The present disclosure concerns a belt conveyor roller wear liner superposable against an outer peripheral surface of a roller cylindrical body, the roller wear liner comprising: a shock-absorbing matrix; and a plurality of inserts, spaced-apart from one another and embedded in the shock-absorbing matrix with external surfaces of the inserts and the shock-absorbing matrix, extending between the inserts, being exposed outwardly, the roller wear liner being substantially ring-shaped. It also concerns a corresponding belt conveyor roller assembly, a corresponding belt conveyor and a corresponding method.

The invention is directed to a drop and slide out idler assembly that can all be removed from a first side of a conveyor system. The assembly includes a first end roller unit with a roller having an axis of rotation at an angel with respect to the horizontal, and a middle roller unit with a roller having an axis of rotation that is horizontal. The assembly further includes a second end roller having a roller that can be raised at one end to have an axis of rotation at an angle with respect to the horizontal, and lowered to have an axis of rotation that is horizontal. In the lowered position, the second end roller unit can be slid out from under a conveyor belt of the system through the first side.

The invention is directed to a drop and slide out idler assembly that can all be removed from a first side of a conveyor system. The assembly includes a first end roller unit with a roller having an axis of rotation at an angel with respect to the horizontal, and a middle roller unit with a roller having an axis of rotation that is horizontal. The assembly further includes a second end roller having a roller that can be raised at one end to have an axis of rotation at an angle with respect to the horizontal, and lowered to have an axis of rotation that is horizontal. In the lowered position, the second end roller unit can be slid out from under a conveyor belt of the system through the first side.

A multi-belt conveyor is described. The multi-belt conveyor comprises a base assembly comprising a base frame that extends along a length of the multi-belt conveyor. Further, the multi-belt conveyor comprises a conveyor bed having a plurality of cartridges positioned adjacently to each other and mounted to the base frame. In this regard, each cartridge of the plurality of cartridges comprises a set of conveyor belts configured to move in a direction along the conveyor bed at a defined speed. Further, in accordance with example embodiments, a cartridge of the plurality of cartridges is configured to be removed from the conveyor bed without removing an adjacent cartridge from the plurality of cartridges. Further, each cartridge of the multi-belt conveyor comprises an actuation assembly comprising: a drive pulley, a roller-slider bed comprising a plurality of rollers, and the set of conveyor belts mounted around the roller-slider bed and the drive pulley.

An externally driven conveyor pulley with an integrated thermal control system by which the temperature of the pulley may be controlled whether the pulley is rotating or stationary. The present invention includes a rotary connection device (or plurality of such devices) designed to transfer fluid (liquid or gaseous) or electrical current into/out of a rotating object. The rotary connection device may be a slip-ring for electrical power transfer or a rotary union for liquid transfer, but any device designed to transmit fluid or electricity into a rotating object could be utilized. In one embodiment, temperature control is achieved by transmitting temperature controlled fluids through the pulley via at least one rotary connection device. In an alternative embodiment, temperature control is achieved by transmitting electricity via the rotary connection device to a temperature regulating device in the rotating object. The temperature regulating device could be any electrical heating or cooling unit.

An externally driven conveyor pulley with an integrated thermal control system by which the temperature of the pulley may be controlled whether the pulley is rotating or stationary. The present invention includes a rotary connection device (or plurality of such devices) designed to transfer fluid (liquid or gaseous) or electrical current into/out of a rotating object. The rotary connection device may be a slip-ring for electrical power transfer or a rotary union for liquid transfer, but any device designed to transmit fluid or electricity into a rotating object could be utilized. In one embodiment, temperature control is achieved by transmitting temperature controlled fluids through the pulley via at least one rotary connection device. In an alternative embodiment, temperature control is achieved by transmitting electricity via the rotary connection device to a temperature regulating device in the rotating object. The temperature regulating device could be any electrical heating or cooling unit.

A transfer module assembly includes a frame, a conveyor belt with internal rotating elements, where the conveyer belt is supported by the frame, conveyor drive rollers supported by the frame and configured to drive the conveyor belt, a flat transfer belt mounted beneath the conveyor belt and configured to contact undersides of the internal rotating elements of the conveyor belt in operation, and flat transfer belt drive rollers supported by the frame and configured to drive the flat transfer belt. The conveyor drive rollers are friction-based and operate without use of a sprocket, and comprise depressions for receiving the internal rotating elements of the conveyor belt.

A modular transfer system with a primary flow system and a diverter system. The primary flow system includes a primary flow belt for conveying an article along a primary flow path from an infeed side of the modular transfer system to a pass-through side of the modular transfer system. The diverter system includes one or more diverter belts for diverting an article from the primary flow path towards a divert side of the modular transfer system. The primary flow belt includes multiple movable components contacting the diverter belt. The movable components can have one or more rotational degrees of freedom.

A conveyor belt (36) is arranged in tiers at spiral stack conveyor unit (32) and/or (34). A ceiling or top sheet (58) is positioned over the spiral stack(s). A circulation fan (60, 62) draws thermal processing medium laterally from the tiers of the spiral stack, up the exterior of the stack and across the top of the stack above the ceiling or top sheet and through a heat exchanger (64). The treated thermal processing medium is then routed across the remainder of the diameter of the spiral stack and then down the side of the spiral stack diametrically opposite to the circulating fan thereby to enter the spiral stack in a lateral direction diametrically toward the circulating fan. At least one opening (70) is formed in the ceiling downstream of the heat exchanger and into the interior of the conveyor drive hub. The outer wall of the drive hub is partially open thereby to provide an alternative flow path for the thermal processing medium to enter the spiral stack from the interior of the drive hub.

A conveyor belt (36) is arranged in tiers at spiral stack conveyor unit (32) and/or (34). A ceiling or top sheet (58) is positioned over the spiral stack(s). A circulation fan (60, 62) draws thermal processing medium laterally from the tiers of the spiral stack, up the exterior of the stack and across the top of the stack above the ceiling or top sheet and through a heat exchanger (64). The treated thermal processing medium is then routed across the remainder of the diameter of the spiral stack and then down the side of the spiral stack diametrically opposite to the circulating fan thereby to enter the spiral stack in a lateral direction diametrically toward the circulating fan. At least one opening (70) is formed in the ceiling downstream of the heat exchanger and into the interior of the conveyor drive hub. The outer wall of the drive hub is partially open thereby to provide an alternative flow path for the thermal processing medium to enter the spiral stack from the interior of the drive hub.