A material picker assembly is disclosed, including: a connector configured to be attached to an actuator device; and a plurality of picker mechanisms, wherein each picker mechanism includes a suspension element that is configured to absorb impact on the picker mechanism by one or more objects.

A display panel vacuum suction system includes a control device, a robot arm, and a vacuum device. The robot arm includes two or more retractable rods, and each of the retractable rods is connected with a vacuum plate. Each vacuum chamber is disposed in each of the vacuum plates, and each vacuum hole is disposed on a surface of each of the vacuum plates, wherein each vacuum chamber is connected with the vacuum device by a suction pipe. The control device controls expansion and retraction of the retractable rods of the robot arm, so that the vacuum plates connected with the retractable rods can be combined to pick up a single display panel or pick up two display panels respectively. By combining vacuum plates, and controlling the opening or closing of the vacuum holes of each of the vacuum plates, different sizes of display panels can be sucked.

A vacuum powered pickup tool with mechanically moveable discrete nozzles allows for selective activation of the nozzles through the mechanical movement of the nozzles relative to a vacuum manifold. The movement of a nozzle from an inactive position where an inlet port of the nozzle is fluidly decoupled with the vacuum manifold to an active position where the inlet port is fluidly coupled with the vacuum manifold allows for independent activation of discrete nozzles of the pickup tool. Aspects also contemplate varying an associate manifold through movement of the manifolds accessible to the inlet port of the nozzle when in the active position.

A vacuum device for a material handling system includes a vacuum device body and a sealing element. The vacuum device body has a vacuum passageway in which a vacuum is generated in response to activation of a pressurized air supply that forces pressurized air through a venturi device. The sealing element moves to a sealing position to substantially seal the vacuum passageway when the air supply is activated, and is urged toward the sealing position via pressurized air that is diverted from an inlet of the vacuum device to the sealing element. The sealing element moves to substantially vent the vacuum passageway when the air supply is deactivated. The vacuum passageway may be in fluid communication with a vacuum cup, which seals against the object when the sealing element is at the sealing position and the vacuum generating device generates at least a partial vacuum in the vacuum passageway.

A vacuum powered pickup tool with mechanically moveable discrete nozzles allows for selective activation of the nozzles through the mechanical movement of the nozzles relative to a vacuum manifold. The movement of a nozzle from an inactive position where an inlet port of the nozzle is fluidly decoupled with the vacuum manifold to an active position where the inlet port is fluidly coupled with the vacuum manifold allows for independent activation of discrete nozzles of the pickup tool. Aspects also contemplate varying an associate manifold through movement of the manifolds accessible to the inlet port of the nozzle when in the active position.

A waste sorting manipulator can include a gripper assembly for interacting with one or more waste objects to be sorted within a working area. There is at least one servo for moving the gripper assembly between the manipulator and the working area. There is also at least one slidable coupling mounted between the at least one servo and the gripper assembly for allowing relative movement between the at least one servo and the gripper assembly.

An electronic component handler including a first holding section and a second holding section holding an electronic component by adsorption, a suction section giving the first holding section and the second holding section an adsorption force to adsorb the electronic component, a suction flow path, a first branch flow path, a second branch flow path, a first opening/closing section opening and closing the first branch flow path, a second opening/closing section opening and closing the second branch flow path, a first pressure measurement section measuring first pressure inside the first branch flow path, a second pressure measurement section measuring second pressure inside the second branch flow path, and a control section, in which the control section opens the first branch flow path by the first opening/closing section and causes the first holding section to adsorb the electronic component, and checks whether or not the first pressure is lower than preset pressure when the second branch flow path is opened by the second opening/closing section.

An end-of-arm tool for attachment to a robotic arm, includes a housing, an outer suction cup assembly that includes an outer suction cup located at the distal end of the housing, and an inner suction cup assembly that extends centrally through the outer suction cup assembly. The inner suction cup assembly includes a lower suction tube, an inner suction cup that is positioned at a distal end of the lower suction tube and is in fluid communication with the lower suction tube. The inner suction cup is concentrically located relative to the outer suction cup. The tool includes an actuator configured to selectively extend and retract the lower suction tube with respect to the outer suction cup.

Systems, methods, and computer-readable media are disclosed for toroidal suction grippers. In one embodiment, an example device may include a first annular elastic membrane configured to form an orifice having a toroid geometry, and a first vacuum suction device disposed in the first annular elastic membrane. The first annular elastic membrane may be configured to be actuated to grasp an object.

A system for preventing debris buildup in vacuum sensor lines includes: a manifold, including a positive air pressure source and a controller; and one or more positive air pressure lines. Each positive air pressure line is in fluid communication with the manifold and can be placed in fluid communication with a vacuum sensor line. The controller is operably connected to and selectively activates the positive air pressure source to emit a positive flow of air, which can be directed into the one or more positive air pressure lines, and then into and through the associated vacuum sensor lines to evacuate debris. In some embodiments, a positive flow of air can also be directed through one or more vacuum lines of the end effector to promote the release of a parcel engaged with the end effector and/or clear the vacuum lines of debris.