A work-piece transfer apparatus, comprising at least one work-piece engagement structure; at least one first robot arm pivotally connected to the work-piece engagement structure; a first motor coupled to the first robot arm and being adapted for translating the first robot arm fore and aft in a generally horizontal direction; a second motor; at least one second robot arm being in operating driving relationship with the second motor and operatively coupled with the work-piece engagement structure for raising and lowering the work-piece engagement structure; and a support structure for supporting the apparatus or portions thereof; wherein the first motor and second motor are operated synchronously to raise, lower, and/or translate the work-piece engagement structure in a fore and aft direction by way of one or both of the first robot arm and second robot arm.

A workpiece conveyance device is used for a press device. The workpiece conveyance device includes a support component, first and second moving members, a driver, and a transmission mechanism. The support component supports a holder that detachably holds a workpiece. The first moving member pivotably supports the support component. The first and second moving members are movable in the up and down direction. The driver moves the second moving member in the up and down direction. The transmission mechanism transmits an up and down movement of the second moving member to the first moving member so as to move the first moving member in the up and down direction in conjunction with the up and down movement of the second moving member. The transmission mechanism causes an amount of movement of the first moving member to be greater than an amount of movement of the second moving member.

A workpiece conveyance device is used for a press device. The workpiece conveyance device includes a support component, first and second moving members, a driver, and a transmission mechanism. The support component supports a holder that detachably holds a workpiece. The first moving member pivotably supports the support component. The first and second moving members are movable in the up and down direction. The driver moves the second moving member in the up and down direction. The transmission mechanism transmits an up and down movement of the second moving member to the first moving member so as to move the first moving member in the up and down direction in conjunction with the up and down movement of the second moving member. The transmission mechanism causes an amount of movement of the first moving member to be greater than an amount of movement of the second moving member.

This transfer device is a transfer device which transfers an object to be transferred and includes a pivoting arm supported by a frame and configured to be rotatably driven around a pivot axis, a main arm which is rotatably connected to the pivoting arm and to which a support part which supports the object to be transferred is connected at a distal end portion, and an inclination adjustment part which is slidably connected to the main arm in a longitudinal direction of the main arm and has a parallel link mechanism to adjust an inclination of the main arm.

A method for planning movements for a servo press and a movement controller configured to plan movements for a servo press and an associated computer program product, wherein a minimum transfer time and a minimum return time are taken into account in a movement cycle for a transport apparatus.

An apparatus is provided for molding a contact pad in place on an automation template. The apparatus includes an automation template having a contact pad retainer and a molding cap received over the contact pad retainer and retained using a self-locking fit. A mold cavity is formed between the automation template and the molding cap.

A high-speed stamping transfer robot, including a Y-axis portion, a Z1-axis portion, a Z2-axis portion (upper arm), a mechanical lower arm portion and a tooling portion, wherein the Z1-axis portion is fixedly connected to the Y-axis portion; the Z2-axis portion (upper arm) is in rotational connection with the Z1-axis portion and the Y-axis portion and is capable of moving vertically relative to the Z1-axis portion while moving horizontally relative to the Y-axis portion; the mechanical lower arm portion is in rotational connection with the Z2-axis portion (upper arm) and is capable of rotating relative to the Z2-axis portion (upper arm); and the tooling portion is fixedly connected to the mechanical lower arm portion. Through linkage among the respective axis portions, high-speed and high-load stable transfer of sheets between presses can be realized.

A high-speed stamping transfer robot, including a Y-axis portion, a Z1-axis portion, a Z2-axis portion (upper arm), a mechanical lower arm portion and a tooling portion, wherein the Z1-axis portion is fixedly connected to the Y-axis portion; the Z2-axis portion (upper arm) is in rotational connection with the Z1-axis portion and the Y-axis portion and is capable of moving vertically relative to the Z1-axis portion while moving horizontally relative to the Y-axis portion; the mechanical lower arm portion is in rotational connection with the Z2-axis portion (upper arm) and is capable of rotating relative to the Z2-axis portion (upper arm); and the tooling portion is fixedly connected to the mechanical lower arm portion. Through linkage among the respective axis portions, high-speed and high-load stable transfer of sheets between presses can be realized.

A system (100) for handling parts (300) in a press line comprises two industrial robots (101a, 101b) and at least one control unit (400) for the control of the robots, wherein each industrial robot is an articulated robot with at least four axes mounted in series between a robot base (2) and a robot wrist (3), wherein each industrial robot further comprises an arm (4) that has a proximal end (4a) fixed to the robot wrist (3) and a distal end (4b) carrying an additional rotational axis (A7), a motor (43) mounted on the arm near the proximal end, and a transmission (41) between the motor and the additional rotational axis. A method for handling parts in a press line may comprise operating the system such that the two robots jointly handle a part, or such that they each handle a part, either in an alternating or in a parallel mode.

A system (100) for handling parts (300) in a press line comprises two industrial robots (101a, 101b) and at least one control unit (400) for the control of the robots, wherein each industrial robot is an articulated robot with at least four axes mounted in series between a robot base (2) and a robot wrist (3), wherein each industrial robot further comprises an arm (4) that has a proximal end (4a) fixed to the robot wrist (3) and a distal end (4b) carrying an additional rotational axis (A7), a motor (43) mounted on the arm near the proximal end, and a transmission (41) between the motor and the additional rotational axis. A method for handling parts in a press line may comprise operating the system such that the two robots jointly handle a part, or such that they each handle a part, either in an alternating or in a parallel mode.