A pharmaceutical filling system for a high volume pharmacy is described. The system can include a manual pick/pack device and method. The system may include a rotation assembly, a left door and a right door, both positioned below the rotation assembly, a left divider positioned below the left door, and a right divider positioned below the right door, and a left gathering table positioned below the left divider, and a right gathering table positioned below the right divider. The system may also include a control device in electronic communication with the rotation assembly, the doors and the dividers for control of same.

A transfer apparatus contains a conveying unit, a sorting unit, which is configured for receiving and sorting articles from the conveying unit, and a transfer unit with a feeding unit. The transfer unit forms a transporting connection between the conveying unit and the sorting unit. A discharging unit is positioned on a portion of the conveying unit and is configured to discharge an article onto the transfer unit only when the article is at a predefined minimum distance from a previously discharged article.

An automatic station for picking up articles which can be used in a machine for packaging articles, which achieves a greater efficiency, relative to the prior art stations, in terms of percentage of the articles picked up.

An automatic station for picking up articles which can be used in a machine for packaging articles, which achieves a greater efficiency, relative to the prior art stations, in terms of percentage of the articles picked up.

A device and a method for the separation of elongated parts (long parts) from bulk materials. The device comprises a conveying device (1), a deflecting device (2) and a rake with webs (4) being oriented longitudinally to the conveying direction. According to the method, the bulk material is transported on the conveying device (1), and then long parts (10) are oriented by means of a deflecting device (2) transversely to the conveying direction. After passing through the deflecting device (2), the transversely oriented long parts are transferred to the rake (4) and discharged as coarse materials (7). Compact parts (11) fall through this rake and thus end up in the fine material (6).

A device and a method for the separation of elongated parts (long parts) from bulk materials. The device comprises a conveying device (1), a deflecting device (2) and a rake with webs (4) being oriented longitudinally to the conveying direction. According to the method, the bulk material is transported on the conveying device (1), and then long parts (10) are oriented by means of a deflecting device (2) transversely to the conveying direction. After passing through the deflecting device (2), the transversely oriented long parts are transferred to the rake (4) and discharged as coarse materials (7). Compact parts (11) fall through this rake and thus end up in the fine material (6).

An article conveying device 4 includes a movable conveyer 12 for conveying a culture vessel 3 (article) and longitudinal mover 13b for moving the movable conveyer 21, and a conveyer driving motor 14 is provided separately from the movable conveyer 12, and a driving magnet MA rotated by a driving shaft 32 driven by the conveyer driving motor 14 and a driven magnet MB provided on the movable conveyer 12 and connected to the driving magnet MA by a magnetic force in a non-contact manner are provided. A plurality of the driven magnets MB is provided along a moving direction of the movable conveyer 12 by the longitudinal mover 13b, and an interval between the plurality of the driven magnets MB is matched with a moving distance of the movable conveyer 12 by the longitudinal mover 13b.

An article conveying device 4 includes a movable conveyer 12 for conveying a culture vessel 3 (article) and longitudinal mover 13b for moving the movable conveyer 21, and a conveyer driving motor 14 is provided separately from the movable conveyer 12, and a driving magnet MA rotated by a driving shaft 32 driven by the conveyer driving motor 14 and a driven magnet MB provided on the movable conveyer 12 and connected to the driving magnet MA by a magnetic force in a non-contact manner are provided. A plurality of the driven magnets MB is provided along a moving direction of the movable conveyer 12 by the longitudinal mover 13b, and an interval between the plurality of the driven magnets MB is matched with a moving distance of the movable conveyer 12 by the longitudinal mover 13b.

A conveying system, such as a conveying system for material including non-ferrous metals, includes a conveying belt and a stabilizer. The conveying belt includes a conveying surface and is adapted to convey the material on the conveying surface. The stabilizer is configured to apply a stabilizing force onto the material on the conveyor belt such that the material is stabilized while being conveyed. A method of stabilizing material on a conveyor belt includes receiving the material on the conveying surface of the conveyor belt, conveying the material at a conveying speed with the conveyor belt, and applying the stabilizing force onto the material with a stabilizer such that vertical displacement of at least some of the material is dampened and/or minimized at the conveying speed.

A conveying system, such as a conveying system for material including non-ferrous metals, includes a conveying belt and a stabilizer. The conveying belt includes a conveying surface and is adapted to convey the material on the conveying surface. The stabilizer is configured to apply a stabilizing force onto the material on the conveyor belt such that the material is stabilized while being conveyed. A method of stabilizing material on a conveyor belt includes receiving the material on the conveying surface of the conveyor belt, conveying the material at a conveying speed with the conveyor belt, and applying the stabilizing force onto the material with a stabilizer such that vertical displacement of at least some of the material is dampened and/or minimized at the conveying speed.