JP2018155276A - Rotary device, work machine and manufacturing method of machined workpiece - Google Patents

Abstract

A cam device having a structure for transmitting rotation of a roller gear cam having a ball-screw structure to rotation of a turret having a plurality of cam followers arranged on a circumference, in which generation of vibration can be suppressed even when a large load is applied. is to be A rotating device according to an embodiment has a motor, a first roller gear cam, a turret, and a second roller gear cam. A first roller gear cam is rotated by the motor and has a first tapered rib. The outer periphery of the turret is provided with a plurality of cam followers that sequentially engage with the first tapered rib by rotation of the first roller gear cam. The second roller gear cam has a second tapered rib, and suppresses at least vibration of the turret by sequentially engaging the plurality of cam followers provided on the turret with the second tapered rib to rotate. [Selection diagram] Fig. 1

Description

  Embodiments described herein relate generally to a rotating device, a machine tool, and a machined product manufacturing method.

  2. Description of the Related Art Conventionally, a rotating device with a roller having a structure that prevents backlash from occurring is known as a rotating device that converts rotation of an output shaft of a motor into rotation of a rotating body having a different rotation direction (for example, Patent Document 1). Thru | or patent document 5).

  This roller-equipped rotating device is commercially available under the trade name Roller Drive (registered trademark), and is mounted on the rotating body with a cylindrical rotating body in which a plurality of rollers are mounted on the circumference instead of the gear teeth. It is composed of a ball screw that meshes with some of the rollers. In particular, the ball screw has a special structure in which a crest formed on the ball screw meshes with a gap between adjacent rollers and always contacts two or more rollers. Therefore, even if the rotation direction of the ball screw is reversed, the rotation direction of the rotating body can be changed in the reverse direction without causing backlash.

  A ball screw that constitutes a rotating device with a roller is also called a roller gear cam because it engages with a plurality of rollers arranged like a gear and its rotational phase is displaced, and the peak of the ball screw is also called a taper rib in accordance with the taper shape. The On the other hand, each roller engaged with the taper rib of the roller gear cam functions as a cam follower (cam follower) of the roller gear cam. A rotating device in which the roller gear cam is engaged with a turret having a plurality of cam followers arranged on the circumference is also called a cam device.

  As described above, in the cam device having the structure for transmitting the rotation of the roller gear cam having the ball screw-like structure to the rotation of the turret having a plurality of cam followers arranged on the circumference, backlash can be avoided. For this reason, it has been proposed to use the cam device as a rotation mechanism or a speed reducer for an inclined table of a machine tool. In particular, when a cam device is used as a speed reducer for a printing apparatus that requires constant speed, two roller gear cams are provided so that the phase of the taper rib that engages with the cam follower is shifted by 180 degrees. Techniques have been devised to prevent fluctuations.

JP 2005-138275 A JP 2011-147260 A JP 2012-157554 A JP 2012-161200 A JP 2014-224548 A

  However, even when the cam device described above is used as a rotating mechanism for a tilting table or a rotating table of a machine tool, especially when machining a material with high strength such as metal parts such as metal titanium or when performing high-speed cutting Has a problem that vibration that cannot be ignored occurs. The occurrence of vibrations in machine tools leads to tool breakage and machining accuracy degradation.

  Therefore, the present invention provides a cam device having a structure for transmitting the rotation of a roller gear cam having a ball screw-like structure to the rotation of a turret having a plurality of cam followers arranged on the circumference, and generates vibration even when a large load is applied. It aims to be able to suppress.

  Another object of the present invention is to further improve the quality of machine machine parts when performing high-speed cutting or machining difficult-to-cut materials.

  The rotating device according to the embodiment of the present invention includes a motor, a first roller gear cam, a turret, and a second roller gear cam. The first roller gear cam is rotated by the motor and has a first tapered rib. A plurality of cam followers that are sequentially engaged with the first taper ribs by rotation of the first roller gear cam are provided on the outer periphery of the turret. The second roller gear cam has a second taper rib, and suppresses at least vibration of the turret by rotating the plurality of cam followers provided in the turret and the second taper rib sequentially engaged with each other.

  The machine tool according to the embodiment of the present invention uses the above-described rotating device as at least one rotating mechanism on the spindle side for holding a tool and on the table side for setting a workpiece.

  Moreover, the manufacturing method of the machined goods which concerns on embodiment of this invention manufactures a machined goods by performing the machining of a metal material using the machine tool mentioned above.

The block diagram of the rotation apparatus which concerns on the 1st Embodiment of this invention. The figure which shows the example which used the rotation apparatus as a rotation mechanism for inclining the main spindle side of a machine tool. The block diagram of the rotation apparatus which concerns on the 2nd Embodiment of this invention. The block diagram of the rotation apparatus which concerns on the 3rd Embodiment of this invention. The block diagram of the rotation apparatus which concerns on the 4th Embodiment of this invention.

  A manufacturing method of a rotating device, a machine tool, and a machined product according to an embodiment of the present invention will be described with reference to the accompanying drawings.

(First embodiment)
(Configuration and function)
FIG. 1 is a configuration diagram of a rotating device according to the first embodiment of the present invention.

  The rotating device 1 is a device that changes the direction of rotational movement. Therefore, it can also be said that the rotating device 1 is a cam device. The rotating device 1 can be used, for example, as a rotating mechanism for constituting a main shaft of a machine tool, an inclination driving shaft of a table, or a rotating driving shaft.

  The rotating device 1 includes a motor 2, a first roller gear cam 3, a turret 4, and a second roller gear cam 5. The first roller gear cam 3 has a structure in which a first taper rib 3B is provided spirally on the rotary shaft 3A. The first taper rib 3B is a spiral rib that tapers toward the tip. The second roller gear cam 5 also has a structure in which a second tapered rib 5B is provided on the rotating shaft 5A in a spiral shape. The second taper rib 5B is also a spiral rib that tapers toward the tip. The turret 4 is an annular, columnar, or disk-shaped rotating body. A plurality of cam followers 6 are rotatably mounted on the circumference of the turret 4 at equal intervals.

  The motor 2 is a motor that can change the rotation direction of the output shaft. That is, the rotation direction of the motor 2 can be reversed. The motor 2 is a power source that applies torque to the first roller gear cam 3. Accordingly, the output shaft of the motor 2 is connected to one end of the rotating shaft 3 </ b> A constituting the first roller gear cam 3.

  Both ends of the rotating shaft 3A constituting the first roller gear cam 3 are rotatably held by cylindrical first holding portions 7 each having a bearing 7A. The first holding part 7 on the motor 2 side is fixed to a casing which is a non-rotating part of the motor 2. Therefore, the first roller gear cam 3 is rotated by the motor 2 in a state where both ends are rotatably held by the two first holding portions 7. Accordingly, the rotation shaft 3A of the first roller gear cam 3 serves as an input shaft for the rotation motion. Further, the rotation direction of the first roller gear cam 3 can be changed by changing the rotation direction of the motor 2.

  The output shaft of the motor 2 may be transmitted directly from the output shaft of the motor 2 to the rotary shaft 3A via a gear, a rotary belt, or the like without being directly connected to the rotary shaft 3A.

  The plurality of cam followers 6 provided on the outer periphery of the turret 4 are arranged so as to sequentially engage with the first taper rib 3 </ b> B by the rotation of the first roller gear cam 3. Therefore, the rotation axis of the turret 4 and the rotation axis of the rotation shaft 3A constituting the first roller gear cam 3 are in a torsional relationship, and the rotation axis of each cam follower 6 and the rotation axis of the rotation shaft 3A are on the same plane. Thus, the turret 4 and the first roller gear cam 3 are arranged.

  Further, the first taper rib 3B of the first roller gear cam 3 can move the cam follower 6 in the rotation direction of the turret 4 while fitting the gap between the adjacent cam followers 6 when the rotary shaft 3A is rotated. It is designed in such a shape. For example, the shape of the first taper rib 3 </ b> B is designed so that the height of the first taper rib 3 </ b> B changes along the arcuate outer peripheral surface of the turret 4. Further, the shape of the rotary shaft 3A is designed so that the thickness of the rotary shaft 3A between the first tapered ribs 3B changes along the arc-shaped locus of the cam follower 6 in general.

  In the example shown in FIG. 1, the first taper rib 3 </ b> B is designed to simultaneously fit into a plurality of gaps formed between a plurality of continuous cam followers 6. For this reason, pressure can be simultaneously applied to the plurality of cam followers 6 from the first tapered rib 3B. As a result, it is possible to eliminate backlash between the first roller gear cam 3 and the turret 4 provided with a plurality of cam followers 6 in a gear shape.

  Each cam follower 6 is a roller that moves in the rotational direction of the turret 4 while rolling in contact with the first tapered rib 3B of the first roller gear cam 3. Therefore, when the first roller gear cam 3 is rotated, the rotational motion is transmitted from the first roller gear cam 3 to the turret 4 by the engagement of the first taper rib 3 </ b> B and each cam follower 6. That is, the rotational motion of the first roller gear cam 3 can be converted into the rotational motion of the turret 4. For this reason, the turret 4 becomes an output shaft of the rotational motion.

  The rotation direction of the turret 4 can be changed by changing the rotation direction of the motor 2 and the first roller gear cam 3. That is, by controlling the rotation direction of the motor 2, the turret 4 serving as the output shaft of the rotational motion can be rotated in both directions.

  In addition, when the turret 4 is circular as illustrated in FIG. 1, a rotating shaft may be provided as a rotating shaft. In that case, the rotating shaft that rotates together with the turret 4 becomes the output shaft of the rotating motion.

  A cam device comprising a first roller gear cam 3 on the input side of the rotary motion provided with the first taper rib 3B and a turret 4 on the output side of the rotary motion provided with a plurality of cam followers 6 on the outer periphery is a roller drive (registered trademark). ). Unlike the conventional gear, the rotating device 1 composed of the first roller gear cam 3 and the turret 4 having a plurality of cam followers 6 provided on the outer periphery can eliminate backlash. For this reason, it can be used as a rotational drive mechanism of a machine tool that requires positioning accuracy.

  However, if a large load is applied to the turret 4 side that is the output side of the rotational motion, vibrations that cannot be ignored are generated in the turret 4. In particular, when machining difficult-to-cut materials such as metal titanium and titanium alloys using machine tools, or when performing high-speed cutting of metal parts, the spindle side of the machine tool and the table side for setting workpieces A large cutting force is applied. For this reason, when machining difficult-to-cut materials or when performing high-speed cutting, it is a problem to suppress vibration.

  Therefore, the rotating device 1 includes at least a second roller gear cam 5 for suppressing vibration of the turret 4. The structure of the second roller gear cam 5 is also designed to rotate by sequentially engaging a plurality of cam followers 6 provided on the turret 4 and the second taper rib 5B.

  Therefore, from the viewpoint of sharing parts, the structure of the second roller gear cam 5 can be the same as the structure of the first roller gear cam 3 as illustrated in FIG. On the other hand, in the second roller gear cam 5 for damping, the number of the plurality of cam followers 6 that are in contact with the second taper rib 5B is less than the number of the plurality of cam followers 6 in contact with the first taper rib 3B. The shapes of the second tapered rib 5B and the rotating shaft 5A may be determined so as to be. Therefore, the length and thickness of the second roller gear cam 5 may be designed to be different from the length and thickness of the first roller gear cam 3.

  Further, from the viewpoint of facilitating the design, as illustrated in FIG. 1, the rotation shaft of the first roller gear cam 3 and the rotation shaft of the second roller gear cam 5 are parallel to each other, and the rotation of the first roller gear cam 3 is performed. The first roller gear cam 3, the turret 4, and the second roller gear cam 5 can be arranged so that the plane including the shaft and the rotation axis of the second roller gear cam 5 is perpendicular to the rotation axis of the turret 4.

  However, for reasons such as avoiding interference with other parts, the first roller gear cam 3 and the second roller gear 3 are arranged so that the rotation shaft of the first roller gear cam 3 and the rotation shaft of the second roller gear cam 5 are not parallel to each other. A roller gear cam 5 may be arranged. In addition to the second roller gear cam 5, a roller gear cam for suppressing vibration may be provided. Hereinafter, a case where the roller gear cam for suppressing vibration is only the second roller gear cam 5 will be described as an example.

  Both ends of the rotating shaft 5A constituting the second roller gear cam 5 are rotatably held by a cylindrical second holding portion 8 having a bearing 8A, similarly to the first roller gear cam 3. However, unlike the first roller gear cam 3, a motor for rotating the second roller gear cam 5 is not provided. That is, one of the two first holding portions 7 that rotatably holds the rotating shaft 3A of the first roller gear cam 3 at both ends is fixed to the wall surface via the motor 2, and the other is fixed to the wall surface not via the motor. On the other hand, both the two second holding portions 8 that hold the rotary shaft 5A of the second roller gear cam 5 rotatably at both ends are fixed to the wall surface without a motor.

  Therefore, the second roller gear cam 5 rotates using the rotational movement of the turret 4 as power. That is, the second roller gear cam 5 is configured to rotate following the rotation of the turret 4 only by transmitting the rotation from the turret 4. For this reason, the power source for rotating the 2nd roller gear cam 5 is unnecessary.

  As described above, when the turret 4 is sandwiched between the first roller gear cam 3 and the second roller gear cam 5 in the two directions and supported in contact with each other, the rotation shaft of the turret 4 is compared with the case where the second roller gear cam 5 is not provided. Generation of the turret 4 in a direction perpendicular to the first roller gear cam 3, particularly in a direction away from the first roller gear cam 3, can be remarkably suppressed. In addition, since the second roller gear cam 5 has no power source, a reaction force in a direction opposite to the rotation direction of the turret 4 can be applied to the cam follower 6 from the second taper rib 5B of the second roller gear cam 5.

  As a result, it is possible to suppress vibrations associated with the rotational motion of the rotating device 1 including the turret 4, the first roller gear cam 3, and the second roller gear cam 5. In addition, vibration of the turret 4 can be suppressed even when the entire rotation device 1 is translated or rotated.

  For this reason, the rotating device 1 can be used for a rotating mechanism of a machine tool that is subjected to a high load. That is, it is possible to provide a machine tool that uses the rotating device 1 as at least one rotating mechanism on the spindle side for holding the tool and on the table side for setting the workpiece.

  FIG. 2 is a diagram illustrating an example in which the rotating device 1 is used as a rotating mechanism for inclining the spindle side of the machine tool.

  As shown in FIG. 2, in a machine tool 12 having a spindle 10 for holding a tool T and a table 11 for setting a workpiece, an inclination mechanism 13 for the spindle 10 is configured by two rotating devices 1. be able to. That is, the main shaft 10 can be tilted by holding the main shaft 10 so that the two rotation devices 1 can rotate from both sides. Of course, the rotating device 1 can also be used as a rotating mechanism or tilt mechanism of the table 11 and another rotating mechanism of the main shaft 10.

  As an example of a case where a particularly large load is applied to a machine tool, there is a case where machining of difficult-to-cut materials such as metal titanium or titanium alloy or a case where high-speed cutting is performed. An example of a material that is a target of high-speed cutting is an aluminum alloy. On the other hand, examples of difficult-to-cut materials include metal-based titanium and titanium alloys, and nickel-based alloys such as Inconel (registered trademark) and Hastelloy (registered trademark). Titanium metal is standardized from 1 type to 4 types according to the content of impurities such as oxygen O, nitrogen N, carbon C, iron Fe, and hydrogen H as pure titanium. On the other hand, typical titanium alloys include those called 6-4 alloy, 3-2-5 alloy, and 15-3-3-3 alloy.

  Titanium metal and titanium alloy are metals having the same strength as alloy steel such as stainless steel, and are known as difficult-to-cut materials. That is, when cutting is performed using a metal titanium or titanium alloy having a high strength as a raw material, a cutting resistance is applied as a processing reaction force to the spindle of the machine tool through the tool. For this reason, if the rigidity of the main shaft is small, vibration is generated, which leads to deterioration of processing quality.

  Therefore, as illustrated in FIG. 2, the rotation mechanism in the tilt direction of the main shaft 10 that may be subjected to a large cutting resistance from the workpiece is configured by the rotation device 1 because it can be substantially perpendicular to the tool axis. Can do. As a result, even when cutting difficult-to-cut materials such as titanium metal and titanium alloys or when cutting high-speed metal materials such as aluminum alloys, vibration is suppressed and machined products with good processing quality. Can be manufactured. In particular, a machined product can be manufactured with good quality by machining a metal material using a machine tool 12 equipped with the rotating device 1 as illustrated in FIG. That is, the quality of a machined product such as a titanium processed product can be improved.

  In the rotating device 1 as described above, the second roller gear cam 5 for vibration suppression without power is added to the cam device including the first roller gear cam 3 and the turret 4 provided with a plurality of cam followers 6 on the outer periphery. Is.

(effect)
For this reason, according to the rotating device 1, vibration of the turret 4 can be suppressed with a simple structure, and stable rotational motion can be transmitted. In addition, vibration of the turret 4 can be suppressed even when the entire rotation device 1 is translated or rotated. For this reason, if the rotating device 1 is used as a rotational drive shaft of a machine tool, high-quality machining of difficult-to-cut materials such as titanium metal and titanium alloy becomes possible by suppressing vibration. In addition, high-quality machining can be performed even when high-speed cutting of a metal such as an aluminum alloy is performed.

(Second Embodiment)
FIG. 3 is a configuration diagram of a rotating device according to the second embodiment of the present invention.

  In the rotating apparatus 1A according to the second embodiment shown in FIG. 3, the motor 20 and the motor control circuit 21 for applying torque to the second roller gear cam 5 for damping are provided in the first embodiment. This is different from the rotating device 1 in FIG. Since the other configuration and operation of the rotating device 1A in the second embodiment are not substantially different from those of the rotating device 1 in the first embodiment, the same or corresponding components are denoted by the same reference numerals and described. Omitted.

  The rotating device 1A according to the second embodiment includes a second motor as a power source for supplying power to the second roller gear cam 5 in addition to the first motor 2 as a power source for supplying power to the first roller gear cam 3. 20 is provided. That is, one end of the rotating shaft 5 </ b> A constituting the second roller gear cam 5 is connected to the output shaft of the second motor 20. The second holding portion 8 that rotatably holds one end of the rotary shaft 5A of the second roller gear cam 5 is fixed to the wall surface via the casing of the second motor 20.

  The rotation direction of the second motor 20 is controlled so as to always be the same as the rotation direction of the first roller gear cam 3. That is, the torque applied from the second motor 20 to the second roller gear cam 5 is always in the same direction as the torque applied from the first motor 2 to the first roller gear cam 3. Therefore, the first roller gear cam 3 rotates in the rotation direction of the output shaft of the first motor 2, and the second roller gear cam 5 rotates in the same rotation direction as the rotation direction of the first roller gear cam 3.

  However, a torque smaller than the torque applied to the first roller gear cam 3 from the first motor 2 is applied to the second roller gear cam 5 from the second motor 20. Accordingly, a reaction force in a direction opposite to the rotation direction of the turret 4 is applied from the second tapered rib 5 </ b> B of the second roller gear cam 5 to the cam follower 6.

  The torque applied from the second motor 20 to the second roller gear cam 5 can be adjusted by appropriately determining the output of the second motor 20. For example, a motor having a rated output smaller than the rated output of the first motor 2 can be used as the second motor 20. As a result, a constant torque smaller than the torque applied from the first motor 2 to the first roller gear cam 3 can always be applied from the second motor 20 to the second roller gear cam 5. In this case, the thickness of the rotating shaft 5A of the second roller gear cam 5 may be made thinner than the thickness of the rotating shaft 3A of the first roller gear cam 3 in accordance with the output and torque of the second motor 20.

  Alternatively, at least one of the first motor 2 and the second motor 20 can be configured by a motor capable of variably controlling the output. In this case, the torque applied to the second roller gear cam 5 from the second motor 20 can be adjusted so as to be always smaller than the torque applied to the first roller gear cam 3 from the first motor 2. Even in that case, as illustrated in FIG. 3, the thickness of the rotating shaft 5A of the second roller gear cam 5 is set to the thickness of the rotating shaft 3A of the first roller gear cam 3 in accordance with the output and torque of the second motor 20. It can be made thinner than the thickness.

  The motor control circuit 21 is a circuit that controls the first motor 2 and the second motor 20. The motor control circuit 21 can always control the rotation direction of the first motor 2 and the rotation direction of the second motor 20 in the same direction. That is, the motor control circuit 21 can synchronize the rotation direction of the first motor 2 and the rotation direction of the second motor 20.

  When the output of at least one of the first motor 2 and the second motor 20 can be variably controlled, the motor control circuit 21 variably controls the output of at least one of the first motor 2 and the second motor 20. can do. Specifically, the first motor is configured such that the torque applied from the second motor 20 to the second roller gear cam 5 is always smaller than the torque applied from the first motor 2 to the first roller gear cam 3. The output of at least one of the second and second motors 20 can be controlled.

  In addition, the ratio or difference between the torque applied from the second motor 20 to the second roller gear cam 5 and the torque applied from the first motor 2 to the first roller gear cam 3 can be adjusted. . For this reason, the magnitude of the reaction force applied to the cam follower 6 from the second tapered rib 5B of the second roller gear cam 5 can be adjusted.

  The rotating device 1 </ b> A in the second embodiment described above can apply power to the second roller gear cam 5 for vibration control. For this reason, according to the rotating device 1A in the second embodiment, in addition to the same effect as that obtained by the rotating device 1 in the first embodiment, the cam follower 6 is moved from the second roller gear cam 5 for vibration suppression. Thus, it is possible to obtain an effect that the magnitude of the reaction force applied to the turret 4 that is the output shaft of the rotary motion can be variably controlled. That is, according to the rotating device 1A in the second embodiment, it is possible to control the damping effect of the rotating device 1A by the second roller gear cam 5 for damping.

(Third embodiment)
FIG. 4 is a configuration diagram of a rotating device according to the third embodiment of the present invention.

  The rotating device 1B according to the third embodiment shown in FIG. 4 is different from the rotating device 1 according to the first embodiment in that the second roller gear cam 5 for vibration control can be loaded and slid. . Since the other configuration and operation of the rotating device 1B in the third embodiment are not substantially different from those of the rotating device 1 in the first embodiment, the same or corresponding components are denoted by the same reference numerals and described. Omitted.

  The second roller gear cam 5 of the rotating device 1B according to the third embodiment is slidably held by the slide mechanism 30. As illustrated in FIG. 4, when it is possible to slide both ends of the rotating shaft 5 </ b> A constituting the second roller gear cam 5, linear movement of a linear guide, rail, rack and pinion, etc. is performed. The slide mechanism 30 can be composed of a pair of possible machine element parts. Then, by fixing the two second holding portions 8 that rotatably hold both ends of the rotating shaft 5A to the slide mechanism 30, respectively, both ends of the rotating shaft 5A can be slidably held.

  In this case, the second roller gear cam 5 can be translated by the two slide mechanisms 30 that respectively hold both ends of the rotary shaft 5A via the second holding portion 8. Specifically, the second roller gear cam 5 can be translated in the direction in which the second roller gear cam 5 is pressed against or away from the turret 4, that is, in the radial direction of the turret 4.

  Alternatively, the two second holding portions 8 are connected by a connecting member such as a shaft, and the vicinity of the center of gravity of the connecting member is slid by a single slide mechanism 30 such as a linear guide capable of linear movement. Can also be made. Even in this case, the second roller gear cam 5 can be translated in the radial direction of the turret 4.

  On the other hand, only one end of the rotation shaft 5A constituting the second roller gear cam 5 can be slid, and the other end of the rotation shaft 5A can be held rotatably about an axis parallel to the rotation axis of the turret 4. In this case, the slide mechanism 30 can be configured by a machine element part such as a rail that can perform a curved movement along an arc and a joint that rotatably connects the machine element parts. Then, a machine element part such as a roller or a wheel that can be moved along a circular arc part such as a rail is attached to one of the two second holding parts 8 that hold both ends of the rotating shaft 5A. The other second holding portion 8 can be connected to the joint. Alternatively, one of the two second holding portions 8 that hold both ends of the rotating shaft 5A can be used as a free end without being fixed, and the other second holding portion 8 can be connected to the joint.

  Then, the second roller gear cam 5 can be rotated and moved in the direction in which the second roller gear cam 5 is pressed against the turret 4 or in the direction in which the second roller gear cam 5 is pulled away from the turret 4. That is, the second roller gear cam 5 can be rotated in a plane perpendicular to the rotation axis of the turret 4.

  In addition to the slide mechanism 30 described above, the rotation device 1B according to the third embodiment includes a load applying mechanism 31, a load control device 32, and a vibration sensor 33.

  The load applying mechanism 31 is a device that applies a load to the second roller gear cam 5 for vibration control. The load applying mechanism 31 can be configured by mechanical element parts that can move linearly with power, such as an air cylinder, a hydraulic cylinder, a ball screw, an electric cylinder, or a rack and pinion. Therefore, you may comprise the load provision mechanism 31 and the slide mechanism 30 by the common machine element components which move with motive power, such as a rack and pinion. A spring may be a component of the load applying mechanism 31.

  The position where the load is applied to the second roller gear cam 5 can be freely determined. In the example shown in FIG. 4, two air cylinders are provided as the load applying mechanism 31 so that a load can be applied to both ends of the rotating shaft 5 </ b> A constituting the second roller gear cam 5. That is, an air cylinder for applying a load to each of the two second holding portions 8 slidably held by the slide mechanism 30 such as a linear guide is provided as the load applying mechanism 31.

  Of course, when one end side of the second roller gear cam 5 is rotatably held by the joint, the load applying mechanism 31 can apply the load only to the other end side of the second roller gear cam 5. You can also. Further, when the two second holding portions 8 are connected by a connecting member such as a shaft, a load may be applied near the center of gravity of the connecting member.

  The load control device 32 is a device that variably controls the load applied to the second roller gear cam 5 by controlling the load applying mechanism 31. Therefore, the load applied from the load applying mechanism 31 to the second roller gear cam 5 can be adjusted. The load control device 32 includes a signal generation circuit that outputs a control signal such as an air pressure signal, a hydraulic pressure signal, or an electric signal to the load applying mechanism 31 according to the mechanism of the load applying mechanism 31.

  As a specific example, if the load applying mechanism 31 is an air cylinder, the expansion / contraction amount of the air cylinder can be adjusted by outputting an air pressure signal from the load control device 32 to the air cylinder. Similarly, when the load applying mechanism 31 is a hydraulic cylinder, the amount of expansion and contraction of the hydraulic cylinder can be adjusted by outputting a hydraulic signal from the load control device 32 to the hydraulic cylinder. On the other hand, if the load applying mechanism 31 is a mechanical element that is linearly driven by a motor such as a ball screw, an electric cylinder, or a rack and pinion, the load applying mechanism 31 outputs an electric signal to the load applying mechanism 31. The amount of linear movement can be adjusted.

  The vibration sensor 33 is a sensor for detecting the vibration of the object. The vibration sensor 33 is arranged so as to detect at least one vibration of the first roller gear cam 3, the second roller gear cam 5, and the turret 4. In the example shown in FIG. 4, vibration sensors 33 are attached to the respective second holding portions 8 that hold both ends of the second roller gear cam 5. Accordingly, vibrations at both ends of the rotating shaft 5A constituting the second roller gear cam 5 can be indirectly detected by the vibration sensor 33 via the second holding portion 8.

  The second roller gear cam 5 is in contact with a cam follower 6 attached to the turret 4, and the first roller gear cam 3 is in contact with the cam follower 6 attached to the turret 4. For this reason, the vibrations of the first roller gear cam 3 and the turret 4 are also propagated to the second roller gear cam 5 via the cam follower 6. Therefore, the vibrations of the first roller gear cam 3 and the turret 4 are also detected by the vibration sensor 33 indirectly because they overlap with the vibration of the second roller gear cam 5.

  Of course, the vibration sensor 33 may be directly or indirectly attached to the turret 4 or the first roller gear cam 3, and the vibration sensor 33 may mainly detect the vibration of the turret 4 or the first roller gear cam 3.

  A vibration detection signal acquired as a vibration time waveform signal or the like by the vibration sensor 33 is output to the load control device 32. Therefore, the load control device 32 can variably control the load applied from the load applying mechanism 31 to the second roller gear cam 5 based on the index value such as the maximum value of vibration detected by the vibration sensor 33. In other words, the load applied from the load applying mechanism 31 to the second roller gear cam 5 can be feedback-controlled so that the vibration index value detected by the vibration sensor 33 is equal to or less than the allowable value or less than the allowable value. Ideally, it is desirable to feedback-control the load applied from the load applying mechanism 31 to the second roller gear cam 5 so that the vibrations of the first roller gear cam 3, the second roller gear cam 5, and the turret 4 are minimized. .

  However, from the viewpoint of facilitating the load control algorithm applied from the load applying mechanism 31 to the second roller gear cam 5, the load value may be preset. That is, a load value capable of effectively suppressing vibrations can be determined in advance by a test in accordance with a load applied to the turret 4 serving as an output shaft of the rotational motion. Then, a plurality of load values can be preset according to the use of the rotating device 1B so that the user can select. In this case, the vibration sensor 33 may be omitted.

  As a specific example, if the rotating device 1B is used to configure the tilt mechanism 13 of the spindle 10 in the machine tool 12 illustrated in FIG. 2, the load is loaded according to the strength of the material to be cut. Can be preset. As a result, when machining difficult-to-cut materials such as titanium metal and titanium alloys with high mechanical strength, a large load value is set so that vibration can be further suppressed, while aluminum, magnesium, etc. When machining a material having a relatively low mechanical strength, a small load value can be set in order to reduce energy loss due to the rotation of the second roller gear cam 5.

  The rotating device 1B according to the third embodiment described above uses the slide mechanism 30 to allow the second roller gear cam 5 for vibration control to slide along the linear axis or the arc axis, while using the load applying mechanism 31. The second roller gear cam 5 can be loaded.

  For this reason, according to the rotating device 1B in the third embodiment, in addition to the same effect as that obtained by the rotating device 1 in the first embodiment, the turret is transferred from the second roller gear cam 5 to the cam follower 6 and the turret 4. The effect that the pressing force containing the component in the radial direction of 4 can be provided can be acquired. For this reason, the vibration damping effect of the rotating device 1B by the second roller gear cam 5 can be further improved.

  Moreover, the pressing force applied to the turret 4 from the second roller gear cam 5 via the cam follower 6 can be adjusted. For this reason, the vibration damping effect of the rotating device 1B by the second roller gear cam 5 can be adjusted according to the magnitude of the vibration detected by the vibration sensor 33. As a specific example, the damping effect of the rotating device 1B by the second roller gear cam 5 can be optimized by feedback control that minimizes the vibration detected by the vibration sensor 33. Alternatively, the damping effect of the rotating device 1B by the second roller gear cam 5 can be changed for each purpose.

(Fourth embodiment)
FIG. 5 is a configuration diagram of a rotating device according to the fourth embodiment of the present invention.

  In the rotating device 1C according to the fourth embodiment shown in FIG. 5, the third embodiment is that a motor 40 and a motor control circuit 41 for applying torque to the second roller gear cam 5 for damping are provided. Is different from the rotating device 1B in FIG. Since the other configuration and operation of the rotating device 1C in the fourth embodiment are not substantially different from those of the rotating device 1B in the third embodiment, the same or corresponding components are denoted by the same reference numerals and described. Omitted.

  The rotating device 1 </ b> C in the fourth embodiment includes a second motor as a power source for supplying power to the second roller gear cam 5 in addition to the first motor 2 as a power source for supplying power to the first roller gear cam 3. 40 is provided. That is, the rotating device 1C in the fourth embodiment has both the characteristics of the rotating device 1A in the second embodiment and the characteristics of the rotating device 1B in the third embodiment.

  However, in the rotating device 1C according to the fourth embodiment, unlike the rotating device 1B according to the third embodiment, the torque of the first roller gear cam 3 and the torque of the second roller gear cam 5 can be the same. For this reason, the same motor may be used as the first motor 2 and the second motor 40. Similarly, the same can be used for the first roller gear cam 3 and the second roller gear cam 5.

  Therefore, the motor control circuit 41 performs control to synchronize the rotation direction of the first motor 2 and the rotation direction of the second motor 40, and outputs at least one of the first motor 2 and the second motor 40. Is configured to control the torques of the first motor 2 and the second motor 40 to desired values. For this reason, by controlling the first motor 2 and the second motor 40 by the motor control circuit 41, the torque of the second motor 40 is made smaller than the torque of the first motor 2 as in the second embodiment. It is also possible to make the torque of the first motor 2 and the torque of the second motor 40 the same.

  If the torque of the second motor 40 is made smaller than the torque of the first motor 2, the reaction force corresponding to the difference between the torques is generated by the second roller gear cam 5 as described in the second embodiment. The cam follower 6 can be loaded from the two tapered ribs 5B. Accordingly, both the reaction force in the rotation axis direction of the second roller gear cam 5 due to the difference between the torques and the pressing force including the component in the radial direction of the turret 4 applied from the second roller gear cam 5 by the load applying mechanism 31. Can be loaded on the cam follower 6 and the turret 4.

  Conversely, if the torque of the first motor 2 and the torque of the second motor 40 are the same, the rotation of the second roller gear cam 5 loaded on the cam follower 6 from the second taper rib 5B of the second roller gear cam 5 will be described. The reaction force in the axial direction can be made substantially zero. Accordingly, the pressing force including the radial component of the turret 4 applied from the second roller gear cam 5 by the load applying mechanism 31 can be selectively applied to the cam follower 6 and the turret 4.

  Further, as illustrated in FIG. 5, the vibration detection signal acquired by the vibration sensor 33 can be output not only to the load control device 32 but also to the motor control circuit 41. Then, the motor control circuit 41 can perform feedback control on the output of at least one of the first motor 2 and the second motor 40 based on the vibration detection signal acquired by the vibration sensor 33. Therefore, the torque difference or ratio between the first motor 2 and the second motor 40 is controlled by feedback control so that the vibrations of the first roller gear cam 3, the second roller gear cam 5, and the turret 4 are minimized. Can be optimized.

  The rotating device 1C according to the fourth embodiment described above can adjust the reaction force in the rotation axis direction of the second roller gear cam 5 loaded from the second roller gear cam 5 to the cam follower 6 while adjusting the reaction force from the load applying mechanism 31 to the cam follower. 6, a pressing force including a component in the radial direction of the turret 4 can be loaded.

  For this reason, according to the rotating device 1C in the fourth embodiment, in addition to the same effect as that obtained by the rotating device 1B in the third embodiment, the second roller gear cam 5 loads the cam follower 6 on the second. It is possible to obtain an effect that the reaction force in the rotation axis direction of the second roller gear cam 5 can be adjusted. In particular, the pressing force including the radial component of the turret 4 loaded from the second roller gear cam 5 to the cam follower 6 by the load applying mechanism 31 and the second roller gear cam 5 loaded from the second roller gear cam 5 to the cam follower 6. Both reaction forces in the direction of the axis of rotation can be adjusted and optimized. Further, the reaction force in the rotation axis direction of the second roller gear cam 5 loaded from the second roller gear cam 5 to the cam follower 6 can be switched off.

  As a result, the vibration damping effect of the rotating device 1C by the second roller gear cam 5 can be further improved. Further, the vibration damping effect of the rotating device 1C by the second roller gear cam 5 can be finely controlled according to the purpose of the rotating device 1C.

(Other embodiments)
Although specific embodiments have been described above, the described embodiments are merely examples, and do not limit the scope of the invention. The novel methods and apparatus described herein can be implemented in a variety of other ways. Various omissions, substitutions, and changes can be made in the method and apparatus described herein without departing from the spirit of the invention. The appended claims and their equivalents include such various forms and modifications as are encompassed by the scope and spirit of the invention.

  For example, the rotating device can be configured by combining machine element parts in each embodiment. As a specific example, in the second embodiment, a vibration sensor 33 similar to that in the fourth embodiment is provided, and the motor control circuit 21 uses the first motor based on the vibration detection signal acquired by the vibration sensor 33. The output of at least one of the second and second motors 20 can be feedback-controlled.

1, 1A, 1B, 1C Rotating device 2 Motor 3 First roller gear cam 3A Rotating shaft 3B First taper rib 4 Turret 5 Second roller gear cam 5A Rotating shaft 5B Second taper rib 6 Cam follower 7 First holding portion 7A Bearing 8 Second holding portion 8A Bearing 10 Spindle 11 Table 12 Machine tool 13 Tilt mechanism 20 Motor 21 Motor control circuit 30 Slide mechanism 31 Load applying mechanism 32 Load control device 33 Vibration sensor 40 Motor 41 Motor control circuit T Tool

Claims (11)

A motor,
A first roller gear cam rotated by the motor and having a first tapered rib;
A turret provided on the outer periphery with a plurality of cam followers that are sequentially engaged with the first taper rib by the rotation of the first roller gear cam;
A second roller gear cam for suppressing at least vibration of the turret by rotating by sequentially engaging the plurality of cam followers provided on the turret and the second taper rib.
A rotating device.   The rotating device according to claim 1, wherein the second roller gear cam is configured to rotate only by transmission of rotation from the turret.   The rotating device according to claim 1, further comprising: a motor that applies a torque to the second roller gear cam that is smaller than a torque applied to the first roller gear cam in the same direction as a torque applied to the first roller gear cam. . A slide mechanism for slidably holding the second roller gear cam;
A load applying mechanism for applying a load to the second roller gear cam;
The rotating device according to claim 1, further comprising:   The rotating device according to claim 4, wherein the load applying mechanism is configured to apply the load by an air cylinder.   6. The rotating device according to claim 4, further comprising a load control device that variably controls the load. A vibration sensor for detecting vibration of at least one of the first roller gear cam, the second roller gear cam, and the turret;
The rotation device according to claim 6, wherein the load control device is configured to variably control the load based on an index value of vibration detected by the vibration sensor.   The rotating device according to claim 7, wherein the load control device is configured to feedback control the load so that the vibration index value is equal to or less than an allowable value or less than an allowable value.   A machine tool using the rotating device according to claim 1 as at least one rotating mechanism on a spindle side for holding a tool and a table side on which a workpiece is set.   The machine tool according to claim 9, wherein the rotating device is used as a rotating mechanism for inclining the spindle side.   The manufacturing method of the machined goods which manufactures a machined article by machining a metal material using the machine tool of Claim 9 or 10.

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