1. Field of the Invention
The present invention relates to systems for transferring a work piece from a loading location to a processing location. More particularly, but not necessarily exclusively, the present invention relates to welding systems in automobile assembly lines. For example, the invention may be applied to a parts loading jig which is transferred between a welding station and a loading station.
2. Description of the Related Art
The auto industry has, in recent years, seen significant improvements in work place efficiencies. Robots are able to perform certain repetitive tasks with improved repeatability and accuracy.
It is common, for example, to have robots weld the vehicle sub-assembly components on a jig which holds the component parts of the sub-assembly in position at a welding station. Conventionally, the jig is transferred to a loading station which is a safe distance from the welding station to prevent injury. The jig is then ‘tilted’ to an angle making it more readily accessible to the assembly associate to load the jig.
Two drive units are normally used to perform these functions; one to transfer the jig between the welding and loading stations, and the other to ‘tilt’ the jig once it arrives at the loading station. The two drive units are independent, which means they have to be programmed and maintained separately, adding expense to the assembly process.
It is therefore an object of the present invention to provide a more efficient and cost effective transfer system.
It is another object of one embodiment of the present invention, to provide a transfer system for use in a welding installation wherein the transfer and tilt functions can are carried out by a single drive unit.
In one of its aspects, the present invention provides an apparatus for transferring and tilting a work piece, said apparatus comprising:
a transport carriage assembly for motion along a guide track having a limit position; the transport carriage assembly further comprising:
In one embodiment, the apparatus has a drive unit for driving the carriage assembly along the guide track. The drive unit has a drive motor and a transmission portion arranged to displace the first carriage member, and consequently the second carriage member, relative to the guide track. Desirably, the drive motor is a servo motor.
In another aspect of the present invention, there is provided a transfer device comprising an undercarriage with two or more carriage portions which are movable along a travel path between a first location and a second location, the carriage portions carrying at least one work piece support, a linkage extending between the carriage portions and which is operable to change the position of the work piece support when one carriage portion moves relative to another along the travel path. In one embodiment, the carriage portions are confined to a linear travel path and one of them is stationary during the period of relative moment between the carriage portions. The work piece support is movable between a work piece transfer position and a work piece loading position. The linkage has two pairs of arms which are pivoted together at a common pivot location and to a corresponding carriage portion at each end. The work piece support, which is fixedly attached to one of the pairs of arms near said common pivot location, is in a generally horizontal orientation at one of said locations and is inclined at the other of said locations.
Preferably, a limit station is provided on the travel path to limit movement of one of said carriage portions along the travel path. A releasable anchor portion is also provided for removably anchoring one of said carriage portions as the other carriage portion travels along the travel path.
In still another of its aspects, the present invention provides a transfer device for transferring a work piece from a loading station to a welding station, comprising an undercarriage with at least two carriage portions, which are movable along a travel path between the loading station and the welding station, the pair of carriage portions carrying at least one work piece support, a drive unit for driving the carriage portions along the travel path and a linkage joining the carriage portions. The linkage is operable to change the orientation of the work piece when one carriage portion moves relative to the other carriage portion along the travel path.
In yet another of its aspects, the present invention provides a welding installation comprising a welding station, a loading station and a transfer device for transferring a work piece between the stations. The transfer device has a work piece support and an undercarriage with two or more carriage portions. The carriage portions are movable by a drive unit along a travel path between the loading station and the welding station. The carriage portions are interconnected by a linkage which is operable to change the orientation of the work piece support when the position of one carriage portion changes relative to the other along the travel path.
In yet another aspect of the present invention, there is provided a method of transferring work pieces between a loading station and a welding station, comprising:
In still another aspect of the present invention, there is provided a transfer device for transferring a work piece between a loading station and a welding station, comprising:
In still another of its aspects, there is provided a method of transferring work pieces between a loading station and a work piece processing station, comprising:
Several preferred embodiments of the present invention will be provided, by way of example only, with reference to the appended drawings, wherein:
a,
5
b, and 5c are schematic views of other transfer devices and
a,
6
b and 6c are schematic views of still another transfer device.
Referring to the figures, there is provided a welding installation 10 comprising a welding station 12 and a loading station 14 and a transfer device 16 to transfer a work piece between them.
The transfer device 16 has an undercarriage with two carriage portions 18 and 20 which are confined to travel along a pair of tracks 22 defining a travel path between the welding station 12 and loading station 14. A first carriage portion 18 and a second carriage portion 20 is joined by a linkage 24 which carries a work piece support 26.
The work piece support 26, is shown in its tilted “loading position” in
The angle of the tilt, shown as ‘theta’ in
A drive unit 28 is positioned on the first carriage portion 18 and includes a servo motor 30 and a transmission drive 32 to displace the carriage portions 18 and 20 along their travel path T. In this case, the transmission is a rack and pinion drive but a number of equivalents are also contemplated as will be understood by those skilled in the art including screw, pneumatic, chain or hydraulic drives and the like.
Referring to
The linkage 24 includes a pair of arms 50 which are pivoted to the first carriage portion 18 at pivots 52 and a pair of arms 54 which are pivoted to the second carriage portion 20 at pivot 56. The arms 50 and 54 are pivoted together at a common pivot 58. The work piece support 26 includes a load bearing member 60 which is fixed, at an angle “beta”, to the arms 54. In this case, the pivot 58 is beneath the load bearing member 60. The first carriage portion 18 includes a support extension 42 which supports the load bearing member 60 in its transfer position, as shown in
A particular feature of the device 10 is the way in which the drive unit 28 is capable of performing both the “transfer” and the “tilt” functions. It can transfer (or shuttle) the carriage portions between the welding and loading stations in a first phase of motion and then change the orientation of the work piece support (and in this particular case “tilt” the work piece support) between its loading and transfer positions in a second phase of motion. These two functions are linked to the movement of the carriage portions along the travel path. The first phase occurs as both carriages move together, with no relative movement between them, in the same direction along the travel path, while the second phase occurs when one carriage moves relative to the other, along the travel path. Therefore, the second phase can occur when the first carriage portion 18 approaches second carriage portion 20 to raise (or tilt) the work piece support or when first carriage portion 18 departs from second carriage portion 20 to lower the work piece support. These two phases may or may not occur at the same time.
Referring to
The drive unit 28 continues to displace the first carriage portion 18 along the travel path, while the second carriage portion 20 is now stationary. This causes the position of the first carriage portion 18 to change relative to the second carriage portion 20, in turn causing the arms 50, 54 to move as the pivot 52 moves toward pivot 56, thereby tilting the work piece support 26 upwardly away from the support extension 42 toward its tilted loading position as shown in
The drive unit then reverses and displaces the first carriage portion 18 away from the second carriage portion 20, in turn causing the arms 50, 54 to move to lower the work piece support until it engages the support extension 42 and the pivots 52 and 56 are at their transfer spacing. The clasp 38a is then released from the latch 38c by the actuator 38b so that the carriage portions 18, 20, once again, travel in unison under the force of the drive unit toward the welding station 12.
Desirably, the drive unit 28 is capable of accelerating and decelerating the carriage portions 18, 20 as they approach the loading and welding stations, as well as other intermediate points therebetween in order to minimize loading on the device.
In the preferred embodiment, the tilting movement of the work piece support 20 between the loading and transfer positions occurs only when the second carriage portion 20 is arrested at the limit station. The drive unit, in this case, is the sole source of power to move the carriage portions together in one phase and to move one of the carriage portions relative to the other, when the latter is arrested, in another phase.
Although the carriage portion is arrested at a limit station in the preferred embodiment, it should be understood that the relative motion of the carriage portions (which is necessary to actuate the pivotal movement of the linkage arms) can be generated by other means. For example, a brake may be used to reduce, or to stop, the speed of the second carriage portion 20 relative to the first carriage portion 18.
The device 10 therefore uses the relative movement between the carriage portions to cause a change in the orientation of the work piece support.
a,
5
b and 5c schematically illustrate several other alternative embodiments.
a also illustrates, in dashed lines, a third carriage portion 130 and another workpiece support 132. Though not shown in this embodiment, the drive unit 110 or another drive unit equivalent to it (or equivalent to those earlier described, or other drive unit as would be understood by those skilled in the art), may or may not be provided to displace carriage portion 130 relative to carriage portion 104. For example, carriage portion 130 may simply be configured to abut a block at a limit station (not shown) and cause a change in orientation in the workpiece support 132 when the carriage portion 104 is displaced relative to the carriage portion 130.
a illustrates still a further embodiment in chain dotted lines. In this case, the two separate workpiece supports 106 and 132 are replaced by a single workpiece support 134, which is pivoted to the work piece supports 106 and 132 at pivots 136, 138, or by some other linkage as would be understood by those skilled in the art.
It is also contemplated that more than two carriage portions may be employed to cause more than one sequential change in orientation. For example, three carriage portions may be used, wherein the relative movement between the first and second carriage portions causes a first orientation step and the relative movement between the second and third carriage portions causes a second orientation step. Alternatively, the first and second orientation steps may be implemented by linkage between the two carriage portions, along with suitable controls of the positions or displacement of the two carriage portions as described herein and as would be understood by those skilled in the art. For example, the first orientation step might occur in one portion of the relative movement between the carriage portions, while the second orientation step might occur in a second portion of the relative movement.
It is also contemplated that more than two motors may be used in place of the single servo motor and the limit station as illustrated herein. In this case, the two motors may be operated at different speeds and accelerations to achieve the movement of the carriage portions between the welding and loading stations. For example, the two motors could be controlled so that they accelerate and decelerate at different rates so that there is a gradual relative movement between the carriage portions to bring the work piece to its loading position. Thus, while one of the carriage portions in the illustrated embodiment of
a through 6c illustrate yet another transfer device 150 having a pair of carriage portions 152 and 154 which support a workpiece support 156 by way of a linkage represented by linkage members 158 and 160. The carriage portion 152 has a drive unit (not shown) to displace the transfer device along the track shown schematically at 156. The carriage portion 154 has a rotational drive unit (not shown), for rotating linkage member 160 about its pivot axis 162. The rotational drive unit may be one of a number of forms, including a servo motor. In
While the travel path of the device 10 is linear, it will be understood that the transfer device may also function where the travel path is curvilinear, and operable in one or more horizontal and inclined planes. In other words, the carriage portions may travel from a welding station at one lower elevation to a loading station at an upper elevation.
While the above embodiment involves a welding installation, the transfer device itself may be used to transfer work pieces between loading stations and other work piece processing stations such as those used in a paint line where, for example, it is important to keep an assembly associate safely away from the processing station.
This application is a continuation under 37 C.F.R. 1.53(b) of U.S. patent application Ser. No. 10/659,521 filed Sep. 9, 2003, which is a divisional under 37 C.F.R. 1.53(b) of U.S. patent application Ser. No. 09/894,855 filed Jun. 28, 2001, which claims the benefit of U.S. Provisional Application Ser. No. 60/290,947 filed May 14, 2001, and of U.S. Provisional Application Ser. No. 60/286,815 filed Apr. 26, 2001, which applications are incorporated herein by reference.
Number | Date | Country | |
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60290947 | May 2001 | US | |
60286815 | Apr 2001 | US |
Number | Date | Country | |
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Parent | 09894855 | Jun 2001 | US |
Child | 10659521 | Sep 2003 | US |
Number | Date | Country | |
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Parent | 10659521 | Sep 2003 | US |
Child | 11012080 | Dec 2004 | US |