A system for diverting objects traveling along a conveyor includes an upstream conveyor segment having an inlet end and an outlet end and a downstream conveyor segment having an inlet end and an outlet end. The inlet end of the downstream conveyor segment is located to receive items from the outlet end of the upstream conveyor segment. A conveyor shift mechanism is linked to both the outlet end of the upstream conveyor segment and the inlet end of the downstream conveyor segment for carrying out lateral movement of the outlet end of the upstream conveyor segment in one lateral direction while simultaneously carrying out lateral movement of the inlet end of the downstream conveyor segment in an opposite lateral direction.

An auxiliary conveyor, which is connected with a main conveyor including at least two conveying paths, the auxiliary conveyor including a conveying part configured to receive a load from one of the at least two conveying paths and convey the load through the other of the at least two conveying paths; and a driving part connected with the conveying part and configured to drive the conveying part to move from one of the at least two conveying paths to the other of the at least two conveying paths.

An automatic distribution wall is provided, comprising: at least one sorting and conveying assembly which is arranged linearly, wherein the sorting and conveying assembly comprises a carrying part and a rotating part, the carrying part is used for carrying and conveying articles, and the rotating part is connected to a base of the carrying part to drive the carrying part to rotate about a vertical direction so as to adjust the direction of conveyance of articles by the carrying part to a storage position facing the articles.

Sod harvester stacking head and stacking conveyor configurations can increase the rate at which sod can be harvested. The movement of the stacking head and/or the stacking conveyor can be controlled to maximize the rate at which the stacking head can remove sod from the stacking conveyor. A stacking head can employ multiple pick up positions. A stacking conveyor may also advance sod for pick up at varying rates. A stacking head may include a pivoting connection to allow the stacking head to rotate around a pivot during a pick up operation.

Present embodiments include a linear drive transport system. The system includes a plurality of fixed tracks and a junction track disposed on a conveyor configured to align the junction track with each of the plurality of fixed tracks. The plurality of fixed tracks and the junction track include one of electromagnetic coils or permanent magnets arranged in series along the respective plurality of fixed tracks and the junction track. Further, present embodiments include a plurality of movers configured to move along the fixed tracks and configured to transition between each of the plurality of fixed tracks and the junction track when aligned, wherein the movers comprise the other of the electromagnetic coils or the permanent magnets.

In order to keep the overall length of an insertion feed unit small despite high variability, a vertical paternoster buffer is used as a buffer therein.

A linear drive transport system includes a plurality of fixed tracks and a junction track disposed on a conveyor configured to align the junction track with each of the plurality of fixed tracks. The plurality of fixed tracks and the junction track include one of electromagnetic coils or permanent magnets arranged in series along the respective plurality of fixed tracks and the junction track. In addition, the linear drive transport system includes a plurality of movers configured to move along the fixed tracks and configured to transition between each of the plurality of fixed tracks and the junction track when aligned, wherein the movers comprise the other of the electromagnetic coils or the permanent magnets.

Disclosed is a system for distributing objects designed to be inserted between an upstream machine delivering an input flow of objects in single-row form and a downstream machine requiring an output flow of objects in a controlled multiple-row form, including a conveyor belt that is configured to support and drive the objects in the direction of the flow, a deflector configured to deflect the input flow toward one of the rows of the output flow, and a unit for creating streams, configured to separate the input flow into streams of a predetermined quantity of objects, the unit for creating streams being placed immediately upstream from the rows of the output flow. Also disclosed is a method for distributing objects using such a system.

A transferring assembly for displacing products conveyed by a conveying system from a primary feed direction to a secondary direction, includes: a plurality of transferring units arranged adjacent in the cross direction and adapted to form a conveying plane; each transferring unit including at least one conveying element that rotates around an axis of transversal rotation; at least one activating device of the rotation of the at least one conveying element to drive the angular rotation of the axis of transversal rotation with respect to an axis substantially orthogonal to the primary direction and the axis of transversal rotation. Each transversal rotation axis of each transferring unit is adapted to angularly rotate, with respect to an axis substantially orthogonal to the primary direction and to the axis of transversal rotation driven by the activating device, independently with respect to the transversal rotation axis of the transversally adjacent transferring unit.

A transport conveyor and a transport unit including such a transport conveyor are provided in which the transport conveyor can be made compact in the lateral direction while being compatible with a downstream conveyor whose transport direction is different from that of the transport conveyor. A second transport winding member (9), a first relaying winding member (10), and a second relaying winding member are supported to be swingable about a vertical axis (X1) extending along the vertical direction and located on the other side end portion, along a transport direction, of the transport conveyor (5). An operatively connecting mechanism is provided for causing the second transport winding member (9), the first relaying winding member (10), and the second relaying winding member to swing in an operatively connected manner, to cause the second transport winding member (9) and the second relaying winding member to swing integrally about a vertical axis (X1) and to cause the first relaying winding member (10) to swing about the vertical axis (X1) in the direction in which the second transport winding member (9) and the second relaying winding member swing and by an amount of swing that is greater than the amount of swing of the second transport winding member (9) and the second relaying winding member.