JP5048642B2 - Rotary compressor, rotary compressor manufacturing method, and rotary compressor manufacturing apparatus. - Google Patents

Description

  The present invention relates to, for example, a rotary compressor for a refrigeration / air conditioner having a plurality of compression chambers, a method for manufacturing the rotary compressor, and an apparatus for manufacturing the rotary compressor.

  The rotary compressor uses a motor installed inside the shell as a drive source, and the motor is driven by energization from the glass terminal part. The crankshaft is inserted into the rotor of the motor and rotates with the eccentric part. , Which has a function of sucking gas into the cylinder through the suction muffler and suction pipe, compressing it into the compression chamber composed of springs and rollers, discharging it from the discharge port to the outside of the cylinder, and then discharging it from the discharge pipe to the outside of the shell It is.

  The partition plate is a member that plays a role of partitioning the compression chambers in the two cylinders, and is fixed between the first cylinder and the second cylinder.

  Such a rotary compressor is required to have a large capacity and a low cost.

  Generally, when increasing the capacity of the compression chamber of a rotary compressor having a plurality of cylinders, that is, the capacity of the portion between the inner diameter of the cylinder and the outer diameter of the roller, a method of extending the cylinder in the axial direction of the crankshaft, the cylinder A method of increasing the outer diameter and the inner diameter, and a method of increasing the eccentric amount of the crankshaft while maintaining the outer diameter of the cylinder are considered.

  Here, when the method of elongating the cylinder in the axial direction of the crankshaft or the method of enlarging the cylinder outer diameter is taken, the rotary compressor is increased in size and cost.

  Therefore, a method of increasing the eccentric amount of the crankshaft while keeping the outer diameter of the cylinder as it is and reducing the thickness of the roller, that is, the radial thickness is conceivable.

  Normally, when assembling a rotary compressor having a plurality of cylinders, when the number of cylinders is n, it is necessary to insert n bearings, cylinders, rollers, and n-1 partition plates through the crankshaft.

  Therefore, in order to allow the partition plate to be inserted into the crankshaft, the hole diameter of the partition plate must be geometrically larger than the eccentric portion of the crankshaft. As a result, the assembled compressor is A leakage flow path is generated between the hole in the partition plate located in the middle of the cylinder and the compression chamber in the cylinder, resulting in a problem of poor compression efficiency.

  There is a method to sufficiently increase the thickness of the roller, that is, the thickness in the radial direction so as not to cause a leakage flow path. However, when increasing the amount of eccentricity and increasing the thickness of the roller, increase the inner diameter of the cylinder. Since the thickness of the cylinder, that is, the thickness in the radial direction is small, there is a limit in size to satisfy the required strength.

  Patent Document 1 has been devised to solve such a problem. The crankshaft is divided into a first shaft and a second shaft, a connecting portion is provided on the shaft, and the hole diameter of the partition plate is increased. The first shaft and the second shaft are configured to be larger than the connecting portion and smaller than the eccentric portion of the first shaft or the second shaft.

  According to this patent document 1, the connection part of a 1st shaft and a 2nd shaft is provided in the opening part of a partition plate, and the part below the eccentric shaft part of a 1st shaft is in the opening part of a partition plate. And a female connection part that is rotatably supported by a bearing metal in the opening of the partition plate and has a fitting hole formed in the lower end surface, and an upper end that is a part above the eccentric shaft part of the second shaft The portion is configured by a male coupling portion that is press-fitted into the fitting hole of the female coupling portion of the first shaft. With the female connecting portion of the lower part of the first shaft inserted through the opening of the partition plate, the male connecting portion of the upper end portion of the second shaft is press-fitted into the fitting hole of the female connecting portion of the first shaft. They are assembled by bonding, welding, explosion welding, screw connection, etc., and the hole diameter of the partition plate may be smaller than the hole diameter of the partition plate when the shaft is not divided, and the outer diameter and inner diameter of the cylinder are large. The compressor structure having a large capacity and no leakage flow path is configured as it is.

JP 2005-337210 A (paragraph numbers [0072] and [0073], FIG. 3)

  In the rotary compressor as described above, when a plurality of shafts are connected, the smaller the coaxiality of the connected shafts, the smaller the mechanical loss and the better the bearing life. In particular, it is known that this is remarkable in the case of a metal bearing structure for supporting a shaft.

  However, in the technique in Patent Document 1 described above, a connecting portion between the first shaft and the second shaft is provided in the opening of the partition plate, and the connecting portion can be rotated by a bearing metal provided on the inner peripheral surface of the opening of the partition plate. There is a problem that the structure is complicated and the size is increased.

  In practice, the technique disclosed in Patent Document 1 has a problem in that the coaxiality of each shaft cannot be assembled with high accuracy because the machining error and assembly error of each shaft accumulate.

  The present invention has been made to solve the above-described problems. A rotary compressor, a rotary compressor manufacturing method, and a rotary compressor manufacturing apparatus capable of accurately assembling the coaxiality of each shaft. The purpose is to obtain.

  The present invention includes a first bearing insertion portion to be inserted into the first bearing, a first eccentric portion disposed in the first cylinder, a fitting shaft formed on one end side, and between the first eccentric portion and the fitting shaft. A first shaft having an intermediate shaft positioned; a second eccentric portion disposed in the second cylinder; a fitting hole formed on the second eccentric portion and fitted with a fitting shaft of the first shaft; And a second shaft having a second bearing insertion portion that is inserted into the second bearing, a crankshaft configured by connecting the first shaft and the second shaft, and a shaft through hole through which the crankshaft passes. A partition plate formed between the first shaft and the second shaft and partitioning between the first cylinder and the second cylinder; and a partition plate formed between the shaft through hole and the intermediate shaft formed in the partition plate. A temporary fixing mechanism for temporarily fixing, The shaft is configured such that the fitting shaft of the first shaft is inserted into the shaft through hole formed in the partition plate, and the fitting shaft is fitted into the fitting hole of the second shaft and connected. Is to provide.

  In the present invention, the crankshaft formed by connecting the first shaft having the first eccentric portion and the second shaft having the second eccentric portion is formed on the partition plate that partitions the first cylinder and the second cylinder. In the manufacturing method of the rotary compressor which is inserted into the shaft through-hole and assembled, the step of setting the first shaft, the second shaft and the partition plate coaxially, and the fitting shaft of the first shaft as the shaft through-hole of the partition plate Inserting the first shaft through the shaft through hole of the partition plate into the fitting hole of the second shaft and connecting them to form a crankshaft, and cranking the partition plate A step of temporarily fixing between the first eccentric portion and the second eccentric portion of the shaft, a step of rotatably holding the crankshaft through which the partition plate is inserted, and a bearing insertion portion of the crankshaft A step of grinding, there is provided a method of manufacturing a rotary compressor including a step of separating the partition plate and the crankshaft.

In the present invention, the crankshaft formed by connecting the first shaft having the first eccentric portion and the second shaft having the second eccentric portion is formed on the partition plate that partitions the first cylinder and the second cylinder. In a rotary compressor manufacturing apparatus that is inserted into a shaft through-hole and assembled, a partition that is provided on the base and is placed at a predetermined position and that has a larger opening than the shaft through-hole formed in the partition plate A plate holding base, a second shaft holding base that is attached to the base below the opening of the partition plate holding base and holds the fitting hole of the second shaft on the upper side, and above the opening of the partition plate holding base The first shaft holder is mounted coaxially with the second shaft holder and holds the fitting shaft of the first shaft on the lower side, and the first shaft holder is mounted to hold the first shaft. First By lowering the shaft holder, connecting a second fitted into the fitting hole of the shaft which is held the mating axis of the first shaft to the second shaft holder by inserting the shaft through hole of the partition plate An apparatus for manufacturing a rotary compressor is provided that includes a fitting device and a drive cylinder that raises the partition plate holding base to temporarily fix the crankshaft and the partition plate .

  In the present invention, the crankshaft formed by connecting the first shaft having the first eccentric portion and the second shaft having the second eccentric portion is formed on the partition plate that partitions the first cylinder and the second cylinder. In the rotary compressor manufacturing apparatus that is inserted into the shaft through-hole and assembled, the axial feed device that is provided on the base and moves with the base, and is attached to the axial feed device, and the partition plate is temporarily fixed An apparatus for manufacturing a rotary compressor is provided, which includes a rotary holder that rotatably holds the crankshaft inserted through the shaft and a grinding body that grinds a bearing insertion portion of the crankshaft.

  According to this invention, the crankshaft constituted by connecting the first shaft and the second shaft passes the fitting shaft of the first shaft through the shaft through-hole formed in the partition plate, and the temporary fixing mechanism Since the partition plate is temporarily fixed to the crankshaft and the fitting shaft of the first shaft is fitted and connected to the fitting hole of the second shaft, the structure is simple and the size is reduced. A rotary compressor that can be obtained can be obtained.

  According to the present invention, the first shaft, the second shaft, and the partition plate are coaxially set, the fitting shaft of the first shaft is inserted into the shaft through hole of the partition plate, and the shaft through hole of the partition plate is formed. The crankshaft is configured by fitting the fitting shaft of the inserted first shaft into the fitting hole of the second shaft and connecting them, and the crankshaft in which the partition plate is inserted in a temporarily fixed state is rotatably held. In addition, since the bearing insertion portion of the crankshaft is ground, it is possible to obtain a method of manufacturing a rotary compressor that is simple in structure and can be miniaturized and that can assemble the coaxiality of each shaft with high accuracy. it can.

In addition, according to the present invention, the partition plate holding table provided on the base and having the partition plate placed at a predetermined position and having an opening larger than the shaft through hole formed in the partition plate, and the partition plate holding table A second shaft holding base that is attached to the base below the opening of the second shaft and holds the fitting hole of the second shaft on the upper side, and coaxial with the second shaft holder above the opening of the partition plate holding base. And a first shaft holder that holds the first shaft so that the fitting shaft of the first shaft is on the lower side, and the first shaft holder that is mounted with the first shaft holder and holds the first shaft is lowered. A fitting device for inserting and fitting the fitting shaft of the first shaft into the fitting hole of the second shaft held in the second shaft holding base through the shaft through hole of the partition plate ; Raise the partition plate holder to By and a drive cylinder that temporarily fixed state shift and the partition plate, the rotary compressor can be assembled accurately coaxiality of the shaft as well as the structure can be made simple and compact A manufacturing apparatus can be obtained.

  Further, according to the present invention, the axial feed device that is provided on the base and moves with the base, and the crankshaft that is attached to the axial feed device and in which the partition plate is temporarily inserted in a fixed state can be rotated. And a grinding body for grinding the bearing insertion portion of the crankshaft, the structure is simple and the size can be reduced, and the coaxiality of each shaft can be assembled with high accuracy. An apparatus for manufacturing a rotary compressor can be obtained.

Embodiment 1 FIG.
The rotary compressor in Embodiment 1 of this invention is demonstrated in detail based on figures.

  FIG. 1 is a longitudinal sectional view showing a configuration example of a rotary compressor based on Embodiment 1 of the present invention, and FIG. 1 shows a case of a rotary compressor 100 called two cylinders having two compression chambers as an example. For example, it is used for a refrigeration / air conditioner. FIG. 2 is a sectional view taken along line II-II in FIG.

  The rotary compressor 100 includes a motor 102 that is a driving source and a compression mechanism 103 that are connected inside a shell 101 that is a pressure vessel. The shell 101 includes an upper shell 101a, an intermediate shell 101b, and a lower shell 101c. The upper shell 101a is fixed with a glass terminal 104 for supplying electric power to the motor 102 from the outside and a discharge pipe 105 for discharging the compressed refrigerant to the outside of the rotary compressor 100. The intermediate shell 101 b is attached with a motor 102, a compression mechanism 103, and a suction pipe 106 that guides the refrigerant to the compression mechanism 103. The suction pipe 106 is connected to a suction muffler 107, and the suction muffler 107 separates refrigeration oil and refrigerant and removes dust in the refrigerant.

  The motor 102 includes a stator 102a and a rotor 102b, and the rotor 102b is attached to the crankshaft 108. Thus, the rotational torque generated by the motor 102 is transmitted to the compression mechanism 103 through the rotor 102b and the crankshaft 108.

  The compression mechanism 103 basically includes a crankshaft 108, a first bearing 109, a first cylinder 110, a partition plate 114, a second cylinder 115, and a second bearing 117, and a first spring 111 is provided in the first cylinder 110. The first vane 112 and the first roller 113 are built in, and are divided into a low pressure portion 131 and a high pressure portion 132 by the first vane 112, and a discharge port 133 for discharging the compressed refrigerant is provided. In addition, a second spring (not shown), a second vane (not shown), and a second roller 116 are built in the second cylinder 115, and, like the first cylinder 110, a low pressure portion ( It is divided into a high-pressure part (not shown) and a discharge port (not shown) for discharging the compressed refrigerant.

  FIG. 3 is a development view showing the relationship between the crankshaft 108 and the partition plate 114. The crankshaft 108 includes a first shaft 118 and a second shaft 119. The crankshaft 108 is integrated by connecting the first shaft 118 and the second shaft 119 on the same axis. is there. The first shaft 118 includes a rotor fitting portion 120 to which the rotor 102 b of the motor 102 is attached, a first bearing insertion portion 121 that is inserted into the first bearing 109, and a first eccentricity that is disposed in the first cylinder 110. The partition plate 114 is inserted through the portion 122, the intermediate shaft 123 inserted through the shaft through hole 129 formed in the partition plate 114, and the shaft through hole 129 formed in one end side and formed in the partition plate 114. It has the structure which has the fitting shaft 124 protruded more. Further, a shaft step portion 125 having a small axial width is formed on the first eccentric portion 122 side of the intermediate shaft 123, and a step portion 130 is formed in the shaft through hole 129 of the partition plate 114. The stepped portion 130 constitutes a temporary fixing mechanism, and the stepped portion 130 provided in the shaft through hole 129 of the partition plate 114 and the small width portion of the shaft stepped portion 125 of the intermediate shaft 123 are temporarily fixed. The intermediate shaft 123 is inserted through the shaft through hole 129 of the partition plate 114 while being fitted. The second shaft 119 includes a second eccentric portion 126 disposed in the second cylinder 115 and a fitting hole 127 formed in the second eccentric portion 126 and into which the fitting shaft 124 of the first shaft 118 is fitted. The second bearing insertion portion 128 is inserted into the second bearing 117 formed on one end side. The fitting shaft 124 of the first shaft 118 is inserted into the shaft through hole 129 of the partition plate 114 and fitted into the fitting hole 127 of the second shaft 119, and is connected and fixed coaxially by, for example, press fitting or shrink fitting. Thus, when the rotary compressor 100 is operated, it rotates together.

  The partition plate 114 is inserted between the first shaft 118 and the second shaft 119 and partitions between the first cylinder 110 and the second cylinder 115. Further, the diameter of the shaft through-hole 129 formed near the center of the partition plate 114 is larger than the diameter of the intermediate portion 123 of the first shaft 118 that is positioned through the shaft through-hole 129, and the first shaft 118 has a first diameter. The diameter is smaller than the diameter of the eccentric part 122 and the second eccentric part 126 of the second shaft 119. Further, the shaft through hole 129 of the partition plate 114 is configured to be temporarily fitted to a shaft step portion 125 formed in the intermediate portion 123 of the first shaft 118 and to be in a fixed state. Further, the intermediate shaft 123 is inserted into the stepped portion 130 provided in the shaft through hole 129 of the partition plate 114 with a predetermined gap.

  A first roller 113 and a second roller 116 are rotatably fitted to the first eccentric portion 122 of the first shaft 118 of the crankshaft 108 and the second eccentric portion 126 of the second shaft 119, respectively. A first spring 111 and a second spring that extend and contract in the radial direction are attached to the first cylinder 110 and the second cylinder 115, respectively. The first vane 112 and the second spring are pressed by the pressing force of the first spring 111 and the second spring. Two vanes are pressed against the outer circumferences of the first roller 113 and the second roller 116, respectively. The first vane 112 and the second vane are configured to divide the inside of the first cylinder 110 and the second cylinder 115 into a low pressure portion 131 and a high pressure portion 132, respectively.

  Next, the operation will be described. By supplying electric power from the outside to the motor 102 through the glass terminal 104, the rotor 102b of the motor 102 rotates. As the rotor 102b of the motor 102 rotates, the crankshaft 108 connected to the rotor 102b rotates in unison with each other. Then, the refrigerant sucked into the first cylinder 110 and the second cylinder 115 from the suction pipe 106 connected to the suction muffler 107 is accompanied by the rotation of the crankshaft 108 and the first cylinder 110 and the second cylinder 115. When the pressure is constant and reaches a constant pressure, the gas is discharged into the shell 101 from the discharge port 133 of the first cylinder 110 and the discharge port of the second cylinder 115, and discharged from the discharge pipe 105 to the outside of the rotary compressor 100. Is done.

  As described above, according to the first embodiment of the present invention, the crankshaft 108 configured by coaxially connecting the first shaft 118 and the second shaft 119 has the fitting shaft 124 of the first shaft 118. The partition plate 114 is inserted into a shaft through hole 129, and the fitting shaft 124 of the first shaft 118 is fitted and connected to the fitting hole 127 of the second shaft 119, and the partition plate is temporarily attached to the crankshaft 108. Therefore, the rotary compressor can be obtained which has a simple structure and can be miniaturized.

  That is, like the prior art in Patent Document 1 described above, the connecting portion of the first shaft and the second shaft is arranged in the opening of the partition plate, whereas the first shaft in Embodiment 1 of the present invention. 118 and the second shaft 119 are connected to the outside of the through hole 129 of the partition plate 114, and the complicated connecting portion is not arranged in the through hole 129 of the partition plate 114 as in the prior art. The through hole 129 can also be made small. In the above-described prior art, the connecting portion between the first shaft and the second shaft is disposed in the opening of the partition plate, and the connecting portion constitutes the intermediate shaft of the first shaft, and the intermediate shaft is freely rotatable. The bearing metal is disposed on the inner peripheral surface of the opening of the partition plate so as to be supported by the inner surface of the shaft through hole 129 of the partition plate 114 in the first embodiment of the present invention. No bearing metal is provided, and the intermediate portion 123 of the first shaft 118 is merely inserted into the shaft through hole 129 of the partition plate 114 and positioned in the shaft through hole 129, and the structure is simple and the size can be reduced. A rotary compressor that can be achieved can be obtained.

Embodiment 2. FIG.
In the first embodiment described above, the partition plate 114 is temporarily fixed between the first eccentric portion 122 of the first shaft 118 of the crankshaft 108 and the second eccentric portion 126 of the second shaft 119. As a mechanism, a shaft step portion 125 is formed in the intermediate shaft 13, a stepped portion 130 is formed in the shaft through hole 129 of the partition plate 114, and a shaft through hole 129 of the partition plate 114 is formed in the intermediate shaft 13. Although the case where the partition plate 114 is temporarily fixed by being fitted to the stepped portion 125 has been described, the first eccentric portion of the intermediate shaft 123 of the first shaft 118 is shown in FIGS. 4 and 5. A key-like protrusion 134 having a small axial width provided on the side 122 and a key groove 135 that engages with the key-like protrusion 134 provided in the shaft through hole 129 of the partition plate 114. In this case, the partition plate 114 is temporarily moved by engaging the key groove 135 provided in the shaft through hole 129 of the partition plate 114 with the key-shaped protrusion 134 provided in the intermediate shaft 123. Can be fixed.

Embodiment 3 FIG.
A manufacturing method for a rotary compressor according to Embodiment 3 of the present invention, particularly a manufacturing method including assembly and grinding finishing of a crankshaft, will be described with reference to the flowchart shown in FIG.

  In STEP 1, the first bearing insertion portion 121 of the first shaft 118, the shaft through-hole 129 of the partition plate 114, and the second bearing insertion portion 128 of the second shaft 119 are set so that the axial centers thereof are coaxial. . At this time, the phase of the first eccentric part 122 of the first shaft 118 and the second eccentric part 126 of the second shaft 119 are shifted by 180 °.

  In STEP 2, the fitting shaft 124 of the first shaft 118 is inserted into the shaft through hole 129 formed in the partition plate 114.

  In STEP 3, the crankshaft 108 is configured by fitting the fitting shaft 124 of the first shaft 118 inserted into the shaft through hole 129 of the partition plate 114 into the fitting hole 127 of the second shaft 119, for example, press-fitting and connecting. To do. At this time, the crankshaft 108 and the partition plate 114 that are integrally configured by connecting the first shaft 118 and the second shaft 119 are not fixed to each other, and the partition plate 114 is not fixed to the first eccentric portion 112. And the second eccentric portion 126 can freely move in the axial direction, move in the radial direction, tilt with respect to the axial center, and rotate.

  In STEP4, the partition plate 114 is moved to the first eccentric portion 112 side of the first shaft 118 of the crankshaft 108, and an axial load is applied to the shaft step portion 125 formed on the intermediate shaft 123 to the shaft of the partition plate 114. By fitting the stepped portion 130 formed in the through hole 129, that is, by press-fitting the shaft through hole 129 of the partition plate 114 into the shaft step portion 125 of the intermediate shaft 123, the partition plate 114 is inserted into the shaft step portion of the intermediate shaft 123. 125 is temporarily fixed.

  When the key-shaped protrusion 134 is provided on the intermediate shaft 123 and the key groove 135 is provided in the shaft through hole 129 of the partition plate 114, the partition plate 114 is connected to the first eccentric portion of the first shaft 118 of the crankshaft 108. The partition plate 114 is moved by engaging the key groove 135 formed in the shaft through hole 129 of the partition plate 114 with the key-shaped protrusion 134 formed on the intermediate shaft 123 by applying an axial load. The intermediate shaft 123 is temporarily fixed.

  In STEP5, both ends of the crankshaft 108 are ground so that the first bearing insertion portion 121 and the second bearing insertion portion 128 of the crankshaft 108 that are integrally configured by connecting the first shaft 118 and the second shaft 119 can be ground. The center is centered and held so that the part can be rotated.

  In STEP 6, the crankshaft 108 is rotated, and the first bearing insertion portion 121 and the second bearing insertion portion 128 are ground by a grinding body such as a grindstone, so that final finishing is performed.

  By manufacturing the crankshaft 108 as described above, the coaxiality between the first shaft 118 and the second shaft 119 of the crankshaft 108 can be obtained with high accuracy. That is, since the first bearing insertion portion 121 of the first shaft 118 and the second bearing insertion portion 128 of the second shaft 119 are finished by grinding with a grinding body such as a grindstone, assembly errors of each shaft are completely eliminated. The accuracy of the coaxiality of each shaft is remarkably improved, and there is substantially no difference in the coaxiality of each shaft. Therefore, according to the rotary compressor 100 manufactured according to the third embodiment, there is provided a method for manufacturing a rotary compressor in which the structure is simple and the size can be reduced, and the coaxiality of each shaft can be accurately assembled. Obtainable.

  As a matter of course, the grinding residue is removed by means such as air blow after the completion of grinding. Further, a solid lubricant such as molybdenum disulfide is applied to the first bearing insertion portion 121 and the second bearing insertion portion 128 of the ground crankshaft 108 when inserted into the first bearing 109 and the second bearing 117, respectively. Therefore, lubrication characteristics such as wear resistance are improved.

  By the way, a method for assembling the crankshaft 108 manufactured according to the third embodiment described above to the compression mechanism 103 will be described with reference to the flowchart shown in FIG.

  In STEP 11, the amount of eccentric deviation between the first bearing insertion part 121 and the first eccentric part 122 of the first shaft 118 is measured.

  In STEP 12, the amount of eccentric deviation between the second bearing insertion portion 128 and the second eccentric portion 126 of the second shaft 119 is measured.

  In STEP 13, when the first shaft 118 rotates between the first cylinder 110 and the first bearing 109 based on the measurement result in STEP 11 described above, the outer peripheral surface of the first roller 113 and the inner peripheral surface of the first cylinder 110 Assemble so that the gap is optimal.

  In STEP14, when the second shaft 115 rotates the second cylinder 115 and the second bearing 117 based on the measurement result in STEP12 described above, the outer peripheral surface of the second roller 116 and the inner peripheral surface of the second cylinder 115 Assemble so that the gap is optimal.

  In STEP 15, the first roller 113 and the first vane 112 are inserted into the first cylinder 110.

  In STEP 16, the crankshaft 108 and the partition plate 114, which are ground and finished, are inserted into the first cylinder 110.

  In STEP 17, the partition plate 114 and the finished crankshaft 108 are separated, that is, the partition plate 114 is subjected to a load in the axial direction opposite to the first eccentric portion 122 of the crankshaft 108 and the intermediate shaft 123 is applied. Is separated from the shaft step 125. As a result, the temporarily fixed state is released. In the case of a temporarily fixed state by the key-shaped protrusion 134 and the key groove 135, the partition plate 114 and the intermediate shaft 123 are separated by releasing the key connection.

  In STEP 18, the second cylinder 115 in which the second roller 116 and the second vane are set is inserted into the crankshaft 108 which has been ground and finished.

  In STEP 19, the first cylinder 110, the partition plate 114, and the second shaft 119 of the first shaft 118, the shaft through hole 129 of the partition plate 114, and the second bearing 117 of the second shaft 119 are coaxial. The two cylinders 115 are positioned and fastened with bolts or the like.

  The crankshaft 108 and the partition plate 114 that have been ground and finished as described above are assembled with the first bearing 109, the first cylinder 110, the second cylinder 115, the second bearing 117, and the like in a state of good coaxiality. The compression mechanism 103 is configured.

Embodiment 4 FIG.
A manufacturing apparatus for a rotary compressor according to Embodiment 4 of the present invention, particularly a manufacturing apparatus for assembling a crankshaft, will be described with reference to FIG. In FIG. 8, the configuration of each part of the crankshaft 108 and the first shaft 118, the configuration of each part of the second shaft, and the configuration of each part of the partition plate 114 are the same as the configurations of the above-described embodiments.

  The assembling apparatus 200 includes a partition plate holding base 202 provided on the base 201 and having a partition plate 114 placed at a predetermined position and having an opening 202a larger than a shaft through hole 129 formed in the partition plate 114, A second plate that is attached to the base 201 below the opening 202a of the partition plate holding base 202 and holds the second bearing insertion portion 128 of the second shaft 119 so that the fitting hole 127 of the second shaft 119 is on the upper side. The shaft holding base 203, the drive cylinder 204 that moves up and down the partition plate holding base 202, and the second shaft holding base 203 are arranged coaxially with the second shaft holding base 203 above the opening 202 a of the partition plate holding base 202. A first shaft holder 205 that holds the rotor fitting portion 120 of the first shaft 118 so that the fitting shaft 124 is on the lower side, and a first shaft holder 205. The fitting shaft 124 of the first shaft 118 is moved through the through-hole 129 of the partition plate 114 and the partition plate holding base 202 by lowering the first shaft holder 205 attached and holding the first shaft 118 vertically downward. And a fitting device 206 made of, for example, a press machine, which is connected to the fitting hole 127 of the second shaft 119 held by the second shaft holding base 203 through the opening 202a. As a matter of course, the first shaft holder 205 and the second shaft holder 203 are arranged on the same axis. Therefore, the fitting shaft 124 of the first shaft 118 and the fitting hole 127 of the second shaft 119 are set so as to be coaxial.

  The manufacturing apparatus according to the fourth embodiment sets and holds the second shaft 119 on the second shaft holding base 203 so that the fitting hole 127 is on the upper side. The partition plate 114 is placed on the partition plate holding table 202. The first shaft 118 is held by the first shaft holder 205 so that the fitting shaft 124 is on the lower side. At this time, the first shaft 118, the second shaft 119, and the shaft through hole 129 of the partition plate 114 are set coaxially, and the first eccentric portion 122 of the first shaft 118 and the second eccentric portion 126 of the second shaft 119 are set. Is set so that the phase is shifted by 180 °. Then, by lowering the first shaft holder 205 holding the first shaft 118 vertically downward by the fitting device 206 formed of a press machine, the first shaft 118 is also lowered in conjunction. The fitting shaft 124 of the first shaft 118 is inserted through the through hole 128 of the partition plate 114 and the opening 202a of the partition plate holding base 202, and the second shaft 119 held by the second shaft holding base 203 is fitted. After a vertical downward force is applied to the hole 127 and press-fitted, the drive cylinder 204 is driven to lift the partition plate holding base 202 upward, and a vertical upward force is applied to the partition plate 114, so that the first shaft 118 and the first shaft 118 The two shafts 119 are coaxially connected and integrated to form the crankshaft 108, and the partition plate 114 is temporarily fixed to the crankshaft 108.

  According to the fourth embodiment, the second shaft 119 is held by the second shaft holding base 203, the first shaft 118 is held by the first shaft holder 205, and the partition plate 114 is attached to the partition plate holding base 202. The first shaft 118, the second shaft 119, and the shaft through hole 129 of the partition plate 114 are set on the same axis, the fitting device 206 is driven to lower the first shaft holder 205, and the first shaft holder 205 is lowered. By connecting the shaft 118 and the second shaft 119 coaxially to form the crankshaft 108, the structure can be simplified and the size can be reduced, and the coaxiality of each shaft can be assembled with high accuracy. An apparatus for manufacturing a rotary compressor can be obtained.

Embodiment 5 FIG.
A manufacturing apparatus for a rotary compressor according to a fifth embodiment of the present invention, particularly a manufacturing apparatus for grinding the crankshaft, will be described with reference to FIGS. FIG. 9 is a front view, FIG. 10 is a plan view, and FIG. 11 is an enlarged view of a main part. In these drawings, the components of the crankshaft 108 and the first shaft 118, the components of the second shaft, and the components of the partition plate 114 are the same as those of the above-described embodiments.

  The grinding device 300 is provided on a base 301 and is attached to the axial feed device 302 that moves in the axial direction together with the base 301 and the crankshaft 108 through which the partition plate 114 is inserted. The rotary holder 303 is held by a grinding wheel 304 made of, for example, a grindstone.

  The rotation holder 303 rotatably holds the crankshaft 108 at both center portions. The axial feed device 302 to which the rotary holder 303 is attached moves in the axial direction, thereby moving the crankshaft 108 in the axial direction and changing the grinding position.

  The grinding body 304 is composed of, for example, a grindstone, and is configured to advance and retreat in a direction orthogonal to the axial direction of the crankshaft 108 by a driving device (not shown). The first bearing insertion portion 121 and the second bearing insertion portion 128 are ground and subjected to final finishing.

  In the manufacturing apparatus according to the fifth embodiment, the crankshaft 108 in which the first shaft 118 and the second shaft 119 are integrally connected by the manufacturing apparatus according to the fourth embodiment described above is attached to the axial feeding device 302. Centering is performed at both center portions by the rotating holder 303, and the crankshaft 108 is rotatably held. As an example, the drawing shows a state where the second bearing insertion portion 128 of the second shaft 119 of the crankshaft 108 is ground, and the axial feed device 302 is driven to drive the second bearing insertion portion of the second shaft 119. It moves in the axial direction so that 128 comes near the position of the grindstone that is the grinding body 304. Next, the grindstone that is the grinding body 304 is advanced in a direction orthogonal to the axial direction of the crankshaft 108, and the second bearing insertion portion 128 of the second shaft 119 is ground to perform final finishing. When the final finishing of the second bearing insertion portion 128 of the second shaft 119 is completed, the position of the grindstone where the first bearing insertion portion 121 of the first shaft 118 is the grinding body 304 is driven by driving the axial feed device 302. Move in the axial direction to come close. Next, the grindstone that is the grinding body 304 is advanced in a direction orthogonal to the axial direction of the crankshaft 108, and the first bearing insertion portion 121 of the first shaft 118 is ground to perform final finishing. In addition, grinding with the grindstone which is the grinding body 304 may grind the 2nd bearing insertion part 128 of the 2nd shaft 119 after grinding the 1st bearing insertion part 121 of the 1st shaft 118 previously.

  According to the fifth embodiment, the first bearing insertion portion 121 of the first shaft 118 of the crankshaft 108 and the second bearing insertion portion 128 of the second shaft 119 are ground by the grindstone that is the grinding body 304 and finally obtained. By performing the finishing process, the assembly error of each shaft is completely eliminated, the accuracy of the coaxiality of each shaft is remarkably improved, and there is substantially no difference in the coaxiality of each shaft. . Therefore, according to the rotary compressor 100 manufactured according to the fifth embodiment, a rotary compressor manufacturing apparatus that has a simple structure and can be miniaturized, and that can accurately assemble the coaxiality of each shaft. Obtainable.

  As described above, even when the partition plate 114 not to be processed is inserted into the crankshaft 108 to be processed so as to move in the axial direction, move in the radial direction, tilt with respect to the axis, and rotate freely, the partition plate 114 is inserted. Is temporarily fixed to the crankshaft 108 so as to rotate integrally with the crankshaft 108, so that the first bearing insertion portion 121 of the first shaft 118 and the second shaft 119 of the second shaft 119 of the crankshaft 108 are rotated. The bearing insert 128 can be ground. Furthermore, since the first shaft 118 and the second shaft 119 are ground after assembling, the highly accurate crankshaft 108 can be manufactured even if there is an assembly error between the first shaft 118 and the second shaft 119.

Embodiment 6 FIG.
In the sixth embodiment described above, the case where there is one grinding body 304 has been described. However, in this sixth embodiment, as shown in the plan view of FIG. The first bearing insertion portion 121 of the first shaft 118 of the crankshaft 108 and the second bearing insertion portion 128 of the second shaft 119 are simultaneously ground by the grindstone of the grinding body 304 to perform final finishing. In this case, the grinding efficiency is further improved.

Embodiment 7 FIG.
The seventh embodiment relates to the rotary compressor manufactured by the manufacturing method in the third embodiment described above or the manufacturing apparatus in any one of the fourth to sixth embodiments described above.

  In the rotary compressor according to the seventh embodiment, the diameter of the shaft through hole 128 of the partition plate 114 can be smaller than the diameters of the first eccentric portion 122 and the second eccentric portion 125 of the crankshaft 108, and the coaxial accuracy of the crankshaft 108 is increased. Therefore, even if the eccentric amount of the crankshaft 108 is increased, gas leakage does not occur from the shaft through hole 128 of the partition plate 114, and a small and large capacity rotary compressor can be obtained. Is possible.

It is a longitudinal cross-sectional view which shows the rotary compressor in Embodiment 1 of this invention. It is sectional drawing in the II-II line of FIG. 1 which shows the rotary compressor in Embodiment 1 of this invention. It is an expanded view which shows the relationship between the crankshaft and partition plate of the rotary compressor in Embodiment 1 of this invention. It is an expanded view which shows the relationship between the crankshaft and partition plate of the rotary compressor in Embodiment 2 of this invention. It is sectional drawing in the IV-IV line of FIG. 1 which shows the rotary compressor in Embodiment 2 of this invention. It is a flowchart which shows the assembly / manufacturing method of the crankshaft of the rotary compressor in Embodiment 3 of this invention. It is a flowchart which shows the manufacturing method of the rotary compressor in Embodiment 3 of this invention. It is a longitudinal cross-sectional view which shows the manufacturing apparatus of the rotary compressor in Embodiment 4 of this invention. It is a front view which shows the manufacturing apparatus of the rotary compressor in Embodiment 5 of this invention. It is a top view which shows the manufacturing apparatus of the rotary compressor in Embodiment 5 of this invention. It is a principal part enlarged view which shows the manufacturing apparatus of the rotary compressor in Embodiment 5 of this invention. It is a top view which shows the manufacturing apparatus of the rotary compressor in Embodiment 6 of this invention.

Explanation of symbols

  100: Rotary compressor, 108: Crankshaft, 109: First bearing, 110: First cylinder, 114: Partition plate, 115: Second cylinder, 117: Second bearing, 118: First shaft, 119: Second Shaft, 121: first bearing insertion portion, 122: first eccentric portion, 123: intermediate shaft, 124: fitting shaft, 125: shaft step portion, 126 :: second eccentric portion, 127: fitting hole, 128: Second bearing insertion portion, 129: shaft through hole, 130: stepped portion, 201: base, 202: partition plate holder, 202a: opening, 203: second shaft holder, 205: first shaft holder , 206: fitting device, 301: base, 302: axial direction feeding device, 303: rotating holder, 304: grinding body.

Claims (8)

A first bearing insertion portion to be inserted into the first bearing, a first eccentric portion disposed in the first cylinder, a fitting shaft formed on one end side, the first eccentric portion and the fitting shaft; A first shaft having an intermediate shaft positioned therebetween,
A second eccentric portion disposed in the second cylinder; a fitting hole formed in the second eccentric portion and into which the fitting shaft of the first shaft is fitted; and a second bearing formed on one end side. A second shaft having a second bearing insertion portion to be inserted;
A crankshaft configured by connecting the first shaft and the second shaft;
A partition plate that is formed with a shaft through-hole through which the crankshaft passes, is inserted between the first shaft and the second shaft, and partitions between the first cylinder and the second cylinder;
A temporary fixing mechanism for temporarily fixing the partition plate between the shaft through hole formed in the partition plate and the intermediate shaft;
The crankshaft is inserted by inserting the fitting shaft of the first shaft into the shaft through hole formed in the partition plate, and fitting the fitting shaft into the fitting hole of the second shaft. A rotary compressor characterized by being configured.   The temporary fixing mechanism includes a stepped portion formed in the shaft through hole so that a shaft step portion formed in the intermediate shaft and a shaft through hole of the partition plate are temporarily fixed to the shaft step portion. The rotary compressor according to claim 1, further comprising:   The temporary fixing mechanism includes a key-like protrusion provided on the intermediate shaft, and a key groove formed in a shaft through hole of the partition plate and engaged with the key-like protrusion. The rotary compressor according to claim 1. A crankshaft formed by connecting a first shaft having a first eccentric part and a second shaft having a second eccentric part is inserted into a shaft through hole formed in a partition plate separating the first cylinder and the second cylinder. In the manufacturing method of the rotary compressor to be assembled, the first shaft, the second shaft, and the partition plate are coaxially set, and the fitting shaft of the first shaft is used as the shaft through hole of the partition plate. And inserting the fitting shaft of the first shaft, which is inserted through the shaft through hole of the partition plate, into the fitting hole of the second shaft to form the crankshaft. And a step of temporarily fixing the partition plate between the first eccentric portion and the second eccentric portion of the crankshaft, and the crankshaft through which the partition plate is inserted A step of holding the rolling capable, said the step of grinding the bearing insertion portion of the crank shaft, the manufacturing method of the rotary compressor characterized by comprising the step of separating the said partition plate the crankshaft. A crankshaft formed by connecting a first shaft having a first eccentric part and a second shaft having a second eccentric part is inserted into a shaft through hole formed in a partition plate separating the first cylinder and the second cylinder. In the rotary compressor manufacturing apparatus to be assembled, the partition plate holding base is provided on a base and the partition plate is placed at a predetermined position and has an opening larger than the shaft through hole formed in the partition plate. A second shaft holding base that is attached to the base below the opening of the partition plate holding base and holds the fitting hole of the second shaft on the upper side, and an opening of the partition plate holding base A first shaft holder that is disposed on the same axis as the second shaft holding base and holds the fitting shaft of the first shaft on the lower side, and the first shaft holder is mounted, By lowering the first shaft holder that holds one shaft, the fitting shaft of the first shaft is inserted through the shaft through hole of the partition plate and held by the second shaft holding base. A fitting device that is fitted and connected to the fitting hole of the second shaft; and a drive cylinder that raises the partition plate holding base to temporarily fix the crankshaft and the partition plate . An apparatus for manufacturing a rotary compressor.   The said fitting apparatus consists of press machines, The manufacturing apparatus of the rotary compressor of Claim 5 characterized by the above-mentioned.   A crankshaft formed by connecting a first shaft having a first eccentric part and a second shaft having a second eccentric part is inserted into a shaft through hole formed in a partition plate separating the first cylinder and the second cylinder. In the rotary compressor manufacturing apparatus to be assembled, the axial feed device that is provided on the base and moves together with the base, the axial feed device is attached, and the partition plate is temporarily inserted in a fixed state. An apparatus for manufacturing a rotary compressor, comprising: a rotary holder that rotatably holds the crankshaft; and a grinding body that grinds a bearing insertion portion of the crankshaft.   A rotary compressor manufactured by the manufacturing method according to claim 4 or the manufacturing apparatus according to any one of claims 5 to 7.

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