A feeding device for feeding products from a storage container on to a conveyor belt moving in a conveyor direction is provided wherein a feeding belt at a storage container opening on a lower side of the storage container receives products to be conveyed and transports them to an upper side of the conveyor belt, in order to deliver the products on to the conveyor belt in a feeding region on the upper side of the conveyor belt, the feeding belt has a number of holes, the dimensions of which are adapted to the products to be conveyed such that a respective product can fall through an associated hole. A guiding element extending from the storage container opening to the feeding region on the upper side of the conveyor belt, including a guiding surface arranged directly below the feeding belt, is arranged on a lower side of the feeding belt in such a way that the guiding surface prevents the products from falling through the holes of the feeding belt until the products are delivered on to the upper side of the conveyor belt in the feeding region. The holes are arranged in the feeding belt in a matrix shape. The guiding surface of the guiding element forms a low-friction and abrasion-resistant flat sliding surface.

A conveying system employs independently controlled flights. The flights are controlled separately from a conveying surface using a linear transport system. The linear transport system allow the position of the flights to be controlled based on a parameter, such as the length of a conveyed object. The flights are pivotally mounted to a mover of the linear transport system and can pivot relative to the conveying surface to allow the flights to fit in a space between an end of carryway and a receptacle.

A separating device of an optical testing unit for testing rotationally symmetrical test objects includes two corresponding pocket wheels, each having a plurality of pockets distributed uniformly over a circumference. The pocket wheels rotate synchronously in opposite directions about parallel axes in response to a drive. A continuous conveyor transports the test objects on a transporting plane. Depending on the geometry of the test objects, the distances between the respective pocket wheels and between the pocket wheels and the transporting plane are determined so that the test objects, which are fed via and accumulating section, are moved between the pocket wheels while being guided by two pockets of the two pocket wheels and are released by the two pockets downstream of an engagement section. Once released the test objects are accelerated to a higher transporting speed in an accelerating section of the continuous conveyor and are separated as a result.

A separating device of an optical testing unit for testing rotationally symmetrical test objects includes two corresponding pocket wheels, each having a plurality of pockets distributed uniformly over a circumference. The pocket wheels rotate synchronously in opposite directions about parallel axes in response to a drive. A continuous conveyor transports the test objects on a transporting plane. Depending on the geometry of the test objects, the distances between the respective pocket wheels and between the pocket wheels and the transporting plane are determined so that the test objects, which are fed via and accumulating section, are moved between the pocket wheels while being guided by two pockets of the two pocket wheels and are released by the two pockets downstream of an engagement section. Once released the test objects are accelerated to a higher transporting speed in an accelerating section of the continuous conveyor and are separated as a result.

A device and a method for separating materials. The device includes a material receiving plate arranged to receive materials to be separated, a first pair of supporting members coupled to opposite sides of the material receiving plate via respective pendulum rods, and a second pair of supporting members coupled to the opposite sides of the material receiving plate via respective pendulum rods and spaced apart from the first pair of supporting members. The device also includes a driving mechanism and a transmission mechanism.

A device and a method for separating materials. The device includes a material receiving plate arranged to receive materials to be separated, a first pair of supporting members coupled to opposite sides of the material receiving plate via respective pendulum rods, and a second pair of supporting members coupled to the opposite sides of the material receiving plate via respective pendulum rods and spaced apart from the first pair of supporting members. The device also includes a driving mechanism and a transmission mechanism.

A roller assembly for use in a conveyor system is disclosed. The roller assembly includes a central rod having first and second ends and a longitudinal axis. The roller assembly includes a plurality of rollers rotatably mounted to the central rod such that adjacent rollers abut each other. A first shaft extends through each of the plurality of rollers and is offset from and extends parallel to the longitudinal axis of the rod, causing the plurality of rollers to rotate about the central rod in unison. A first collar and a second collar are mounted on respective first and second ends of the central rod. Each collar is selectably movable to the central rod so as to hold the plurality of rollers in a fixed position along a length of the central rod. A conveyor system with the roller assembly is also disclosed.

A roller assembly for use in a conveyor system is disclosed. The roller assembly includes a central rod having first and second ends and a longitudinal axis. The roller assembly includes a plurality of rollers rotatably mounted to the central rod such that adjacent rollers abut each other. A first shaft extends through each of the plurality of rollers and is offset from and extends parallel to the longitudinal axis of the rod, causing the plurality of rollers to rotate about the central rod in unison. A first collar and a second collar are mounted on respective first and second ends of the central rod. Each collar is selectably movable to the central rod so as to hold the plurality of rollers in a fixed position along a length of the central rod. A conveyor system with the roller assembly is also disclosed.

A separating device of an optical testing unit for testing rotationally symmetrical test objects includes two corresponding pocket wheels, each having a plurality of pockets distributed uniformly over a circumference. The pocket wheels rotate synchronously in opposite directions about parallel axes in response to a drive. A continuous conveyor transports the test objects on a transporting plane. Depending on the geometry of the test objects, the distances between the respective pocket wheels and between the pocket wheels and the transporting plane are determined so that the test objects, which are fed via and accumulating section, are moved between the pocket wheels while being guided by two pockets of the two pocket wheels and are released by the two pockets downstream of an engagement section. Once released the test objects are accelerated to a higher transporting speed in an accelerating section of the continuous conveyor and are separated as a result.

A separating device of an optical testing unit for testing rotationally symmetrical test objects includes two corresponding pocket wheels, each having a plurality of pockets distributed uniformly over a circumference. The pocket wheels rotate synchronously in opposite directions about parallel axes in response to a drive. A continuous conveyor transports the test objects on a transporting plane. Depending on the geometry of the test objects, the distances between the respective pocket wheels and between the pocket wheels and the transporting plane are determined so that the test objects, which are fed via and accumulating section, are moved between the pocket wheels while being guided by two pockets of the two pocket wheels and are released by the two pockets downstream of an engagement section. Once released the test objects are accelerated to a higher transporting speed in an accelerating section of the continuous conveyor and are separated as a result.