DE102014107533A1 - Reconfigurable robotic gripper assembly - Google Patents

Abstract

A reconfigurable end effector assembly includes a main spar, limb, and branches. The branches extend radially outward from the limb. Tandem branch connection assemblies connect the branches to the link and include first and second branch connections each having a retaining cam. Tool modules mounted on the branches are slidable and rotatable with respect to the branches. The link assemblies rotate and translate with respect to the longitudinal axis of the link only when the retaining cam is released. A configuration tool has an actuator and fingers. The branch connections define openings into which the fingers engage. The tool includes a latch that engages the retaining cam and clamps and releases the retaining cam. A flexible fairing unit is mountable on the limb and is configured to route pieces of conduit to each of the tool modules.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of US Provisional Application No. 61 / 828,808, filed May 30, 2013, which is hereby incorporated by reference in its entirety.

TECHNICAL AREA

The present disclosure relates to a reconfigurable robotic gripper assembly.

BACKGROUND

Robot gripping members are used in a variety of manufacturing processes to perform work on a given workpiece. Gripping devices may include tool modules with end tools that can grasp, transport, align, and release the workpiece, depending on the design. Certain gripping members include a main spar that is gripped and moved by a material handling robot when needed. The limbs of the gripping member extend outwardly from the main spar. Several branches extend radially outward from the links to form a field of tooling modules.

The individual tool modules and end tools can be manually adjusted to a desired position and orientation prior to performing a work task. Such gripping members can simplify the manufacturing process. However, conventional designs for joining the various limbs and branches, as well as directing power to the end tools, may be suboptimal in terms of package size, adjustability, and weight.

SUMMARY

A gripper assembly disclosed herein is intended to address the problems noted above, in part by using lightweight tandem splice assemblies, each of which uses a pair of retaining cams with respective handles. The pair of retaining cams form an eccentric connection that allows for relatively quick locking / unlocking and repositioning of the various branches of a grasper assembly.

The gripper assembly may include a configuration tool with an actuator. The actuator may be used to directly engage the retaining cam grips and the two branch connections of each tandem branch connection arrangement. The configuration tool automatically releases the retaining cam and then rotates and / or linearly positions the branch connections with respect to a given member, the particular configuration being determined by the design of the workpiece.

In addition, a flexible trim unit may also be included that directs pneumatic tubes or other flexible conduits to each of the end tools. Unlike prior art packages, this accomplishes the flexible trim unit of the present invention without bearing the structural load of the branches.

The foregoing features and advantages and other features and advantages of the present invention will become more readily apparent from the following detailed description of some of the best modes and other embodiments for carrying out the invention as defined in the appended claims when read in conjunction with the accompanying drawings becomes.

BRIEF DESCRIPTION OF THE DRAWINGS

1 FIG. 10 is a schematic illustration in plan view of a reconfigurable gripper assembly having a plurality of configurable tool modules and a configuration tool in accordance with the present disclosure. FIG.

2 is a schematic illustration in a perspective view of a branch portion of the Greiforgananordnung of 1 ,

3 Fig. 3 is a schematic illustration in perspective view of an exemplary tandem branch connection arrangement as shown in Figs 2 is shown.

3A Fig. 3 is a schematic illustration in perspective view of a flexible snap-in socket associated with the tandem branch connection arrangement of Figs 3 can be used to connect separate eccentric branch connections.

4 FIG. 12 is a schematic illustration in a plan view of an exemplary embodiment of the present invention. FIG 1 shown configuration tool.

5 FIG. 3 is a schematic illustration in a side view of a flexible trim unit associated with the reconfigurable gripper assembly of FIG 1 can be used.

6 FIG. 12 is a schematic illustration in a plan view of FIG 5 shown flexible fairing unit.

PRECISE DESCRIPTION

With reference to the drawings, wherein like numerals denote like components throughout the several figures, FIG 1 a reconfigurable gripper assembly 10 shown schematically. The gripper assembly 10 includes a main spar 12 that has a T-fitting 15 or another suitable connector with a link 16 connected, which is a longitudinal axis 11 having. The Member 16 can, as in 2 and 4 shown is an inner wall 19 exhibit. The main spar 12 can be positioned anywhere in a Cartesian frame of reference (xyz reference frame), ie in free space, as from a robot (R) 14 for example, from a multi-axis material handling robot of the type typically used in a logistic manufacturing facility. As will be well understood in the art, such a robot may be programmable, attached to a stationary or movable base, and configured to support the main spar 12 as needed with respect to a workpiece (WP) to position.

One link 16 the gripping device arrangement 10 extends at right angles with respect to the main spar 12 with the help of the T-fitting 15 and provides the necessary structural cross support for a variety of branches 18 ready. Each of the branches 18 carries a tool module 20 where each tool module 20 an end tool 22 includes. The branches 18 can freely on the limb 16 to be appropriate. As described here, the branches are 18 with the attached tool modules 20 movable and therefore can be arranged as needed to allow the end tools 22 to the workpiece (WP) z. As a glass plate, a body structure sheet or the like tack or interact with this in other ways.

To stick with the non-limiting example of a body panel, the corresponding end tools are 22 in the various figures are shown as pneumatic suction cups of the type used for securing and moving automotive or other body panels without damaging the finished viewing surfaces thereof. However, other end tools can easily do so 22 can be considered within the intended scope of the present invention, such as pliers, clamps, spray nozzles, etc., and therefore, the specific construction of the end tools 22 vary.

In the 1 shown tool modules 20 are with a corresponding branch 18 via a linear / rotatable locking mechanism 24 connected, ie any device or any mechanism that allows the tool modules 20 in place in both a rotational direction (arrow A) and a linear direction (arrow B) with respect to a longitudinal axis 13 of the branch 18 be locked and selectively unlocked in each direction to a translation or rotation of the tool module 20 with reference to the branch 18 to enable. An exemplary locking mechanism suitable for use as the locking mechanism 24 may be suitable, for example, in Lin et al. ( US 2011/0182655 ) and is hereby incorporated by reference in its entirety. Every branch 18 extends from the longitudinal axis 11 of the limb 16 out radially to the outside. The different branches 18 are in turn via a corresponding tandem branch connection arrangement 30 with the limb 16 connected.

The tandem branch connection arrangement 30 whose structure is described in more detail below with reference to 2 and 3 is described, allows quick adjustment and repositioning of each branch 18 with respect to the axis 11 of the limb 16 as indicated by arrows C and D in FIG 1 is displayed, either manually or via a configuration tool (CT) 50 , An example of such a configuration tool 50 will be described below with reference to 4 described. Each tandem branch connection arrangement 30 connects different branches 18 with the limb 16 in an eccentric configuration. The configuration tool 50 from 4 can directly with a given tandem branch connection arrangement 30 couple to the tandem branch connection arrangement 30 to selectively unlock and the branches 18 reposition as needed or an operator can accomplish this task manually.

2 represents a separate branch segment of the Greiforgananordnung 10 from 1 along the axis 13 that is, from the tandem branch connection arrangement 30 to the tool module 20 , The tandem branch connection arrangement 30 is with respect to the axis 13 over the locking mechanism 24 locked in a desired orientation. A flexible line 63 , z. As a pneumatic tube or a pneumatic hose, that allows a force to the end tool 22 is delivered, in this case a negative pressure, via an end tool 22 is provided in the form of a suction cup. In other embodiments, the conduit 63 provide electrical power or hydraulic fluid power. The tandem branch connection arrangement 30 is in a similar way with respect to the axis 11 of member 16 locked in a desired orientation.

The term "tandem" specifically refers to the use of two identical but inversely oriented, eccentric branch connections 32A and 32B , The branch connections 32A and 32B are independently positioned or configured, but may be coupled to an integrated tandem unit described below. Each branch connection 32A and 32B includes a pair of interior walls 33 and 37 each defining an opening in which the member 16 or the branch 18 are included. The branch connections 32A . 32B are then over a fastener 35 on the branch 18 clamped. At each branch connection 32A . 32B is a holding cam 34 provided, ie two retaining cams 34 per tandem branch connection arrangement 30 to thereby make the branch connections 32A and 32B on the limb 16 clamp.

When they are clamped, the retaining cams lock 34 the tandem branch connection arrangement 30 in a safe way with the link 16 in the axial direction and the direction of rotation. The tandem branch connection arrangement 30 can via an actuation of the retaining cam 34 Simply be released from the deadlock to allow the tandem branch connection arrangement 30 along the axis 11 can freely slide or rotate around them, ie the respective arrows C and D in 1 , Although it is in for simplicity 2 has been omitted, the interior walls can 33 . 37 be provided with a friction interface, such as a node pattern, wedges or a friction material to minimize the likelihood that over time a jammed retaining cam 34 nevertheless with reference to the axis 11 can move.

Regarding 3 is the tandem branch connection arrangement 30 relative to a portion of the limb 16 shown in a clamped position. Optional home position marks (M) can be made on different surfaces of the gripper assembly 10 from 1 marked or labeled, here along the link 16 shown to facilitate reconfiguration in certain cases. Configuring the gripper assembly 10 on the home position marks (M) of 3 can be done manually. Therefore, the home position markings (M) should be easily identifiable to a human operator with placement at, for example, physical boundaries of a range of motion of each connection and / or at locations free from conflict with other parts of the end effector assembly 10 are. The home position marks (M) provide reference lines or datums for quickly resetting all connections of the end effector assembly 10 to a desired configuration, which may be particularly useful after a production cycle or tool collision. In some embodiments, machine imaging may be used to image the home location markers (M) to automate the reconfiguration process, or an operator may also use the home location markers (M) to manually reconfigure the setting.

Regarding 3A can the tandem branch connection arrangement 30 from 3 although they are from separate branch connections 32A and 32B is constructed using a flexible snap-in socket 40 form an integrated tandem unit. The flexible snap-in socket 40 can be a pair of flanges 42 . 43 from a flexible rubber or polymeric material, the flanges 42 . 43 through a piece of an annular side wall 41 are separated. The annular side wall 41 may be cut open as shown, around an angled slot 45 define. The presence of the slot 45 allows the flanges 42 and 43 whose pages are in the view of 3 are visible, partially collapse when the sidewall 41 is compressed. This in turn allows the socket 40 through the tandem branch connection arrangement 30 passes. Because the jack 40 is elastic, it springs back into the generally cylindrical shape of 3A as soon as the flange 43 completely through the branch connections 32A and 32B gone through, with the flanges 42 and 43 the branch connections 32A . 32B flank. When the retaining cams 34 can unlock each branch connection 32A and 32B independent on the limb 16 while still rotating along the axis 11 be moved together.

Regarding 4 can the gripper assembly 10 from 1 via the configuration tool 50 be automatically adjusted as mentioned above. In an exemplary embodiment, the configuration tool includes 50 an actuator housing 53 with actuators 52 and 52A which apply a movement as indicated by an arrow J and / or by arrows F and G, as disclosed below. The configuration tool 50 can be a logic board 58 , Actuating finger 54 that's about the actor 52 be moved and a retaining cam 55 include that over the actor 52A is moved, and the one with the handle 36 the holding cam 34 engages. The actors 52 and 52A may be any pneumatic, hydraulic or electromechanical device configured to apply a force to the actuating fingers 54 and the retaining cam 55 apply, for example ball screws or other linear or rotary actuators.

A robot (not shown) moves the configuration tool 50 in position with respect to a given branch connection 32A or 32B and closes over the actor 52 the actuating fingers 54 selectively with the help of signals sent to the logic board 58 be issued. The partially closed and fully closed positions are in 4 are shown by the respective solid and broken lines at E1 and E2. A continued movement away from the branch connection 32A or 32B moves the actuating fingers 54 in a fully open position, ie out of engagement with the branch connection 32A or 32B , The actor 52 moves the actuating fingers 54 far enough to the branch connection 32A or 32B release and then closes the actuating fingers 54 to the branch connection 32A or 32B to take. An end 38 the actuating finger 54 penetrates into the centering opening 38 to go directly to the special branch connections 32A or 32B intervene. In an alternative embodiment, only one of the actuating fingers moves 54 while remaining stationary, a configuration that can reduce complexity without sacrificing much of the manner of the forceps functionality shown.

The holding cam 55 from 4 As shown, it may be generally L-shaped or otherwise shaped to fit the handle 36 the holding cam 34 to take up and to intervene. An arm 56 can with the holding cam 55 connected or integrally formed therewith and become another actuator 52A in the actuator housing 53 extend. During a configuration of the gripping member, the actuator closes 52 the actuating fingers 54 partly such that the end 39 each actuating finger 54 in the centering hole 38 penetrates to the special branch connection 32A or 32B partially to engage. The holding cam 55 and the associated arm 56 turn to move around with the handle 36 the holding cam 34 to engage. Then the other actuator moves 52A the retaining cam 55 and the associated arm 56 vertically in a position I and thus the handle 36 the holding cam 34 in a position H, ie to the actuator 52A down (arrow F) to the branch connection 32A or 32B for reconfiguration of the gripping member to unlock.

To the tandem branch connection arrangement 30 to reconfigure, the actuating fingers 54 from the actor 52 then completely closed to the branch connection 32A or 32B safely grab and move while the configuration tool 50 is rotated and translated via a material handling robot (not shown). The actuator moves at the desired branch connection position 52A the retaining cam 55 and the associated arm 56 in the direction of arrow G, thereby moving the handle 36 the holding cam 34 in a locking position and thereby locks the branch connection 32A or 32B ,

Regarding 5 and 6 is a flexible fairing unit 60 in a side and a top view (view from above) shown. The fairing unit 60 can with the Greiforgananordnung 10 from 1 used to pieces a flexible pipe 63 and to accommodate these to the various end tools 22 (please refer 1 and 2 ). The administration 63 directs the required negative pressure, the required compressed air, required hydraulic fluids or required electricity to the end tools 22 depending on the specific construction to the end tools 22 to activate. The administration 63 can be provided in suitable pieces that allow a sufficiently large range of motion. Unlike prior art flexible trim units, the construction of FIG 5 and 6 the structural burdens of different branches 18 not and instead provides only the necessary support for flexible or rigid carriers 70 . 72 ready.

As in 5 Best shown is the limb 16 from a spar socket 64 be surrounded. branch lines 62 extend radially from the branch connection 32A or 32B out to the outside, with each branch rail 62 a U channel 61 defined by the line 63 is included. The locking mechanism 24 is along a given branch 18 (please refer 1 ) on the branch rails 62 separated from the flexible fairing unit 60 positioned, with the end of the line 63 attached to the corresponding end tool 22 (please refer 1 ) ends, near the locking mechanism 24 is arranged.

An I-beam 68 extends parallel to the axis 11 of in 1 shown member 16 and supports the flexible vehicle 70 and the rigid carrier 72 , where the rigid carrier 72 a given tandem branch connection arrangement 30 surrounds / encircles. Consequently, it is possible for the wearer 70 . 72 linear along a branch 18 (please refer 1 ), but the carriers 70 . 72 do not rotate in conjunction with a rotation of the branch 18 (please refer 2 ).

The flexible and the rigid carrier 70 respectively. 72 are in 6 with reference to the I-beam 68 shown. A cable guide constructed of nylon or other solid wear resistant material is a special type of flexible carrier 70 that with the flexible paneling unit 60 can be used, although any other construction can be used that is capable of the line 63 to pick them up and shield them from damage without restricting their movement. The in the flexible carrier 70 housed pipe 63 can become a central distributor 75 be guided, z. B. a pneumatic distributor in the example of Saugnäpfen that for the end tools 22 from 1 be used. Such a distributor 75 Can be used to the line 63 to direct to the different connection points. The use of the distributor 75 also allows the flexible carrier 70 every branch 18 about half the length of the I-beam 68 includes.

Consequently, the gripper assembly described herein provides 10 regardless of whether they are using the configuration tool 50 from 1 and 4 automatically or manually configured, provides the advantage of a quick release, lightweight clamp connection design. The present construction maintains advantages of existing branch and limb type gripping members. In an automated production line, where a material handling robot typically serves a station, reconfiguration of grabbing devices via stacking operations or mixed operations can be achieved. In a stacking run, where larger time spans are available while switching from one stack of parts to another, each robot can have its gripper assembly 10 Park on a passive reconfiguration rack (not shown).

After parking, the robot can use a configuration tool 50 (please refer 4 ) and the Greiforgananordnung 10 reconfigure. Another configuration tool can be used to lock the locking mechanism 24 to reconfigure, such as in US 2011/0182655 is fully incorporated herein by reference. If time permits, one or more racks on a slide can serve all robots. In mixed operations, the change is usually a cycle time to keep production flowing. Here, the robot can the Greiforgananordnung 10 in an active configuration rack (not shown), such rack providing a set of configuration tools 50 comprising all tandem branch connection arrangements 30 automatically and simultaneously in a short period of time.

The detailed description and drawings or figures are supportive and descriptive of the invention, but the scope of the invention is defined only by the claims. Although the best mode, if any, and other embodiments for carrying out the claimed invention have been described in detail, various alternative constructions and embodiments exist for practicing the invention defined in the appended claims.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2011/0182655 [0019, 0035]

Claims (8)

A reconfigurable end effector assembly comprising: a main spar with one end; a member which is arranged at right angles with respect to the main spar and which is rigidly connected to the end of the main spar; a plurality of branches extending radially outward from the member; a plurality of tandem branch connection assemblies each connecting at least two of the branches to the member, each of the tandem branch connection assemblies comprising first and second branch connections, and wherein each of the first and second branch connections comprises a releasable retaining cam; and a plurality of tool modules each mounted on a respective one of the branches and selectively slidable and rotatable with respect thereto; wherein each of the tandem branch connection assemblies rotates and translates with respect to a longitudinal axis of the member only when the retaining cam is released. The reconfigurable end effector assembly of claim 1, further comprising a configuration tool having an actuator and a pair of actuating fingers movable by means of said actuator, said first and second branch connections defining centering apertures engaged by said pair of actuating fingers. The reconfigurable end effector assembly of claim 2, wherein the configuration tool comprises a retainer cam that is movable by the actuator and that engages a retainer cam, and wherein movement of the retainer cam in respective first and second directions clamps and releases the retainer cam. The reconfigurable end effector assembly of claim 1, further comprising a flexible trim unit and a flexible conduit, the flexible trim unit comprising a spar bushing surrounding the member and directing the flexible conduit to each of the tool modules. The reconfigurable end effector assembly of claim 4, wherein the flexible trim unit further comprises a branch rail defining a U-channel that receives a corresponding one of the flexible leads. A reconfigurable end effector assembly according to claim 4, wherein the flexible trim unit comprises a manifold to which all flexible conduits are routed. The reconfigurable end effector assembly of claim 1, further comprising a flexible snap-in socket positioned in one of the tandem branch connection assemblies, the flexible snap-on socket having a pair of flanges securing the first and second branch connections together. The reconfigurable gripper assembly of claim 1, wherein the plurality of tool modules comprises a pneumatic suction cup.

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