An enclosure includes a furnace 1 and plates 7A to 7D arranged in the furnace 1 and used for placement of articles 5. Each of the plates 7A to 7D is movable vertically in the furnace 1. The enclosure further includes guide members 60A and 60B, each of which is disposed adjacent to a side of one plate of the plates 7A to 7D that is disposed at a loading/unloading position where the articles 5 are allowed to be loaded into or unloaded from the furnace 1. The guide members 60A and 60B guide the articles 5 and are rotatable with vertical movement of the plate.

Disclosed are systems and methods for aseptically filling pharmaceutical containers with a pharmaceutical substance and then lyophilizing it. In one general aspect, the system and method can employ a lyophilizer loader subsystem having an interior chamber in communication with an interior chamber of a lyophilizer subsystem via a portal with a sealable door, with the collective interior being aseptically sealable. An articulated robotic arm can be employed to batch transfer to the lyophilizer subsystem container nests bearing the pharmaceutical containers. In one embodiment, the nests may be transferred serially to the loader subsystem, with the articulated robotic arm being configured to transfer the nests of containers in batches to the lyophilizer subsystem. The articulated robotic arm can also be configured to be used to move batches of nests within the lyophilizer subsystem. One implementation includes two articulated arms and a joint rotary wrist driven by two rotary shoulders.

A can curing oven including a housing assembly, a transfer assembly, and a number of heating units. The housing assembly defines a generally enclosed space. The transfer assembly is structured to support and move a number of can bodies. The transfer assembly includes an elongated transfer belt. The transfer belt is movably coupled to the housing assembly and is structured to move through the housing assembly enclosed space. The number of heating units are structured to generate an effective amount of received heat.

A conveyance system includes a chamber 1, a plate 7A disposed in the chamber 1, the plate 7A being used for disposing an article thereon, an in-chamber bridge 19 disposed in the chamber 1 and capable of coming into contact with the plate 7A, a moving member 3A that moves along the in-chamber bridge 19 and the plate 7A to move the article on the in-chamber bridge 19 and the plate 7A, and a sterilization device 100 that sterilizes an interior of the chamber 1, in which the chamber 1 is allowed to be tightly sealed, with the moving member 3A disposed on the in-chamber bridge 19.

A conveying device includes first guide rails 2A, 2B; second guide rails 12A, 12B for being connected to the first guide rails 2A, 2B; a movable holding part that holds the second guide rails 12A, 12B such that the second guide rails 12A, 12B are movable in transverse directions with respect to longitudinal directions of the second guide rails 12A, 12B; and moving parts 3A, 3B that move by being guided by the corresponding first guide rails 2A, 2B and the corresponding second guide rails 12A, 12B.

A conveyance device includes: moving members 3A and 3B that move along a table 7 for disposing an article 5 thereon; shafts 21A and 21B that are rotatably connected to the moving members 3A and 3B; a contact member 22 configured to come into contact with the article 5, the contact member 22 being connected to the shafts 21A and 21B; inhibiting mechanisms 23A and 23B that inhibit rotation of the shafts 21A and 21B so that the contact member 22 is held above the article 5, the inhibiting mechanisms 23A and 23B being disposed at the moving members 3A and 3B; and dogs 24A and 24B that come into contact, at a predetermined location with the inhibiting mechanisms 23A and 23B to deactivate inhibition of rotation of the shafts 21A and 21B by the inhibiting mechanisms 23A and 23B, thereby lowering the contact member 22 toward the table 7.

The invention relates to an automatic cleaning process, carried out during cleaning sequences during which all or at least part of an element to be cleaned is cleaned, each element to be cleaned being positioned inside a controlled atmosphere booth belonging to a coating facility. The cleaning sequences of the element(s) are programmed during imposed production stoppages of the facility. The invention also relates to a drying station, intended to be positioned inside a booth with a controlled atmosphere belonging to a coating facility, this drying station being dimensioned to receive all or part of a spraying robot, comprising a moving arm at the end of which a handle and a sprayer attached on the handle are provided.

A workpiece processing arrangement comprises a spray booth (2) defining a work space (21), and operable to provide a controlled environment for spraying of material, a first oven (4) located adjacent a first end of the spray booth, the first oven defining an internal zone, and a second oven (5) located adjacent a second end of the spray booth, the second oven defining an internal zone (51). The arrangement also includes a transport rail (6) which extends from the internal zone (41) of the first oven (4), through the work space (21) of the spray booth (2) into the internal zone (51) of the second oven (5), the transport rail (6) being adapted for transport of a workpiece (10) between the work space (21) of the spray booth (2) to the internal zone of the first or second oven (4, 5). A corresponding method of processing a work piece in such an arrangement indicates the steps to be used when processing a first and a second workpiece The ovens may have both a baking and a curing zone. A ventilation system with an air curtain (23) may be included.

A continuous-flow drying installation for drying workpieces, in particular vehicle bodies, having a heating zone enclosed by a first housing, in which the workpieces can be heated to a temperature T1, and having a cooling zone enclosed by a second housing, in which the workpieces heated in the heating zone can be cooled to a temperature T2<T1. The cooling zone is arranged completely above the heating zone. The continuous-flow drying installation additionally has a conveying zone enclosed by a third housing, in which there is arranged a transfer unit with which the workpieces heated in the heating zone can be transferred from the heating zone to the cooling zone, and a separating device which separates the heating zone from the conveying zone in an at least substantially air-tight manner but allows the workpieces to pass.

A can curing oven including a housing assembly, a transfer assembly, and a number of heating units. The housing assembly defines a generally enclosed space. The transfer assembly is structured to support and move a number of can bodies. The transfer assembly includes an elongated transfer belt. The transfer belt is movably coupled to the housing assembly and is structured to move through the housing assembly enclosed space. The number of heating units are structured to generate an effective amount of received heat.