JP2008025846A - Revolving part structure of robot or the like - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a revolving part structure of a robot or the like, simple in structure and inexpensive. <P>SOLUTION: In the revolving part structure of a robot or the like, the driving turning force of a driving motor 50 is transmitted from an external gear 52 fixed to an output shaft 51 directly to an external gear 53 fixed to one specified crank pin 37a, thereby rotating the crank pin 37a of an eccentric differential speed reducer 17. As compared with the case of rotating the crank pin through a cylinder having an external gear at both ends by the rotary driving force of the motor, therefore, the external gear of the cylinder meshing with the external gear of the motor is eliminated, so that the structure is simplified and reduced in cost. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

    The present invention relates to a swivel structure of an industrial robot such as a swivel trunk, an arm joint or a machine tool, that is, a swivel structure of a robot or the like.

    As a conventional turning part structure of a robot or the like, for example, those described in Patent Document 1 and Patent Document 2 are known. Here, the former is disposed between the fixed part and the rotating part, has a hollow hole in the central part, and has two or more crank pins, and the rotational drive applied to the crank pins. An eccentric differential speed reducer that decelerates the force and transmits it to the rotating part to rotate the rotating part, a drive motor attached to the rotating part, a first external gear fixed to the output shaft of the drive motor, A second external gear that is rotatably supported by the speed reducer while maintaining a coaxial relationship with the hollow hole, and a third external gear that meshes directly with the first external gear, and a third external gear that is disposed axially away from the second external gear. A cylindrical body that has an external gear and rotates by receiving a rotational driving force from the first external gear, and is fixed to each crank pin in a state of being directly meshed with the third external gear, and the rotational driving force of the cylindrical body And a fourth external gear for transmitting the gears to the crank pins. It is intended.

The latter is arranged between the fixed part and the rotating part, has a hollow hole in the center part, and has two or more crank pins, and the rotational driving force applied to the crank pins. An eccentric differential type speed reducer that transmits the rotation to the rotating part and rotates the rotating part, a drive motor attached to the rotating part, a first external gear fixed to the output shaft of the drive motor, and the hollow A cylindrical body having a second external gear and a third external gear that are rotatably supported by the speed reducer while maintaining a coaxial relationship with the hole, and that are disposed apart from each other in the axial direction, and the first external gear and the first external gear A second external gear that meshes directly with both external gears and transmits the rotational driving force of the first external gear to the cylindrical body, and is fixed to each crank pin in direct mesh with the third external gear; 5th outside to transmit the rotational driving force of each to the crank pin And the car, but with a.
JP-A-7-108485 JP-A-7-124883

    However, in the turning structure of a robot or the like such as the former, the second external gear has a large diameter, so that there is a problem that a large noise is generated during turning. The reason for this is that the distance between the output shaft of the drive motor and the center shaft of the speed reducer must be greater than a certain value for reasons such as avoiding interference between the drive motor and the wiring or piping that passes through the hollow hole. This is because the first external gear fixed to the output shaft of the drive motor must have a small diameter in response to a request for downsizing the entire apparatus, and the second external gear inevitably has a large diameter. In order to reduce the diameter of the second external gear, it has been proposed to interpose a fourth external gear as an idle gear between the first external gear and the second external gear, as in the latter case. In this way, in order to rotate the two crank pins synchronously, the first, second, third and fourth external gears and two fifth external gears corresponding to the two crank pins, a total of six As a result, there is a problem that the structure is complicated and the manufacturing cost is high.

  An object of the present invention is to provide a turning part structure such as a robot that can effectively reduce noise during turning while being simple and inexpensive.

    Such an object is to provide a rotating part structure such as a robot provided with a speed reducer disposed between a fixed part and a rotating part and a drive motor for transmitting a rotational driving force to the speed reducer. The eccentric differential type reduction gear has a large number of pin teeth on the inner periphery, a case fixed to the fixed portion, a case accommodated in the case, The rotation includes: a pinion having external teeth that mesh with each other; a plurality of crank pins inserted into through holes formed in the pinion; and a carrier that rotatably supports the crank pin and is rotatably supported by the case. A carrier is fixed to the part, and a drive motor is attached at a predetermined distance in the radial direction from the center of the speed reducer, and the transmission member is fixed to the output shaft of the drive motor; This is achieved by a turning part structure of a robot or the like that is fixed to a specific one of the number of crank pins and that includes a second transmission member that directly transmits the rotational driving force from the first transmission member. Can do.

  When rotating the rotating part with respect to the fixed part, the drive motor is operated to rotate the output shaft and the first transmission member integrally. At this time, the second transmission member fixed to the specific one crank pin receives the rotational driving force directly from the first transmission member, and rotates the specific crank pin. As a result, the eccentric differential speed reducer decelerates the rotational driving force applied to the specific crank pin, transmits it to the rotating part, and rotates the rotating part. At this time, the rotational driving force may be transmitted from the second transmission member to a crank pin other than the specific crank pin, and the crank pin may be rotated in the same manner as the specific crank pin. Here, in order to rotate the crankpin, only the first and second transmission members are required, the structure is simplified, the manufacturing cost is reduced, and noise during turning can be effectively reduced.

  As the first and second transmission members, an external gear or a pulley around which a belt is stretched can be used.

Embodiment 1 of the present invention will be described below with reference to the drawings.
1 and 2, reference numeral 11 denotes a main body (base) of an industrial robot as a fixed portion, and a space 12 in which wiring and piping are accommodated is formed in the main body 11. A swiveling body 13 serving as a rotating portion that rotates around a vertical axis is installed above the main body 11, and a hole 14 that extends vertically is formed on the rotating shaft of the swiveling body 13.

  Reference numeral 17 denotes an eccentric differential type speed reducer disposed between the main body 11 and the swivel body 13. The speed reducer 17 has a substantially cylindrical case 19 fixed to the upper end of the main body 11. On the inner periphery of the case 19, a large number of cylindrical pin teeth 20 are provided in a state where only half are embedded in the central portion in the axial direction. These pin teeth 20 extend in the axial direction and are spaced equidistantly in the circumferential direction. Reference numeral 21 denotes two disk-shaped pinions accommodated in the case 19, and large-diameter through holes 22 are formed in the center of these pinions 21. Further, external teeth 23 having a smaller number of teeth than the pin teeth 20 of the case 19 are formed on the outer periphery of the pinions 21, and these external teeth 23 mesh with the pin teeth 20. 26 is a carrier disposed in the case 19, and this carrier 26 is disposed on one side flange 27 disposed on one side (lower side) of the pinion 21 and on the other side (upper side) of the pinion 21 in the axial direction. A plurality of axially extending flanges disposed on and fixed to the revolving body 13 and having a lower end integrally connected to the first flange 27 and an upper end detachably connected to the other flange 28 The connecting rods 29 are loosely fitted into loose fitting holes 30 formed in the pinion 21. Reference numeral 32 denotes a pair of bearings interposed between the one and other flanges 27 and 28 and the case 19, and the carrier 26 is rotatably supported by the case 19 by these bearings 32. Further, seal members 33 are interposed between the one-side and other-side flanges 27 and 28 and both ends of the case 19 in the axial direction. 37 is two or more axially extending crankshafts arranged here at equal distances in the circumferential direction, here two crankpins, each crankpin 37 having one axial end (lower end) on one side via a bearing 38 The other end of the flange 27 is rotatably supported by the other flange 28 via a bearing 39. Each crank pin 37 has two crank portions 40 that are eccentric at the center, and these crank portions 40 are inserted into through holes 41 formed in the pinion 21 with needle bearings 42 interposed therebetween. Yes. Reference numeral 43 denotes a cylindrical body. The cylindrical body 43 has one axial end portion (lower end portion) inserted and fixed in the one-side flange 27, and the axial central portion is loose in the through hole 22. Further, the other axial end portion (upper end portion) is loosely fitted in the hole 14 of the swivel body 13. Reference numeral 44 denotes a seal member interposed between the other axial end of the cylindrical body 43 and the swivel body 13. The case 19, the pinion 21, the carrier 26, the crank pin 37, and the cylindrical body 43 as a whole are arranged so that the rotational driving force applied to the crank pin 37 is decelerated and transmitted to the revolving body 13 so that the revolving body 13 is vertically The speed reducer 17 is configured to rotate around a certain axis, and the speed reducer 17 is provided with the cylindrical body 43 as described above, so that the hollow hole 45 communicating the inside of the revolving body 13 and the space 12 at the center. Is formed. The hollow holes 45 are used for passing cables, pipes, etc. here, such as cables 46.

  Reference numeral 50 denotes a drive motor (servo motor) attached to the swivel body 13, and an output shaft 51 of the drive motor 50 is arranged in the radial direction from the center of the hollow hole 45 in order to avoid interference with the cables 46. The predetermined distance is larger than the distance from the center of the hollow hole 45 to the rotating shaft of the crankpin 37. As a result, the crank pin 37 is positioned between the output shaft 51 of the drive motor 50 and the cylindrical body 43. An external gear 52 as a first transmission member is fixed to the tip of the output shaft 51, and the other axial end (upper end) of the crank pin 37 protruding from the carrier 26 of one particular crank pin 37a. An external gear 53 as a second transmission member is fixed, and the external gear 53 and the external gear 52 are directly meshed with each other. As a result, the rotational driving force of the external gear 52 is directly transmitted to the external gear 53 to first rotate the specific crank pin 37a. If the external gears 52 and 53 are directly meshed with each other in this way, the drive motor 50 can be arranged in a wide range around the crankpin 37a. A cylindrical gear 55 coaxial with the hollow hole 45 is disposed in the speed reducer 17, specifically between the external gear 53 and the cylindrical body 43, and one end (lower end) in the axial direction of the cylindrical gear 55 is The bearing 56 is rotatably supported on the other flange 28 of the speed reducer 17. Note that the other axial end portion (upper end portion) of the cylindrical gear 55 is rotatably supported by the swing body 13 via a bearing 57. The cylindrical gear 55 is directly meshed with the external gear 53. As a result, the cylindrical gear 55 is rotated by directly receiving the rotational driving force from the external gear 53. An external gear 58 that meshes directly with the cylindrical gear 55 is fixed to the other axial end (upper end) protruding from the carrier 26 of the crank pin 37b other than the specific crank pin 37a. The crank pin 37 b is rotated by directly receiving the rotational driving force from 55, and the rotational torque is distributed to the two crank pins 37. The drive motor 50 may be attached to the main body (fixed part) 11 or the fixed part of the case 19.

Next, the operation of the first embodiment of the present invention will be described.
When the swivel body 13 is swung with respect to the main body 11, the drive motor 50 is operated to rotate the output shaft 51 and the external gear 52 integrally. At this time, since the external gear 53 is directly meshed with the external gear 52, the rotational drive force is directly received from the external gear 52, and the specific crank pin 37a is first rotated. As a result, the pinion 21 rotates eccentrically (revolves) at the same rotational speed as the crank pin 37a. At this time, the external teeth 23 of the pinion 21 are smaller in number of teeth than the pin teeth 20 of the case 19 and mesh with the pin teeth 20 of the case 19, and the case 19 is fixed to the main body 11 so that the case 19 cannot rotate. Therefore, the rotational driving force applied to the specific crank pin 37 a is decelerated at a high ratio by the case 19 and the pinion 20, taken out by the carrier 26, and transmitted to the revolving body 13. As a result, the revolving structure 13 rotates at a low speed and a large torque around the vertical axis. At this time, the rotational driving force from the external gear 53 is transmitted to the crank pins 37b other than the specific crank pin 37a via the cylindrical gear 55 and the external gear 58 that are directly meshed with each other. 37b also rotates in the same manner as the specific crank pin 37a. Here, since the external gear 53 fixed to the crankpin 37a is located between the external gear 52 (the output shaft 51 of the drive motor 50) and the cylindrical gear 55, these external gears 52 and 53 and the cylindrical gear Any of the gears 55 can have a small diameter, which can effectively reduce noise during turning. Moreover, in order to rotate the two crank pins 37a and 37b described above, the four gears of the external gears 52, 53 and 58 and the cylindrical gear 55 may be used. As a result, the structure is simplified and the manufacturing is possible. Cost is also low.

    3 and 4 are views showing Embodiment 2 of the present invention. In this embodiment, the pulley 60 is used as the first transmission member fixed to the output shaft 51 of the drive motor 50, and the pulley 61 is also used as the second transmission member fixed to the specific crank pin 37a. The timing belt 62 is stretched over the belts 60 and 61 so that the rotational driving force is directly transmitted from the pulleys 60 to 61. Further, in this embodiment, an intermediate gear 63 is provided between the axial center portion of the specific crank pin 37a, more specifically, between the two crank portions 40, and between the pinion 21 and the intermediate gear 63 and the cylindrical body 43. A cylindrical gear 65 having both ends rotatably supported by the carrier 26 via a bearing 64 is provided. By directly meshing the intermediate gear 63 and the cylindrical gear 65, the rotational driving force of the pulley 61 is transmitted to the cylindrical gear 65 via a specific crank pin 37a and the intermediate gear 63. The cylindrical gear 65 is directly meshed with an external gear 66 provided at the center in the axial direction of the other crank pin 37b. As a result, the crank pin 37b has the same rotational speed in the same direction as the crank pin 37a. Rotate. Since the intermediate gear 63 is provided at the axial center of the crank pin 37a supported at both ends, noise due to meshing with the cylindrical gear 65 is reduced, and the rotational force of the crank pin 37a is reduced. Since it is merely transmitted to the crankpin 37b via the cylindrical gear 65 and the external gear 66, a narrow width is sufficient. In this embodiment, the pulleys 60 and 61, the intermediate gear 63, the cylindrical gear 65, and the five gears of the external gear 66 may be used to rotate the two crank pins 37a and 37b. As a result, the structure is simple and the production cost is low. Further, as described above, the cylindrical gear 65 is housed in the speed reducer 17, and the seal member 67 is provided between the crank pin 37 and the other flange 28, so that the oil and grease in the speed reducer 17 are sealed. Accordingly, the pulleys 60 and 61 can be used as the first and second transmission members. Other configurations and operations are the same as those in the first embodiment.

  The present invention can be applied to the industrial field of a turning unit structure such as a robot.

It is front sectional drawing which shows Example 1 of this invention. It is II sectional view taken on the line of FIG. It is front sectional drawing which shows Example 2 of this invention. It is II-II arrow sectional drawing of FIG.

Explanation of symbols

11 ... Fixed part 13 ... Rotating part
17… Eccentric differential reducer 37… Crank pin
37a ... Specific crank pin 45 ... Hollow hole
50 ... Drive motor 51 ... Output shaft
52 ... 1st transmission member 53 ... 2nd transmission member
55 ... Cylindrical gear 58 ... External gear

Claims (1)

    In a swivel structure of a robot or the like provided with a speed reducer disposed between a fixed part and a rotating part and a drive motor that transmits a rotational driving force to the speed reducer, the speed reducer includes a transmission member and an eccentric differential type speed reducer. The eccentric differential reducer has a plurality of pin teeth on the inner periphery, a case fixed to the fixed portion, and a pinion that is housed in the case and has external teeth that mesh with the pin teeth And a plurality of crank pins each inserted into a through-hole formed in the pinion, and a carrier that rotatably supports the crank pin and is rotatably supported by the case, and the carrier is fixed to the rotating portion A drive motor is mounted at a predetermined distance in the radial direction from the center of the speed reducer, and the transmission member is fixed to the output shaft of the drive motor; and a plurality of crank pins Among the fixed to a specific one crank pin, the swivel part structure such as a robot first rotational driving force from the transfer member is characterized by being composed of a second transmission member is directly transmitted.

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