A transport device includes a first transport-element that comprises rotatable transport-element sections and that defines a transport path for transporting materials between front and rear deflection-devices. The path has successive sections along a transport direction and extends between drive-arrangements spaced apart along the transport path. The drive-arrangements interactively connect to the transport-element at different locations along the transport path. Rotatable transport-element sections are repositioned relative to one another in such a way to change an overall length of the first transport-element. Targeted controlling of adjacent transport path sections at a differential speed by way of the first and second drive-arrangements creates an accumulation or a gap of transport material on a transport-path section.

A mounting element (1) for mounting a trolley (29) to a continuous conveyor (30) of a conveyor device has at least two articulated parts (2, 3) connected to one another for articulation. A first of the articulated parts (2) is set-up for articulation of the mounting element (1) to the continuous conveyor (30) and a second of the articulated parts (3) is set-up for connecting the mounting element (1) to the trolley (29).

Various continuous chain conveyors, parts for same (e.g., chain guides, chain drives, etc.), packaging and handling equipment and systems and related methods are disclosed herein. In one form, a chain conveyor comprising a primary continuous chain having a first portion configured to carry objects along a path and a return portion, a motor operably coupled to the primary continuous chain so as to induce movement of the chain, a first sprocket engaging the return portion of the primary continuous chain, wherein movement of the return portion causes the first sprocket to rotate, a second sprocket coupled to the first sprocket by a drive shaft, wherein rotation of the first sprocket causes the second sprocket to rotate, and an auxiliary chain operably coupled to the second sprocket such that rotation of the second sprocket causes movement of the auxiliary chain.

A conveyor system and method for cascaded accumulation on a series of in-line roller belts. An accumulation system comprises a series of roller belts that can be actuated in contiguous zones to accelerate conveyed articles forward at twice the belt speed. When articles start to accumulate on the accumulation conveyor, the belt rollers are deactuated downstream to upstream zone by zone. Then the belts are stopped as they fill with accumulated articles. The process is repeated in cascade for the upstream roller belts as articles continue to accumulate.

A conveyor system and method for cascaded accumulation on a series of in-line roller belts. An accumulation system comprises a series of roller belts that can be actuated in contiguous zones to accelerate conveyed articles forward at twice the belt speed. When articles start to accumulate on the accumulation conveyor, the belt rollers are deactuated downstream to upstream zone by zone. Then the belts are stopped as they fill with accumulated articles. The process is repeated in cascade for the upstream roller belts as articles continue to accumulate.

A conveyor system may include a pipe conveyor with a head end, a tail end, and an inclined section. The conveyor system may also include a conveyor belt including a first portion and a second portion. The conveyor belt may form a pipe shape when the first and second portions of the conveyor belt are overlapped. The pipe shape may extend from a pipe closing point to a pipe opening point and may enclose two or more longitudinally spaced-apart centering structures. The centering structures may allow for self-bridging of a bulk material carried in a pipe volume above each centering structure. Means of implementing this material-transport principle within a pipe conveyor system are described.

A conveyor system may include a pipe conveyor with a head end, a tail end, and an inclined section. The conveyor system may also include a conveyor belt including a first portion and a second portion. The conveyor belt may form a pipe shape when the first and second portions of the conveyor belt are overlapped. The pipe shape may extend from a pipe closing point to a pipe opening point and may enclose two or more longitudinally spaced-apart centering structures. The centering structures may allow for self-bridging of a bulk material carried in a pipe volume above each centering structure. Means of implementing this material-transport principle within a pipe conveyor system are described.

A conveyor system and method for cascaded accumulation on a series of in-line roller belts. An accumulation system comprises a series of roller belts that can be actuated in contiguous zones to accelerate conveyed articles forward at twice the belt speed. When articles start to accumulate on the accumulation conveyor, the belt rollers are deactuated downstream to upstream zone by zone. Then the belts are stopped as they fill with accumulated articles. The process is repeated in cascade for the upstream roller belts as articles continue to accumulate.

A conveyor system and method for cascaded accumulation on a series of in-line roller belts. An accumulation system comprises a series of roller belts that can be actuated in contiguous zones to accelerate conveyed articles forward at twice the belt speed. When articles start to accumulate on the accumulation conveyor, the belt rollers are deactuated downstream to upstream zone by zone. Then the belts are stopped as they fill with accumulated articles. The process is repeated in cascade for the upstream roller belts as articles continue to accumulate.