The present application relates to a substrate transfer device, comprising a horizontally arranged cross beam, and support beams longitudinally arranged at two ends of the cross beam, wherein a substrate carrier is suspended on the cross beam, the substrate carrier is located between the two support beams, and the substrate carrier is parallel to a plane where the two support beams are located, the substrate carrier comprises two side walls oppositely arranged in a horizontal direction, and each of the support beams is provided with an auxiliary clamping structure for clamping the substrate carrier during transferring of the substrate carrier.

A method and apparatus for dispensing and retrieving products is provided. An apparatus may include: a plurality of shelf units. Each shelf unit extends longitudinally between a first end and a second end. The first end may be configured to receive articles, and the second end may be configured to present articles for retrieval in a retrieval position. Each of the plurality of shelf units is arranged with a respective second end facing a retrieval area. Each of the plurality of shelf units is inclined with the first end being lower than the second end. The apparatus may also include a retrieval device comprising an end-of-arm tool. The retrieval device is disposed within the retrieval area and configured to attach the end-of-arm tool to an article in a retrieval position of each of the plurality of shelf units.

A robotic system, assembly and computer assisted media for providing therapeutic treatment not limited to muscle lengthening. An adjustable probe is mounted to a carriage, in turn supported in width and depth extending relationship upon a portable trolley supported frame or other movable carriage which can be positioned over a patient support device for applying treatment to a given patient muscle areas according input parameters selected from any of heat, cold, vibration (frequency), pulse pressure and duration. A processor input for any of a PC, tablet, laptop or smartphone with mobile application communicates with the software component for providing directions to actuate the probe to apply a treatment protocol. The input can be communicated remotely via NFC, Bluetooth or Cloud capabilities with a remote care provider or ACO organization.

Examples described herein provide a system that includes a pallet. The pallet includes a base and a support member extending from the base. The support member is configured to support another pallet upwardly adjacent to and spaced from goods on the pallet. The support member is configured with an indexing feature. The system further includes a robot including a pallet engaging member configured to engage the pallet at the indexing feature on the support member. The system further includes a control system to control the robot based on a task.

A suction assembly includes a main body, a sealing ring, an air duct, and a suction head. The main body includes a columnar wall, a top cover arranged at one end of the columnar wall and defining a first through hole, and a bottom cover arranged at another end of the columnar wall and defining a second through hole. The first through hole communicates with a negative pressure generating device. The sealing ring is sealed in the main body and movably arranged between the top cover and the bottom cover. The air duct includes a first end and a second end opposite the first end. The first end passes through the second through hole and is fixed in the sealing ring. The suction head is coupled to the second end.

A system and method for a planar positioning system for an output member, the system having a pair of x-coordinate linear carriages and a pair of y-coordinate linear carriages. The system has a guide mechanism for the pair of x-coordinate linear carriages and the pair of y-coordinate linear carriages. The system has a plurality of movement and constraining cables extending from the pair of x-coordinate linear carriages and the pair of y-coordinate linear carriages to the output member for driving the output, wherein the pair of x-coordinate linear carriages and the output member move in sync in the x-direction and the pair of y-coordinate linear carriages and the output member move in sync in the y-direction. A restraint mechanism restrains the output member in an additional degree of freedom besides the x- and y-directions. The restraint can be a cable uptake and release device.

A method for synchronous control of a gantry mechanism with online inertia matching is applicable to a machine tool equipped with a gantry mechanism. The gantry mechanism includes two rails, a crossbeam and a saddle, in which the saddle is disposed on the crossbeam, and the crossbeam is disposed by crossing the two rails. Each of the two rails is furnished with a driving apparatus for synchronously driving the crossbeam, and the driving apparatus includes a drive motor and a lead screw. This method includes the steps of: obtaining gantry-mechanism information; detecting position information of the saddle on the crossbeam; evaluating the position information and the gantry-mechanism information to derive load-inertia variety information; and, evaluating the load-inertia variety information to adjust torque-output information of the drive motor corresponding to the respective driving apparatus.

An automated analyzer that receives samples prepared for analysis in an automated pre-analytical module and a method of operation of such automated analyzer. The automated analyzer includes a shuttle transfer station that receives a shuttle carrier from the automated pre-analytical system. The shuttle transfer station has a clamping assembly for the shuttle. The clamping assembly has jaws that advance engagement members into contact with a bottom portion of sample containers disposed in the shuttle. The clamping assembly secures the sample containers in the shuttle when sample is aspirated from the sample containers. The automated analyzer also has a multichannel puncture tool that is adapted to be carried by a robotic gripper mechanism. The multichannel puncture tool has multiple puncture members that each defines a channel Each channel is in communication with a different trough in the consumable. A pipette can pass through the channel in the puncture tool.

A robotic sample handling system (100) may be provided for performing sample handling tasks in a laboratory environment. The system may comprise at least one robotic arm (140), (142) which is controllable to be positioned in a plane parallel to a work area and along a Z-axis perpendicular to the work area, and a controller (180) configured to control the robotic arm to position and operate the robotic arm as part of a sample handling task. The work area may comprise a module (204) for use with one or more of the samples, wherein the module comprises a mechanism which is actuatable by downward force, and wherein the controller is configured to control the robotic arm to actuate the mechanism by pushing downward in Z-direction. For example, the module may be a stand (204) for a sample container which comprise a push-push mechanism which may be operated by the robotic arm to bring the sample in the sample container in a vicinity of an effector, such as a magnet or a heat source.

A method and a cutting system for sheets includes a cutting center, a sorting apparatus with handlers for gripping pieces cut by the cutting center, and a transfer board, movable between the handler area and the inside of the cutting center, supporting the sheets. The cutting center includes a cutting head movably mounted above the transfer board with a distance detection sensor, detecting distance data with respect to a sheet on the transfer board. The cutting center and sorting apparatus have respective first and second control logics. A data interface unit lies between the first and second control logic, by which distance data from the distance detection sensor, are transferred. The second control logic has a processor defining, periodically during operation cycles, an altitude map based on the distance data detected in a number of positions, and controlling a gripping step of the handlers based on the altitude map.