The invention relates generally to improvements in robotic systems performing automated manipulated functions on workpieces such as automotive vehicle bodies. More specifically, the invention pertains to robotic paint finishing of such objects in automatic paint finishing lines of high capacity.
Conventional robotic automotive paint finishing booths, such as that depicted in
The paint application process can be performed either on a moving or stationary object, such as a car body. In either case, the object is indexed down the finishing line after the paint application process is complete.
Conventional paint robots 102a–f as shown in
The term “arm”, as used herein, is intended to encompass either a manipulator arm composed of a single arm element or an assembly comprising a multi-segment arm, where pairs of the segments may be interconnected by joints as shown in
Such a prior art arrangement has the favorable features of repeatability of design, spare parts and maintenance; lower programming effort for identical robot units; and favorable downgrade arrangements should one of the robots fail. However, the prior art arrangement also presents important disadvantages. All robots are of the largest size required to paint the highest and the furthest portions of the object from the paint distribution devices, for example, the roof of the car body 106 shown in
An additional disadvantage of the prior art arrangement is that the combined effect of large envelope and high paint applicator relocation speed requires a sturdier robot to cope with the static and dynamic loads that it must handle which, in turn, results in higher total system cost. Also disadvantageous is the fact that the robots 102 require a relatively wide booth in order to paint vertical surfaces on object 106, due to the length of the manipulator arms of the robots. The robots 102 require space, either in front or at the back, in order to position the paint application device, such as an atomizer 107, at a suitable spraying distance in front of the surface to be painted.
Additionally, robots 102 often must be moved forward or backward along the line in order to paint the lower portions of part 106, such as a rocker panel, which requires a relatively longer spray booth paint application zone 104, along with an additional traveling axis (also known as the X-rail) being provided for robot movement longitudinally along application zone 104.
Finally, another disadvantage of the prior art arrangement is that at least two of the robots 102 perform very simple operations of reciprocating in the vertical surface of part 106. A much simpler machine than a full 7-axis robot can perform this operation.
Accordingly, in a first aspect of the invention, in a robot for performing predetermined operations under direction of a controller, the invention provides an improvement whereunder the robot is equipped with a plurality of manipulatable arms with at least two of the plurality of arms performing like operations.
In another aspect of the invention, a robotic system for performing predetermined operations under direction of a controller utilizes a cluster comprising a plurality of single manipulator arm robots such that each of the plurality is coupled to a common mounting stand, with at least two of the plurality of arms performing like operations.
In yet another aspect of the invention, a paint finishing booth having a paint application zone utilizes an arrangement of paint application robots wherein a robot cluster has a plurality of commonly controlled manipulator arms, each equipped with at least a paint application device and positioned within the paint application zone of the booth for applying paint at a first side of a workpiece being transported through the application zone.
In still a further aspect of the invention, a robotic system for performing predetermined operations under direction of a controller utilizes a cluster of single manipulation arm robots such that at least two bases of the robots extend in different directions toward a mounting end of their respective manipulator arms.
The objects and features of the invention will become apparent from a reading of a detailed description, taken in conjunction with the drawing, in which:
a presents a top plan view of a paint application booth arranged in accordance with prior utilization of single arm robots;
b is a cross-sectional view of the booth of
a is a top plan view of a paint application booth arranged in accordance with a first embodiment of the invention;
b is a cross-sectional view of the booth of
a is a top plan view of a booth arranged in accordance with a second embodiment of the invention;
b is a cross-sectional view of the booth of
c presents details of the mounting arrangement of the first robot cluster of
d details of the mounting arrangement for the robot cluster on the opposite side of the booth of
a sets forth a top plan view of a paint application booth arranged in accordance with a third embodiment of the invention;
b is a cross-sectional view of the booth of
c sets forth details of the mounting arrangement of the first robot cluster of
d sets forth the mounting details of the second robot cluster of the booth of
With reference to
Positioned within paint application zone 204 on opposite sides of the conveyor system 208 are first and second clusters of robot arms or arm assemblies 202a and 202b. In the embodiment of
Placing each cluster of commonly controlled manipulator arms in a common substantially vertical plane substantially reduces the length L1 of paint application zone 204 in comparison to the length L2 which would be required for the prior art arrangement set forth in
Such multiple manipulator arm clusters are referred to herein as “spider” or “octupus” robots. As with the conventional robots 102 of
The arrangement in accordance with the embodiment of
Hence, the embodiment of
Additionally, the embodiment of
The embodiment of
With reference to
As used herein, “common mounting stand” is intended to encompass not only the single mounting stands set forth in the drawing, but also slightly separated stands grouped in a cluster with a separation distance between attachment points of the root arms of each robot being less than the length of the longest arm segment of all the arm assemblies in the cluster.
Likewise, the term “common controller” or “controller” is intended to encompass not only a single robot controller, but also a plurality of coordinated controllers, each controlling the motion of the individual robots within a cluster.
The invention additionally contemplates separate mounting stands within a cluster, wherein each robot base is mounted such that at least two of the bases extend in different directions toward a connection with their respective arms.
Booth 300 has a first manipulator arm cluster 302a and a second manipulator arm cluster 302b positioned at opposite sides of a conveyor system 308 which transports workpieces such as automotive bodies, 306 along a central portion of booth 300 through a paint application zone 304.
As seen from
Each robot of the cluster has coupled thereto a manipulator arm—310-1 for robot 307-1, 310-2 for robot 307-2, 310-3 for robot 307-3, 311-1 for robot 308-1, 311-2 for robot 308-2 and 311-3 for robot 308-3.
Also associated with each robot cluster is a plurality of paint application devices, with one or more application devices being associated with each robot manipulator arm. For cluster 302a, the paint distribution or application devices are designated 312-1, 312-2 and 312-3 associated respectively with manipulator arms 310-1, 310-2 and 310-3. Similarly, paint distribution or application devices 313-1, 313-2 and 313-3 are respectively associated with manipulator arms 311-1, 311-2 and 311-3 of cluster 302b. As used herein, the term “paint distribution or application” refers to a process wherein a liquid or powder substance is applied to surfaces of an object, such as a car body.
With the arrangement of
At least one middle robot of each cluster, 307-1 for cluster 302a and 308-1 for cluster 302b, is equipped with arms of the longest reach of the plurality of arms in each cluster. This longest arm 310-1 and 311-1 is responsible for coating the highest vertical surface of body 306 and most of its horizontal surfaces, such as the roof of the body. The two side robots of each cluster 307-2, 307-3 for cluster 302a and 308-2, 308-3 for cluster 302b are rotated 90° from their normal orientation such that their vertical arms have become horizontal and almost parallel with the length of the booth. This orientation makes both side robots in each cluster completely free in their reciprocative motion over the vertical and lower horizontal surfaces of the object 306. The two side robots of each cluster can be equipped with different or with the same arm lengths depending upon a specific coating process and the shape of the workpiece being coated. Additionally, the side robots can be mounted at any angle between 0° and 180° with respect to the middle robot.
The embodiment of
A second alternative arrangement set forth in
With reference to
In the embodiment of
Cluster 402a is equipped with two manipulator arms, 410-1 and 410-2, while cluster 402b has manipulator arms 411-1 and 411-2 likewise extending in opposite directions at their bases. Each arm of each cluster is equipped with a paint application or distribution device 412-1 for arm 410-1, 412-2 for arm 410-2, 413-1 for arm 411-1 and 413-2 for arm 411-2.
Again, the required application zone 404 length L5 is seen to be substantially shorter, on the order of one-half of the required length L6 which must be provided for prior art arrangements using horizontally-spaced individual arm robots in accordance with the prior art.
The longer arm of each cluster—410-1 and 411-1 is mounted above the common stand and is responsible for the horizontal surfaces and upper vertical surfaces of body 406. The shorter arms 410-2 and 411-2 are responsible for the lower portions of the vertical surfaces of the body 406.
Whether or not one can reduce the number of manipulator arms in each cluster depends upon the available application throughput of the paint application devices 412.
The invention has been described with reference to preferred embodiments which are presented for the sake of example only. Those skilled in the relevant art will readily recognize that one could combine the various embodiments set forth herein. For example, the embodiments of
The scope and spirit of the invention is to be determined by appropriate interpretation of the appended claims.
This application is a continuation of U.S. Ser. No. 09/947,142, filed Sep. 5, 2001 now U.S. Pat. No. 6,757,586.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 09947142 | Sep 2001 | US |
Child | 10761115 | US |