A securing system, such as a welding system, includes a robot configured to transfer a part to a home position. A securing station has a frame and a gun supported on the frame. The gun includes first and second members movable relative to one another, which are first and second weld gun electrodes, for example. The gun is configured to secure a component to the part in a securing position during a securing operation. A float assembly interconnects the gun to the frame and is configured to permit the gun to glide relative to the welding frame between the home position and the securing position. A homing assembly includes a homing guide configured to release the welding gun from the home position during the securing operation, such as resistance welding fasteners to sheet metal workpieces.

A securing system, such as a welding system, includes a robot configured to transfer a part to a home position. A securing station has a frame and a gun supported on the frame. The gun includes first and second members movable relative to one another, which are first and second weld gun electrodes, for example. The gun is configured to secure a component to the part in a securing position during a securing operation. A float assembly interconnects the gun to the frame and is configured to permit the gun to glide relative to the welding frame between the home position and the securing position. A homing assembly includes a homing guide configured to release the welding gun from the home position during the securing operation, such as resistance welding fasteners to sheet metal workpieces.

An appliance for loading a suspended transport pocket from above with a transport item, in particular with a piece item, including a feed device for feeding the transport item into a transfer region of a suspended conveying device with a guide rail and with transport pockets that are movable along the guide rail. The course of the guide rail is designed such that the transport pocket is conveyed away upwards out of the transfer region in a suspended manner.

An apparatus is for conveying cases from an upstream end to one of a first downstream end and a second downstream end. The apparatus includes a conveyor and a diverter assembly that receives the case and dispenses the case toward the first downstream end or the second downstream end. The diverter assembly is pivotable to thereby direct the case toward the first downstream end or the second downstream end, and the diverter assembly is configured to clamp the case to thereby stop conveyance of the case as the diverter assembly pivots and also pivot the case to clear an obstruction presented by an adjacent conveyor.

A conveyor device (100) includes a conveyor track (11, 12, 13) and a plurality of transport units conveyable along the conveyor track (11, 12, 13), at least two first guide rollers (2.1-2.7) and a conveyor chain (3), which travels over the at least two first guide rollers (2.1-2.7) and comprises catches (31), via which the conveyor chain (3) can be brought into releasable engagement with the transport units (8) for driving the transport units (8), the conveyor device (100) further including a belt (4) moving along with the conveyor chain (3) over the at least two guide rollers (2.1-2.7), wherein the belt (4), in the respective area of the first guide rollers (2.1-2.7), is arranged, respectively, between the first guide roller (2.1-2.7) and the conveyor chain (3) such that the conveyor chain (3) lies against the belt (4).

A conveyance facility for conveying a bag includes: a carrier including a traveling wheel, and a support supporting the bag being suspended, the carrier conveying the bag; and a traveling rail supporting the traveling wheel so as to be travelable. The traveling rail forms a first path, and a detour path branching from a location in the middle of the first path. A branch unit for switching a conveyance path of the carrier from the first path to the detour path is provided at a branch portion between the first path and the detour path. The branch unit is capable of directing the support from the first path to the detour path.

A controller for an independent cart system simplifies programming and automatically adapts operation each mover travelling along a track. The controller includes a configuration table defining segments of the track, which includes a maximum velocity and/or a maximum acceleration for each mover within the segment. A motion command for a mover commands motion across multiple segments between the starting point and the ending point. As the mover travels, the controller receives a position feedback signal corresponding to the present location of the mover. The controller obtains the maximum velocity and/or maximum acceleration for the mover corresponding to the segment in which it is located. The controller automatically adjusts the speed and/or acceleration of the mover along the segment in which it is presently located. As the mover transitions between segments, the controller automatically adjusts the speed and/or acceleration according to the new segment in which the mover is located.

A controller for an independent cart system simplifies programming and automatically adapts operation each mover travelling along a track. The controller includes a configuration table defining segments of the track, which includes a maximum velocity and/or a maximum acceleration for each mover within the segment. A motion command for a mover commands motion across multiple segments between the starting point and the ending point. As the mover travels, the controller receives a position feedback signal corresponding to the present location of the mover. The controller obtains the maximum velocity and/or maximum acceleration for the mover corresponding to the segment in which it is located. The controller automatically adjusts the speed and/or acceleration of the mover along the segment in which it is presently located. As the mover transitions between segments, the controller automatically adjusts the speed and/or acceleration according to the new segment in which the mover is located.

A system comprises a track surface and includes a plurality of motors. The system may further include a plurality of chains. Each chain may be coupled to a motor and may be disposed along a length of the track surface. A plurality of pushers may further be included, with each pusher coupled to a chain of the plurality of chains. In some examples, a controller may be coupled to the plurality of motors.

A securing system, such as a welding system, includes a robot configured to transfer a part to a home position. A securing station has a frame and a gun supported on the frame. The gun includes first and second members movable relative to one another, which are first and second weld gun electrodes, for example. The gun is configured to secure a component to the part in a securing position during a securing operation. A float assembly interconnects the gun to the frame and is configured to permit the gun to glide relative to the welding frame between the home position and the securing position. A homing assembly includes a homing guide configured to release the welding gun from the home position during the securing operation, such as resistance welding fasteners to sheet metal workpieces.