A feeding device for feeding products from a storage container on to a conveyor belt moving in a conveyor direction is provided wherein a feeding belt at a storage container opening on a lower side of the storage container receives products to be conveyed and transports them to an upper side of the conveyor belt, in order to deliver the products on to the conveyor belt in a feeding region on the upper side of the conveyor belt, the feeding belt has a number of holes, the dimensions of which are adapted to the products to be conveyed such that a respective product can fall through an associated hole. A guiding element extending from the storage container opening to the feeding region on the upper side of the conveyor belt, including a guiding surface arranged directly below the feeding belt, is arranged on a lower side of the feeding belt in such a way that the guiding surface prevents the products from falling through the holes of the feeding belt until the products are delivered on to the upper side of the conveyor belt in the feeding region. The holes are arranged in the feeding belt in a matrix shape. The guiding surface of the guiding element forms a low-friction and abrasion-resistant flat sliding surface.

A circulating conveyor may comprise: a first conveying line and a second conveying line, wherein both the first conveying line and the second conveying line have a loading position and an unloading position at the two ends and clamps may be circularly conveyed between the first conveying line and the second conveying line in a clockwise or counterclockwise direction; and a circulating adapter. The circulating adapter may comprise a first circulating adapter and a second circulating adapter arranged in pairs at both the loading position and the unloading position, wherein the first circulating adapter and the second circulating adapter may be used for conveying the clamps between the first conveying line and the second conveying line.

A conveyor system comprising a fixed, non-powered rail defining a conveyor path and an automated conveyor carrier (ACC) supported on the rail to be movable along the conveyor path. The ACC includes an on-board motor and an on-board electrical power source selectively powering the on-board motor to drive the ACC along the rail. The ACC may include a wireless sleep mode module operable to selectively shut off power to an on-board ACC controller.

Provided is a container processing system capable of improving a speed of processing containers with a simple configuration and providing a compact production line. The container processing system (10) includes a container conveyer (20) having a container conveying path (21a) that conveys containers (C) arranged in a row and a container processor (40) that performs processing on the containers (C) in a container processing area (A2) set lateral to a container transfer area (A1) set in a segment of the container conveying path (21a). The container conveyer (40) includes a container carrier (21) conveying the containers (C) arranged in the row along the container conveying path (21a) and a container transferer (22) moving a container row including the plurality of containers (C) arranged in the row in the container transfer area (A1) toward the container processing area (A2).

A firewood handling device for firewood pieces comprises a conveyor including one or more rotating, endless chains, wherein the conveyor extends from an input end to an output end. The conveyor chains are provided with carriers which project outwards from the outer sides of the chains and extend across and on a distance from each other in relation to the longitudinal extension of the conveyor such that spaces are formed between the carriers into which firewood pieces can be positioned. The carriers are formed with at least two, not cut through slots or recesses from below as well as from above which overlap each other. The conveyor in its output end is provided with at least two inner guiding members as well as with at least two outer guiding members.

A conveyor system including a fixed, non-powered rail defining a conveyor path, and a plurality of automated conveyor carriers supported on the rail. Each carrier includes an on-board motor, at least one wheel forming an interface with the rail, and an on-board power source selectively powering the on-board motor to drive the ACC along the rail. Each of the plurality of carriers operates to power the on-board motor from the on-board power source under the direction of instructions programmed to a local controller. Each of the local controllers is programmed with an algorithm for independent wear monitoring of the at least one wheel and further programmed to take at least one responsive action based on an identification of the at least one wheel being worn.

Disclosed here is a cargo drive unit for a cargo hold of an aircraft. The cargo drive unit includes at least one driven power transmission element, which is configured to transmit drive forces to a load arranged in the cargo hold, in order to move the load inside the cargo hold. The cargo drive unit also includes a sensor unit configured to acquire at least one movement parameter of the load. The cargo drive unit also includes a control unit configured to control the power transmission element according to the acquired movement parameter. Also disclosed here is a cargo hold that includes such a cargo drive unit, and a related method for operating such a cargo hold.

A method of operating a conveyor system having a fixed, non-powered rail defining a conveyor path and a plurality of automated conveyor carriers (ACC). The ACCs are supported on the rail such that an interface is formed between the rail and at least one wheel of each of the ACCs. The ACCs are independently driven along the conveyor path through a plurality of work stations defining a forward direction by an on-board motor and an on-board power source selectively powering the on-board motor. A first ACC of the plurality drives itself to oscillate back and forth with respect to the forward direction at a selected one of the plurality of work stations. During the oscillating of the first ACC, a second ACC of the plurality of ACCs is stopped or moves only in a single direction.

A conveyor system including a fixed, non-powered rail defining a conveyor path, and a plurality of automated conveyor carriers supported on the rail. Each carrier includes an on-board motor, at least one wheel forming an interface with the rail, and an on-board power source selectively powering the on-board motor to drive the ACC along the rail. Each of the plurality of carriers operates to power the on-board motor from the on-board power source under the direction of instructions programmed to a local controller.

A conveyor system including a fixed, non-powered rail defining a conveyor path, and a plurality of automated conveyor carriers supported on the rail. Each carrier includes an on-board motor, at least one wheel forming an interface with the rail, and an on-board power source selectively powering the on-board motor to drive the ACC along the rail. Each of the plurality of carriers operates to power the on-board motor from the on-board power source under the direction of instructions programmed to a local controller.