Various embodiments are directed to a diverter apparatus and method of using the same. In various embodiments, the diverter apparatus is configured to selectively direct an exemplary object traveling along a conveyor travel path to one of a plurality of adjacent conveyor locations. In various embodiments, the diverter apparatus may comprise a diverter conveyor surface, a cam follower, and a cam comprising a rotational range of motion about a cam shaft axis, the cam being physically engaged with the cam follower. Various embodiments are directed to a diverter apparatus configured to utilize a plurality of forces generated by the rotational motion of the cam to facilitate the transition of the directional configuration of the diverter conveyor surface from the first directional configuration to the second directional configuration, and, subsequently, from the second directional configuration back to the first directional configuration, again using the rotational motion of the cam.

A conveyor for conveying articles supported on independently powered and controllable trays. Each tray comprises a blade suspended from an article-supporting platform. A series of drive coils is embedded in the blade. A battery and a controller embedded in the tray drive the drive coils. The blade rides in a slot between two conveyor rails that support the tray platform. The slot is bounded by an array of permanent magnets along each rail. The drive coils produce an electromagnetic field that interacts with the permanent-magnet field in the slot to form a brushless dc motor that propels the tray along the rails.

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.

The invention relates to an apparatus for the single-track or multi-track conveying of objects along a conveying path extending in a conveying direction, wherein the conveying path for at least one track comprises at least one conveying device that takes over objects at the input side from a functional unit connected upstream and that transfers objects at the output side to a functional unit connected downstream; and wherein the conveying device as a whole and/or in an output-side end region is adjustable transversely to the conveying direction by means of an adjustment device such that the transverse position of objects to be transferred is changed within the respective track.

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.

A conveyor for conveying articles supported on independently powered and controllable trays. Each tray comprises a blade suspended from an article-supporting platform. A series of drive coils is embedded in the blade. A battery and a controller embedded in the tray drive the drive coils. The blade rides in a slot between two conveyor rails that support the tray platform. The slot is bounded by an array of permanent magnets along each rail. The drive coils produce an electromagnetic field that interacts with the permanent-magnet field in the slot to form a brushless dc motor that propels the tray along the rails.

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.

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.

A conveyor device for a transport container for spectacle lenses includes a linear conveyor unit for conveying the transport container in a rectilinear direction, a rotary unit for rotating the linear conveyor unit, and a first housing element for the rotary unit. The first housing element includes a plate and rotates conjointly with the linear conveyor unit in the direction of rotation. The first housing element that conjointly rotates in the rotation of the linear conveyor unit has a first opening through which the linear conveyor unit penetrates the plate and wherein the linear conveyor unit is spaced apart from the plane by an assigned gap dimension, which is smaller than or equal to 5 mm.