A method of operating a conveyor system includes providing a fixed, non-powered first rail supporting first and second trolleys of a first carrier, at least one of which is self-driving. The first and second trolley are conveyed in line along the first rail with a load bar therebetween. The first carrier defines a length measured along the first rail and a width measured transverse. The first carrier is conveyed to a branch point where a second rail branches from the first rail. The second trolley is conveyed along the second the rail to turn the first carrier so that it is conveyed with the load bar traversing between the first and second rails. The width is substantially less than the length such that the turning of the first carrier reduces an occupancy of the first carrier along the first rail.

An object processing system is disclosed that includes a plurality of track sections, and a plurality of remotely actuatable carriers for controlled movement along at least portions of the plurality of track sections, wherein each of the remotely controllable carriers is adapted to support and transport an object processing bin.

The invention relates to a conveying device comprising at least one movable carriage on which at least one first group and at least one second group of track rollers are disposed, and a track rail disposed so as to be locationally fixed for guiding the carriage. The track rail has at least one track face, at least one straight portion and at least one curved portion. The track rollers are configured in such a manner that during movement of the carriage along the straight portion, exclusively the track rollers of the first group roll on the track face assigned to the straight portion, and during movement of the carriage along the curved portion, exclusively the track rollers of the second group roll on the track face assigned to the curved portion. The invention furthermore relates to a further conveying device and corresponding carriages, as described herein.

A conveyor for suspended objects includes a first rail profile having a first upper track and a second track arranged below the first track, a conveyor chain that can be moved continuously in a direction of conveyance in the first track. The conveyor includes holding adapters for holding objects to be conveyed, with each holding adapter having a head part that is mounted so as to roll in the second track and is coupled to the conveyor chain. A sorting portion having a switch that follows in the direction of conveyance and via which the holding adapters can be transferred from the first rail profile to a second rail profile. The switch includes an overdrive and a drive belt, with the overdrive configured such that during operation the running speed of the drive belt is higher than the running speed of the conveyor chain.

A conveyor for suspended objects has a first rail profile having a first, upper track and a second track arranged below the first track, a conveyor chain having lateral friction roller pressing surfaces to drive the conveyor chain continuously in the first track. Holding adapters for conveyed objects are coupled to the conveyor chain, with the holding adapters being transferred into the first rail profile by an induct switch. A pressing piece arranged on a side of the conveyor chain opposite the drive roller is adjustable between an active and a passive position. The adjustment path of the pressing piece is dimensioned such that in the active position the conveyor chain is in contact with the drive roller and in the passive position the conveyor chain is not in contact with the drive roller, whereby in the active position the drive roller can be driven by the conveyor chain.

A running rail (1) for a conveyor system, the running rail (1) having a cross-sectional profile comprising at least three interconnected profiled portions which comprise a first profiled portion (2), laterally open to the outside, for receiving first rollers (32) of a carriage (30), a second profiled portion (3), laterally open to the outside, for receiving second rollers (33) of a carriage (30), a third profiled portion (4), open in the vertical direction, for receiving third rollers (34) of a carriage (1), wherein the first (2) and the second profiled portion (3) are mirror symmetrical to a vertical central plane (40) of the running rail (1).

A carriage for a rail-guided conveying system includes a carriage body, which is designed for embracing a runner rail and which includes a first and a second limb. The limbs are connected to one another by way of a transversely extending connecting section. The first limb has a first roller pair and the second limb has a second roller pair. The first and the second roller pair of the two limbs are arranged crosswise equal and offset to one another. In each case a first runner roller of the first and of the second roller pair is designed as a support roller, via which the load of the carriage can be transmitted onto the runner rail, and a second roller of the first and second roller pair is designed as a guide roller for guiding the carriage along the runner rail.

A method of transporting a vehicle engine wire harness from a component preparation location to a component pick location is provided. The method includes placing the vehicle engine wire harness on a hook of a component hanger. The component hanger with vehicle engine wire harness is directed along a supply track assembly through a heated enclosure to the component pick location at a vehicle assembly line.

A transport apparatus includes a transport rail extending along a predetermined path, a transport vehicle configured to be movable along the transport rail to transport a material, and a brake unit mounted on the transport vehicle to be adjacent to the transport rail and configured to apply an eddy current braking force to the transport vehicle.

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 and electrical power source selectively powering the motor to drive the carrier along the rail. Each of the plurality of ACCs operates to power the on-board motor from the on-board electrical power source under the direction of instructions programmed to a local controller on the respective ACC. Wherein each of the local controllers of the respective ACCs is programmed to carry out independent power level management for its own on-board electrical power source and configured to selectively operate an adaptive low power indicator to communicate a low power status based only in part on the power level of the on-board electrical power source and further based on one or more parameters of a current work cycle.