JP2015039765A - Rotation processing machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rotation processing machine capable of quickly and easily forming a grinding wheel tooth flank of a rotary grinding wheel and improving productivity of a helical gear.SOLUTION: A rotation processing machine 1 includes: a rotating device 2 for supporting and rotating a workpiece 8 formed with helical teeth 81; a processing device 3 for performing grinding of helical teeth 81 of the workpiece 8 rotated by the rotating device 2 by grinding teeth 71 of the rotary grinding wheel 7; and a carrier device 4 for carrying the workpiece 8 in/out of the rotating device 2. The carrier device 4 brings grippers 51 close to the rotating device 2 and brings dressers 52 close to the processing device 3. The carrier device 4 holds a dress gear 55 for forming grinding teeth 71 of the rotary grinding wheel 7 by the grippers 51 and mounts the dress gear 55 on the rotating device 2. The rotation processing machine 1 forms tooth flanks 711 and tooth bottom surfaces 712 of the grinding teeth 71 by the dress gear 55 and forms tooth crests 713 of the grinding teeth 71 by the dressers 52.

Description

  The present invention relates to a rotary processing machine including a processing device that performs grinding processing on a rotating workpiece with a rotating grindstone.

  In a rotary processing machine that performs grinding on a workpiece rotated by a rotary device using a rotary grindstone of a processing device, the shape of the rotary grindstone is appropriately formed using a dresser according to the type of workpiece to be processed. For example, in a rotating wheel that grinds the helical teeth of a workpiece, a dresser is prepared for each type of workpiece, and the pressure angle and tooth profile roundness of the wheel surface of the rotating wheel (curved bulge from the tooth root to the tooth tip) (Shape) is adjusted.

  For example, in Patent Document 1, a table that holds and rotates a workpiece, a counter column that supports one end of the workpiece, and a grindstone shaft for mounting a grindstone that grinds the workpiece are advanced and retreated on the bed. A gear grinding machine provided with a column is disclosed. In this gear grinding machine, a dressing device for dressing a grindstone mounted on a grindstone shaft is provided on a ring-shaped member that can turn the outer periphery of a counter column. Thereby, the dressing apparatus is rationally arranged in the gear grinding machine.

  Further, for example, Patent Document 2 discloses a gear tooth surface modification method for modifying a tooth surface so as not to cause a single contact based on misalignment of the gear shaft when the gear is disposed. Yes. In this tooth surface modification method, in order to keep the meshing transmission error small, the crowning amount and tooth profile that can avoid contact with each other in the error tooth surface obtained by converting misalignment into pressure angle error and torsion angle error. The rounding amount is obtained.

JP-A-2005-111600 JP-A-8-197332

  However, in the gear grinding machine of Patent Document 1, the dressing device is fixed to the ring-shaped member of the counter column, and it is necessary for the operator to manually change the dressing device for each type of workpiece. For this reason, it takes time to replace the dressing apparatus, and the productivity of the helical gear cannot be improved so much. Moreover, in the said patent document 2, no device about a dressing apparatus is made | formed.

  The present invention has been made in view of such a background, and is intended to provide a rotary processing machine that can quickly and easily form a grindstone tooth surface of a rotary grindstone and improve the productivity of a helical gear. It is what was done.

One aspect of the present invention is a rotating device that supports and rotates a workpiece on which helical teeth are formed, and a processing device that grinds the helical teeth of the workpiece rotated by the rotating device with grinding teeth of a rotating grindstone. In a rotary processing machine comprising: a conveying device that carries the workpiece into and out of the rotating device,
The conveying device has a gripper for sandwiching the workpiece and a dresser for forming the grinding teeth around the turning center axis, respectively, and swivels around the turning center axis. A gripper is made to approach the rotating device, and the dresser is made to approach the processing device, and a dress gear for forming the grinding teeth is sandwiched between the grippers and attached to the rotating device. Has been
The rotary processing machine is configured to form a tooth surface of the grinding tooth by the dress gear and shape a tooth tip surface of the grinding tooth by the dresser.

In the rotary machine, the grinding teeth of the rotary grindstone are formed using both the dresser and the dress gear.
When forming the grinding teeth of the rotating grindstone in the processing apparatus, a dress gear having a required shape is sandwiched by the gripper of the transport apparatus according to the type of workpiece. Then, the conveying device is turned, the dress gear held by the gripper is brought close to the rotating device, and is mounted on the rotating device. Thereby, the required dress gear can be easily carried into the rotating device. In addition, after forming the grinding teeth of the rotating grindstone, the dress gear can be easily carried out of the rotating device by the conveying device.

  Further, in the rotary machine, the tooth surface of the grinding tooth is formed by the dress gear, while the tooth tip surface of the grinding tooth is formed by the dresser. Therefore, when the shape of the tooth surface of the grinding tooth (pressure angle, roundness of the tooth profile) differs depending on the type of workpiece, the dress gear can be replaced by the conveying device. On the other hand, the shaping of the tip surface of the grinding tooth, which cannot be performed with a dress gear, can be performed with the same dresser even if the type of workpiece is different.

  Therefore, according to the rotary processing machine, the dress gear can be quickly exchanged according to the type of workpiece, and the dressing surface and the dresser can be used in combination to quickly and rapidly form the tooth surface of the grinding wheel of the rotary grindstone. It can be done easily. The time required for exchanging the dress gear can be shortened, and the productivity of the helical gear produced by grinding the helical teeth of the workpiece can be improved.

In the rotary machine, the workpiece is ground as follows.
When the work is carried into the rotating device, the work sandwiched between the grippers is made to approach the rotating device by turning of the conveying device and then supported by the rotating device. Then, the grinding teeth of the rotating grindstone in the processing device grind the helical teeth of the workpiece rotated by the rotating device. Thereafter, when the work is carried out from the rotating device, the work after the grinding process is held between the rotating device and the gripper, and the conveying device is turned.

The perspective view which shows the rotary processing machine concerning an Example. The top view which shows the rotary processing machine concerning an Example. Explanatory drawing which expands and shows the state which shape | molds the tooth surface and tooth base of the grinding tooth of a rotary grindstone with a dress gear concerning an Example. Explanatory drawing which expands and shows the state which shape | molds the tooth-tip surface of the grinding tooth of a rotary grindstone with a dresser concerning an Example. The perspective view which shows the rotary processing machine of the state which grinds to the helical tooth of a workpiece | work with the grinding tooth of a rotary grindstone concerning an Example. The front view which shows the rotary processing machine of the state which carries in / out the workpiece support jig | tool concerning an Example.

A preferred embodiment of the rotary machine described above will be described.
In the rotary processing machine, the conveying device is configured such that a swivel loader portion is rotatably disposed on a swivel strut portion through which the swivel center axis passes, and the gripper is arranged on an outer periphery of the swivel loader portion. The plurality of grippers are arranged so as to be movable in the vertical direction, and are configured to hold the workpiece or the dress gear by a pair of holding portions that open and close in the horizontal direction. Also good.
In this case, by moving each gripper in the vertical direction, the work can be carried into and out of the rotating device quickly and easily.

Further, the rotating device is configured to support the workpiece up and down via a workpiece support jig, and the workpiece support jig includes an upper jig portion attached to an upper support portion in the rotating device, A lower jig part to be mounted on a lower support part in the rotating device, and each gripper not only clamps the work but also the lower jig in a state where the upper jig part is placed. You may be comprised so that a tool part may be clamped.
In this case, a workpiece support jig for supporting the workpiece can be sandwiched between grippers of the transport device and carried into and out of the rotating device. Therefore, when the type of workpiece to be processed is changed, the workpiece support jig for supporting the workpiece can be replaced quickly and easily.

In addition, the dress gear is configured to be supported by the upper support portion and the lower support portion of the rotating device by using the work support jig having the upper jig portion and the lower jig portion. May be.
In this case, it is not necessary to use a dedicated jig when supporting the dress gear to the rotating device. Therefore, it is possible to facilitate the setup when the dress gear is supported on the rotating device instead of the workpiece, and to further improve the productivity of the helical gear produced by grinding the helical teeth of the workpiece.

Hereinafter, embodiments of a rotary machine will be described with reference to the drawings.
As shown in FIGS. 1 and 2, the rotary machine 1 of this example supports a rotating device 2 that supports and rotates a workpiece 8 on which a helical tooth 81 is formed, and a helical tooth 81 of the workpiece 8 that is rotated by the rotating device 2. Furthermore, a processing device 3 that performs grinding with the grinding teeth 71 of the rotating grindstone 7 and a transport device 4 that carries the workpiece 8 into and out of the rotating device 2 are provided. The conveying device 4 has a gripper 51 for sandwiching the workpiece 8 and a dresser 52 for forming the grinding teeth 71 around the turning center axis 401.

  The conveying device 4 is configured to turn around the turning center axis 401 so that the gripper 51 approaches the rotating device 2 and the dresser 52 approaches the processing device 3. Further, the conveying device 4 is configured to be attached to the rotating device 2 with a dress gear 55 for forming the grinding teeth 71 of the rotating grindstone 7 sandwiched between the grippers 51. As shown in FIG. 3, the rotary machine 1 forms the tooth surface 711 and the tooth bottom surface 712 of the grinding tooth 71 by the dress gear 55, and forms the tooth tip surface 713 of the grinding tooth 71 by the dresser 52 as shown in FIG. 4. It is configured as follows.

Below, it demonstrates in detail with reference to FIGS. 1-6 about the rotary machine 1 of this example.
As shown in FIG. 5, the processing device 3 and the rotation device 2 of this example constitute a gear grinder that grinds the helical teeth 81 formed on the outer periphery of the workpiece 8 by the grinding teeth 71 of the rotating grindstone 7. The rotary machine 1 of the present example is a gear grinding machine that enables conveyance of the workpiece 8 and changeover (exchange) of the workpiece support jig 6 that supports the workpiece 8. In the processing device 3 and the rotation device 2 of this example, the helical surface 81 of the workpiece 8 is subjected to a finish processing of the tooth surface to produce a helical gear as a product. The helical gear can be a helical gear that is used with the axial directions of gears meshing with each other being parallel, or a screw gear that is used with the axial directions of gears meshing with each other being orthogonal.

As shown in FIG. 6, the processing apparatus 3 is configured by inclining a rotation center axis 301 of a grindstone gripping part (grindstone axis) 31 on which the rotating grindstone 7 is mounted with respect to the horizontal direction. The rotating device 2 is configured to rotate around a rotation center axis 201 along the vertical direction.
The processing device 3 is configured to rotate the grindstone gripping portion 31 about a rotation center axis 300 orthogonal to or intersecting with the rotation center axis 201 of the rotation device 2 and to move back and forth, left and right, and up and down. The grindstone gripping portion 31 is configured to grip the shaft portions on both sides of the rotating grindstone 7. The rotating device 2 is disposed in a space between the processing device 3 and the conveying device 4.

  As shown in FIG. 5, the rotating device 2 is configured to support the workpiece 8 up and down via a workpiece support jig 6. The jig support portion 21 of the rotating device 2 includes an upper support portion 212 and a lower support portion 211. The workpiece support jig 6 is divided into an upper jig portion 62 to be attached to the upper support portion 212 in the rotating device 2 and a lower jig portion 61 to be attached to the lower support portion 211 in the rotating device 2. It is comprised so that may be pinched. The workpiece 8 is supported by the rotating device 2 with the axial direction thereof being the vertical direction.

  The rotating device 2 is configured to support the workpiece 8 from the upper and lower sides via the workpiece supporting jig 6 and rotate around a rotation center axis 201 parallel to the turning center axis 401 of the transport device 4. The lower support portion 211 of the rotating device 2 is attached to the upper end portion of the rotary table 20 that is rotated by a drive source such as a motor. The upper support 212 of the rotating device 2 is provided on the swivel support column 41 of the transport device 4 so as to be slidable up and down by an actuator.

  As shown in FIG. 1 and FIG. 2, the transport device 4 is configured such that a turning loader portion 42 is turnably disposed on a turning column portion 41 through which a turning center axis 401 passes. Each gripper 51 is disposed on the turning loader unit 42 so as to be movable in the vertical direction by being driven by an actuator. Each gripper 51 is configured to sandwich the workpiece 8 by a pair of sandwiching portions 511 that are driven by other actuators to open and close in the lateral direction. The dresser 52 is fixed to the turning loader portion 42 so as not to move in the vertical direction in order to improve the accuracy of forming the grinding teeth 71 of the rotating grindstone 7. The turning center axis 401 of the turning support column 41 is oriented in the vertical direction, and each gripper 51 and dresser 52 are configured to turn around the turning support column 41 in the horizontal direction by the turning loader unit 42.

  As shown in FIGS. 5 and 6, each gripper 51 is configured to sandwich the lower jig part 61 or the dress gear 55 in a state where the upper jig part 62 is placed, in addition to sandwiching the workpiece 8. ing. Each gripper 51 is configured to sandwich an outer peripheral portion of the workpiece 8 where the helical teeth 81 are formed, an outer peripheral portion of the lower jig portion 61, or an outer peripheral portion of the dress gear 55 where the dress teeth 551 are formed. The gripper 51 is configured to be able to hold a plurality of types of workpieces 8 and lower jig parts 61 having different outer diameters by changing the distance between the pair of holding parts 511. The sandwiching inner side surfaces 512 of the pair of sandwiching portions 511 are formed in a V shape in which inclined surfaces come into contact with two places in the circumferential direction in order to facilitate sandwiching of the workpiece 8 and the lower jig portion 61.

  The conveying device 4 is a turning loader that can turn so that a plurality of grippers 51 disposed at the same radial distance from the turning center axis 401 are sequentially opposed to the rotating device 2. Each gripper 51 can directly and directly hold the workpiece 8, the workpiece support jig 6, and the dress gear 55. The conveying device 4 holds the workpiece 8, the workpiece support jig 6 or the dress gear 55 between the grippers 51, turns the turning loader unit 42, and rotates the workpiece 8, the workpiece support jig 6 or the dress gear with the rotating device 2. 55 is configured to deliver.

As shown in FIG. 5 and FIG. 6, the plurality of grippers 51 are provided with the workpiece 8, the workpiece support jig 6, or the dress gear 55 from the direction orthogonal to the turning center axis 401 of the transport device 4 and the rotation center axis 201 of the rotating device 2. Are respectively configured to pass between the lower support portion 211 and the upper support portion 212 of the rotating device 2.
The grippers 51 of this example are provided at two positions that are shifted from each other in the circumferential direction of 180 ° in the circumferential direction of the turning loader portion 42. In addition, the dresser 52 is located at two positions in the circumferential direction of the turning loader portion 42, that is, a position that is 90 ° out of phase with the position where the gripper 51 is provided, and that is shifted 180 ° in the circumferential direction. Is provided. The grippers 51 can be provided at three or more locations around the turning loader portion 42. Further, the dresser 52 may be provided only at one place around the turning loader unit 42.

  As shown in FIG. 5, the dresser 52 includes a rotating shaft portion 521 provided with a grinding outer peripheral surface 522, and a support bracket 524 provided with a pair of supporting portions 525 that rotatably support both ends of the rotating shaft portion 521. have. The grinding outer peripheral surface 522 of the rotating shaft portion 521 has a very simple shape, and grinds the tip surface 713 of the grinding tooth 71 of the rotating grindstone 7. The support bracket 524 is fixed to the turning loader unit 42. As shown in FIG. 4, the dresser 52 forms the tip surface 713 of the grinding tooth 71 that cannot be molded by the dress gear 55, and assists the molding of the grinding tooth 71 by the dress gear 55.

  The dress gear 55 has substantially the same shape as the workpiece 8 and has dress teeth 551 having substantially the same shape as the helical teeth 81 of the workpiece 8. The dress gear 55 is supported by the upper support portion 212 and the lower support portion 211 of the rotation device 2 by using the workpiece support jig 6 for supporting the workpiece 8 on the upper support portion 212 and the lower support portion 211 of the rotation device 2. Is done. Thereby, when the dress gear 55 is supported on the rotating device 2 instead of the workpiece 8, it is not necessary to set up a jig for supporting the dress gear 55 on the rotating device 2.

As shown in FIG. 3, the tooth surface 552 of the dressing tooth 55 of the dress gear 55 is shaped so as to grind the helical tooth 81 having the required pressure angle and rounded tooth profile by the tooth surface 711 of the grinding tooth 71 of the rotating grindstone 7. Is formed. The shape of the tooth surface 552 of the dress teeth 551 of the dress gear 55 determines the pressure angle and the roundness of the tooth profile that are formed on the helical teeth 81 of the workpiece 8 by the grinding teeth 71. The pressure angle is expressed as an angle formed by a radial line in the radial direction from the center of the workpiece 8 and a tangent to the tooth profile. The roundness of the tooth profile is expressed as a curved bulge shape (the size of the convex shape in the radial direction) from the tooth root to the tooth tip of the helical tooth 81.
Further, the tip surface 553 of the dressing tooth 551 of the dress gear 55 is formed in a shape that forms the bottom surface 712 of the grinding tooth 71 of the rotating grindstone 7.

  The torsion angle (inclination angle around the axial direction of the workpiece 8) formed on the helical tooth 81 of the workpiece 8 is changed by adjusting the inclination angle of the rotation center axis 301 of the grindstone gripping portion 31 that grips the rotating grindstone 7. can do. The crowning (roundness in the tooth trace direction or width direction) formed on the helical tooth 81 of the workpiece 8 is the center of rotation of the grindstone gripping portion 31 that grips the rotary grindstone 7 while grinding in the tooth trace direction of the helical tooth 81. It can be formed by changing the inclination angle of the axis 301.

In the rotary machine 1, the workpiece 8 is ground by the grinding teeth 71 of the rotary grindstone 7 as follows.
As shown in FIG. 5, when the work 8 is carried into the rotating device 2, the rotating device 2 is provided with a work support jig 6 corresponding to the workpiece 8 to be ground, for holding the gripper 51 in the transport device 4 and a turning loader. The part 42 is turned and installed. Then, the work 8 is sandwiched between the grippers 51, and the work 8 is brought close to the rotating device 2 by turning of the turning loader unit 42. Next, the gripper 51 is moved up and down and the upper jig part 62 in the upper support part 212 is moved up and down to support the work 8 between the upper jig part 62 and the lower jig part 61 in the rotating device 2. Next, the grinding teeth 71 of the rotating grindstone 7 rotated by the grindstone gripping portion 31 of the processing device 3 perform grinding on the helical teeth 81 of the workpiece 8 rotated by the rotating device 2. Thereafter, when the workpiece 8 is unloaded from the rotating device 2, the workpiece 8 after the grinding process is held between the rotating device 2 and the gripper 51, and the turning loader portion 42 of the transport device 4 is turned.

Further, in the rotary machine 1, the tip surface 713 of the grinding tooth 71 of the rotating grindstone 7 is formed by the outer peripheral grinding surface 522 of the dresser 52, and the tooth surface 711 of the grinding tooth 71 by the dress gear 55 and A root surface 712 is formed.
As shown in FIG. 5, when forming the tooth surface 711 of the grinding tooth 71 of the rotating grindstone 7 into a predetermined shape, the work supporting jig 6 is mounted on the rotating device 2. Then, the dress gear 55 is sandwiched between the grippers 51 of the transport device 4, and the dress gear 55 is brought close to the rotating device 2 by the turning of the turning loader unit 42. Next, the gripper 51 is raised and lowered, and the upper jig portion 62 is raised and lowered in the upper support portion 212, and the dress gear 55 is supported between the upper jig portion 62 and the lower jig portion 61 in the rotating device 2.

Next, as shown in FIG. 3, the tooth surface 711 of the grinding tooth 71 of the rotating grindstone 7 rotated by the grindstone gripping portion 31 of the processing device 3 is formed by the dress teeth 551 of the dress gear 55 rotated by the rotating device 2. At this time, the tooth surface 552 of the dressing tooth 55 of the dress gear 55 forms the tooth surface 711 of the grinding tooth 71, and the tooth tip surface 553 of the dressing tooth 551 forms the tooth bottom surface 712 of the grinding tooth 71.
Next, as shown in FIGS. 1 and 2, the turning loader portion 42 of the conveying device 4 is turned so that the dresser 52 faces the rotating grindstone 7 of the processing device 3. Next, the grindstone gripping portion 31 of the processing device 3 is moved, and the grinding outer peripheral surface 522 of the dresser 52 is brought into contact with the tip surface 713 of the grinding tooth 71 of the rotating grindstone 7 gripped by the grindstone gripping portion 31. Further, as shown in FIG. 4, the rotating grindstone 7 is rotated by the grindstone gripping portion 31, the rotating shaft portion 521 of the dresser 52 is rotated, and the grinding tooth 71 of the rotating grindstone 7 is rotated by the grinding outer peripheral surface 522 of the rotating shaft portion 521. The tip surface 713 is formed.

  Further, the grinding teeth 71 of the rotating grindstone 7 can be divided and formed at a plurality of locations in the axial direction of the rotating grindstone 7. Each part of the grinding tooth 71 formed by dividing can be formed such that at least one of a module, a pressure angle, and a roundness of the tooth profile formed on the helical tooth 81 of the workpiece 8 is different from each other.

Next, the effects of the rotary machine 1 of this example will be described.
When forming the grinding teeth 71 of the rotary grindstone 7 in the processing device 3, the dress gear 55 having a required shape is held by the gripper 51 of the transport device 4 according to the type of the workpiece 8. Then, the conveying device 4 is turned, and the dress gear 55 sandwiched between the grippers 51 is brought close to the rotating device 2 and attached to the rotating device 2. Thereby, the required dress gear 55 can be easily carried into the rotating device 2. In addition, after the formation of the grinding teeth 71 of the rotating grindstone 7, the dress gear 55 can be easily carried out of the rotating device 2 by the conveying device 4.

  In the rotary processing machine 1, the tooth surface 711 and the tooth bottom surface 712 of the grinding tooth 71 are formed by the dress gear 55, while the tooth tip surface 713 of the grinding tooth 71 is formed by the dresser 52. Therefore, the dress gear 55 can be replaced by the conveying device 4 when the pressure angle of the tooth surface 711 of the grinding tooth 71 and the shape of the tooth profile are different depending on the type of the workpiece 8. On the other hand, the formation of the tip surface 713 of the grinding tooth 71, which cannot be performed by the dress gear 55, can be performed by the same dresser 52 even if the type of the workpiece 8 is different.

  Therefore, according to the rotary processing machine 1 of the present example, the dress gear 55 can be quickly replaced according to the type of the workpiece 8, and the grinding tooth of the rotary grindstone 7 can be obtained by using the dress gear 55 and the dresser 52 in combination. The tooth surface 711 in 71 can be formed quickly and easily. The time required for replacing the dress gear 55 can be shortened, and the productivity of the helical gear produced by grinding the helical teeth 81 of the workpiece 8 can be improved.

DESCRIPTION OF SYMBOLS 1 Rotating machine 2 Rotating device 211 Lower support part 212 Upper support part 3 Processing apparatus 4 Conveying apparatus 41 Rotating support | pillar part 42 Rotating loader part 51 Gripper 52 Dresser 55 Dress gear 6 Work support jig 61 Lower jig part 62 Upper jig part 7 Rotating grinding wheel 71 Grinding teeth 711 Tooth surface 712 Tooth base 713 Tooth surface 8 Workpiece

One aspect of the present invention is a rotating device that supports and rotates a workpiece on which helical teeth are formed, and a processing device that grinds the helical teeth of the workpiece rotated by the rotating device with grinding teeth of a rotating grindstone. In a rotary processing machine comprising: a conveying device that carries the workpiece into and out of the rotating device,
The conveying device has a gripper capable of sandwiching the workpiece and a dresser for forming the tip surface of the grinding tooth around the turning center axis, and is turned around the turning center axis. The gripper is made to approach the rotating device, and the dresser is made to approach the processing device, and a dress gear for forming a tooth surface of the grinding tooth is sandwiched between the gripper. It is configured to be mounted on the rotating device,
The rotation is characterized in that the dressing gear mounted on the rotating device forms the tooth surface of the grinding tooth, and the dresser close to the processing device forms the tooth tip surface of the grinding tooth. In the processing machine.

Claims (4)

A rotating device that supports and rotates a workpiece on which helical teeth are formed, a processing device that grinds the helical teeth of the workpiece rotated by the rotating device with a grinding tooth of a rotating grindstone, and the above-described rotating device In a rotary processing machine provided with a transfer device that carries in and out a workpiece,
The conveying device has a gripper for sandwiching the workpiece and a dresser for forming the grinding teeth around the turning center axis, respectively, and swivels around the turning center axis. A gripper is made to approach the rotating device, and the dresser is made to approach the processing device, and a dress gear for forming the grinding teeth is sandwiched between the grippers and attached to the rotating device. Has been
A rotary processing machine configured to form a tooth surface of the grinding tooth by the dress gear and to form a tooth tip surface of the grinding tooth by the dresser. The conveying device is configured by turning a turning loader portion on a turning column portion through which the turning center axis passes,
A plurality of grippers are provided in the swivel loader portion, and the plurality of grippers are arranged so as to be movable in the vertical direction, and the workpiece or the dress gear is provided by a pair of clamping portions that open and close in the horizontal direction. The rotary processing machine according to claim 1, wherein the rotary processing machine is configured to sandwich the workpiece. The rotating device is configured to support the workpiece up and down via a workpiece support jig,
The work support jig has an upper jig part to be attached to an upper support part in the rotating device, and a lower jig part to be attached to a lower support part in the rotating device,
3. The gripper according to claim 1, wherein the gripper is configured to sandwich the lower jig part in a state where the upper jig part is placed, in addition to sandwiching the workpiece. Rotary machine.   The dress gear is configured to be supported by the upper support portion and the lower support portion of the rotating device, also using the work support jig having the upper jig portion and the lower jig portion. The rotary machine according to claim 3.

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