A system and a method for destacking and conveying articles disposed in stacks include a conveying device which is constructed for transporting the articles in a conveying direction. The conveying device is inclined relative to the horizontal at an angle of inclination and has a drive device and adhesion elements. The adhesion elements exert an adhesion force on articles with which they are in contact. The system also includes a controller which is connected to the drive device of the conveying device. In order to provide for more effective destacking for the system and the method, the adhesion elements are connected to the controller and constructed to be activated by the controller.

A conveyor for transporting and elevating articles and a method and system for conveying articles up inclines is provided. The conveyor has a conveyor belt and a plurality of support elements extending outward from the article-conveying surface of the conveyor belt advancing upward along the incline. The support elements prevent conveyed articles from sliding down the conveyor belt on the incline. The article-conveying surface of the conveyor belt may provide a low-friction retention surface to articles leaning away from the conveyor belt on the incline.

A conveyor for transporting and elevating articles and a method and system for conveying articles up inclines is provided. The conveyor has a conveyor belt and a plurality of support elements extending outward from the article-conveying surface of the conveyor belt advancing upward along the incline. The support elements prevent conveyed articles from sliding down the conveyor belt on the incline. The article-conveying surface of the conveyor belt may provide a low-friction retention surface to articles leaning away from the conveyor belt on the incline.

The bristle brush comprises a support plate (1), a plurality of flexible bristles (2) emerging from one of the surfaces thereof, the ends of the bristles (2) furthest from the support plate (1) defining a support surface intended to receive a part to be transported and/or cut, wherein said support plate (1) comprises a leading edge (11) and a trailing edge (12), said leading (11) and trailing (12) edges comprising complementary shapes. It enables a conveyor belt formed by said brushes to achieve very small turning radii.

A vertical conveying device for the transport of sample container carriers having sample tubes received therein between a bottom level and a top level of a sample distribution system is presented. The vertical conveying device comprises a plurality of conveying surfaces which are movable along a circulating path. A sample distribution system having such a vertical conveying device and to a laboratory automation system having such a sample distribution system are also presented.

Proposed is a film processing system including a supply unit configured to supply a film fabric, a cutting unit configured to cut the film fabric and to form a film product by dividing the film fabric, a transfer unit including a classifier configured to selectively guide the film product along any one of a predetermined non-inverted path and an inverted path, an inverter configured to invert the film product guided along the inverted path up and down, and an inspection transfer device configured to transfer the film product delivered from the classifier in a non-inverted state or the film product delivered from the inverter in an inverted state in a predetermined reference direction, and an inspection unit configured to inspect the film product delivered to the inspection transfer device.

Proposed is a film processing system including a supply unit configured to supply a film fabric, a cutting unit configured to cut the film fabric and to form a film product by dividing the film fabric, a transfer unit including a classifier configured to selectively guide the film product along any one of a predetermined non-inverted path and an inverted path, an inverter configured to invert the film product guided along the inverted path up and down, and an inspection transfer device configured to transfer the film product delivered from the classifier in a non-inverted state or the film product delivered from the inverter in an inverted state in a predetermined reference direction, and an inspection unit configured to inspect the film product delivered to the inspection transfer device.

A mechanism for inserting coil springs (10) produced by multiple coil winding devices of a pocketed coil assembly machine (100) between fabrics (21, 22) for forming pockets enclosing the coil springs (10) is provided. The mechanism comprises belt conveyor mechanisms (200) with multiple parallel conveyor belts, which may be individually controlled. Each of the conveyor belts is associated with a respective one of the coil winding devices and is configured to receive coil springs (10) produced by the respective coil winding device. The mechanism further comprises a push mechanism (420) configured to push the coil springs (10) arranged on the conveyor belts, in a direction transversal to a conveying direction of the conveyor belts, between the fabrics and into a welding stage (500) of the pocketed spring assembly machine (100).

A mechanism for inserting coil springs (10) produced by multiple coil winding devices of a pocketed coil assembly machine (100) between fabrics (21, 22) for forming pockets enclosing the coil springs (10) is provided. The mechanism comprises belt conveyor mechanisms (200) with multiple parallel conveyor belts, which may be individually controlled. Each of the conveyor belts is associated with a respective one of the coil winding devices and is configured to receive coil springs (10) produced by the respective coil winding device. The mechanism further comprises a push mechanism (420) configured to push the coil springs (10) arranged on the conveyor belts, in a direction transversal to a conveying direction of the conveyor belts, between the fabrics and into a welding stage (500) of the pocketed spring assembly machine (100).

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.