A method for producing and/or recycling a conveyor belt, the conveyor belt having at least one belt layer, the at least one belt layer or one of the belt layers including a tension member, the tension member including a matrix material and filaments embedded in the matrix material, includes: providing a tension member starting material by: providing a recyclate, which already contains filaments or filament groups, or combining a recyclate, which already contains filaments or filament groups, with the matrix material and/or filaments, or combining the matrix material with filaments; producing an extrudable state of the tension member starting material by mixing the provided tension member starting material in a mechanically-aided manner and influencing a temperature on the provided tension member starting material; and extruding the tension member, forming the at least one belt layer of the conveyor belt, from the tension member starting material.

An insulating glass unit cooling assembly and method of cooling an insulating glass unit is provided. The cooling assembly includes a cooling unit that directs air at insulating glass units and a conveyor that transports insulating glass units along a path of travel defining an axis of travel for the insulating glass units. The conveyor has a conveyor planar surface that supports a corresponding planar glass surface of the insulating glass units as the insulating glass units are conveyed along the axis of travel such that the planar surface of the insulating glass units are substantially horizontal and substantially parallel to the conveyor planar surface. The air from the cooling unit is directed in a path substantially parallel with the conveyor planar surface and the planar glass surface of the insulating glass units as the insulating glass units travel along the conveyor.

An insulating glass unit cooling assembly and method of cooling an insulating glass unit is provided. The cooling assembly includes a cooling unit that directs air at insulating glass units and a conveyor that transports insulating glass units along a path of travel defining an axis of travel for the insulating glass units. The conveyor has a conveyor planar surface that supports a corresponding planar glass surface of the insulating glass units as the insulating glass units are conveyed along the axis of travel such that the planar surface of the insulating glass units are substantially horizontal and substantially parallel to the conveyor planar surface. The air from the cooling unit is directed in a path substantially parallel with the conveyor planar surface and the planar glass surface of the insulating glass units as the insulating glass units travel along the conveyor.

A cross-belt sorter (1) comprises a plurality of interconnected carriers (3) which are drivable behind each other in a conveying direction (X). Each of the carriers (3) is provided with a cross-belt (7) for supporting a product. The cross-belt (7) is drivable in a belt driving direction (Y) extending transversely to the conveying direction (X). A pushing element (25) is mounted to the cross-belt (7) for pushing against a product on the cross-belt (7) in the event that a product on the cross-belt (7) tends to move with respect to the cross-belt (7) in opposite direction of the belt driving direction (Y). The pushing element (25) has an upright orientation with respect to the cross-belt (7) and is supported in the belt driving direction (Y) by a supporting member (26) which is at least between opposite side edges of the cross-belt (7) fixed to the pushing element (25) and to the cross-belt (7) at respective distances from an intersection between the pushing element (25) and the crossbelt (7).

A cross-belt sorter (1) comprises a plurality of interconnected carriers (3) which are drivable behind each other in a conveying direction (X). Each of the carriers (3) is provided with a cross-belt (7) for supporting a product. The cross-belt (7) is drivable in a belt driving direction (Y) extending transversely to the conveying direction (X). A pushing element (25) is mounted to the cross-belt (7) for pushing against a product on the cross-belt (7) in the event that a product on the cross-belt (7) tends to move with respect to the cross-belt (7) in opposite direction of the belt driving direction (Y). The pushing element (25) has an upright orientation with respect to the cross-belt (7) and is supported in the belt driving direction (Y) by a supporting member (26) which is at least between opposite side edges of the cross-belt (7) fixed to the pushing element (25) and to the cross-belt (7) at respective distances from an intersection between the pushing element (25) and the crossbelt (7).

A system for arranging containers and container lids on a rack. The system comprises a first rotation unit for receiving the rack, a second rotation unit for conveying the rack, and a robotic arm configured to arrange containers and container lids conveyed by the one or more motorized conveyor elements onto the rack received by the first rotation unit. The first rotation unit is configured to rotate the rack received relative to the robotic arm around a first vertical axis, to allow the robotic arm to arrange containers on the rack, and to convey the rack received to the second rotation unit. The second rotation unit is configured to rotate the rack around a second vertical axis, and to convey the rack to one or more motorized conveyor elements configured for conveying the rack, or one or more transport vehicles configured for transporting the rack.

A system for arranging containers and container lids on a rack. The system comprises a first rotation unit for receiving the rack, a second rotation unit for conveying the rack, and a robotic arm configured to arrange containers and container lids conveyed by the one or more motorized conveyor elements onto the rack received by the first rotation unit. The first rotation unit is configured to rotate the rack received relative to the robotic arm around a first vertical axis, to allow the robotic arm to arrange containers on the rack, and to convey the rack received to the second rotation unit. The second rotation unit is configured to rotate the rack around a second vertical axis, and to convey the rack to one or more motorized conveyor elements configured for conveying the rack, or one or more transport vehicles configured for transporting the rack.

The invention relates to a belt (1) as a continuous traction means, in particular for conveyor belts of agricultural machines, in particular baling presses, comprising at least one fabric layer (2) embedded, at least in certain regions, in a polymer layer (3), in particular rubber layer, whereby end regions (1a, 1b) of the belt (1) lie flat on top of one another in an overlap region (4) and are connected to each other for creating a continuous belt (1) reinforced by the fabric layer (2). According to the invention, it is provided that the end regions (1a, 1b) of the belt (1) are connected to each other by at least one thread (7) forming a seam (9), whereby, to that end, said at least one thread (7) penetrates the end regions (1a, 1b) of the belt (1) in a seam region (6) in several stitches (8), whereby the fabric layer (2) of the belt (1) is embedded in the polymer layer (3) at least across said seam region (6), and the thread (7) is embedded in transition regions (20) between the stitches (8) into the polymer layer (3) in such a manner shallowly at a depth of penetration (T) that the thread (7) runs below surfaces (10a, 10b) of the belt (1).

For washed laundry items, such as flat laundry items, that have been separated into singles, spread out and fed to a mangle or the like, for automating these processes a method and device for pulling the singles onto a belt conveyor with a front transverse edge region transversely to the feed direction. Using a guide means in front of the belt conveyor, a front transverse edge of the laundry item is aligned at right angles to the feed direction when being pulled. Once pulled on, the laundry item is centered with respect to the track center of the following transfer conveyor by the belt conveyor. From the belt conveyor the laundry item is placed on a following transfer conveyor where the front transverse edge of the laundry item is aligned at right angles to the feed direction and a sagging of the transverse edge of the laundry item is eliminated.

For washed laundry items, such as flat laundry items, that have been separated into singles, spread out and fed to a mangle or the like, for automating these processes a method and device for pulling the singles onto a belt conveyor with a front transverse edge region transversely to the feed direction. Using a guide means in front of the belt conveyor, a front transverse edge of the laundry item is aligned at right angles to the feed direction when being pulled. Once pulled on, the laundry item is centered with respect to the track center of the following transfer conveyor by the belt conveyor. From the belt conveyor the laundry item is placed on a following transfer conveyor where the front transverse edge of the laundry item is aligned at right angles to the feed direction and a sagging of the transverse edge of the laundry item is eliminated.