An automated pick and place apparatus includes a robotic arm having at least three degrees of freedom. An end effector is mounted to the robotic arm and includes a gripping device for gripping a target object. An actuator actuates the gripping device. An object alignment device is mounted to the robotic arm. The object alignment device includes a body having a base and an end face opposite the base. An alignment projection is slidingly received by the body within an opening and extending outwardly beyond the end face. The alignment projection has an extended configuration and a retracted configuration. A sensor detects when the alignment projection is in the retracted configuration and provides a signal to a processor.

A robot system includes a robot, a vision sensor, and a controller. The vision sensor is configured to be detachably attached to the robot. The controller is configured to measure a reference object by using the vision sensor and calibrate a relative relationship between a sensor portion of the vision sensor and an engagement portion of the vision sensor, and teach the robot by referring to the relative relationship and by using the vision sensor, after the vision sensor is attached to the robot.

A pin field, comprising a plurality of pins mounted parallel with each other in a frame. The plurality of pins are extendable and retractable from the frame for sensing an object or for manipulation of the object in a working environment wherein a distal end of each pin in the plurality of pins comprises a combination pressure and temperature sensor.

A robot system includes a robot, a vision sensor, and a controller. The vision sensor is configured to be detachably attached to the robot. The controller is configured to measure a reference object by using the vision sensor and calibrate a relative relationship between a sensor portion of the vision sensor and an engagement portion of the vision sensor, and teach the robot by referring to the relative relationship and by using the vision sensor, after the vision sensor is attached to the robot.

A gripping device for handling sample containers is presented. The sample containers are closed by caps of a given cap type or are not closed by caps. The gripping device comprises a number of fingers configured to collectively cause gripping of a sample container, a tactile sensor device arranged at at least one of the fingers and configured to sample a longitudinal profile of the sample container and of the cap, if any, being gripped, and a control device coupled to the tactile sensor device. The control device determines if the sample container is closed by a cap or not closed by a cap based on the sampled longitudinal profile.

A gripping device includes a side supporting unit supporting or releasing a side of a workpiece, a plurality of pusher members pushing the workpiece downward, and a pusher member shifting unit shifting the pusher members in a direction toward or away from the workpiece. An engaging pin to be engaged with a through-hole created in the workpiece is disposed inside at least one of the pusher members.

For handling blanks, semi-finished products or finished products in an automated production processes, a gripping device (3) is provided that has a gripper (4) that is assigned a stripper (5), with the stripper having at least one stripping element (6). The stripping element (6) can be moved as required past the gripper (4) in a stripping movement between a starting position and an end position in order to remove bodies (2) possibly interfering with the gripping process from a gripping region of the gripper (4). This occurs in particular when the gripper (4) has already gripped a body (2) to be gripped.

A connector fitting device for fitting a female connector to a male connector includes a movable arm body connected to a base on a base end side of the movable arm body and a gripper connected to a distal end side of the movable arm body. The connector fitting device is configured to move the gripper to an arbitrary position in a three-dimensional space and in an arbitrary direction in the three-dimensional space. The movable arm body includes a device main body, a first arm, a second arm, and a third arm.

A robot assembling system for assembling a multi-layer cage comprises a first assembling workstation, a second assembling workstation, a third assembling workstation, and a robot. The multi-layer cage includes a bottom case, a top case, a partition plate, and a partition assembly. The first assembling workstation assembles the partition plate and the partition assembly to form a partition device. The second assembling workstation assembles the partition device and the top case to form a top case assembly. The third assembling workstation assembles the top case assembly and the bottom case to form the multi-layer cage. The robot transmits the bottom case, the top case, the partition plate, the partition assembly, the partition device, or the top case assembly between the workstations. The robot assists an assembly process at each of the workstations.

A robot system having a robot with a jamming gripper is disclosed. The jamming gripper may comprise granular material within a deformable membrane configured to phase transition between a malleable state and a rigid state upon modification of its internal pressure. The phase transition of the gripper may allow the robot to engage and/or grasp a target object by conforming to the shape of the target object while in its malleable state, then transitioning to its rigid state in order to firmly grasp the object. In some situations, the robot may be configured to select and/or engage a stencil before engaging the target object, so as to pre-shape the gripper before engagement with the target object.