Methods, apparatuses, systems, computing devices, and/or the like are provided. An example method may include a conveyor unit. An example conveyor unit may include a conveyor frame, a main drive connected to the frame, and a transverse drive connected to the frame. An example main drive may include at least one main roller. An example transverse drive may include at least one transverse drive belts with a drive portion and a bypass portion. An example conveyor system may include a first conveyor unit, a second conveyor unit, and a sensing system. The example method may include the sensing system detecting and determining the location of an object. The example method may also include a transverse drive applying a force to the object.

A conveying device has: a main conveyor unit; a sub conveyor unit; and a lifting and lowering unit that lifts and lowers at least one of the main conveyor unit and the sub conveyor unit, wherein the main conveyor unit has a main conveying passage disposed in a fixed region, the main conveying passage conveying a conveyance object, wherein the sub conveyor unit has a sub conveying passage disposed in the fixed region, the sub conveying passage conveying the conveyance object in an intersecting direction with respect to a conveying direction of the main conveying passage, wherein a conveyance attitude is capable of being changed between a main conveyance attitude in which a conveying surface of the sub conveying passage is located below a conveying surface of the main conveying passage, and a sub conveyance attitude in which both ends in the intersecting direction of the conveying surface of the sub conveying passage are located above the conveying surface of the main conveying passage, and in the sub conveyance attitude, the conveying surface of the sub conveying passage is inclined in a height direction.

A conveying device has: a main conveyor unit; a sub conveyor unit; and a lifting and lowering unit that lifts and lowers at least one of the main conveyor unit and the sub conveyor unit, wherein the main conveyor unit has a main conveying passage disposed in a fixed region, the main conveying passage conveying a conveyance object, wherein the sub conveyor unit has a sub conveying passage disposed in the fixed region, the sub conveying passage conveying the conveyance object in an intersecting direction with respect to a conveying direction of the main conveying passage, wherein a conveyance attitude is capable of being changed between a main conveyance attitude in which a conveying surface of the sub conveying passage is located below a conveying surface of the main conveying passage, and a sub conveyance attitude in which both ends in the intersecting direction of the conveying surface of the sub conveying passage are located above the conveying surface of the main conveying passage, and in the sub conveyance attitude, the conveying surface of the sub conveying passage is inclined in a height direction.

A conveyor system for conveying electrically conductive articles such as aluminum cans. The conveyor system comprises a plurality of coils below the top surface of an electromagnetic conveyor at a junction between an infeed conveyor and a discharge conveyor. The coils propagate electromagnetic flux waves that induce currents in the electrically conductive articles that force the articles to follow a conveying path from the infeed to the discharge conveyor. Dead spots on the electromagnetic conveyor can be eliminated by adjusting the coil drive waveforms.

The present invention includes an on-line wheel transfer mechanism. A cylinder, bearing seats and a linear guide rail are mounted on a base. A rack is connected to the linear guide rail through a guide rail seat, an output shaft of the cylinder is connected to the rack, and a rotating shaft A is mounted on the two symmetrical bearing seats. A gear and two rotating arms A are fixed on the rotating shaft A. The rack is engaged with the gear, a rotating shaft B is mounted on two symmetrical bearing seats B, two rotating arms B are fixed on the rotating shaft B, the rotating arms A are hinged to brackets through a rotating shaft C, and the rotating arms B are hinged to the brackets through a rotating shaft D. The rotating shafts constitute a parallelogram hinge four-bar mechanism.

A conveyor system for conveying electrically conductive articles such as aluminum cans. The conveyor system comprises a plurality of coils below the top surface of an electromagnetic conveyor at a junction between an infeed conveyor and a discharge conveyor. The coils propagate electromagnetic flux waves that induce currents in the electrically conductive articles that force the articles to follow a conveying path from the infeed to the discharge conveyor. Dead spots on the electromagnetic conveyor can be eliminated by adjusting the coil drive waveforms.

The present invention includes an on-line wheel transfer mechanism. A cylinder, bearing seats and a linear guide rail are mounted on a base. A rack is connected to the linear guide rail through a guide rail seat, an output shaft of the cylinder is connected to the rack, and a rotating shaft A is mounted on the two symmetrical bearing seats. A gear and two rotating arms A are fixed on the rotating shaft A. The rack is engaged with the gear, a rotating shaft B is mounted on two symmetrical bearing seats B, two rotating arms B are fixed on the rotating shaft B, the rotating arms A are hinged to brackets through a rotating shaft C, and the rotating arms B are hinged to the brackets through a rotating shaft D. The rotating shafts constitute a parallelogram hinge four-bar mechanism.

An apparatus for multi-axial transfer of objects in assembly line includes a first conveyor assembly, a second conveyor assembly, a first drive assembly, and a pivot point arrangement. The first conveyor assembly includes a plurality of rollers in a horizontal plane. The second conveyor assembly includes a plurality of geared chain arrangements mounted on at least one drive shaft. At least one of the plurality of rollers and the at least one drive shaft are coupled to the bevel gear arrangement. The first drive assembly includes a first motor coupled to the bevel gear arrangement to cause movement of an object in contact with the first conveyor assembly and the second conveyor assembly along a first axis and a second axis in the horizontal plane, respectively. The plurality of geared chain arrangements are movable along a third axis in a vertical plane using the pivot point arrangement.

A mobile driving device for driving a roller conveyor includes a chassis frame, a traction device mounted to the chassis frame, wherein the traction device is adapted to move the chassis frame on a supporting surface, a first drive unit mechanically coupled to the traction device to transmit a driving force to the traction device for moving the chassis frame on the supporting surface, a roller driving device mounted to the chassis frame, wherein the roller driving device is adapted to be mechanically coupled to one or a plurality of rollers of the roller conveyor, and a second drive unit mechanically coupled to the roller driving device for transmitting a conveying force to the roller driving device.

The invention relates to a line sorter for sorting items of various shapes, sizes and weights, in particular postal parcels or airport baggage. The invention is particularly related to the propulsion system (304, 306, 406) for the sorter. It may be seen as an object of the invention to provide a line sorter with a reduced need for energy input at a given sorting capacity. It is disclosed that a closed loop chain including sorting carts or slats (302) is provided with couplings (312) and is provided for moving along line sorter track sections. The linear synchronous motor propulsion system is provided for moving said closed loop chain, and a gap between adjacent permanent magnets (306) is the same or substantially the same between each of the permanent magnets.