Patent Grant
11235475
The present disclosure generally relates to a robotic apparatus in which an operating unit for operating an object is interchangeable and to a method for controlling the robotic apparatus.
Automation of work such as assembly and processing of industrial products having a compact and complicated structure, such as cameras and printers, has been recently performed. Parts for use for this type of industrial product are often small precision parts and vary in shape.
Meanwhile, continuous production of a variety of products using the identical robotic apparatus is required. Therefore, at the manufacturing site, changing the setup including interchanging of the end effector and the tools of the robotic apparatus is required according to the kind of workpiece and process change. In the case where the configuration of this kind of robotic apparatus is manually changed by an operator, much labor and time is required. For this reason, there is an increasing demand for automatic setup change, in which setup change is performed by programming the robotic apparatus as much as possible.
In view of the above circumstances, the robotic apparatus is required to have a compact and simple configuration, specifications and performance that allow gripping, assembling, and processing various kinds of workpieces. At the same time, it is desired to increase the operation rate of the entire robotic apparatus by automatically interchanging tools for work, such as gripping, assembling, and machining of workpieces, without the need for work or assistance of workers to perform an automatic setup change with a minimum change of the apparatus configuration.
For automatic interchanging of an operating unit of the robotic apparatus, such as tools or the components thereof, reduction in the size and weight of the tools, reduction of a interchanging time of the tools and the components, and an increase in the mounting accuracy of interchanging are required. The tools include various devices, such as a hand for gripping and conveying a workpiece, a spray gun for painting, and a welding machine, which are interchangeable with respect to a robot arm according to the workpiece or the process.
Some tools like hands are configured so that finger portions that handle the workpiece are interchangeable. Particularly to interchange the finger portions of the hand, the structures disclosed in Japanese Patent Application No. 2006-44630 and Japanese Patent No. 5892765 have been proposed.
For example, a robot hand disclosed in Japanese Patent Application No. 2006-44630 includes a common base, which is a hand main body mounted to a robot arm, and a finger unit detachably mounted to the common base and including a plurality of fingers. In mounting the finger unit to the common base, the finger unit is placed on a predetermined jig, and the robot arm is moved close to the finger unit from above. A pair of locating pins projecting from the upper end of the finger unit is fit in a pair of locating holes formed at the lower end of the common base, and lock pins are engaged with the locating pins, so that the finger unit is mounted to the common base.
A robot hand disclosed in Japanese Patent No. 5892765 includes an interchangeable claw module that is detachably mounted to a robot arm including finger members. The interchangeable claw module includes claw members, claw support members including the claw members and insertion holes in which the finger members of the robot hand can be inserted, guide mechanism that guide the claw members in a corresponding opening and closing direction of the finger members, and a frame member that supports the claw members via the guide mechanisms. The claw members of the interchangeable claw module are gripped with the finger members of the robot hand to support the interchangeable claw module and the driving force of the finger members is transmitted to the claw members to move the claw members.
In the robot hand disclosed in Japanese Patent Application No. 2006-44630, each finger unit includes an opening and closing driving source for opening and closing the plurality of finger members, so that the manufacturing cost is high. Furthermore, it is necessary to seek the origin of the actuator for each interchanging. This increases the interchanging time and decreases the working efficiency.
The robot hand disclosed in Japanese Patent No. 5892765 is configured to support the interchangeable claw module with the finger members of the robot hand and to grip a workpiece by moving the claw members. This has the problem of increasing the size and weight of the entire end effector including the robot hand and the interchangeable claw module. The increase in the size and weight of the entire end effector can cause an increase in the vibration of the distal end of the end effector and decrease the accuracy of positioning for gripping the workpiece.
What is needed is a robotic apparatus in which tools can be interchanged without the need for seeking the origin caused by driving due to an electrical detaching mechanism and in which the distal end of the robot arm is reduced in size and weight.
Aspects of the present disclosure provide a robotic apparatus including a robot arm and configured to grip an object using an interchangeable tool that is detachable to the robot arm. The interchangeable tool includes a finger that comes into contact with the object. The robotic apparatus includes a robot-arm-side mount surface to which the interchangeable tool is mounted and an interchangeable-tool-side mount surface to be mounted to the robot arm. The robot-arm-side mount surface includes a robot-arm-side fixing portion configured to hold the interchangeable tool in a mounted state and a driving mechanism for driving the finger in the mounted state. The interchangeable-tool-side mount surface includes an interchangeable-tool-side fixing portion to be engaged with the robot-arm-side fixing portion and an opening and closing mechanism that is connected to the driving mechanism in the mounted state. The opening and closing mechanism is activated in conjunction with the driving mechanism.
Further features of the present disclosure will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Embodiments of the present disclosure will be described with reference to the attached drawings. The embodiments below are given for mere illustration, and the configuration of the details can be appropriately changed by those skilled in the art without departing from the spirit of the present disclosure.
The robotic apparatus 20 in
The robot arm 100 includes seven links 101 to 107 and six joints 111 to 116 that connect the links 101 to 107 together so as to swing and rotate. Although the links 101 to 107 of the present embodiment have fixed lengths, links that can be extended by, for example, linear actuators, may be used.
Referring to
Consider the interchangeable tools 300a and 300b as operating units that can be mounted to and detached from the robot-arm-side mount surface 210. For example, in the state illustrated in
In the case where the shapes of the workpieces W of the product to be assembled and work thereon vary, the workpiece W to be gripped and assembled differ, so that the interchangeable tool 300 is selectively used according to the workpiece W and the work. For example, first, second, third . . . interchangeable tools 300 including finger members 330 having different lengths and shapes are prepared in advance and are interchanged according to the workpiece W or the work, so that a finger member optimal for the workpiece W and the work can be used.
The “operating unit” detachably mounted to the robot-arm-side mount surface 210 is not limited to the gripping “fingers”. Examples of work tools other than fingers include drivers, drills, and welding machines. Not only the fingers, any tools having a mechanism for interchanging the operating unit, described later, can be mounted. The number of tools to be driven may be increased according to the operation.
The control unit 600 serving as a control unit for the robot system 10 may be a computer using a microprocessor element or the like. This control unit 600 allows the robotic apparatus 20 and the interchanging unit 500 to be controlled.
The computer constituting the control unit 600 includes a CPU 601, a ROM 602 that stores programs for controlling the components, a RAM 603, and a communication interface 604. Among them, the RAM 603 is used to temporarily store data, such as a teaching point and a control instruction, from the controller 610.
An example of the controller 610 is an operating unit, such as a teaching pendant. Alternatively, the controller 610 may be another computer capable of editing robot programs. The controller 610 can be connected to the control unit 600 via a wired or wireless communication connecting unit and has a user interface function, such as robot operation and state display.
The CPU 601 receives, for example, teaching point data input from the controller 610, via the communication interface 604. The CPU 601 can generate the paths of the axes of the robotic apparatus 20 on the basis of the teaching point data input from the controller 610 and can transmit the paths to the robotic apparatus 20 as control target values via the communication interface 604.
Next, an example of a configuration for mounting and detaching the interchangeable tool 300 serving as an operating unit in the present embodiment will be described. In the present embodiment, the finger member 330 includes a pair of finger members, and therefore a configuration for mounting and detaching the interchangeable tool 300 including the two finger members will be described.
The driving mechanism includes a pair of drive bases 211a and 211b. The drive bases 211a and 211b can be moved linearly by a slide guide including guide blocks 204a and 204b and guide rails 205a and 205b.
The drive bases 211a and 211b are respectively fixed to two horizontal sides 214a and 214b with the guide blocks 204a and 204b and screws.
Driving transmission members 212a and 212b are respectively disposed on the drive bases 211a and 211b. Racks 225a and 225b (see
Next, a robot-arm-side fixing portion will be described. Referring back to
The locator pins 240a and 240b respectively include fitting shafts 241a and 241b and contact portions 242a and 242b and have, at their ends, balls 243a and 243b movable toward the center. The balls 243a and 243b can be respectively moved forward and backward with respect to the peripheral surfaces of the locator pins 240a and 240b by supplying or exhausting compressed air to or from the locator pins 240a and 240b.
The compressed air is supplied to the locator pins 240a and 240b in a state in which the locator pins 240a and 240b are respectively fit in stepped fitting holes 340a and 340b (see
Referring next to
First, the robot-arm-side mount surface 311 will be described. The interchangeable-tool-side mount surface 311 has a circular shape around the axial center S of the robot arm 100. The interchangeable-tool-side mount surface 311 includes the two finger support members 314a and 314b that respectively support the finger members 330a and 330b and fitting portions 341a and 341b.
The interchangeable-tool-side mount surface 311 has two openings 313a and 313b. The finger support members 314a and 314b are respectively arranged so that the finger members 330a and 330b pass through the openings 313a and 313b. The guide rails 322a and 322b are arranged, with the openings 313a and 313b therebetween, respectively. The finger support members 314a and 314b are respectively fixed to two sets of horizontal sides 315a and 315b with the guide blocks 321a and 321b and screws. The guide blocks 321a and 321b can be moved along the guide rails 322a and 322b, so that the finger support members 314a and 314b serve as an opening and closing mechanism for opening and closing the finger members 330a and 330b.
The two stepped fitting holes 340a and 340b, the two finger support members 314a and 314b, and the driving transmission holes 317a and 317b on the interchangeable-tool-side mount surface 311 are disposed in a circle around the axial center S. The stepped fitting holes 340a and 340b and the finger support members 314a and 314b are arranged such a straight line connecting the centers of the stepped fitting holes 340a and 340b and a straight line connecting the finger support members 314a and 314b are substantially perpendicular to each other.
The stepped fitting holes 340a and 340b respectively have the fitting portions 341a and 341b, contact portions 342a and 342b, and engaging portions 343a and 343b. The locator pins 240a and 240b are respectively inserted into the stepped fitting holes 340a and 340b, so that the fitting portions 341a and 341b and the fitting shafts 241a and 241b are fit each other. When the balls 243a and 243b move radially outward, the balls 243a and 243b respectively engage the engaging portions 343a and 343b and are urged diagonally upward. Furthermore, the contact portions 342a and 342b of the stepped fitting holes 340a and 340b and the contact portions 242a and 242b of the locator pins 240a and 240b are brought into close contact with each other, so that the locator pins 240a and 240b and the stepped fitting holes 340a and 340b are positioned into a mechanically connected state. In other words, the interchangeable tool 300 is mounted to the robot arm 100.
In contrast, when the balls 243a and 243b move radially inward, the engagement between the balls 243a and 243b and the engaging portions 343a and 343b is released, so that the locator pins 240a and 240b and the stepped fitting holes 340a and 340b become separable.
The interchangeable-tool-side mount surface 311 corresponds to the substantial mount surface of the interchangeable tool 300 and has prepared holes for a plurality of screws and locating holes so that any tool can be mounted.
Next, the pair of finger support members 314a and 314b will be described in detail. Referring to
Referring back to
When the drive bases 211a and 211b are brought close to each other in the direction of arrow A in
Next, the finger members 330a and 330b will be described. As illustrated in
The finger members 330a and 330b are respectively integrated with the finger support members 314a and 314b.
The finger support members 314a and 314b are respectively fixed to the guide blocks 321a and 321b with screws.
In
In contrast, by driving the drive bases 211a and 211b in the direction of arrow B, the pair of finger support members 314a and 314b are respectively driven via the driving transmission members 212a and 212b and the driving transmission holes 317a and 317b. As a result, the pair of finger members 330a and 330b move in the direction of arrow B to release the gripping of the workpiece W.
In the present embodiment, considerations are made to facilitate an operation for attaching and detaching various interchangeable tools 300 according to work and designing new interchangeable tools.
In other words, in a state in which the interchangeable tool 300 is mounted to the robot arm 100, as illustrated in
Defining the typical mount surface makes it easy to standardize the arrangement of the attaching and detaching mechanism and the driving transmission system also when developing a new interchangeable tool, allowing providing a highly versatile robotic apparatus.
The shape of the finger member 330 is given for illustration, and various shapes can be employed according to the shape or posture of the workpiece to be gripped.
Next, tool stockers 510a and 510b in which the interchangeable tool 300 of the present disclosure removed from the robot-arm-side mount surface 210 is stored will be described. Hereinafter, the tool stockers 510a and 510b are sometimes referred to as “tool stocker 510” as a generic name of all tool stockers.
To store the interchangeable tool 300 in the tool stocker 510, the robot arm 100 is operated to move the interchangeable tool 300 to a predetermined position above the tool stocker 510. Next, the interchangeable tool 300 is moved in the direction of arrow C to insert the finger members 330a and 330b into the opening 512 into a predetermined position on the grounding portion 511.
In this state, the solenoid valve 521 is activated to supply or exhaust air to or from the attaching and detaching mechanism constituted by the locator pins 240a and 240b and the stepped fitting holes 340a and 340b. This causes the balls 243a and 243b to move inward, so that the clamping of the robot-arm-side mount surface 210 and the interchangeable tool 300 is released. Thus, only the interchangeable tool 300 is stored in the tool stocker 510.
Next, the interchanging system of the present embodiment will be described. As illustrated in
Thereafter, the robot arm 100 is controlled using the control unit 600 to move the robot-arm-side mount surface interchangeable tool 300a to above the storage case.
Next, the interchangeable tool 300a is moved downward toward the workpiece Wa to be gripped. The motor 221 is driven using the control unit 600 to drive the drive bases 211a and 211b, thereby respectively controlling the finger support members 314a and 314b and the finger members 330a and 330b via the driving transmission members 212a and 212b and the driving transmission holes 317a and 317b. Thus, the workpiece Wa is gripped. The interchangeable tool 300a is moved upward from the storage case, and the workpiece Wa is taken out. Thereafter, the robot arm 100 conveys the workpiece Wa to a target position, and releasing the gripping of the workpiece Wa by controlling the finger members 330a and 330b, so that the workpiece Wa is placed on the target position.
To grip the workpiece Wb, the robot arm 100 is controlled using the control unit 600 to move the interchangeable tool 300a to above the tool stocker 510a. The attaching and detaching mechanism constituted by the locator pins 240a and 240b and the stepped fitting holes 340a and 340b is activated, with the interchangeable tool 300a mounted in the tool stocker 510a. After the interchangeable tool 300a and the robot-arm-side mount surface 210 are unclamped from each other, the robot arm 100 is controlled with the control unit 600 so that the robot-arm-side mount surface 210 is moved upward from the tool stocker 510a. At that time, the interchangeable tool 300a is stored into the tool stocker 510a.
Next, the robot-arm-side mount surface 210 is moved to above the tool stocker 510b by controlling the robot arm 100 with the control unit 600. The interchangeable tool 300b is acquired as in the above. Next, the interchangeable tool 300b is move to above the storage case by controlling the robot arm 100 with the control unit 600.
Next, the target workpiece Wb is gripped by the interchangeable tool 300b, and the workpiece Wb is taken out, as is the workpiece Wa. The interchangeable tool 300b is moved to convey the workpiece Wb to a target position. The gripping of the workpiece Wb is released by controlling the finger members 330a and 330b to place the workpiece Wb at a target position.
Thus, in the robotic apparatus 20 including the interchangeable tool 300 of the present disclosure, the robot-arm-side mount surface 210 and the interchangeable-tool-side mount surface 311 have the same configuration. Furthermore, the robot arm 100 includes a driving source, such as a motor.
Therefore, there is no need for individual interchangeable tools 300 to have a driving source, such as a motor, and an electrical circuit for opening and closing the finger member 330, reducing cost and the size and weight of the entire robot hand. Furthermore, since the finger members 330 themselves are interchanged, the end effector 200 at the end of the robot arm 100 is not increased in size, unlike Japanese Patent No. 5892765.
Furthermore, since the finger member 300 can be opened and closed by the mechanical attaching and detaching mechanism, there is no need to seek the origin of the actuator for each interchanging operation caused by an electrical attaching and detaching mechanism. This facilitates repeated interchange only by remembering the operation of interchanging the interchangeable tool 300 with the control unit 600. Interchanging the interchangeable tool 300 allows operating a workpiece using a finger suitable for the shape of the workpiece, enhancing the versatility.
Furthermore, the robot-arm-side fixing portion and the driving mechanism, and the interchangeable-tool-side fixing portion and the opening and closing mechanism are each arranged in substantially perpendicular positions so that their occupied areas do not overlap on the mount surface. This decreases the length E out of the entire length F of the end effector 200, as illustrated in
The two interchangeable tools 300a and 300b and the two tool stockers 510a and 510b in the present embodiment are given for mere illustration. The number of interchangeable tools 300 can be increased according to the kind of tool corresponding to the shape and posture of the workpiece to be operated.
In the case of not only gripping but also painting or welding the workpiece W, the finger members 330a and 330b may be removed as appropriate and may be interchanged with another member according to the application.
The present embodiment has been described as applied to a ball-plunger configuration of the fixing portion between the robot-arm-side mount surface 210 and the interchangeable tool 300, in which the balls 243a and 243b are moved forward and backward by compressed air into engagement with the engaging portions 343a and 343b. Alternatively, it may be changed by the those skilled in the art to a configuration of connection using an electromagnet and a permanent magnet.
Also a configuration in which driving transmission members are provided at the finger support members 318a and 318b, as illustrated in
The present disclosure is applicable to industrial robots.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2017-056239 filed Mar. 22, 2017, which is hereby incorporated by reference herein in its entirety.
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