A transport device in a transport chamber having a reduced pressure atmosphere and including a sidewall extending along an arrangement direction. The transport device includes a first robot fixed at a first robot position in the transport chamber and configured to transfer a substrate to and from a first chamber provided outside the transport chamber, and a second robot fixed at a second robot position in the transport chamber and configured to transfer the substrate to and from a second chamber provided outside the transport chamber on the sidewall. Additionally, the transport device includes a mobile buffer configured to hold the substrate and move along a movement locus extending along the arrangement direction and located between the sidewall and each of the first robot position and the second robot position. The movement locus includes a first position for transferring the substrate to and from the first robot and a second position for transferring the substrate to and from the second robot.

Devices, systems, and methods for autonomously sorting dirty laundry articles into batched loads for washing are described. For example, an autonomous sorting system includes an enclosed channel including a stationary floor extending between an inlet end and an outlet end of the channel, a plurality of arms disposed in series along the enclosed channel for selectively grasping at least one of the plurality of deformable articles in sequence. The system includes an outlet orifice adjacent the outlet end through which each separated deformable article exits the enclosed channel upon release by the terminal gripper of the one of the plurality of arms, and one or more conveyors disposed adjacent the outlet end configured for receiving thereon a plurality of bins for collecting for washing together two or more articles of the plurality of deformable articles released through the outlet orifice having a common sensor-detected one or more characteristics.

A testing system collects a specimen from a subject and measures the collected specimen to test the specimen, and includes a box to allow at least one of specimen collection for collecting and receiving the specimen, preprocessing for processing the collected specimen before measurement, or specimen measurement for measuring the preprocessed specimen to be performed therein.

A substrate transfer robot for transferring a substrate in a vacuum chamber, includes: a transfer arm platform having coupling holes, wherein a link connecting member with blades is engaged at a front area of the transfer arm platform and a support shaft of a lower support is inserted into the lower space of one of the coupling holes; and a first and a second transfer arm part each including an end effector for supporting the substrate, multiple transfer link arms and subordinate link arms, and a common link arm that are connected to each other or to the transfer arm platform, wherein, the transfer link arms include at least some of drive shafts, interlocked with transfer driving motors or speed reducers, and output shafts interlocked with the drive shafts, and wherein the end effectors are positioned at different heights from each other through using a bracket.

Processe and system for preparing a vehicle surface (e.g., an aircraft fuselage) for painting include a preparation booth (100) which is sized and configured to house the vehicle (F). At least one robotic assembly (200a, 200b) is reciprocally movable within the preparation booth (100) relative to a longitudinal axis of the vehicle (F), and is provided with a robotic hand (230) having at least one abrasive disc (242a) attached to an attachment pad (242) of the robotic hand (230), and at least one nozzle (252a, 252b, 252c) for discharging a stream of rinse fluid. Operation of the at least one robotic assembly (230) will cause the at least one abrasive disc (242a) of the robot hand (230) to abrade the surface of the vehicle (F). The robotic hand (230) may thereafter be maneuvered so that the at least one nozzle (252a, 252b, 252c) is directed toward the abraded vehicle surface (F). A stream of rinse fluid may then be discharged through the at least one nozzle (252a, 252b, 252c) and towards the abraded surface of the vehicle (F) so as to rinse the abraded surface of particulate matter.

Processe and system for preparing a vehicle surface (e.g., an aircraft fuselage) for painting include a preparation booth (100) which is sized and configured to house the vehicle (F). At least one robotic assembly (200a, 200b) is reciprocally movable within the preparation booth (100) relative to a longitudinal axis of the vehicle (F), and is provided with a robotic hand (230) having at least one abrasive disc (242a) attached to an attachment pad (242) of the robotic hand (230), and at least one nozzle (252a, 252b, 252c) for discharging a stream of rinse fluid. Operation of the at least one robotic assembly (230) will cause the at least one abrasive disc (242a) of the robot hand (230) to abrade the surface of the vehicle (F). The robotic hand (230) may thereafter be maneuvered so that the at least one nozzle (252a, 252b, 252c) is directed toward the abraded vehicle surface (F). A stream of rinse fluid may then be discharged through the at least one nozzle (252a, 252b, 252c) and towards the abraded surface of the vehicle (F) so as to rinse the abraded surface of particulate matter.

Systems and methods permit filling containers with a product. A filling arm is disposed within a chamber. An optical sensor is configured to sense openings of the containers within the chamber. Locations of the sensed openings are used to guide the filling arm to fill the containers with a product.

Systems and methods permit filling containers with a product. A filling arm is disposed within a chamber. An optical sensor is configured to sense openings of the containers within the chamber. Locations of the sensed openings are used to guide the filling arm to fill the containers with a product.

The system comprising containment equipment is intended for the aseptic transfer of a powder, namely for emptying a container filled with powder into a collection container and/or for filling a container with powder from a storage container. The containment equipment has a working chamber surrounded by a housing. A robot is installed in the containment equipment, having an arm arrangement that moves over a pivot range. If there is a collection container it has an inlet leading from the working chamber, and if there is a storage container it has an outlet leading off into the working chamber. The container can be closed at least with a first closure element. A transfer head is mounted at the inlet into the collection container and/or at the outlet of the storage container, each protruding into the working chamber. The passive part forms the double flap together with an active part contained in the transfer head.

A method for transferring at least one filling needle of a number of filling needles into an isolator which has a transfer lock, the method having the following steps: providing a first needle carrier within the transfer lock, said needle carrier carrying the number of filling needles; providing a second needle carrier in a first position within the isolator; robot-assisted transferring of the at least one filling needle of the number of filling needles from the first needle carrier to the second needle carrier; and robot-assisted placing of the at least one filling needle of the number of filling needles in the second needle carrier, wherein the at least one filling needle of the number of filling needles is held directly during the robot-assisted placing. A transfer system, in which such a method can be conducted, is also disclosed.