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.

Some embodiments of the technology disclosed herein relate to a sensor device. An elongate sleeve has a first end and a second end and extends along a longitudinal axis. A plurality of sensors are fixed relative to the sleeve. A first endcap is coupled to the first end, where the first endcap has an endcap body. A first axle is coupled to the endcap body, where the first axle extends along the longitudinal axis and the first axle defines a retaining feature. An intermediate component is coupled to the first axle, and the intermediate component is selectively rotatable about the longitudinal axis. The sensor device has an orientation locking structure that is configured to be engaged to selectively fix the orientation of the intermediate component about the longitudinal axis relative to the endcap body.

Some embodiments of the technology disclosed herein relate to a sensor device. An elongate sleeve has a first end and a second end and extends along a longitudinal axis. A plurality of sensors are fixed relative to the sleeve. A first endcap is coupled to the first end, where the first endcap has an endcap body. A first axle is coupled to the endcap body, where the first axle extends along the longitudinal axis and the first axle defines a retaining feature. An intermediate component is coupled to the first axle, and the intermediate component is selectively rotatable about the longitudinal axis. The sensor device has an orientation locking structure that is configured to be engaged to selectively fix the orientation of the intermediate component about the longitudinal axis relative to the endcap body.

An idler wheel support for a conveyor belt comprises a gear rack adjustment mechanism or for use in adjusting the position of one end portion an idler wheel supporting frame. The gear rack is provided at said one end portion of the frame, such as on a foot, or on a base to which the foot is slidably coupled. A tool comprising a gear is selectively positioned for pivoting on the foot or base that does not have the gear rack with the gear engaged with the gear rack. When so engaged, pivoting the gear shifts said one end portion of the frame and adjusts the angle of the frame relative to the longitudinal conveyor frame axis and adjusts the longitudinal tracking of the conveyor belt. The gear can be mounted on a lever and positioned for pivotal engagement with the gear rack to enable adjustment of the belt tracking while the belt is moving.

An inclined flange roller is located outward of an end portion of a tension roller in the belt width direction. The inclined flange roller includes a flange surface capable of being in contact with the edge portion of a belt in a region in which the belt is wound around the tension roller and a roller surface capable of being in contact with an inner peripheral surface of the belt between the flange surface and an end portion of the tension roller in the belt width direction.

An inclined flange roller is located outward of an end portion of a tension roller in the belt width direction. The inclined flange roller includes a flange surface capable of being in contact with the edge portion of a belt in a region in which the belt is wound around the tension roller and a roller surface capable of being in contact with an inner peripheral surface of the belt between the flange surface and an end portion of the tension roller in the belt width direction.

A conveyor employs an infeed assembly and outfeed assembly, each comprising a nosebar assembly that may be mounted to a conveyor frame to transition a conveyor belt between a returnway and a carryway. The outfeed assembly further includes a drive sprocket and a limiter to ensure engagement of drive elements on the conveyor belt with the drive sprockets. A limiter plate ensures proper placement of the limiter relative to the drive sprocket. The infeed assembly and outfeed assembly components may be easily mounted to and removed from the conveyor frame to facilitate replacement, cleaning or maintenance.

A conveyor employs an infeed assembly and outfeed assembly, each comprising a nosebar assembly that may be mounted to a conveyor frame to transition a conveyor belt between a returnway and a carryway. The outfeed assembly further includes a drive sprocket and a limiter to ensure engagement of drive elements on the conveyor belt with the drive sprockets. A limiter plate ensures proper placement of the limiter relative to the drive sprocket. The infeed assembly and outfeed assembly components may be easily mounted to and removed from the conveyor frame to facilitate replacement, cleaning or maintenance.

Drum motors for driving a conveyor belt are disclosed. In some embodiments, the drum motors include a shell having a polymer body such as wax-filled cast nylon.

Drum motors for driving a conveyor belt are disclosed. In some embodiments, the drum motors include a shell having a polymer body such as wax-filled cast nylon.