This application is a 371 application of the international PCT application serial no. PCT/JP2014/069497, filed on Jul. 23, 2014, which claims the priority benefit of Japan application no. 2013-153029, filed on Jul. 23, 2013. The entirety of each of the above-mentioned patent applications is hereby incorporated by reference herein and made a part of this specification.
The present invention relates to a rolling machine and a method of rolling a gear using the rolling machine. More specifically, the present invention relates to a rolling machine that enables various components to be manufactured by rolling and a rolling machine that corrects a tooth trace and the like of the gear with the rolling machine and a method of rolling a gear using the rolling machine.
In general, in gear machining by a machine tool, after machining by cutting, grinding, and the like, a pitch error, a tooth shape error, a tooth trace (a crossing line of a tooth surface and a pitch surface) error, and the like of the gear are measured by a gear measuring device, an error due to the machine tool or a tool is found by data of the measurement, and the machine tool or the tool is correctly adjusted. Usually, when a gear is molded through rolling by a round die, after trial rolling, the rolled gear is measured by a gear measuring device, the round die is redesigned and reground according to an error obtained by the measurement, and a desired tooth shape of the gear is obtained with high accuracy.
There are various profile deviations of gears. Helix deviations are specified by the Japan Industrial Standard (JIS) as well. By measuring helix deviations in the gear measuring device, for example, in the case of a spur gear, it is possible to measure an error of formation of a lead inclining with respect to a spur gear center axis by a helix, an error of tapering of the helix, and the like. With the gear measuring device, it is also possible to measure a shape of a crowning in which both ends of the spur gear are formed as slight curved surfaces to be thinned. To correct these errors and the like, clamp bolts for fixing a supporting table, a turning table, and the like, which support the round die, are loosened, an angle is adjusted by an angle adjustment screw, and turning angles and positions of the supporting table, the turning table, and the like are adjusted in order to adjust a turning angle on an inclined shaft (an A shaft) turned around a pushing-in direction (an X axis) for pushing in the round die and a turning angle on a taper shaft (a B shaft) turned around a Y axis. That is, an operator alternately repeats work for adjusting an attachment angle, a position, and the like of the round die and performing trial turning again to modify a desired helix.
When the turning angles are adjusted, since the turning angles are very small angles and the mass of the supporting table is large and a frictional force is also large, as adjustment for moving the supporting table, fine adjustment is difficult because a load of the supporting table is large and the supporting table easily bends. The adjustment needs to be performed by operating a clamp bolt, an angle adjustment screw, a position adjustment screw, and the like with a technique and a skill of a skilled person. The accurate angle adjustment and position adjustment are not easy for a non-skilled person. Conversely, it is also likely that an error is caused because the inclined shaft (the A shaft) and the taper shaft (the B shaft) can be moved and adjusted. There is a demand for development of a rolling machine that can facilitate adjustment of the inclined shaft (the A shaft) and the taper shaft (the B shaft) and can perform adjustment of a helix, a profile, and the like actively making use of an adjustment function. On the other hand, the applicant proposed a structure including four columnar guide surfaces in a guiding section (a guide section) in order to avoid, as much as possible, deformation of a machine body during rolling by a round die to which a high load is applied (see Patent Literature 1). In general, in a rolling machine by a round die, to avoid deformation of a supporting table that supports the round die, a bar material for deformation prevention called stay bolt is laid over in an upper part between left and right supporting tables.
The four guiding sections of the rolling machine or a stay bolt structure has a drawback in that a raw material, which is a workpiece to be rolled, is prevented from being carried in/out because the guiding sections or the stay bolt becomes an obstacle. However, for the rolling machine for the gear, it is undesirable to remove the guiding sections or the stay bolt to reduce the rigidity of the machine body. Further, these rolling machines are not always optimum as the rolling machine for the gear. That is, these rolling machines have an angle adjusting function in the taper shaft (the B shaft) direction important for the rolling of the gear but are manually adjusted and do not have an automatic adjustment function. In the machining of the gear by the rolling machine in the past, a tooth surface and the like of the gear to be rolled are different in a position in an axial direction. Therefore, in order to correct the difference, there has been proposed a method of adjusting a shape error of the tooth surface in the axial direction by regularly and reversely rotating the round die (see Patent Literature 2). This method has a drawback in that a machining time is long because the round die is reversely rotated. The method equalizes the shape error in the axial direction and cannot perform fine adjustment.
[PTL 1] Japanese Patent Application Laid-Open No. H11-285765
[PTL 2] WO2003/000442 A1
The present invention has been devised in view of the circumstances in the past and attains objects described below.
It is an object of the present invention to provide a rolling machine that can adjust, with a control motor mechanism, a turning angle on an inclined shaft (an A shaft) turned around a push-in direction (an X axis) of a round die and a turning angle on a taper shaft (a B shaft) turned around a Y axis.
It is another object of the present invention to set a position of a guide surface high and provide a rolling machine having high rigidity.
It is still another object of the present invention to provide a method of rolling a gear using, in order to correct a helix deviations, a profile deviation, and the like of the gear, a rolling machine that can adjust a turning angle on an inclined shaft (an A shaft) turned around a push-in direction (an X axis) of a round die and a turning angle on a taper shaft (a B shaft) turned around a Y axis.
In order to solve the problems, the prevent invention adopts means described below.
A rolling machine according to the present invention 1 is a rolling machine including: a plurality of cylindrical round dies disposed centering on a raw material, which is a workpiece, to roll the raw material from the outer circumference of the raw material; die-rotation driving means for driving to rotate the round dies; raw material supporting means for rotatably supporting the raw material; and push-in means for bringing the round dies close to each other from the outer circumference toward the raw material and pushing in the round dies while rotating the round dies in the same direction in synchronization with each other, the rolling machine further including: a B-shaft swinging table that swings on a taper shaft (a B shaft) turning around a Y axis orthogonal to a push-in direction (an X axis) of the round dies; a die table that swings on an inclined shaft (an A shaft) turning around the push-in direction (the X axis) of the round dies on the B-shaft swinging table; taper-shaft adjusting means for adjusting a swing angle of the B-shaft swinging table on the taper shaft (the B shaft); and inclined-shaft adjusting means for adjusting a swing angle of the die table on the inclined shaft (the A shaft).
In the rolling machine according to the present invention 2, in the present invention 1, one of the round dies is mounted on a fixed headstock fixed on a bed, the other of the round dies is mounted on a moving headstock that moves on the bed, and guiding means on the bed of the moving headstock is a plurality of linear guide mechanisms (7, 7, 9) having different heights in the vertical direction.
In the rolling machine according to the present invention 3, in the present invention 1 or 2, the inclined-shaft adjusting means and the taper-shaft adjusting means are means for correcting a helix and/or a profile of a gear.
In the rolling machine according to the present invention 4, in the present invention 2, the plurality of linear guide mechanisms (7, 7, 9) are disposed at an equal distance from a position of a power point in the push-in direction.
The rolling machine according to the present invention 5 includes, in the present inventions 1 to 4, work-rotation driving means for rotating the raw material in synchronization with the rotation driving of the round dies to control driving of rotation of the raw material around the axis of the raw material.
In the rolling machine according to the present invention 6, in the present inventions 1 to 4, the inclined-shaft adjusting means and/or the taper-shaft adjusting means includes a screw shaft (105) driven by a numerically rotation-angle-controllable motor (103) disposed on a fixed side, and is configured to bring a cam member (101), which operates integrally with a moving object (107, 405) movable in the axial direction according to rotation of the screw shaft (105), into contact with the die table (108) or the B-shaft swinging table (60, 801) to numerically adjust a direction of the round dies.
In the rolling machine according to the present invention 7, in the present inventions 1 to 4, the inclined-shaft adjusting means and/or the taper-shaft adjusting means includes a shaft (76, 113, 802) driven to rotate by a numerically rotation-angle-controllable motor (71, 112) disposed on a fixed side, and is configured to bring an eccentric cam member (77, 111, 804a, 804b), which operates according to the rotation driving of the shaft (76, 113, 802), into contact with a cam follower (78, 109, 806a, 806b) integral with the die table (21) or the B-shaft swinging table (60, 801) to numerically adjust a direction of the round dies.
In the rolling machine according to the present invention 8, in the present inventions 1 to 4, the inclined-shaft adjusting means and/or the taper-shaft adjusting means includes gear transmission means (304, 305, 311, 312) driven by a numerically rotation-angle-controllable motor (303, 307) disposed on a fixed side, and is configured to rotate the die table (301) or the B-shaft swinging table (60) according to a rotating motion of the gear transmission means (304, 305, 311, 312) to numerically adjust a direction of the round dies.
In the rolling machine according to the present invention 9, in the present inventions 1 to 4, the inclined-shaft adjusting means and/or the taper-shaft adjusting means includes a screw shaft (504) driven by a numerically rotation-angle-controllable motor (502) disposed on a fixed side, includes a taper member (506, 508) screwed into the screw shaft (504) and capable of advancing and retracting according to rotation of the screw shaft (504), and is configured to press the die table (507) or the B-shaft swinging table (60) according to a moving motion of the taper member (506, 508) to numerically adjust a direction of the round dies.
In the rolling machine according to the present invention 10, in the present inventions 1 to 4, the inclined-shaft adjusting means and/or the taper-shaft adjusting means includes a shaft (605, 707) driven by a numerically rotation-angle-controllable motor (603, 705) disposed on a fixed side, is provided with, in the shaft (605, 707), two eccentric members (601, 703a, 703b) coming into contact with the die table (608, 701a, 701b) and spaced apart in the axial direction, and is configured to rotate the eccentric members (601, 703a, 703b) according to rotation of the shaft (605, 707) to change an eccentric distance, and press the die table (608, 701a, 701b) or the B-shaft swinging table (60) to numerically adjust a direction of the round dies.
A method of rolling a gear by a rolling machine according to the present invention 11 is a method of rolling a gear by a rolling machine including: a plurality of cylindrical round dies disposed centering on a raw material, which is a workpiece, to roll the raw material from the outer circumference of the raw material; die-rotation driving means for driving to rotate the round dies; raw material supporting means for rotatably supporting the raw material; and push-in means for bringing the round dies close to each other toward the raw material and pushing in the round dies while rotating the round dies in the same direction in synchronization with each other, the method including: adjusting, in order to correct a helix and/or a profile of the gear, a turning angle on an inclined shaft (an A shaft) turned around a push-in direction (an X axis) of the round dies; and adjusting a turning angle on a taper shaft (a B shaft) turned around a Y axis orthogonal to the axis of the raw material.
In the method of rolling the gear by the rolling machine according to the present invention 12, in the present invention 11, the raw material is rotated in synchronization with the rotation driving of the round dies and controlled to be driven.
In the rolling machine and the method of rolling the gear using the rolling machine according to the present invention, the turning angle on the inclined shaft (the A shaft) turned around the push-in direction (the X axis), which is a direction in which the round dies are pushed in, and the turning angle on the taper shaft (the B shaft) turned around the Y axis can be adjusted by the control motor (a servo motor). Therefore, even a non-skilled person can perform fine and highly accurate adjustment. The moving headstock is guided by a plurality of guide rails having different heights. The guide rails are disposed at an equal distance from a rolling center position (a power point position). Therefore, it is possible to obtain the rolling machine having high rigidity during rolling. The rolling machine can perform fine and highly accurate angle adjustment in the inclined shaft (the A shaft) and the taper shaft (the B shaft). Therefore, the rolling machine is suitable for correcting a helix of the gear.
A rolling machine 1 according to an embodiment of the present invention is explained below with reference to the drawings.
[Moving Headstock 50]
The round die 3 is mounted on the moving headstock 50. Two linear guide rails 7 are fixedly disposed at an interval on the upper surface of the bed 2 (see
On the other hand, a rectangular sub-bed 8 is erected and disposed on a sideward side of the upper surface of the bed 2. A lower part of the sub-bed 8 is fixed by bolts or the like and provided integrally with the bed 2. The sub-bed 8 faces the side-surface guiding section 53, which configures the moving headstock 50 on the lower frame 6. On a side surface of the sub-bed 8, a linear guide rail 9 is disposed and fixed in parallel to the linear guide rails 7 on the bed 2. A slider (a movable member) 11 is provided on a side surface of the side-surface guiding section 53 and is guided by the linear guide rail 9 disposed on the sub-bed 8 to reciprocatingly move. A linear guide mechanism is configured by the linear guide rail 9 and the slider 11. The moving headstock 50 is guided by the two linear guide rails 7 disposed on the same plane and the one linear guide rail 9 disposed on a surface perpendicular to the plane.
Eventually, the moving headstock 50 is guided by three sets of linear guide mechanisms in total configured by the two linear guide rails 7 and the slider 10 on the bed 2 and the one linear guide rail 9 and the slider 11 on the sub-bed 8. This means that the moving headstock 50 is guided by two surfaces orthogonal to each other, and the moving headstock 50 has high rigidity against a rolling pressure. According to the guide by these linear guide mechanisms, the moving headstock 50 is capable of reciprocatingly moving in the X-axis direction. As shown in
Since the moving headstock 50 is guided at three points during the movement, movement in the X-axis direction is also stable. Further, on an operation side of the rolling machine 1, a linear guide mechanism for reinforcement or guide for the moving headstock 50 is absent. Therefore, there is no obstacle in carrying in/out a raw material and the like.
The bed 2, the sub-bed 8, and the X-axis driving mechanism fixing table 14 are integral and configure a machine body, which is a main body of the rolling machine 1. The machine body has high rigidity because the machine body forms a box shape with three surfaces thereof opened. Since the upper surface and the front surface are opened, the machine body does not hinder operation by an operator and does not hinder carrying-in and carrying-out of a machining raw material. A transmission 15 incorporating a gear transmission mechanism is disposed and mounted on the rear end face of the X-axis driving mechanism fixing table 14. An output shaft of the transmission 15 is coupled to the rear end of the ball screw. An input shaft of the transmission 15 is coupled to an output shaft of the X-axis control driving motor 16. These transmission driving mechanisms are publicly-known techniques and detailed explanation thereof is omitted. When the X-axis control driving motor 16 is driven to rotate, the output shaft of the transmission 15 drives the ball screw to rotate. When the ball screw is driven to rotate, rotation in a rotating direction of the ball nut 13 screwed in the ball screw is regulated. Therefore, the ball nut 13 is pushed or pulled in the X-axis direction. The moving headstock 50 is guided by the two linear guide rails 7 and the one linear guide rail 9 to be capable of reciprocatingly moving in the X-axis direction.
The round die 3 is mounted on a round die table 21 disposed on the front surface of the moving headstock 50. A rotation driving control motor 23 is mounted on a side part of the round die table 21. A reduction gear (not shown in the figure) is coupled between the rotation driving control motor 23 and a round die shaft 24. In this example, the reduction gear is incorporated in the rotation driving control motor 23. The round die shaft 24 is coupled to an output shaft of the reduction gear. The round die 3 is attached to the round die shaft 24 and fixed by a key during rolling. Both ends of the round die shaft 24 are rotatably supported on a bearing supporting table 25 and supported by a bearing disposed on the inside of the bearing supporting table 25. The bearing supporting table 25 is mounted and fixed on the round die table 21. Therefore, the round die 3 is driven to rotate on the round die table 21 by the rotation driving control motor 23 and the built-in reduction gear.
[Inclined-Shaft Adjusting Means (A Shaft) 30]
The round die table 21 is capable of turning in the push-in direction (the X axis) of the round die 3, that is, around an inclined shaft (an A shaft) shown in
Therefore, the rear surface of the round die table 21 slides to be turnable on a turning sliding surface 65 on the front surface of the moving headstock 50. The turning of the round die table 21 is driven by a desired angle amount by controlling an inclined-shaft control motor 31 which is numerically rotation-angle-controllable (see
The ball screw 36 is rotatably supported by a bearing in a bearing bracket 37. The distal end of the ball screw 36 is also rotatably supported by a bearing in a bearing bracket 39. The bearing bracket 37 is fixed to the B-shaft swinging table 60 (see
A cam follower 46 rotatably supported by a roller is inserted into the cam follower groove 44. The cam follower 46 rolls in the cam follower groove 44 (the Z-axis direction). A supporting shaft 47 of the cam follower 46 is fixed to the round die table 21 by a nut 48. As it is understood from the above explanation of the structure, the round die table 21 turns about the A shaft according to the rotation driving of the inclined-shaft control motor 31. That is, when the inclined-shaft control motor 31 is driven to rotate, the reduction gear, the timing pulley 32, the timing belt 33, the timing pulley 34, the ball-screw driving shaft 35, and the ball screw 36 are driven. According to the rotation of the ball screw 36, the ball nut 41 screwed in the ball screw 36 moves in the up-down direction (the up-down direction in
According to the up-down movement of the ball nut 41, the cam follower groove 44 also moves up and down. The cam follower 46 inserted into the cam follower groove 44 is also driven to move in the up-down direction while slightly rolling in the cam follower groove 44. The round die table 21 fixed to the cam follower 46 is turned in the A shaft according to the up-down movement of the cam follower 46. As it is understood from this explanation, the cam follower 46 can roll in the cam follower groove 44. Therefore, a radial position of the cam follower 46, that is, a radial position centering on the shaft 63 shown in
[Taper-Shaft Adjusting Means (a B Shaft) Mounted on the Moving Headstock 50]
Taper-shaft adjusting means (a B shaft) is angle adjusting means for adjusting a turning angle about a taper shaft (a B shaft) turned around a Y axis orthogonal to the push-in direction (the X-axis direction) of the round die 3 and orthogonal to the axis of a raw material to be rolled. Details of the taper-shaft adjusting means are explained below.
The upper frame 51 and the lower frame 6, which are tabular members, are disposed vertically in parallel (in the vertical direction). The side-surface guiding section 53 that couples the upper frame 51 and the lower frame 6 is disposed and fixed on side surfaces of the upper frame 51 and the lower frame 6. The slider 11 provided in the side-surface guiding section 53 is guided by the linear guide rail 9 disposed and fixed on the sub-bed 8. A ball nut receiver 54 is fixedly disposed between the upper frame 51 and the lower frame 6. The ball nut receiver 54 is a member for receiving a push-in force in the X-direction from the ball nut 41 and transmitting the push-in force to the upper frame 51 and the lower frame 6. Eventually, the upper frame 51, the lower frame 6, and the ball nut receiver 54 are an integral structure.
The B-shaft swinging table 60 is disposed between the upper frame 51 and the lower frame 6 (see
The shaft 63 explained above is rotatably supported on the front surface of the B-shaft swinging table 60 by a bearing. The center line of the shaft 63 rotates around the X axis. That is, the shaft 63 configures the A shaft. The center line of the shaft 63 substantially coincides with the center line of a ball screw that drives the X axis. Therefore, a driving force of the ball screw can be directly transmitted to the round die 3 in the X-axis direction. A bearing 64 is provided at an end portion on the front surface of the shaft 63. The bearing 64 is inserted into the rear surface of the round die table 21 and supports turning of the A shaft in a turning direction of the X axis.
[Driving Mechanism 70 for the B Shaft]
A driving mechanism 70 for the B shaft is explained.
On the other hand, as shown in
[Driving Mechanism for the Round Die 4]
The round die 4 is opposed to and symmetrically arranged with the round die 3. Functions of rotation and turning of the round die 4 are substantially the same as the functions of the round die 3. Explanation of the structure and the functions of the round die 4 is omitted. However, the fixed headstock 5 mounted with the round die 4 is fixed on the bed 2. The fixed headstock 5 in this embodiment does not move. During rolling, the moving headstock 50 mounted with the round die 3 approaches the fixed headstock 5 to thereby perform the rolling. However, the fixed headstock 5 mounted with the round die 4 may also be configured to be movable in the X-axis direction, and the fixed headstock 5 and the moving headstock 50 mounted with the round die 3 may be caused to approach each other during the rolling.
[Work Supplying/Gripping Mechanism 90]
The rolling machine 1 includes, as shown in
In the case of a long workpiece, the center of the distal end of the workpiece is supported by a center 95 of a tailstock. In rolling of a gear, rotation control of a workpiece is often not performed. Therefore, the rotation control motor 91 does not drive to control the workpiece. Instead, both ends of the workpiece are gripped by both the centers or the work piece is gripped by the collet chuck 92 and is not connected to an output shaft of the rotation control motor 91.
[Rolling of a Gear]
Rolling of a spur gear using sintered metal as a raw material by the rolling machine 1 in this embodiment is explained. A tooth shape of a gear of a sintered alloy, which is a sintered gear, is formed close to that of a final product. A plastic flow is caused only in a surface layer close to a tooth surface to roll and mold the gear. Therefore, rotation control of a work piece is not performed, and the workpiece freely rotates. Rotation driving of the round die 3 and the round die 4 and the rotation of the X-axis control driving motor 16 are simultaneously controlled. Rolling is performed according to the control. A helix deviations of a machined gear is measured. As a result, if a difference from a desired shape of the crowning is unacceptable, the inclined-shaft adjusting means (the A shaft) 30 is actuated to perform necessary fine adjustment. The inclined-shaft control motor 31 is driven to rotate and the round die table 21 is turned in the A shaft to correct the crowing.
In the case of the helix deviations, similarly, the inclined-shaft control motor 31 is driven to rotate and the round die table 21 is turned in the A shaft to correct the helix deviations. In the case of an error in which the helix is tapered, the B-shaft control motor 71 is driven and the B-shaft swinging table 60 is turned about the shaft 61 to correct the round die 3 and the round die 4 in the B shaft. The configuration, in which an angle of the helix of the gear to be machined is corrected by automatically changing the directions of the dies of the A shaft and the B shaft by controlling to drive the control motor, has been explained hereinabove.
[Example of Helix Data]
It goes without saying that the configuration of the present invention is not limited to the embodiment explained above and may be other configurations. A plurality of examples are explained below concerning other embodiments. Since the A shaft and the B shaft are common in that both the shafts change the directions of round dies 3 and 4 (hereinafter referred to as dies) and change angles of the dies, the configuration applied to the A shaft is explained below. Therefore, since this configuration can also be applied to the B shaft, explanation of the B shaft is omitted.
All of configuration diagrams of figures referred to below are explanatory diagrams shown as partial diagrams of a portion where an angle is changed. In the explanation of the configuration, a supporting structure to which the dies can be attached to be turned is explained as a “die table” (in the embodiment explained above, equivalent to the round die table) and a supporting structure that supports the die table on the fixed side is explained as a “fixed table” (in the embodiment explained above, equivalent to the B-shaft swinging table). Both of motors for driving are numerically rotation-angle-controllable motors and are provided with reduction gears.
On the other hand, in the die table 108, a cam follower groove section 109, which is a groove formed in a forked shape, is provided. The cam follower 101 is inserted into and engaged with the cam follower groove section 109. When the nut body 107 is driven by the motor 103 and moves, the cam follower 101 integral with the nut body 107 drives the cam follower groove section 109. Since the cam follower groove section 109 is integral with the die table 108, the movement of the cam follower groove section 109 is a swinging motion about an A point. According to the swinging motion, the round die 3 is turned around the A point by a small angle in a direction indicated by an arrow. The motor 103 has a function of controlling a desired rotation angle according to numerical control and performing rotation driving and rotates the ball screw 105 via the reduction gear 104.
In this way, a die 110 can change a setting angle in a range of a small angle that should be corrected according to the control by the motor 103. The die 110 is adapted to tooth trace correction machining of a gear according to the position change at the very small angle. The configuration of this example is similar to the configuration of the embodiment explained above. However, the configuration of this example is different from the configuration explained above in that the cam follower 101 is integral with the nut body 107 side and the cam follower groove section 109 is provided in the die table 108. The configuration of the embodiment partially shown in
In this embodiment, as shown in
In this configuration, as shown in
This gear mechanism may be a worn/worn wheel configuration shown in
In this configuration, as shown in
The nut body 405 moving in the axial direction meshes with the ball screw 403. The cam follower 406 is fixed to the nut body 405. The cam follower 406 is movably engaged with the cam follower groove member 407 integrally provided on the die table 408. In this configuration, two driving devices are disposed in parallel across an A point of a die 410. In this configuration, when the die table 408 is swung by a small angle as explained above, two motors 402 are synchronized and controlled to rotate in opposite directions to each other, whereby angle control is performed.
Since the control of the two motors can be individually performed, different kinds of control can be respectively performed for the two motors. Therefore, since play (backlash) can be prevented, it is possible to prevent a slight shift of a helix due to vibration or the like by maintaining a lock state. When the motors 402 are controlled to rotate in the same direction, it is possible to forcibly shift the A point position of the die 410 (see X in
This configuration is a wedge structure as shown in
The male engaging body 506 fits in the female engaging body 508 and is capable of moving relative to each other along the taper shape via a slipping motion according to mutual contact of taper parts 506a and 508a. The male engaging body 506 moves together with a motion of the nut body 505 according to the rotation of the motor 502. Since engaging sections are tapered, the female engaging body 508 moves back and forth in a direction indicated by an arrow in a direction perpendicular to a moving direction of the nut body 505. Consequently, the die table 507 integral with the female engaging body 508 swings a small angle about a die A point as indicated by an arrow.
The engaging sections of the male engaging body 506 and the female engaging body 508 have different moving forms, that is, one linearly moves and the other turns, according to a positional shift in a taper direction. Therefore, according to a change in a position in the taper direction, a positional shift in a turning direction occurs simultaneously. Relief for facilitating the movement is required in design. The shape of the male engaging body 506 in this example is a round shape in section. However, the male engaging body 506 is not limited to this shape. Although not shown in the figure, in order to ensure this wedge effect, this wedge device may be provided to be spaced apart in a symmetrical position across the A point. In this case, a pressing direction of the male engaging body 506 against the female engaging body 508 is fixed to prevent backlash. In this case, the configuration is performed only in the pressing direction, and is therefore simplified.
In this configuration, two eccentric cams 601 are applied. A configuration shown in
In the driving shaft 605 from the motor 603, the two circular eccentric cams 601 are provided to be spaced apart from each other. The two circular eccentric cams 601 integrally rotate in the same direction. On the other hand, on a die table 608, a contact surface 609 with which the two circular eccentric cams 601 are in contact is provided. The two circular eccentric cams 601 are always in contact with the contact surface 609. The two circular eccentric cams 601 are fixed to the driving shaft 605 with the directions thereof shifted 180 degrees in the radial direction from each other.
In
The cam members 703a and 703b having the same shape are disposed with the positions thereof shifted 180 degrees. Like the fixed table explained above, a numerically rotation-angle-controllable motor 705 is attached to a fixed table 704 via a reduction gear 706. A driving shaft 707 from the motor 705 is rotatably supported by a bearing 708. The two cam members 703a and 703b are fixed to be spaced apart with directions thereof turned 180 degrees.
On the other hand, the die tables 701a and 701b have contact surfaces 709a and 709b with which the cam members 703a and 703b are respectively in contact. The die tables 701a and 701b always maintain a contact state. According to the rotation of the cam members 703a and 703b, the die tables 701a and 701b symmetrically swing and incline. The configuration in
Therefore, the two dies 702a and 702b respectively incline a small angle in a direction of an arrow with the A points as fulcrums with respect to parallel die positions indicated by alternate long and two short dashes lines. In the inclination, as explained above, a difference in the turning of the dies 702a and 702b is a difference S4−S3 between the major axis sections and the minor axis sections.
A configuration in another embodiment 7 is a modification of the driving mechanism of the B shaft shown in
The B-shaft swinging table 801 is provided to be capable of turning about the shaft 61 (the B shaft). A shaft body 802 is rotatably provided piercing through the center portion of the B-shaft swinging table 801. One end portion of the shaft body 802 is coupled to the motor 71, which can be numerically rotation-angle-controlled, via a reduction gear 75. Both end portions of the shaft body 802 are supported by a frame via bearings 803. Two eccentric cams 804a and 804b are integrally fixed to both the end portions of the shaft body 802 in the same configuration via keys 805. Since the eccentric cams 804a and 804b involve wear, a material having high hardness compared with the other members is used.
On the other hand, in the B-shaft swinging table 801, two contact members 806a and 806b are provided to be opposed to each other and to be opposed to the eccentric cams 804a and 804b. Like the eccentric cams 804a and 804b, the contact members 806a and 806b are formed of a material having high hardness that can withstand wear. Both of the contact members 806a and 806b are fixed to the B-shaft swinging table 801 by bolts, and one contact member 806b is formed in a wedge configuration for performing interval adjustment.
That is, as shown in the figure, one contact member 806b, which is a wedge member, is inserted and pulled out in a direction of an arrow by a pushing and pulling member 807, whereby the interval between the two contact members 806a and 806b is adjusted according to the diameter of the circular eccentric cams 804a and 804b. When the shaft body 802 is rotated a small angle by the motor 71 via the reduction gear 74, the eccentric cams 804a and 804b change, while integrally rotating, eccentric positions according to the rotation and press the contact members 806a and 806b.
According to the pressing, the B-shaft swinging table 801 turns in a direction of an arrow with the B shaft as a fulcrum. According to the turning, it is possible to adjust the B-shaft swinging table 801 a small angle about the B shaft. In this example, liners 808 are provided on side surfaces of the contact members 806a and 806b to prevent a burr involved in a relative motion from occurring. In this example, the two eccentric cams 804a and 804b are provided on both sides of the shaft body 802. However, one eccentric cam may be provided in the center portion of the shaft body 802. In this example, since such a configuration by the eccentric cams 804a and 804b is adopted, in the motions of the eccentric cams 804 and 804b, stable turning without backlash can be performed. As a result, it is possible to accurately perform control of a turning angle of the B shaft.
In this way, as a matter common to all the embodiments explained above, the numerically rotation-angle-controllable motor is applied. Therefore, as change amounts caused by associated motions involved in the rotation of the motor, all positions and angles of the motor can be numerically grasped by calculation. Therefore, turning angles of the A shaft and the B shaft can be automatically controlled at an accurately digitized angle even if the turning angle is a small angle.
Number | Date | Country | Kind |
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2013-153029 | Jul 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2014/069497 | 7/23/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/012330 | 1/29/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4950112 | Huber | Aug 1990 | A |
20010039820 | Shinbutsu | Nov 2001 | A1 |
Number | Date | Country |
---|---|---|
88100946 | Dec 1986 | CN |
S47-33048 | Nov 1972 | JP |
S48-38544 | Nov 1973 | JP |
S49-25551 | Jul 1974 | JP |
55-131430 | Oct 1980 | JP |
59-85338 | May 1984 | JP |
S60-71115 | Apr 1985 | JP |
H02-66916 | Mar 1990 | JP |
03-140659 | Jun 1991 | JP |
11-285765 | Oct 1999 | JP |
2000-018362 | Jan 2000 | JP |
2005-028365 | Feb 2005 | JP |
2013-510001 | Mar 2013 | JP |
03000442 | Jan 2003 | WO |
Entry |
---|
“International Search Report (Form PCT/ISA/210)”, mailed on Sep. 22, 2014, pp. 1-5, in which seven of the listed references (JP11-285765, JP59-85338, JP2005-028365, JP2000-018362, JP03-140659, JP55-131430 and JP2013-510001) were cited. |
“Office Action of China Counterpart Application”, issued on Sep. 29, 2016, p. 1-p. 6, in which the listed reference was cited. |
Number | Date | Country | |
---|---|---|---|
20160175916 A1 | Jun 2016 | US |