable scroll includes a movable-side wrap having a spiral shape, the movable-side wrap being combined with the fixed-side wrap to define a compression chamber. The compression mechanism is configured to discharge a refrigerant compressed in the compression chamber. The motor is configured to drive the movable scroll to cause the movable scroll to revolve relative to the fixed scroll. The drive shaft couples the movable scroll to the motor. The casing accommodates therein the compression mechanism, the motor, and the drive shaft. The housing is accommodated in the casing. The floating member is supported by the housing. The floating member is pushed toward the movable scroll by a pressure in a back pressure space between the floating member and the housing to press the movable scroll against the fixed scroll.
In the scroll compressor according to the first aspect of the present invention, (A) the floating member includes a plurality of supported portions arranged circumferentially. The housing includes a supporting portion. The supporting portion supports the supported portions of the floating member such that the floating member is slidable in an axial direction of the drive shaft.
In the scroll compressor according to the first aspect of the present invention, alternatively, (B) the floating member includes a body member and an outer peripheral member separate from the body member. The outer peripheral member is mounted to an outer periphery of the body member. The housing supports the outer peripheral member such that the floating member is slidable in the axial direction of the drive shaft,
According to the first aspect of the present invention, in the scroll compressor having the configuration (A), the floating member is not supported at its outer peripheral side face by the housing at its inner peripheral side face, but the plurality of supported portions of the floating member are supported by the corresponding supporting portion of the housing. Ensuring accuracy, such as processing accuracy and mounting accuracy, for the supported portions and the supporting portion is relatively easier than ensuring accuracy for the entire outer periphery of the floating member. The scroll compressor having this configuration is therefore capable of reducing inclination of the floating member and is also capable of reducing the number of man-hours for assembly and manufacture.
According to the first aspect of the present invention, in the scroll compressor having the configuration (B), the body member of the floating member is assembled into the scroll compressor, and then the outer peripheral member is mounted to the body member. Accuracy, such as roundness, for the outer peripheral member is therefore ensured even when the body member undergoes, for example, strain in assembling the body member. The scroll compressor having this configuration is consequently capable of reducing inclination of the floating member and is also capable of reducing the number of man-hours for assembly and manufacture.
According to a second aspect of the present invention, in the scroll compressor according to the first aspect, each of the supported portions is a bush disposed on the floating member. The supporting portion includes bolts respectively inserted into the bushes.
According to the second aspect of the present invention, in the scroll compressor, the bolts of the supporting portion are respectively inserted into the bushes serving as the supported portions with ease even when an axis of each bush is not aligned with an axis of the corresponding bolt. This configuration therefore improves ease of assembly of the scroll compressor.
According to a third aspect of the present invention, in the scroll compressor according to the second aspect, the floating member further includes a bearing pivotally supporting the drive shaft. A ratio of a distance from a center of each bush to a center of the movable-side wrap in the axial direction of the drive shaft to a distance from a center of the bearing to the center of each bush in the axial direction of the drive shaft falls within a range from 0.5 or more to 1.5 or less.
According to the third aspect of the present invention, the scroll compressor cancels out a rotation moment around each bush to reduce inclination of the floating member relative to the movable scroll. According to the third aspect, the scroll compressor therefore operates with good efficiency by reducing a refrigerant leakage from a clearance between a distal end of a wrap and an end plate in a scroll.
According to a fourth aspect of the present invention, in the scroll compressor according to the first aspect, each of the supported portions is a ring disposed on the floating member. The supporting portion includes control pins respectively inserted into the rings.
According to the fourth aspect of the present invention, the scroll compressor is capable of reducing inclination of the floating member and is also capable of reducing the number of man-hours for assembly and manufacture, with a relatively simple structure.
According to a fifth aspect of the present invention, in the scroll compressor according to the first aspect, each of the supported portions is a recess or a protrusion disposed in or on the floating member. The supporting portion includes protrusions disposed on the housing and respectively fitted to the recesses in the floating member, or recesses disposed in the housing and to which the protrusions on the floating member are respectively fitted.
According to the fifth aspect of the present invention, the scroll compressor is capable of reducing inclination of the floating member and is also capable of reducing the number of man-hours for assembly and manufacture, with a relatively simple structure.
According to a sixth aspect of the present invention, in the scroll compressor according to any of the first to fifth aspects, the floating member includes a pressing portion having a cylindrical shape. The pressing portion extends toward the movable scroll. The pressing portion has on its end a thrust surface to be brought into contact with the movable scroll. The pressing portion has in its all-around inner face a groove. In the scroll compressor, a relation of (D/T)2/(L/T)3≤0.6, where T represents a thickness of the thrust surface in a radial direction of the pressing portion, L represents a length from the thrust surface to the groove in the axial direction of the drive shaft, and D represents a depth of the groove in the radial direction of the pressing portion, is satisfied.
According to the sixth aspect of the present invention, in the scroll compressor, the thrust surface of the floating member inclines while following inclination of the movable scroll. This configuration thus reduces occurrence of partial contact of the movable scroll with the thrust surface of the floating member.
The present invention provides a scroll compressor capable of reducing inclination of a floating member and capable of reducing the number of man-hours for assembly and manufacture.
A scroll compressor according to an embodiment of the present invention will be described below with reference to the drawings. It should be noted that embodiments to be described below are merely illustrative and may be appropriately modified without departing from the scope of the present invention.
Terms including “upper”, “lower”, and others may be used for the sake of description on directions and arrangement under the definition that an arrow U in
In the following description, terms including “parallel”, “orthogonal”, “horizontal”, “vertical”, “identical”, and others do not intend to represent strictly parallel, orthogonal, horizontal, vertical, identical, and other relationships. The terms including “parallel”, “orthogonal”, “horizontal”, “vertical”, “identical”, and others involve substantially parallel, orthogonal, horizontal, vertical, identical, and other relationships.
A description will be given of a scroll compressor 100 according to a first embodiment of the present invention. The scroll compressor 100 is a so called fully hermetic compressor. The scroll compressor 100 is configured to suck, compress, and discharge a refrigerant. A non-limiting example of the refrigerant is a hydrofluorocarbon (HFC) refrigerant such as R32. It should be noted that R32 is merely an example of the refrigerant, and the scroll compressor 100 may be configured to compress and discharge any refrigerant in addition to R32.
The scroll compressor 100 is used in a refrigeration apparatus. For example, the scroll compressor 100 is installed in an outdoor unit of an air conditioning apparatus to constitute a part of a refrigerant circuit in the air conditioning apparatus.
As illustrated in
A specific description will be given of the casing 10, compression mechanism 20, floating member 30, housing 40, seal member 60, motor 70, drive shaft 80, and lower bearing housing 90 in the scroll compressor 100.
With reference to
The compression mechanism 20 is disposed on an upper side of the casing 10. With reference to
The casing 10 is partitioned into a first space S1 and a second space S2. With reference to
The partition plate 16 is a plate member having an annular shape as seen in plan view. The partition plate 16 of the annular shape is fixed at its all-around inner peripheral side to an upper portion of a fixed scroll 21 in the compression mechanism 20 (to be described later). The partition plate 16 is also fixed at its all-around outer peripheral side to an inner face of the casing 10. The partition plate 16 is fixed to the fixed scroll 21 and the casing 10 so as to keep a space below the partition plate 16 and a space above the partition plate 16 hermetic. The space below the partition plate 16 corresponds to the first space S1. The space above the partition plate 16 corresponds to the second space S2.
The first space S1 is a space in which the motor 70 is disposed. The first space S1 is a space into which the refrigerant that is not compressed yet by the scroll compressor 100 flows from the refrigerant circuit, a part of which is constituted of the scroll compressor 100, in the air conditioning apparatus. In other words, the first space S1 is a space into which the low-pressure refrigerant in a refrigeration cycle flows. The second space S2 is a space into which the refrigerant discharged from the compression mechanism 20, that is, the refrigerant compressed by the compression mechanism 20 flows. In other words, the second space S2 is a space into which the high-pressure refrigerant in the refrigeration cycle flows. The scroll compressor 100 is a so called low pressure dome-type scroll compressor.
With reference to
With reference to
With reference to
With reference to
The compression mechanism 20 mainly includes the fixed scroll 21, and a movable scroll 22 that is combined with the fixed scroll 21 to define the compression chamber Sc. The compression mechanism 20 is configured to discharge the refrigerant compressed in the compression chamber Sc. For example, the compression mechanism 20 is a compression mechanism having an asymmetric wrap structure. Alternatively, the compression mechanism 20 may be a compression mechanism having a symmetric wrap structure.
With reference to
As illustrated in
The fixed-side wrap 21b is a wall-shaped member protruding downward, that is, protruding toward the movable scroll 22, from the lower face of the fixed-side end plate 21a. When the fixed scroll 21 is seen from below, the fixed-side wrap 21b is formed in a spiral shape (an involute shape) extending from a region near a center of the fixed-side end plate 21a toward an outer periphery of the fixed-side end plate 21a.
The fixed-side wrap 21b is combined with a movable-side wrap 22b of the movable scroll 22 (to be described later) to define the compression chamber Sc. With reference to
With reference to
With reference to
The peripheral portion 21c has a thick cylindrical shape. With reference to
As illustrated in
The movable-side wrap 22b is a wall-shaped member protruding upward, that is, protruding toward the fixed scroll 21 from the upper face of the movable-side end plate 22a. When the movable scroll 22 is seen from above, the movable-side wrap 22b is formed in a spiral shape (an involute shape) extending from a region near a center of the movable-side end plate 22a toward an outer periphery of the movable-side end plate 22a.
The movable-side end plate 22a is disposed above the floating member 30.
During the operation of the scroll compressor 100, the floating member 30 is pushed toward the movable scroll 22 by a pressure in a back pressure space B (see
The back pressure space B is a space defined between the floating member 30 and the housing 40. With reference to
With reference to
The boss portion 22c is a cylindrical portion whose upper end is closed with the movable-side end plate 22a. With reference to
With reference to
With reference to
The cylindrical portion 30a has an approximately cylindrical shape. With reference to
The pressing portion 34 has an approximately cylindrical shape. The pressing portion 34 extends from the cylindrical portion 30a toward the movable scroll 22. The pressing portion 34 has on its upper end a thrust surface 34a (see
During the operation of the scroll compressor 100, force acting on the movable scroll 22 occasionally inclines the movable-side end plate 22a with respect to a horizontal plane. In such a case, preferably, the thrust surface 34a inclines while following the inclination of the movable-side end plate 22a in order to reduce partial contact of the thrust surface 34a with the movable-side end plate 22a. For this reason, with reference to
In forming the elastic groove 35, preferably, a relation expressed by Formula (1) is established among a thickness T of the thrust surface 34a in a radial direction of the pressing portion 34 (see
(D/T)2/(L/T)3≤0.6 (1)
With reference to
With reference to
In the first embodiment, the floating member 30 includes four protrusion portions 30b disposed at equal angular intervals around the center of the floating member 30. However, the number of protrusion portions 30b is not limited to four. The number of protrusion portions 30b may be appropriately determined. Preferably, the floating member 30 includes three or more protrusion portions 30b from the viewpoint of reducing inclination of the floating member 30.
The upper bearing housing 31 is disposed below the cylindrical portion 30a, that is, below the eccentric portion space 38. With reference to
In order to reduce partial contact of the bearing metal 32 with the main shaft 82 even when the main shaft 82 of the drive shaft 80 inclines due to an influence of, for example, force acting on the movable scroll 22, preferably, the upper bearing housing 31 inclines while following the inclination of the main shaft 82. For this reason, with reference to
The floating member 30 is configured to press the movable scroll 22 against the fixed scroll 21. In addition, the floating member 30 includes the upper bearing housing 31 serving as the bearing of the drive shaft 80. The floating member 30 thus produces the following advantageous effect.
When the floating member 30 receives force from the movable scroll 22, this force generates a moment on the floating member 30 at a position around each bush 37a supporting the floating member 30. With regard to this moment, the upper bearing housing 31 of the floating member 30 cancels out the moment around each bush 37a being generated from the force from the movable scroll 22, with a moment around each bush 37a being generated from force received by the upper hearing housing 31.
With reference to
However, the configuration of the floating member 30 is merely illustrative. Alternatively, the floating member 30 may have only the function of pressing the movable scroll 22 against the fixed scroll 21. For example, the housing 40 rather than the floating member 30 may have a function of the bearing of the drive shaft 80.
With reference to
With reference to
The housing body 44 has an approximately cylindrical shape. The housing body 44 is mounted to the inner face of the casing 10. The housing body 44 is fixed by press fitting to the inner face of the casing 10; however, a method of mounting the housing body 44 is not limited.
The supporting portion 41 supports the bushes 37a disposed on the floating member 30, that is, disposed in the through-holes 37 of the protrusion portions 30b, such that the floating member 30 is slidable in the axial direction of the drive shaft 80, that is, the vertical direction. With reference to
The seal member 60 (see
The first chamber B1 communicates with the compression chamber Sc being in the midstream of compression, via a first flow path 64. The first flow path 64 is a refrigerant flow path for guiding into the first chamber B1 the refrigerant being in the midstream of compression in the compression mechanism 20. The first flow path 64 extends over the fixed scroll 21 and the housing 40. The second chamber B2 communicates with the discharge port 21d of the fixed scroll 21 via a second flow path 65. The second flow path 65 is a refrigerant flow path for guiding into the second chamber B2 the refrigerant discharged from the compression mechanism 20. The second flow path 65 extends over the fixed scroll 21 and the housing 40.
With this configuration, the pressure in the second chamber B2 is normally higher than the pressure in the first chamber B1 during the operation of the scroll compressor 100. Since the first chamber B1 is larger in area than the second chamber B2 as seen in plan view, the force of the pressure in the back pressure space B to press the movable scroll 22 against the fixed scroll 21 is less prone to become excessively large. The pressure in the compression chamber Sc becomes normally higher at the inner side than at the outer side. Therefore, force of the pressure in the compression chamber Sc to push the movable scroll 22 downward and force of the floating member 30 to push the movable scroll 22 upward are balanced with ease when arranging the second chamber B2, in which the pressure is nominally higher, inside with respect to the first chamber B1.
With referent to
Each of the second seal member 62 and the third seal member 63 is, but not limited to, an O-ring. The O-ring is an annular gasket having a circular cross section. Each of the second seal member 62 and the third seal member 63 is made of, for example, synthetic resin. The material for each of the second seal member 62 and the third seal member 63 may be appropriately determined in accordance with an operating temperature, a kind of a refrigerating machine oil or a refrigerant with which the second seal member 62 and the third seal member 63 are in contact, and other conditions.
With referent to
With referent to
The first seal member 61 partitions the back pressure space B into the first chamber B1 and the second chamber B2. With reference to
With reference to
With reference to
A description will be given of a structure of the first seal member 61. With reference to
The first seal member 61 is a gasket that is deformable such that its U-shaped opening expands or narrows. The first seal member 61 is accommodated in the accommodation groove 33 with its opening directed sideward as described above. The dimension of the first seal member 61 therefore changes while following the movement of the floating member 30.
In a state in which the scroll compressor 100 is not operated and the inside of the casing 10 is under an approximately identical pressure as a whole, the first seal member 61 is pushed from above by the weight of the movable scroll 22 and the weight of the floating member 30. In this state, the U-shaped opening of the first seal member 61 is narrowed as compared with a case where no force acts on the first seal member 61. Also in such a state, the first seal member 61 is not crushed by the weight of the movable scroll 22 and the weight of the floating member 30, but the leaf spring 61b presses the U-shaped seal 61a against the floating member 30.
The first seal member 61 having the U-shaped cross section is accommodated in the accommodation groove 33 of the floating member 30 with its opening directed sideward. The first seal member 61 is accommodated in the accommodation groove 33 of the floating member 30 with its opening particularly directed inward. In other words, the first seal member 61 is accommodated in the accommodation groove 33 of the floating member 30 with its opening directed to the second chamber B2. The first seal member 61 functions as follows when being disposed in the accommodation groove 33 in the orientation described above.
As described above, the pressure in the inner second chamber B2 is normally higher than the pressure in the outer first chamber B1. When the pressure in the second chamber B2 is higher than the pressure in the first chamber B1, the first seal member 61 is deformed such that its opening is enlarged, thereby sealing the flow of the refrigerant from the second chamber B2 into the first chamber B1. This configuration therefore prevents both the pressure in the first chamber B1 and the pressure in the second chamber B2 from rising to a relatively high level that is equal to the pressure of the refrigerant to be discharged from the compression mechanism 20. The force of the pressure in the back pressure space B to press the movable scroll 22 against the fixed scroll 21 is thus less prone to become excessively large.
Although the pressure in the inner second chamber B2 is normally higher than the pressure in the outer first chamber B1 as described above, the pressure of the compression chamber Sc being in the midstream of compression, that is, the pressure in one of the compression chamber Sc closer to the outer periphery than the innermost compression chamber Sc is, becomes sometimes higher than the pressure in the innermost compression chamber Sc, depending on operating conditions (e.g., a case where the low pressure in the refrigeration cycle is relatively high). In such a case, the pressure in the outer first chamber B1 becomes higher than the pressure in the inner second chamber B2. When the pressure in the first chamber B1 is higher than the pressure in the second chamber B2, the first seal member 61 does not seal, because of its structure, the flow of the refrigerant from the first chamber B1 into the second chamber B2. The pressure in the compression chamber Sc being in the midstream of compression is thus released, via the first chamber B1 and the second chamber B2, to the space (the second space S2) into which the refrigerant discharged from the compression mechanism flows. This configuration therefore prevents the compression mechanism 20 from receiving excessively large pressure due to, for example, liquid compression, and also prevents the force to press the movable scroll 22 against the fixed scroll 21 from becoming excessively large due to a rise of the pressure in the back pressure space B.
The motor 70 is configured to drive the movable scroll 22. With reference to
The rotor 72 is a cylindrical member into which the drive shaft 80 is inserted. The rotor 72 is coupled to the movable scroll 22 via the drive shaft 80. When the rotor 72 rotates, the motor 70 drives the movable scroll 22 to cause the movable scroll 22 to revolve relative to the fixed scroll 21.
The drive shaft 80 couples the rotor 72 of the motor 70 to the movable scroll 22 of the compression mechanism 20. The drive shaft 80 extends in the vertical direction. The drive shaft 80 transmits the driving force of the motor 70 to the movable scroll 22.
With reference to
The eccentric portion 81 is disposed on an upper end of the main shaft 82. The eccentric portion 81 has a center axis that is eccentric relative to a center axis of the main shaft 82. The eccentric portion 81 is coupled to the bearing metal 26 in the boss portion 22c of the movable scroll 22.
The main shaft 82 is pivotally supported by the bearing metal 32 disposed in the upper bearing housing 31 of the floating member 30 and a bearing metal 91 disposed in the lower bearing housing 90 to be described later. The main shaft 82 is inserted into and coupled to the rotor 72 of the motor 70 at a position between the upper bearing housing 31 and the lower bearing housing 90. The main shaft 82 extends in the vertical direction.
The drive shaft 80 has an oil passage (not illustrated). The oil passage includes a main passage (not illustrated) and a branch passage (not illustrated). The main passage extends from a lower end to an upper end of the drive shaft 80 in the axial direction of the drive shaft 80. The branch passage extends from the main passage in a radial direction of the drive shaft 80. The refrigerating machine oil in the oil reservoir space 11 is pumped up by a pump (not illustrated) disposed on the lower end of the drive shaft 80, and then is supplied to, for example, sliding portions between the drive shaft 80 and the bearing metals 26, 32, and 91, and a sliding portion of the compression mechanism 20, via the oil passage
The lower bearing housing 90 (see
A description will be given of the operation of the scroll compressor 100. The following description concerns the operation of the scroll compressor 100 in a normal state, that is, a state in which the pressure of the refrigerant to be discharged from the compression mechanism 20 through the discharge port 21d is higher than the pressure in the compression chamber Sc being in the midstream of compression.
When the motor 70 is driven, the rotor 72 rotates, and the drive shaft 80 coupled to the rotor 72 also rotates. When the drive shaft 80 rotates, the movable scroll 22 does not rotate, but revolves relative to the fixed scroll 21, by the action of the Oldham's coupling 25. Then, the low-pressure refrigerant in the refrigeration cycle, which has flown into the first space S1 through the suction pipe 13, is sucked into the compression chamber Sc close to the peripheral edge of the compression mechanism 20, via a refrigerant passage (not illustrated) in the housing 40. As the movable scroll 22 revolves, the first space S1 does not communicate with the compression chamber Sc. As the volume of the compression chamber Sc decreases by the revolution of the movable scroll 22, the pressure in the compression chamber Sc rises. In addition, the refrigerant is injected into the compression chamber Sc being in the midstream of compression, through the injection pipe 15. The pressure of the refrigerant rises as the refrigerant moves from the compression chamber Se close to the peripheral edge, that is, the outer compression chamber Sc, to the compression chamber Sc close to the center, that is, the inner compression chamber Sc. The high-pressure refrigerant in the refrigeration cycle is finally obtained. The refrigerant compressed by the compression mechanism 20 is discharged from the compression mechanism 20 to the second space S2 through the discharge port 21d located near the center of the fixed-side end plate 21a. The high-pressure refrigerant in the refrigeration cycle is discharged from the second space S2 through the discharge pipe 14.
(4-1)
According to the first embodiment, the scroll compressor 100 includes the compression mechanism 20, the motor 70, the drive shaft 80, the floating member 30, and the housing 40. The compression mechanism 20 includes the fixed scroll 21 and the movable scroll 22. The fixed scroll 21 includes the fixed-side wrap 21b having a spiral shape. The movable scroll 22 includes the movable-side wrap 22b having a spiral shape. The movable-side wrap 22b is combined with the fixed-side wrap 21b to define the compression chamber Sc. The compression mechanism 20 is configured to discharge a refrigerant compressed in the compression chamber Sc. The motor 70 is configured to drive the movable scroll 22 to cause the movable scroll 22 to revolve relative to the fixed scroll 21. The drive shaft 80 couples the movable scroll 22 to the motor 70. The floating member 30 is pushed toward the movable scroll 22 by a pressure in a back pressure space B to press the movable scroll 22 against the fixed scroll 21. The housing 40 supports the floating member 30. The back pressure space B is defined between the housing 40 and the floating member 30. The floating member 30 includes a plurality of supported portions (bushes 37a) arranged circumferentially. The housing 40 includes a supporting portion 41. The supporting portion 41 supports the supported portions (the bushes 37a) of the floating member 30 such that the floating member 30 is slidable in an axial direction of the drive shaft 80.
According to the first embodiment, in the scroll compressor 100, the floating member 30 is not supported at its outer peripheral side face by the housing 40 at its inner peripheral side face, but the plurality of supported portions (the bushes 37a) of the floating member 30 are supported by the corresponding supporting portion 41 of the housing 40. Ensuring accuracy, such as processing accuracy and mounting accuracy, for the supported portions (the bushes 37a) and the supporting portion 41 is relatively easier than ensuring accuracy for the entire outer periphery of the floating member 30. The scroll compressor 100 is therefore capable of reducing inclination of the floating member 30 and is also capable of reducing the number of man-hours for assembly and manufacture.
(4-2)
According to the first embodiment, in the scroll compressor 100, each of the supported portions is a bush 37a disposed on the floating member 30. The supporting portion 41 includes bolts 42 respectively inserted into the bushes 37a.
According to the first embodiment, in the scroll compressor 100, the bolts 42 of the supporting portion 41 are respectively inserted into the bushes 37a serving as the supported portions with ease even when an axis of each bush 37a is not aligned with an axis of the corresponding bolt 42. This configuration therefore improves ease of assembly of the scroll compressor 100.
(4-3)
According to the first embodiment, in the scroll compressor 100, the floating member 30 farther includes the bearing metal 32 (a bearing) pivotally supporting the drive shaft 80. The ratio (A1/A2) of the distance A1 from the center of each bush 37a to the center of the movable-side wrap 22b in the axial direction of the drive shaft 80 to the distance A2 from the center of the bearing metal 32 to the center of each bush 37a in the axial direction of the drive shaft 80 falls within a range from 0.5 or more to 1.5 or less.
According to the first embodiment, the scroll compressor 100 cancels out the rotation moment around each hush 37a to reduce inclination of the floating member 30 relative to the movable scroll 22. The scroll compressor 100 therefore operates with good efficiency by reducing the refrigerant leakage from the clearance between the distal end of the wrap and the end plate in the scroll.
(4-4)
According to the first embodiment, in the scroll compressor 100, the floating member 30 includes the pressing portion 34 having a cylindrical shape. The pressing portion 34 extends toward the movable scroll 22. The pressing portion 34 has on its end the thrust surface 34a to be brought into contact with the movable scroll 22. The pressing portion 34 has in its all-around inner face the elastic groove 35. In the scroll compressor 100, a relation of (D/T)2/(L/T)3≤0.6, where T represents the thickness of the thrust surface 34a in the radial direction of the pressing portion 34, L represents the length from the thrust surface 34a to the elastic groove 35 in the axial direction of the drive shaft 80, and D represents the depth of the elastic groove 35 in the radial direction of the pressing portion 34, is satisfied.
According to the first embodiment, in the scroll compressor 100, the thrust surface 34a of the floating member 30 inclines while following inclination of the movable scroll 22. This configuration thus reduces occurrence of partial contact of the movable scroll 22 with the thrust surface 34a of the floating member 30.
The following description concerns modifications of the first embodiment. It should be noted that the following modifications may be appropriately combined insofar as there are no inconsistencies.
According to the first embodiment, the scroll compressor 100 is a so-called low pressure dome-type scroll compressor including a high-pressure space, that is, the second space S2 into which the refrigerant discharged from the compression mechanism 20 flows, and a low-pressure space, that is, the first space S1 in which the motor 70 for driving the compression mechanism 20 is disposed. However, a scroll compressor according to the present invention is not limited to a low pressure dome-type scroll compressor. The structure of the scroll compressor 100, in which the floating member 30 is slidably supported by the supporting portion 41, described in the first embodiment, is applicable to a so-called high pressure dome-type scroll compressor.
According to the first embodiment, in the scroll compressor 100, the first chamber B1 is located outward with respect to the second chamber B2. However, a scroll compressor according to the present invention is not limited to this structure. For example, the second chamber B2 may be located outward with respect to the first chamber B1. It is however preferable that the second chamber B2 be located inward with respect to the first chamber B1 from the viewpoint of pressing the movable scroll 22 against the fixed scroll 21 with appropriate force.
According to the first embodiment, in the scroll compressor 100, the first chamber B1 is larger in area than the second chamber B2 as seen in plan view. However, a scroll compressor according to the present invention is not limited to this structure. For example, the second chamber B2 may be larger in area than the first chamber B1 as seen in plan view. It is however preferable that the first chamber B1 be larger in area than the second chamber B2 from the viewpoint of preventing force to press the movable scroll 22 against the fixed scroll 21 from becoming excessively large.
According to the first embodiment, in the scroll compressor 100, the back pressure space B is partitioned into the first chamber B1 and the second chamber B2. However, a scroll compressor according to the present invention is not limited to this structure. For example, the back pressure space B may be a space which is not partitioned and into which the refrigerant being in the midstream of compression by the compression mechanism 20 is guided, or a space which is not partitioned and into which the refrigerant discharged from the compression mechanism 20 is guided.
According to the first embodiment, the scroll compressor 100 is a vertical scroll compressor in which the drive shaft 80 extends vertically. However, a scroll compressor according to the present invention is not limited to this structure. The present invention is also applicable to a horizontal scroll compressor in which a drive shaft extends horizontally.
According to the first embodiment, the supporting portion 41 including the bolts 42 in the housing 40 supports the bushes 37a, disposed in the floating member 30 and serving as the supported portions, such that the floating member 30 is slidable in the axial direction of the drive shaft 80. However, the supported portions and the supporting portion are not limited to this configuration.
As illustrated in
As illustrated in
Although not illustrated in the drawings, the floating member 230 may have a protrusion serving as a supported portion, and the housing 240 may include a supporting portion having a recess.
The use of these configurations provides a scroll compressor capable of reducing inclination of the floating members 130 and 230 and capable of reducing the number of man-hours for assembly and manufacture, with a relatively simple structure.
A description will be given of a scroll compressor according to a second embodiment of the present invention. The scroll compressor according to the second embodiment is similar to the scroll compressor according to the first embodiment except for a structure of a floating member 330 and how a housing 340 supports the floating member 330. For this reason, the following description mainly concerns the structure of the floating member 330 and how the housing 340 supports the floating member 330.
The floating member 330 includes a body member 331 and an outer peripheral member 332 mounted to an outer periphery of the body member 331.
The body member 331 corresponds to the floating member 30 in the first embodiment from which the protrusion portions 30b are removed. The body member 331 is not described in the second embodiment.
The outer peripheral member 332 is separate from the body member 331. The outer peripheral member 332 is a flat plate member having an annular shape. The outer peripheral member 332 is fastened to the body member 331 with fixing means such as bolts (not illustrated).
The housing 340 surrounds an outer periphery of the outer peripheral member 332. The housing 340 supports at its inner peripheral face the outer peripheral member 332 such that the floating member 330 is slidable in an axial direction of a drive shaft 80.
Next, a description will be given of advantageous effects of the configuration described above.
For example, if the body member 331 is not separated from the outer peripheral member 332, but is integrated with the outer peripheral member 332, an outer periphery of the floating member occasionally undergoes, for example, strain after assembling the floating member into the scroll compressor 100. The occurrence of strain is apt to cause, for example, partial contact of an outer peripheral face of the floating member with an inner peripheral face of the housing 340. Ensuring a large clearance between the outer peripheral face of the floating member and the inner peripheral face of the housing 340 enables avoidance of the partial contact. In this case, however, the floating member is apt to be supported unsatisfactorily, so that the floating member 330 is apt to incline when moving in the vertical direction. This results in ununiform force of the floating member 330 to press the movable scroll 22.
According to the second embodiment, since the body member 331 is separate from the outer peripheral member 332, the outer peripheral member 332 is mounted to the body member 331 after the body member 331 is assembled into the scroll compressor 100. Hence, accuracy, such as roundness, for the outer peripheral member 332 is ensured even when the body member 331 undergoes, for example, strain in assembling the body member 331. The configuration described in the second embodiment therefore provides the scroll compressor 100 capable of reducing inclination of the floating member 330 and capable of reducing the number of man-hours for assembly and manufacture.
In the configuration described in the second embodiment, preferably, a ratio of a distance from a center of the outer peripheral member 332 to a center of a movable-side wrap 22b in the axial direction of the drive shaft 80 to a distance from a center of a bearing metal 32 to the center of the outer peripheral member 332 in the axial direction of the drive shaft 80 falls within a range from 0.5 or more to 1.5 or less. More preferably, the ratio falls within a range from 0.7 or more to 1.3 or less.
The scroll compressor according to the second embodiment may be implemented in conjunction with the modifications of the first embodiment insofar as there are no inconsistencies.
The present invention is useful as a scroll compressor in which a floating member presses a movable scroll against a fixed scroll, the scroll compressor being capable of reducing inclination of the floating member and being capable of reducing the number of man-hours for assembly and manufacture.
20: compression mechanism
21: fixed scroll
21
b: fixed-side wrap
22: movable scroll
22
b: movable-side wrap
30, 130, 230, 330: floating member
32: bearing metal (bearing)
34: pressing portion
34
a: thrust surface
35: elastic groove (groove)
37
a: bush (supported portion)
37
b: ring (supported portion)
40, 140, 240, 340: housing
41, 141, 241: supporting portion
42: bolt
70: motor
80: drive shaft
100: scroll compressor
142: control pin
237: recess (supported portion)
242: protrusion (supporting portion)
331: body member
332: outer peripheral member
A1: distance from center of bush to center of movable-side wrap
A2: distance from center of bearing to center of bush
B: back pressure space
Sc: compression chamber
Patent Literature 1: JP 2000-337276 A
Number | Date | Country | Kind |
---|---|---|---|
2016-169771 | Aug 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2017/023781 | 6/28/2017 | WO | 00 |