A modular conveying assembly includes active roller control for reducing backline pressure without product to product contact when accumulating products. Methods are discussed for manipulating objects by a bump-through indexing operation, a slug-control indexing operation, a catch-and-release indexing operation, box or case turning operations, and zero-pressure accumulation operations.

A modular conveying assembly that includes a plurality of roller bodies, a driving member, a positive stop body, and a positive stop actuator. Each roller body includes a top surface, a driven axle mounted to the roller body for conveyance therewith, a roller fixed to the driven axle, and a driven surface fixed to the driven axle. The rollers define a support plane. The driving member selectively engages the driven surfaces to affect rotation of the driven axle. The positive stop body is coupled to the plurality of roller bodies and includes a positive stop that is movable relative to the positive stop body between a first position and a second position. The positive stop extends above the support plane in the second position. The positive stop actuator selectively engages the positive stop to move the positive stop between the first position and the second position.

A device for transporting objects, such as containers, bottles, multipacks and packaged items, comprising a first transporting device having a first conveying speed, at least a second transporting device which is arranged in parallel to the first transporting device and has a second conveying speed, wherein the first and the at least one second transporting device form with each other a substantially closed transport surface and have the same conveying direction, and at least one lifting device, by which at least one of the transporting devices is height-adjustable so that at least a portion of a transport surface of the at least one transporting device can be raised and lowered above and/or below a transport surface of the other transporting device.

An automated parcel distribution system includes a plurality of operatively connected individual conveyor belts arranged in zones; a set of sensors arranged on lateral sides of the conveyor belts and at the boundaries between adjacent conveyor belts; and a processor configured to adjust the speed of individual conveyor belts based on sensor data to evenly distribute parcels on the conveyor belts. The processor may receive the data from the set of sensors and determine the volume of parcels in each zone based on width and length measurements of the parcels obtained from the sensors. The processor may slow down, speed up, or maintain a speed of the conveyor belts for a predetermined period in order to evenly distribute the parcels on the conveyor belts. The set of sensors may be arranged on lateral sides and at the boundary between two adjacent conveyor belts.

Embodiments provide methods, systems, and apparatuses for loading workpieces in a flow direction into the spaced apart lugs on a lugged conveyor with the workpieces oriented transverse to the flow direction. The lug loader includes an array of pairs of endless conveyors configured to convey workpieces toward a lugged conveyor. The first and second endless conveyors of each pair are spaced laterally apart across the flow direction and aligned substantially in the flow direction. The array can form a continuous or discontinuous transport surface. Some pairs of endless conveyors in the array may overlap one or more other pairs of endless conveyors in the array. At least one pair of endless conveyors in the array may include two or more endless conveyors that are independently driven at different speeds and/or in different directions to de-skew a workpiece.

Embodiments provide methods, systems, and apparatuses for loading workpieces in a flow direction into the spaced apart lugs on a lugged conveyor with the workpieces oriented transverse to the flow direction. The lug loader includes an array of pairs of endless conveyors configured to convey workpieces toward a lugged conveyor. The first and second endless conveyors of each pair are spaced laterally apart across the flow direction and aligned substantially in the flow direction. The array can form a continuous or discontinuous transport surface. Some pairs of endless conveyors in the array may overlap one or more other pairs of endless conveyors in the array. At least one pair of endless conveyors in the array may include two or more endless conveyors that are independently driven at different speeds and/or in different directions to de-skew a workpiece.

A modular conveying assembly that includes a plurality of roller bodies, a driving member, a positive stop body, and a positive stop actuator. Each roller body includes a top surface, a driven axle mounted to the roller body for conveyance therewith, a roller fixed to the driven axle, and a driven surface fixed to the driven axle. The rollers define a support plane. The driving member selectively engages the driven surfaces to affect rotation of the driven axle. The positive stop body is coupled to the plurality of roller bodies and includes a positive stop that is movable relative to the positive stop body between a first position and a second position. The positive stop extends above the support plane in the second position. The positive stop actuator selectively engages the positive stop to move the positive stop between the first position and the second position.

An infeed rollcase for transporting an infeed object. The rollcase uses a split drive system to move infeed objects at varying speeds in different infeed decks of the infeed rollcase. By detecting the position of each infeed object along a front portion of each infeed deck, the drive speed of the split drive system is varied such that the infeed objects maintain a predetermined position (e.g., overlapping) with respect to a preceding infeed object.

A transport device for transporting at least one product (12a; 12b), with at least one guide unit (14a; 14b), with at least one conveyor unit (16a; 16b), which has at least one continuous conveyor unit (18a; 18b) mounted movably relative to the guide unit (14a; 14b), which comprises at least one movably mounted conveyor element (20a; 20b), and at least one further movably mounted conveyor element (22a; 22b), which are connected to each other to form the continuous conveyor unit (18a; 18b) and are at least jointly movable relative to the guide unit (14a; 14b), and with at least one conveyor drive unit (24a; 24b) for driving the continuous conveyor unit (18a; 18b) relative to the guide unit (14a; 14b), in particular for driving the continuous conveyor unit (18a; 18b) in rotation about the guide unit (14a; 14b).

Disclosed is a system for processing confectionary product, the system includes a collecting device disposed in line with at least one upstream confectionary production station disposed upstream of the collecting device and at least one downstream confectionary production station disposed downstream of the collecting device. At least one conveying device is configured to convey the confectionary product from the at least one upstream confectionary production station to the collecting device, receive the confectionary product from the collecting device, and convey the confectionary product to the at least one downstream confectionary production station. The collecting device is configured to collect confectionary product from the conveying device while the at least one upstream confectionary station is operational and the at least one downstream confectionary production station is non-operational.