The invention relates generally to a material feeding apparatus, and particularly to a gripper type material feeding apparatus for intermittently feeding a workpiece such as a strip-like sheet material, a wire material, or the like, to a stamping machine or similar machine.
Existing gripper type material feeding devices utilize a movable linearly guided gripper mechanism for intermittently feeding a workpiece to a stamping machine. Some such gripper type feeding devices typically utilize a cam for the actuation of the feeding motion. Such devices are exemplified in U.S. Pat. No. 6,283,352 and U.S. Pat. No. 6,213,369. Such devices utilize a rotary oscillating cam mechanism with a fixed rotation angle, a lengthwise adjustable driving member attached to the actuator, and a linkage arrangement or other transmission elements between the actuator and the gripper mechanism. The lengthwise adjustable driving member comprises mechanical adjusting components for changing the index distance of the feed apparatus and the workpiece. The disadvantage of such arrangements is that the mechanical adjustments are complex and inconvenient.
Other existing gripper type material feeding apparatus utilize a pneumatic or a hydraulic cylinder for the actuation of the feeding motion. Typically an adjustable mechanical stop is provided for changing the index distance of the feed apparatus and the workpiece. An example of such device is seen in U.S. Pat. No. 5,505,360. The disadvantage of such devices is that adjustment of the mechanical stop is inconvenient. Furthermore, the pneumatic or hydraulic cylinder used in such devices suffers from a speed limitation due to the slow response of this type of such actuators.
Other existing gripper type material feeding apparatus utilize a pneumatic or a hydraulic cylinder for the actuation of the feeding motion, chain and sprocket transmission elements for converting the linear motion of the cylinder into a rotary motion of a driving member, fixed stops on the rotating driving member, connecting links, and mechanical adjusting components for the lengthwise adjustment of the connection distance of the driving member to the connecting link. An example of such device is seen in U.S. Pat. No. 4,577,791. A disadvantage of such a device is that the device and the mechanical adjusting components are complex, inconvenient and high maintenance. Furthermore, the pneumatic or hydraulic cylinder used in such feeding apparatus suffers from a speed limitation due to the slow response of this type of actuator.
Still other existing gripper type material feeding apparatus utilize a reversible motor, lead screws and threaded bushings for the actuation of the feeding motion. An example of such a device is seen in U.S. Pat. No. 5,909,835. The disadvantage of this device is that a large angle of rotation of the motor is necessary due to the nature of lead screw and threaded bushing transmission elements. The operational speed of such a device is therefore limited. Furthermore, this type of feeding device suffers from high wear characteristics and high maintenance costs.
There exists then the need for a gripper type material feeding apparatus which does not require mechanical adjustments for changing the feeding distance of the feeding device or the workpiece, is suitable for operating at high index cycle rates, and is low maintenance.
In one general aspect, this application discloses an apparatus for the intermittent feeding of a workpiece. Specifically, the apparatus includes a first linearly guided gripper mechanism which is movable in a first direction of workpiece feeding and in a second direction opposite to the first direction. The first gripper mechanism includes a first gripping member and a second gripping member wherein the second gripping member is movable relative to the first gripping member for gripping the workpiece. The apparatus further includes a gripper mechanism drive actuator which is angularly adjustable, reversible and rotary, a fixed length driving member connected to the gripper mechanism drive actuator for rotation therewith. The apparatus further includes a first gripper mechanism drive connecting link with a first end pivotally connected to a first end of the fixed length driving member and with a second end pivotally connected to the first gripper mechanism for moving the first gripper mechanism in the first direction of workpiece feeding and the second direction opposite to the first direction.
For the present invention to be clearly understood and readily practiced, the present invention will be described in conjunction with the following figure, wherein like reference characters designate the same or similar elements, which figure is incorporated into and constitutes a part of the specification, wherein:
It is to be understood that the figures and descriptions of the present invention have been simplified to illustrate elements that are relevant for a clear understanding of the invention, while eliminating, for purposes of clarity, other elements that may be well known. Those of ordinary skill in the art will recognize that other elements are desirable and/or required in order to implement the invention. However, because such elements are known in the art, and because they do not facilitate a better understanding of the present invention, a discussion of such elements is not provided herein. The detailed description will be provided herein below with reference to the attached drawings.
For purposes of the description hereinafter, the terms “upper”, “lower”, “vertical”, “horizontal”, “axial”, “top”, “bottom”, and derivatives thereof shall relate to the invention, as it is oriented in the drawings. However, it is to be understood that the invention may assume various alternative configurations except where expressly specified to the contrary. It is also to be understood that the specific elements illustrated in the drawings and described in the following specification are simply exemplary embodiments of the invention. Therefore, specific dimensions, orientations and other physical characteristics related to the embodiments disclosed herein are not to be considered limiting.
It is to be further understood that the phrase “generally perpendicular to” should not be interpreted in the strictest limitation of perpendicularity, that is, the requirement that two perpendicular lines must intersect. Rather, the phrase “generally perpendicular to” is used to allow for the possibility that the described elements are arranged in such ways that even though the axis or directions of reference may be skew, or non-intersecting, the projection of the axis and or directions onto a projection plane parallel to both axis and or directions will result in projection lines which are perpendicular. Furthermore the phrase “generally perpendicular to” is to be understood as being an orientation close to 90 degrees, for example 85-95 degrees.
It is here to be noted that although the following description of various linkage arrangements and their operation are described in singular, for example driving members and connecting links, any such elements may be present in duplicate where the construction and operation are parallel. Such arrangements shall not be considered outside the scope of the present invention.
An embodiment in accordance with the present invention will be described below with reference to the accompanying drawings.
A feeding apparatus 1, depicted generally in
A workpiece 100 is illustrated and a first direction of workpiece feeding is depicted with a direction arrow.
A first gripper mechanism 3 is supported by and configured for linear movement along linear guides 50 and 51. Linear guides 50 and 51 are supported by frame 2 and stationary relative thereto. In the illustrated embodiment, linear guides 50 and 51 are parallel cylindrical rods. Linear guides 50 and 51 are arranged parallel to the direction of workpiece feeding. First gripper mechanism 3 is therefore linearly guided and movable in a first direction of workpiece feeding and in a direction opposite to the first direction of workpiece feeding.
First gripper mechanism 3 comprises a first gripping member 30 and a second gripping member 15. Second gripping member 15 is movable relative to first gripping member 30. Further, in this embodiment, first gripper mechanism 3 further comprises a first spring 18 and a second spring 19. First and second springs 18 and 19 are arranged for urging second gripping member 15 toward gripping member 30. Alternatively either first spring 18 or second spring 19 or both may be omitted.
A second gripper mechanism 4 is supported by frame 2 and stationary relative thereto. Second gripper mechanism 4 comprises a first gripping member 40 and a second gripping member 25. Second gripping member 25 is movable relative to first gripping member 40. Further, in this embodiment, second gripper mechanism 4 further comprises a first spring 28 and a second spring 29. First and second springs 28 and 29 are arranged for urging second gripping member 25 toward gripping member 40. Alternatively either first spring 28 or second spring 29 or both may be omitted.
A gripper mechanism drive actuator 60 is supported by frame 2 and stationary relative thereto. Gripper mechanism drive actuator 60 is angularly adjustable, reversible and rotary. Gripper mechanism drive actuator 60 is preferably a brushless permanent magnet electric servo motor. Alternatively, gripper mechanism drive actuator 60 may be a stepper motor, a hydraulic motor, a rotary pneumatic actuator, or any reversible rotary actuator that may be adjustable in angle of rotation. Gripper mechanism drive actuator 60 is controlled by a programmable controller 91 (
A drive link or driving member 34 is connected to output shaft 35 of gripper mechanism drive actuator 60 for rotation therewith. Driving member 34, being connected to output shaft 35 for rotation therewith, rotates about a rotation axis 36 of output shaft 35. It should be noted that while driving member 34 is shown as a separate component from output shaft 35 of gripper mechanism drive actuator 60, driving member 34 could be constructed as an integral part of output shaft 35, such as an eccentric feature of output shaft 35.
A gripper mechanism drive connecting link 32 is pivotally connected at a first end by connecting pin 33 to a first end of driving member 34 at a first pivot axis 37 and at a second end by connecting pin 31 to movable gripper mechanism 3 at a second pivot axis 38.
A release actuator 71, depicted generally in
Reversible motor 70 is preferably a brushless permanent magnet electric servo motor controlled by a programmable controller 92. Alternatively, reversible motor 70 is an electric stepper motor, a hydraulic motor, or a rotary pneumatic actuator. Programmable controller 92, depicted generally in the drawings is of conventional design well known in the art. Programmable controller 92 is connected with a wire 94 in a particular sense to motor 70 and in a more general sense to release actuator 71.
A release connecting link 13 (
A release actuator 81, depicted generally in
Reversible motor 80 is preferably a brushless permanent magnet electric servo motor controlled by a programmable controller 93. Alternatively, reversible motor 80 is an electric stepper motor, a hydraulic motor, or a rotary pneumatic actuator. Programmable controller 93, depicted generally in the drawings is of conventional design well known in the art. Programmable controller 93 is connected with a wire 96 in a particular sense to motor 80 and in a more general sense to release actuator 81.
A release connecting link 23 with a first end is pivotally connected at the first end by connecting pin 22 to driving member 21 of release actuator 81 at a first pivot axis 26 and at a second end by connecting pin 24 to second gripping member 25 at a second pivot axis 27.
In operation, release actuator 71 cooperates with springs 18 and 19 to move second gripping member 15 towards first gripping member 30 for gripping workpiece 100. Alternatively, in the absence of springs 18 and 19, release actuator 71 moves second gripping member 15 towards first gripping member 30 for gripping workpiece 100. In particular, output shaft 10 of reversible motor 70 is rotated to move driving member 11, connecting pins 12 and 14, and release connecting link 13 such that second gripping member 15 is moved into contact with workpiece 100 thereby gripping the workpiece 100 between second gripping member 15 and first gripping member 30.
Release actuator 81 moves second gripping member 25 away from first gripping member 40 for releasing a grip on workpiece 100. In particular, output shaft 20 of motor is rotated to move driving member 21, connecting pins 22 and 24, and release connecting link 23 such that second gripping member 25 is moved away from workpiece 100 thereby releasing workpiece 100 from second gripping member 25 and first gripping member 40.
Reversible rotary gripper mechanism drive actuator 60 is rotated to move driving member 34, connecting pins 31 and 33, and gripper mechanism drive connecting link 32 such that first gripper mechanism 3 and workpiece 100 is moved in a first direction of workpiece feeding as depicted by an arrow in the drawings. The feeding distance of workpiece 100 is determined by the rotational angle of rotary gripper mechanism drive actuator 60 and driving member 34. As rotary gripper mechanism drive actuator 60 is preferably a brushless permanent magnet electric servo motor commanded by programmable controller 91, the rotation angle of gripper mechanism drive actuator 60 and therefore the feeding distance of workpiece 100 is easily adjusted.
When the required workpiece feeding distance has occurred, reversible rotary gripper mechanism drive actuator 60 is stopped.
Release actuator 81 cooperates with springs 28 and 29 to move second gripping member 25 towards first gripping member 40 for a gripping of the workpiece 100. Alternatively, in the absence of springs 28 and 29, release actuator 81 moves second gripping member 25 towards first gripping member 40 for gripping workpiece 100. In particular, output shaft 20 of motor 80 is rotated to move driving member 21, connecting pins 22 and 24, and release connecting link 23 such that second gripping member 25 is moved into contact with workpiece 100 thereby gripping the workpiece 100 between second gripping member 25 and first gripping member 40.
Release actuator 71 moves second gripping member 15 away from first gripping member 30 for releasing a gripping force on workpiece 100. In particular, output shaft 10 of reversible motor 70 is rotated to move driving member 11, connecting pins 12 and 14, and release connecting link 13 such that second gripping member 15 is moved away from workpiece 100 thereby releasing workpiece 100 from second gripping member 15 and first gripping member 30. That is, by the actuation of release actuator 71, the second gripping member 15 is moved in a direction relative to first gripping member 30 and in a direction generally perpendicular to the first direction of workpiece feeding.
Reversible rotary gripper mechanism drive actuator 60 is rotated to move driving member 34, connecting pins 31 and 33, and gripper mechanism drive connecting link 32 such that first gripper mechanism 3 is moved in a second direction opposite to the first direction of workpiece feeding.
The operation is periodically repeated in synchronization with the stamping machine or the like.
It will be understood by one skilled in the art, that at any time during the period of operation when first gripper mechanism 3 is stopped or moving in the second direction opposite to the first direction of workpiece feeding, release actuator 81 may be used to release the workpiece from second gripper mechanism 4 to allow for a piloting or final positioning operation of a tool or the like in the stamping machine or the like. Alternatively, after the movement of linearly guided gripper mechanism in the first direction of workpiece feeding actuator 80 may be operated in a manner to open second gripping member 25 to release workpiece 100 prior to the operation of release actuator 71 and the subsequent closing of second gripping member 15 to allow for the piloting or final positioning operation of a tool or the like in the stamping machine or the like.
It will be further understood by one skilled in the art, that to maintain continued gripping of the workpiece between gripping members 15 and 30 when movable gripper mechanism 3 is moving in the first direction of workpiece feeding, release actuator 71 will move. The movement of release actuator 71 is such that release connecting link 13, connecting pin 12, connecting pin 14 and therefore pivot axis 17 is moved such that the distance between second gripping member 15 and first gripping member 30 is constant. Programmable controller 92 is configured for this function.
It will be further understood by one skilled in the art, that programmable controller 92 may be configured to control release actuator 71 in a similar manner to move pivot axis 17 such that the opening distance between first and second gripping members 30 and 15 respectively remains constant while first gripper mechanism 3 is moving the second direction opposite to the first direction of workpiece feeding.
It will be further understood by one skilled in the art, that the gripping force exerted by gripping members 15 onto workpiece 100 may be determined by a force produced by release actuator 71 and controlled by programmable controller 92.
It will be further understood by one skilled in the art, that programmable controller 92 and release actuator 71 may be used to determine the distance between gripping member 15 and gripping member 30 thereby providing a gap between the workpiece 100 and gripping member 15 during the times when first gripper mechanism 3 is stopped or moving in a second direction opposite to the first direction. The distance between the gripping members and therefore the gap between workpiece 100 and gripping member 15 may be specifically optimized for different thicknesses of workpiece 100.
A second embodiment in accordance with the present invention will be described below with reference to the accompanying drawings.
A feeding apparatus 101, depicted generally in
A workpiece 100 is illustrated and a first direction of workpiece feeding is depicted with a direction arrow.
A first gripper mechanism 103 is supported by and configured for linear movement along linear guides 150 and 151. Linear guides 150 and 151 are supported by frame 102 and stationary relative thereto. In the illustrated embodiment, linear guides 150 and 151 are parallel cylindrical rods. Linear guides 150 and 151 are arranged parallel to the direction of workpiece feeding. First gripper mechanism 103 is therefore linearly guided and movable in a first direction of workpiece feeding and in a direction opposite to the first direction of workpiece feeding.
First gripper mechanism 103 comprises a first gripping member 130 and a second gripping member 115. Second gripping member 115 is movable relative to first gripping member 130. Further, in this embodiment, first gripper mechanism 103 further comprises a first spring 118 and a second spring 119. First and second springs 118 and 119 are arranged for urging second gripping member 115 toward gripping member 130. Alternatively either first spring 118 or second spring 119 or both may be omitted.
A second movable gripper mechanism 104 is supported by and configured for linear movement along the linear guides 150 and 151. Second gripper mechanism 104 comprises a first gripping member 140 and a second gripping member 125. Second gripping member 125 is movable relative to first gripping member 140. Further, in this embodiment, second gripper mechanism 104 further comprises a first spring 128 and a second spring 129. First and second springs 128 and 129 are arranged for urging second gripping member 125 toward gripping member 140. Alternatively either first spring 128 or second spring 129 or both may be omitted.
A reversible rotary gripper mechanism drive actuator 160 is supported by frame 102 and stationary relative thereto. Reversible rotary gripper mechanism drive actuator 160 is preferably a brushless permanent magnet electric servo motor. Alternatively, reversible rotary gripper mechanism drive actuator 160 may be a stepper motor, a hydraulic motor, a rotary pneumatic actuator, or any reversible rotary actuator that may be adjustable in angle of rotation. Reversible rotary gripper mechanism drive actuator 160 is controlled by a programmable controller 191 (
A drive link or driving member 134 is connected to output shaft 135 of reversible rotary gripper mechanism drive actuator 160 for rotation therewith. Driving member 134 being connected to output shaft 135 for rotation therewith rotates about a rotation axis 136 of output shaft 135. It should be noted that while driving member 134 is shown as a separate component from output shaft 135 of reversible rotary gripper mechanism drive actuator 160, driving member 134 could be constructed as an integral part of output shaft 135, such as an eccentric feature of output shaft 135.
A first gripper mechanism drive connecting link 132 is pivotally connected at a first end by connecting pin 133 to a first end of driving member 134 at a first pivot axis 137 and at a second end by connecting pin 131 to movable gripper mechanism 103 at a second pivot axis 138.
A second gripper mechanism drive connecting link 142 is pivotally connected at a first end by connecting pin 143 to a second end of driving member 134 at a first pivot axis 147 and at a second end by connecting pin 141 to movable gripper mechanism 104 at a second pivot axis 148.
In operation the distance between rotational axis 136 and first pivot axis 137 is constant. Furthermore, in operation the distance between rotational axis 136 and third pivot axis 147 is constant. That is, driving member 134 is a fixed length driving member.
Also in operation, the rotation axis 136 of output shaft 135 and due to the connection of driving member 134 thereto, is located at the midpoint between the first pivot axis 137 and third pivot axis 147.
Still also in operation, gripper mechanism drive connecting link 142 and gripper mechanism drive connecting link 132 are equal in length.
An release actuator 171, depicted generally in
Reversible motor 170 is preferably a brushless permanent magnet electric servo motor controlled by a programmable controller 192. Alternatively, reversible motor 170 is an electric stepper motor, a hydraulic motor, or a rotary pneumatic actuator. Programmable controller 192, depicted generally in the drawings is of conventional design well known in the art. Programmable controller 192 is connected with a wire 194 in a particular sense to motor 170 and in a more general sense to release actuator 171.
A release connecting link 113 (
An release actuator 181, depicted generally in
Reversible motor 180 is preferably a brushless permanent magnet electric servo motor controlled by a programmable controller 193. Alternatively, reversible motor 180 is an electric stepper motor, a hydraulic motor, or a rotary pneumatic actuator. Programmable controller 193, depicted generally in the drawings is of conventional design well known in the art. Programmable controller 193 is connected with a wire 196 in a particular sense to motor 180 and in a more general sense to release actuator 181.
A release connecting link 123 is pivotally connected at a first end by connecting pin 122 to driving member 121 at a first pivot axis 126 and at a second end by connecting pin 124 to second gripping member 125 at a second pivot axis 127. The arrangement of the release connecting link 123 and second pivot axis 127 is such that the second pivot axis 127 is arranged generally perpendicular to the direction of movement of the second gripping member 125 of the first gripper mechanism 104 relative to the first gripping member 140 of the first gripper mechanism 104 and is further arranged generally perpendicular to the first direction of workpiece feeding. As such, the second pivot axis 127 of the first gripper mechanism 104 is movable in the direction of workpiece feeding and in the direction opposite to the direction of workpiece feeding.
In operation, release actuator 171 cooperates with springs 118 and 119 to move second gripping member 115 towards first gripping member 130 for gripping workpiece 100. Alternatively, in the absence of springs 118 and 119, release actuator 171 moves second gripping member 115 towards first gripping member 130 for gripping workpiece 100. In particular, output shaft 110 of reversible motor 170 is rotated to move driving member 111, connecting pins 112 and 114, and release connecting link 113 such that second gripping member 115 is moved into contact with workpiece 100 thereby gripping the workpiece 100 between second gripping member 115 and first gripping member 130.
Release actuator 181 moves second gripping member 125 away from first gripping member 140 for releasing a grip on workpiece 100. In particular, output shaft 120 of motor 180 is rotated to move driving member 121, connecting pins 122 and 124, and release connecting link 123 such that second gripping member 125 is moved away from workpiece 100 thereby releasing workpiece 100 from second gripping member 125 and first gripping member 140.
Reversible rotary gripper mechanism drive actuator 160 is rotated to move driving member 134, connecting pins 131 and 133, and gripper mechanism drive connecting link 132 such that first gripper mechanism 103 and workpiece 100 is moved in a first direction of workpiece feeding as depicted by an arrow in the drawings. The feeding distance of workpiece 100 is determined by the rotational angle of rotary gripper mechanism drive actuator 160 and driving member 134. As rotary gripper mechanism drive actuator 160 is preferably a brushless permanent magnet electric servo motor controlled by programmable controller 191, the rotation angle of rotary gripper mechanism drive actuator 160 and therefore the feeding distance of workpiece 100 is easily adjusted.
At the same time due to the interconnected nature of the components, connecting pins 141 and 143, and gripper mechanism drive connecting link 142 is moved by driving member 134 such that the second gripper mechanism 104 is moved in a second direction opposite to the first direction of workpiece feeding.
When the required workpiece feeding distance has occurred, reversible rotary gripper mechanism drive actuator 160 is stopped.
Release actuator 181 cooperates with springs 128 and 129 to move second gripping member 125 towards first gripping member 140 for a gripping of the workpiece 100. Alternatively, in the absence of springs 128 and 129, release actuator 181 moves second gripping member 125 towards first gripping member 140 for gripping workpiece 100. In particular, output shaft 120 of motor 180 is rotated to move driving member 121, connecting pins 122 and 124, and release connecting link 123 such that second gripping member 125 is moved into contact with workpiece 100 thereby gripping the workpiece 100 between second gripping member 124 and first gripping member 140.
Release actuator 171 moves second gripping member 115 away from first gripping member 130 for releasing a gripping force on workpiece 100. In particular, output shaft 110 of motor 170 is rotated to move driving member 111, connecting pins 112 and 114, and release connecting link 113 such that second gripping member 115 is moved away from workpiece 100 thereby releasing workpiece 100 from second gripping member 115 and first gripping member 130. That is, by actuation of release actuator 171, the second gripping member 115 is moved in a direction relative to first gripping member 130 and in a direction generally perpendicular to the first direction of workpiece feeding.
Reversible rotary gripper mechanism drive actuator 160 is rotated to move driving member 134, connecting pins 141 and 143, and gripper mechanism drive connecting link 142 such that second gripper mechanism 104 is moved in the first feeding direction of workpiece 100. The feeding distance of workpiece 100 is determined by the rotational angle of rotary gripper mechanism drive actuator 160 and driving member 134.
At the same time due to the interconnected nature of the components, connecting pins 131 and 133, and gripper mechanism drive connecting link 132 is moved by driving member 134 such that first gripper mechanism 103 is moved in a direction opposite to the first feeding direction of workpiece 100.
The operation is periodically repeated in synchronization with the stamping machine or the like.
It will be understood by one skilled in the art, that at any time during the period of operation when the movable gripper mechanisms 103 and 104 are stopped, actuators 171 and 181 may be used to release the workpiece from both first and second movable gripper mechanisms 103 and 104 to allow for a piloting or final positioning operation of a tool or the like in the stamping machine or the like.
Alternative actuator constructions in accordance with the present invention will be described below with reference to the accompanying drawings.
An actuator 271, depicted generally in
Reversible motor 270 is preferably a brushless permanent magnet electric servo motor controlled by the programmable controller 92. Alternatively, reversible motor 270 is an electric stepper motor, a hydraulic motor, or a rotary pneumatic actuator.
Actuator 271 further comprises an internally threaded member 215. Threaded rod 211 and internally threaded member 215 cooperated to produce a linear movement of internally threaded member 215 upon rotation of threaded rod 211. The threads of threaded rod 211 and internally threaded member 215 are preferable of a trapezoidal type power thread. Alternatively the threads of threaded rod 211 and internally threaded member 215 could be of standard triangular type. Alternatively threaded rod 211 could be a ball screw and internally threaded member 215 a re-circulating ball nut.
Release connecting link 13 is at the first end pivotally connected by the connecting pin 12 to internally threaded member 215.
An actuator 371, depicted generally in
Release connecting link 13 is at the first end pivotally connected by the connecting pin 12 to linear thrusting member 310.
Alternative actuators 271 and 371 may be operated to provide a substantively equivalent function to that of actuators 71, 81, 171 and 181.
While the illustrated embodiments are shown having upper gripping members being the movable gripping member, it should be understood that, alternatively, the lower gripping members could be the movable gripping member.
Further, although the apparatus is described as having an actuator and link arrangement for the opening or closing of second gripper mechanism 4 similar to that used for the opening or closing of first gripper mechanism 2, that is with a motor 80, a driving member and a release connecting link 23, the stationary arrangement of second gripper mechanism 4 may allow for omission of a connecting link. Such arrangements do not depart from the spirit of, or exceed the scope of the claimed invention. The embodiment presented represents a preferred embodiment in that common components may be used in the functionally corresponding components of the actuator and link arrangement providing the opening or closing functions of first gripper mechanism 3 and second gripper mechanism 4 thereby reducing the number of different components to be manufactured.
Still further, although the apparatus is described as having separate programmable controllers, it is noted here that individual programmable controllers could be combined in any combination even to the combination of a single programmable controller. In the first embodiment the controllers referenced herein being 91, 92, and 93. In the second embodiment the controllers referenced herein being 191, 192, and 193.
Although the invention has been described in terms of particular embodiments in an application, one of ordinary skill in the art, in light of the teachings herein, can generate additional embodiments and modifications without departing from the spirit of, or exceeding the scope of, the claimed invention. For example, actuators 71, 171 and 181, could be any actuator configured to produce a movement of pivot axis 17, 117 and 127 respectively in a direction generally perpendicular to the first direction of workpiece feeding.
Accordingly, it is understood that the drawings and the descriptions herein are proffered only to facilitate comprehension of the invention and should not be construed to limit the scope thereof.
This application is a national phase application pursuant to 35 U.S.C. §371 of International Application No. PCT/US2010/054972, filed Nov. 1, 2010, which itself claims the benefit under 35 U.S.C. 119 §(e) of the earlier filing date of U.S. Provisional Patent Application No. 61/256,556 filed on Oct. 30, 2009, which is hereby incorporated by reference.
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