A workpiece diverter station is disclosed. The workpiece diverter station includes: a base frame; an X-direction workpiece transporter subassembly; a Z-direction lift assembly; and a Y-direction workpiece transporter subassembly. The X-direction workpiece transporter subassembly is axially fixedly supported with respect to the base frame in a Z-direction. The Z-direction lift assembly is supported by the base frame. The Y-direction workpiece transporter subassembly is connected to the Z-direction lift assembly and is axially movably supported with respect to the base frame in the Z-direction. A portion of a workpiece diverter station is also disclosed. A method for operating a workpiece diverter station is also disclosed. A method for servicing a portion of a workpiece diverter station is also disclosed.

A workpiece diverter station is disclosed. The workpiece diverter station includes: a base frame; an X-direction workpiece transporter subassembly; a Z-direction lift assembly; and a Y-direction workpiece transporter subassembly. The X-direction workpiece transporter subassembly is axially fixedly supported with respect to the base frame in a Z-direction. The Z-direction lift assembly is supported by the base frame. The Y-direction workpiece transporter subassembly is connected to the Z-direction lift assembly and is axially movably supported with respect to the base frame in the Z-direction. A portion of a workpiece diverter station is also disclosed. A method for operating a workpiece diverter station is also disclosed. A method for servicing a portion of a workpiece diverter station is also disclosed.

A conveyance roller 3 including a support shaft 31, a main rotating portion 34, and a sub rotating portion 35, and a driving body 50 that is in contact with the main rotating portion 34 and the sub rotating portion 35 and that supplies a rotational force to the main rotating portion 34 and the sub rotating portion 35 are provided, wherein the main rotating portion 34 and the sub rotating portion 35 are attached along the support shaft 31 and are rotatable independently of each other around the support shaft 31, the sub rotating portion 35 is not configured to contact an object to be conveyed but the main rotating portion 34 is configured to contact the object to be conveyed and bias the object to be conveyed, the driving body 50 is rotated by power around a rotation shaft 51 in a direction intersecting with the support shaft 31, the support shaft 31 is configured to change an orientation of the support shaft 31 by rotating around the rotation shaft 51, and the driving body 50 is in contact with the main rotating portion 34 and the sub rotating portion 35 regardless of the orientation of the support shaft 31.

The present disclosure relates to motor-driven roller operated conveyor systems and more particularly to a roller conveyor system having a transmission arrangement for driving a series of rollers from a gearless external rotor motor so that substantially uniform torque is provided to each of the rollers. Another embodiment discloses synchronizing multiple roller conveyors from a single drive motor.

The present disclosure relates to motor-driven roller operated conveyor systems and more particularly to a roller conveyor system having a transmission arrangement for driving a series of rollers from a gearless external rotor motor so that substantially uniform torque is provided to each of the rollers. Another embodiment discloses synchronizing multiple roller conveyors from a single drive motor.

A machine for assembling rebar cages includes a support frame, axial rollers mounted to the support frame for rotatably supporting a cylindrical wire cage for axial rotation about an axis of elongation, a carriage movably mounted to the support frame for translation, with the carriage adapted for driving an elongate rebar rod in a first axial direction. A drive mechanism is mounted to the support frame for driving the carriage in translation back and forth between a retracted position and an extended position for driving rebar rods into the rebar cages for assembly.

A conveyor roller includes a roller tube, a motor assembly comprising a motor and a motor shaft and a drive assembly engaged with the motor assembly and the roller tube. The drive assembly includes a drive member, a connector, and a sleeve. The drive member includes at least one first slot that axially extends from a front face of the drive member towards a rear face. The connector includes an axial opening and at least one first projection extending radially outwardly. A sleeve disposed at least partially between the connector and the drive member. The sleeve is configured to engage the at least one first slot of the drive member and the at least one first projection of the connector. A portion of the sleeve extends radially outwardly of the drive member, such that the portion of the sleeve is configured to engage an inner surface of the roller tube.

An automatic belt biasing device is provided for biasing a drive belt into frictional contact with rollers of a conveyor. The belt biasing device maintains a drive belt in contact with rollers of a live roller conveyor to provide drive for the rollers to propel items or packages along the conveyor. A spring attached to a pivot arm or pair of scissoring pivot arms adjusts a biasing force applied by guide wheels of the belt biasing device to the drive belt due to changes in drive belt tension. The belt biasing device may be selectively adjustable based on required roller pitch distances. The belt biasing device is pivotably coupled to the roller conveyor allowing the guide wheels to apply equal pressure to the drive belt while allowing the pivot arms to actuate and increase or decrease the biasing force provided by the belt biasing device.

An automatic belt biasing device is provided for biasing a drive belt into frictional contact with rollers of a conveyor. The belt biasing device maintains a drive belt in contact with rollers of a live roller conveyor to provide drive for the rollers to propel items or packages along the conveyor. A spring attached to a pivot arm or pair of scissoring pivot arms adjusts a biasing force applied by guide wheels of the belt biasing device to the drive belt due to changes in drive belt tension. The belt biasing device may be selectively adjustable based on required roller pitch distances. The belt biasing device is pivotably coupled to the roller conveyor allowing the guide wheels to apply equal pressure to the drive belt while allowing the pivot arms to actuate and increase or decrease the biasing force provided by the belt biasing device.

A positive displacement sorter and method of diverting articles includes a conveying surface configured to convey articles in a longitudinal direction and at least one diagonal take-away lane, extending diagonally from the conveying surface to receive articles being diverted from said conveying surface. A plurality of pushers are configured to move together in a lateral direction in order to displace an item on the conveying surface to the diagonal take-away lane. A rotational system is configured to rotate a leading portion of a diverted article in the direction of the take-away lane. A belt drive system is provided for driving live roller conveyors about a curved section of a roller conveyor of the sorter. The drive belt is guided along a single conical drive plane that maintains the orientation of the drive belt relative to the single conical drive plane and limits twisting and stress in the drive belt.