Wrist driving structure for industrial robot

Abstract

A wrist driving structure for an industrial robot having: a first wrist element supported in cantilever fashion rotatably about a first axis; a second wrist element pivotally supported in cantilever fashion at a distal end side of the first wrist element with a proximal end as a supporting point about a second axis intersecting the first axis; a third wrist element supported in cantilever fashion at a distal end side of the second wrist element rotatably about a third axis intersecting the second axis; two driving motors provided in the first wrist element for driving the second wrist element and the third wrist element, respectively; and two gear sets for reducing a rotational speed of the two driving motors in predetermined reduction ratios. Each of the gear sets has a driving gear driven by one of the two driving motors and a driven ring gear which meshes with the driving gear. Two driven ring gears of the two gear sets are disposed coaxially with the second axis. Two driving gears of the two gear sets are positioned parallel to each other at both sides of the second axis.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects, features and advantages of the present invention will become more apparent by reading the following description of preferred embodiments of the invention with reference to appended drawings, in which:

FIG. 1 is a front view showing a wrist driving structure for an industrial robot according to a first embodiment of the present invention;

FIG. 2 is a plan view showing the wrist driving structure for the industrial robot of FIG. 1;

FIG. 3 is an overall view showing an example of an industrial robot;

FIG. 4 is an overall view showing another example of an industrial robot;

FIG. 5 is a front view showing a wrist driving structure for an industrial robot according to a second embodiment of the present invention;

FIG. 6 is a plan view showing the wrist driving structure for the industrial robot of FIG. 5;

FIG. 7 is a front view showing a wrist driving structure for an industrial robot according to a third embodiment of the present invention; and

FIG. 8 is a plan view showing the wrist driving structure for the industrial robot of FIG. 7.

DETAILED DESCRIPTION

The present invention will be described in detail below with reference to the drawings showing specific examples of embodiments. FIGS. 1 and 2 are views showing a wrist driving structure according to a first embodiment of the present invention. FIGS. 3 and 4 are overall views showing examples of an industrial robot to which a wrist driving structure of the present invention can be applied.

As shown in FIGS. 3 and 4, exemplary industrial robots 1A, 1B are robots having six degrees of freedom in orthogonal axes, and FIG. 3 shows an arc welding robot provided with a welding torch 2 as the wrist element of the final shaft, and FIG. 4 similarly shows a handling robot provided with a hand tool 3. In the arc welding robot 1A, to the welding torch 2, there is connected a cable element 4 having a signal cable, a power supply cable, a welding wire, a gas hose and a wire conduit as a bundle. In the handling robot 1B, to the hand tool 3, there is connected a cable element 4 having a signal cable, power supply cable, an air supply tube, and the like as a bundle.

The two exemplary robots 1A, 1B are different in the configuration of the third wrist element 12 as an end-effector, in the construction of the cable element 4 connected to the third wrist element 12, and in the structure of the feeding device 5 for feeding the cable element 4, but have the rest of the components in common. Thus, both have a base 6, an upper arm 7, a forearm 8, and a wrist driving structure having three degrees of freedom about three rotational axes, in common. Therefore, the wrist driving structure for the industrial robot according to the present invention is applicable to both industrial robots 1A, 1B. Individual driving elements are adapted to be driven by servo motors corresponding to the individual driving elements so as to take specified positions and attitudes in accordance with instructions from a robot controller. The wrist driving structure according to the present invention is not limited to the industrial robots 1A, 1B shown in FIGS. 3 and 4, but is also applicable to other industrial robots performing a sealing or picking operation.

The wrist driving structure of the present embodiment is composed of first to third wrist elements 10, 11, 12 having three degrees of freedom about three rotational axes. The first wrist element 10 is provided rotatably about a first axis a as a center axis. The second wrist element 11 is provided pivotally with the proximal end as a support point about a second axis b as a pivoting axis intersecting the first axis a on the distal end side of the first wrist element 10. The third wrist element 12 is provided rotatably about a third axis c as the final shaft intersecting the second axis b on the distal end side of the second wrist element 11.

The wrist driving structure of the present embodiment is constructed as an inline wrist having the first axis a, the second axis b, and the third axis c intersecting at one point. That is, as shown in FIG. 2, the first axis a and the second axis c lie on the same axis line. Therefore, at the time of rotation of the first wrist element 10, the interference radii of other wrist elements 11, 12 can be minimized, and a wrist driving structure having good rotational balance as well as good controllability can thereby be realized.

The first to the third wrist elements 10, 11, 12 are provided on the distal end side of forearm 8 connected to the base 6 and the upper arm 7 which are rotatably interconnected to each other. The upper arm 7 connected to the base 6 is pivotable with the end connected to the base 6 as a supporting point. The forearm 8 connected to the upper arm 7 is pivotable with the other end connected to the upper arm 7 as a supporting point. The base 6, the upper arm 7 and the forearm 8 are rotatable in three degrees of freedom about three rotational axes.

The characteristic portion of the wrist driving structure of the present embodiment is shown in detail in FIGS. 1 and 2. As shown, in the first wrist element 10, there are provided two servo motors (driving motors) 13, 14 for driving the second wrist element 11 and the third wrist element 12, respectively, and two hypoid gear sets 15, 20 for reduction of the rotational speed of individual servo motors 13, 14 in a predetermined reduction ratio. Each of the hypoid gear sets 15, 20 consist of a pinion gear (small driving gear) 16, 21 driven by the servo motors 13, 14, and a ring gear (large driven gear) 17, 22 engaged with the pinion gear 16, 21 so as to rotate the second wrist element 11 or the third wrist element 12. One pinion gear 16 that is offset downward in the direction perpendicular to the axis of the center axis of the ring gears 17, 22 is formed with right hand teeth. The other pinion gear 21 is formed with teeth curved in a direction different from the one pinion gear 16. Thus, the other pinion gear 21 is formed with left hand teeth. The ring gears 17, 22 are laid one upon the other rotatably about the second axis b that is the common center axis.

The first wrist element 10 is supported at its proximal end rotatably on the distal end side of the forearm 8 in cantilever fashion. On the proximal end side of the first wrist element 10, there are provided a servo motor and a reduction gear for rotating the first wrist element 10 at a predetermined reduction ratio. The reduction gear is housed in the first wrist element such that its output section rotates coaxially with the first axis a. In the output section, a penetrating hollow bore is formed such that a control cable connected to the servo motors 13, 14 for driving the second wrist element 11 and the third wrist element 13 may be inserted through the hollow bore. By inserting the control cable through the hollow bore, torsion of the cable produced at the time of rotation of the first wrist element about axis a can be absorbed and damage such as breakage of the cable can be avoided. It is also possible to arrange the cable element 4 connected to the hand tool 3 (FIG. 4) corresponding to the third wrist element 12 along this control cable and to connect a connector provided at the end of the cable element 4 to a wrist flange of the third wrist element 12. In this manner, the cable element 4 arranged along the wrist element is prevented from being exposed to the outside so that the behavior of the cable element 4 is stabilized and a cable routing structure of the cable element 4 having a small interference radius is realized. It is also possible, in an alternative configuration, to pass the cable element 4 along the outside of the forearm 8 and to connect a connector provided at the end of the cable element 4 to a wrist flange of the third wrist element 12. In this manner, although the cable element 4 is exposed to the outside, the cable element 4 is not restricted by the hollow bore, and maintenance can also be assured. In a further alternative configuration, it is also possible to pass the cable element 4 along the outside of the third wrist element 12 and to connect a connector provided at the end of the cable element 4 to a wrist flange of the third wrist element 12. In this case, the same effect as described above can also be obtained.

In the first wrist element 10, there are housed a servo motor 13 for the second wrist element for rotating the second wrist element 11 about the second axis b and a servo motor 14 for the third wrist element for rotating the third wrist element 12 about the third axis c. The servo motor 13 for the second wrist element and the servo motor 14 for the third wrist element are disposed forward and rearward in the direction of the first axis a. In FIG. 1 showing a front view of the first wrist element 10, the output shafts of the individual servo motors 12, 14 are situated at offset positions such that they are generally symmetric with respect to a plane containing the first axis a and the second axis b. Thus, individual servo motors 13, 14 are provided in parallel to each other on two sides of the plane containing the first axis a and the second axis b at positions offset relative to each other in forward-rearward direction and partly overlapping each other.

By disposing the servo motor 13 for the second wrist element on the distal end side of the first wrist element 10 and the servo motor 14 for the third wrist element on the distal end side of the first wrist element 10, the two motors 13, 14 can be arranged in partly overlapping manner so that the cross sectional area of the first wrist element may be made small.

On the distal end side of the first wrist element 10, two hypoid gear sets 15, 20 are provided for transmitting the driving force of two servo motors 13, 14 to the second wrist element 11 and to the third wrist element 12, respectively. In FIG. 1, a pinion gear 16 for the second wrist element is connected via a set of spur gears (or helical gears or the like) 24, 25 to the output shaft of the servo motor 13 situated on the lower side. The pinion gear 16 for the second wrist element is rotatably supported by a pair of front and rear bearings 28, 29 with the distal end side offset in the direction perpendicular to the second axis b as the center axis of the ring gear 17 for the second wrist element so as to mesh with the ring gear 17 for the second wrist element.

A pinion gear 17 for the third wrist element is connected via a drive shaft 32 to the servo motor 14 situated on the upper side. An end of the drive shaft 32 is connected via a set of spur gears (or helical gears or the like) 26, 27 to the output shaft of the servo motor 14, and the other end of the drive shaft 32 is connected via a similar set of spur gears (or helical gears or the like) 33, 34 to the pinion gear 21. Two ends of the drive shaft 32 are supported by bearings 50, 51. The pinion gear for the third wrist element is rotatably supported by a pair of front and rear bearings 30, 31 with the distal end side offset from the second axis b as the center axis of the ring gear 22 for the third wrist element so as to mesh with the ring gear 22 for the third wrist element. The ring gear 22 for the third wrist element rotates the third wrist element 12 about the third axis via a pair of bevel gears 18, 19 which are orthogonal to each other.

In this embodiment, the direction of the tooth form formed on the two pinion gears 16, 21 are, such that the pinion gear 16 for the second wrist element has right hand teeth formed on outer peripheral surface and the pinion gear 21 for the third wrist element has left hand teeth formed on outer peripheral surface. Since the helix direction of the tooth formed on the two pinion gears differs from each other in this manner, it is possible to dispose the two pinion gears 16, 21 at positions offset in the direction perpendicular to the second axis b, symmetrically.

The outer diameters of the ring gear 17 for the second wrist element and the ring gear 22 for the third wrist element having the center axis in common are different, and the ring gear 22 for the third wrist element having smaller outer diameter is rotatably fitted inside the ring gear 17 for the second wrist element. Thus, the ring gear 17 for the second wrist element and the ring gear 22 for the third wrist element are disposed coaxially with the second axis b in common.

Since the motor 13 for the second wrist element and the motor 14 for the third wrist element are disposed at positions generally symmetric with respect to the first axis a, it is possible to reduce the cross sectional area of the first wrist element 10 in the section perpendicular to the axis due to disposition of the two servo motors 13, 14. Since the driving force of these servo motors 13, 14 is transmitted via the hypoid gear sets 15, 20 to respective wrist elements 11, 12, large rotational torque can be transmitted via the hypoid gear sets 15, 20 with a large reduction ratio. For example, large reduction ratio, e.g. ratio of 10-50, can be obtained by one hypoid gear set 15, 20. Therefore, as compared to a prior case where an expensive reduction mechanism or a multi-stage reduction gear mechanism is used, the wrist element 10 can be made compact, and the power transmission efficiency for the servo motors 13, 14 can be increased.

Next, a wrist driving structure for an industrial robot according to a second embodiment of the present invention will be described with reference to FIGS. 5 and 6. Constituents common to this embodiment and to the first embodiment are denoted by same reference numerals or symbols, and duplicate explanation thereof is omitted.

The present embodiment differs from the first embodiment in disposition of the servo motors 13A, 14A in the first wrist element 10A. As shown in the drawings, two servo motors 13A, 14A are disposed side by side in the direction perpendicular to the first axis a. The proximal ends of the pinion gears 16, 21 are directly connected to the output shaft 40, 41 of the two servo motors 13A, 14A. With such a construction, need for gears and drive shafts for connecting the servo motors 13A, 14A to the hypoid gear sets 15, 20 is eliminated so that the wrist driving structure is simplified and cost can be reduced. The present embodiment is otherwise common to the first embodiment, and therefore, further explanation will be omitted.

Next, a wrist driving structure for an industrial robot according to a third embodiment of the present invention will be described with reference to FIGS. 7 and 8. Constituents common to this embodiment and to the first embodiment are denoted by same reference numerals or symbols, and duplicate explanation thereof is omitted.

The present embodiment also differs from the first embodiment in disposition of the servo motors 13B, 14B in the first wrist element 10. In the present embodiment, two servo motors 13B, 14B provided in the first wrist element 10 are disposed in the direction perpendicular to the first axis a. That is, each of the output shafts of the servo motors 13B, 14B are perpendicular to the first axis a. Therefore, the driving force of the servo motors 13B, 14B is transmitted via a pair of bevel gears 35, 36, 42, 43 to the pinion gears 16, 21, respectively. Since there is a distance between the servo motors 13B, 14B and the pinion gears 16, 21, drive shafts 37, 38 are inserted between them. Both ends of each of the drive shafts 37, 38 are supported by bearings 52-55. With this construction, since the servo motors 13B, 14B can be disposed on the proximal end side of the first wrist element 10, moment of inertia about the first axis a can be minimized, so that control response can be improved. Controllability of the wrist element can be improved by using flat type servo motors having a large cross sectional area, and the wrist driving structure can be made inexpensive and compact.

The present invention is not limited to the above-described embodiments, but can be implemented in various modifications. Although two gear sets are both hypoid gear sets 15, 20 in the present embodiment, it is also possible, in the case where large reduction ratio of one of the second wrist element 11 and the third wrist element 12 is not required, to construct two gear sets such that one gear set is hypoid gear set and the other gear set is a set of a worm or bevel gear and ring gear.

Also, the curving direction of teeth formed on the outer peripheral surface of the pinion gears 16, 21 may be arbitrarily as long as the two pinion gears 16, 21 having teeth formed in oppositely curving directions.

Claims

1. A wrist driving structure for an industrial robot comprising: a first wrist element supported in cantilever fashion rotatably about a first axis;a second wrist element supported in cantilever fashion with a proximal end as a supporting point at a distal end side of said first wrist element pivotally about a second axis intersecting said first axis;a third wrist element supported in cantilever fashion at a distal end side of said second wrist element rotatably about a third axis intersecting said second axis;two driving motors provided in said first wrist element for driving said second wrist element and said third wrist element, respectively; andtwo gear sets for reducing a rotational speed of said two driving motors in predetermined reduction ratios;wherein each of said two gear sets comprises a driving gear driven by one of said two driving motors and a driven ring gear which meshes with said driving gear,wherein two driven ring gears of said two gear sets are disposed coaxially with said second axis, andwherein two driving gears of said two gear sets are positioned parallel to each other at both sides of said second axis.

2. A wrist driving structure for an industrial robot according to claim 1, wherein said two gear sets are hypoid gear sets, andwherein said two driving gears are pinion gears, a first pinion gear thereof having right-hand helical teeth, and a second pinion gear thereof having left-hand helical teeth.

3. A wrist driving structure for an industrial robot according to claim 1, wherein said two driven ring gears are coaxially laid one upon the other.

4. A wrist driving structure for an industrial robot according to claim 1, wherein said two driving motors are disposed such that output shafts of said two driving motors are positioned generally symmetrically with respect to a plane containing said first axis and said second axis.

5. A wrist driving structure for an industrial robot according to claim 1, wherein said first axis and said second axis and said third axis intersect at one point.