A toothed belt drive for transport in a production process and/or a packaging process. The toothed belt drive includes a drive roller having a toothing system which runs along an outer circumference, a conveyor belt which is driven by the drive roller in a circulating direction, and a support roller. The conveyor belt includes a toothing system along an inner side and a continuous groove in the toothing system parallel to the circulating direction. The support roller includes a support disk which projects radially as an elevation so as to bear in a force-loading manner against the inner side of the conveyor belt. The elevation is a counterpart to the continuous groove of the conveyor belt. The support disk is arranged so that the elevation lies on a bottom of the continuous groove.

Can conveyors using various stator coil configurations to spread, gap, align, lane, reject, singulate, and rotate aluminum cans as they are propelled along the length of the conveyor. The electrically conductive cans acting as rotors form linear-induction motors (LIMs) with the stators to move the cans.

A high angle conveyor includes a first conveyor belt, a second conveyor belt, a first idler roller engaged with the first conveyor belt, the first idler roller being coupled to a first pivot frame, and a second idler roller engaged with the second conveyor belt, the second idler roller being coupled to a second pivot frame. The first conveyor belt and the second conveyor belt define an inflection point between the first idler roller and the second idler roller. The first and second pivot frames are pivotable from an initial position toward an expanded position in response to a lump of material larger than a specified capacity of the high angle conveyor passing through the inflection point.

A high angle conveyor includes a first conveyor belt, a second conveyor belt, a first idler roller engaged with the first conveyor belt, the first idler roller being coupled to a first pivot frame, and a second idler roller engaged with the second conveyor belt, the second idler roller being coupled to a second pivot frame. The first conveyor belt and the second conveyor belt define an inflection point between the first idler roller and the second idler roller. The first and second pivot frames are pivotable from an initial position toward an expanded position in response to a lump of material larger than a specified capacity of the high angle conveyor passing through the inflection point.

An apparatus for handling three-dimensionally curved snack food chips. The apparatus includes a first conveyor for conveying a series of the snack food chips on a conveying surface and an inverting station located at an output end of the first conveyor. The inverting station includes an inverter configured for transferring the snack food chips from an output end of the first conveyor into contact with an internal concave surface of the inverter. A drive system for the inverter is configured to move the internal concave surface downwardly to cause movement of the snack food chips downward from an upper portion to a lower portion of the internal concave surface. A depositing station is located and configured for depositing the snack food chips from the lower portion of the internal concave surface onto a second conveyor configured for receiving snack food chips from the depositing station and conveying them away.

The invention relates to an apparatus for aligning box-shaped articles of various sizes on a conveyor belt, as well as a printing station, a reading station, and a labelling station including said apparatus. The apparatus comprises an input conveyor belt operable to move transversally with respect to an output conveyor belt conveying direction, to adapt to a transverse size of a transported box-shaped article, and feed said output conveyor belt with corresponding aligned article.

The invention relates to an apparatus for aligning box-shaped articles of various sizes on a conveyor belt, as well as a printing station, a reading station, and a labelling station including said apparatus. The apparatus comprises an input conveyor belt operable to move transversally with respect to an output conveyor belt conveying direction, to adapt to a transverse size of a transported box-shaped article, and feed said output conveyor belt with corresponding aligned article.

Can conveyors using various stator coil configurations to spread, gap, align, lane, reject, singulate, and rotate aluminum cans as they are propelled along the length of the conveyor. The electrically conductive cans acting as rotors form linear-induction motors (LIMs) with the stators to move the cans.

An enclosed belt conveyor system has a rail track (1) and spaced apart 50 carriages (35) that run on wheels (40) supported by the trail track. A continuous carry belt (10) is supported by the carriages (35) and has an enclosed configuration where the carry belt (10) encloses a bulk material for transport by the system. One or more belt 60 guides (45) are positioned along the rail track (1) and engage the continuous carry belt to 10 maintain it in its enclosed configuration.

The conveyor comprises two single-transport-belt conveyor subassemblies (42AL, 42AH) arranged facing each other symmetrically relative to a pinching plane of the conveyor (42A), two sets of rollers (423L, 423H) incorporated in the two conveyor subassemblies and distributed on either side of the pinching plane. A first set of rollers (423L) guides a belt (420AL) of the first conveyor subassembly and a second set of rollers (423H) guides a belt (420AH) of the second conveyor subassembly. The conveyor subassemblies comprise sets of vertically arranged jacks (424L, 424H) which are associated with the sets of rollers, each of the rollers being mounted on a dedicated respective jack.