An apparatus and a method for the automated management of the assembly of a machine for processing and/or packaging pharmaceutical products inside an insulated processing chamber, with controlled atmosphere and delimited by walls, at least one of which is provided with at least one access aperture which can be selectively closed by a primary closing unit. The apparatus includes a transport container able to contain one or more assemblable elements which are introduced into or removed from the processing chamber, and which is associated with the access aperture from the outside of the chamber provided with a secondary closing unit able to cooperate with the primary closing unit so that they can be opened to put the inside of the transport container in communication with the inside of the chamber. The apparatus also includes a handling device and a work tool configured to alternately grip or release the assemblable elements.

An autoteach enclosure system includes a plurality of surfaces that at least partially enclose an interior volume of the autoteach enclosure system. The autoteach enclosure system further includes an autoteach pin at least partially disposed within the interior volume. The autoteach pin is a scannable feature having a fixed position within the autoteach enclosure system. The autoteach enclosure system further includes a front interface coupled to one or more of the plurality of surfaces to interface the autoteach enclosure system with a substantially vertical portion of a load port of a wafer processing system. The autoteach pin enables an autoteach operation of a robot arm of the wafer processing system. The autoteach operation is an operation to automatically teach the fixed position within the autoteach enclosure system to the robot arm of the wafer processing system.

An apparatus and method are presented for removing container covers within a controlled environment enclosure with pre-sterilized nested containers without using gloves. The apparatus comprises an articulated arm apparatus and a gripping apparatus for the pre-sterilized nested containers and can further comprise a controller. The articulated arm apparatus can be configurable for holding and moving a container in three dimensions; and the gripping apparatus can be configured for gripping a container cover sealing the container. The method comprises providing the pre-sterilized nested containers in the form of a container having a plurality of decontaminated parts, moving the container using the articulated arm apparatus while holding a gripping area of the container cover substantially stationary using the gripping apparatus. The apparatus can further comprise a sensor configured for supplying information to the controller for determining the location of the container cover gripping area and an orientation of the container cover. The method can further comprise inspecting the container cover using the sensor. The container can be moved along a path and within a space determined by the controller.

An apparatus for use with an isolator, including a crown for releasably joining with a beta port of the isolator, wherein the crown includes at least one anchoring support; a spring hook on at least one end of the at least one anchoring support; a needle block including at least one through hole for having a needle positioned therein, wherein the at least one needle is joined with tubing; a yoke; and a biasing element releasably joined with the yoke and the at least one anchoring support; wherein the needle block is releasably joined to the crown.

The packaging plant comprises a packaging machine and a robot which is mounted on a transport truck that is repositionable along the packaging machine. The transport truck comprises a frame, a current collector, and a plurality of operating components. The frame is mounted so as to be movable along the packaging machine, has a bearing assembly for the robot, and supports the plurality of operating components. The current collector is configured to wirelessly connect to a current source. The plurality of operating components comprise at least one wireless data transmission device and one drive.

A robot calibration system includes a calibration fixture configured to be mounted on a substrate processing chamber. The calibration fixture includes at least one camera arranged to capture an image including an outer edge of a test substrate and an edge ring surrounding the test substrate. A controller is configured to receive the captured image, analyze the captured image to measure a distance between the outer edge of the test substrate and the edge ring, calculate a center of the test substrate based on the measured distance, and calibrate a robot configured to transfer substrate to and from the substrate processing chamber based on the calculated center of the test substrate.

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

A robotic arm comprising a first arm portion, a second arm portion, the second arm portion moveable between a first axial position, in which the first arm portion and the second arm portion are mutually spaced from each other along said axis, and a second axial position, in which a first end of first arm portion and a second end of the second arm portion are in contact to define a housing, a head rotatable with respect to the first arm portion and around said axis; and a robotic joint. The joint is configured for adopting an operative condition, to make the second arm portion integral with the head. The robotic arm is configured so that said operative condition corresponds to said second axial position and said second angular position and the robotic arm is configured so that, in said operative condition, the joint is located within said housing.

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.

An autoteach system includes an autoteach pin that is a scannable feature having a fixed position within the autoteach system. The autoteach pin enables an autoteach operation of a robot arm of the wafer processing system. The autoteach operation is an operation to automatically teach the fixed position within the autoteach system to the robot arm of the wafer processing system. The autoteach pin includes a first portion including a cylindrical sidewall. The robot arm is to use the first portion to locate the fixed position within the autoteach system. The autoteach portion further includes a second portion including planar sidewalls that are configured to enable calibration of robot arm error.