An ejector unit for detaching an electronic element from an adhesive carrier has an ejector housing with a supporting deck, a light source disposed therein and an ejector lens. The ejector lens has a protruding face. The ejector lens is disposed and oriented with an optical axis extending between the light source and an opening in the supporting deck, and the protruding face of the lens directed towards the opening. The ejector lens is movable relative to the supporting deck along the optical axis to project the protruding face through the opening against the electronic element for lifting the electronic element.

Various example embodiments described herein relate to an item manipulation system including a control system and a robotic arm coupled to the control system. The item manipulation system includes an end effector communicatively coupled to the control system and defines a first end and a second end. The first end of the end effector is rotatably engaged to the robotic arm. The item manipulation system also includes a gripper unit attached to the second end of the end effector. The gripper unit is configured to grip the item. The gripper unit includes at least one flexible suction cup and at least one rigid gripper. Each of the flexible suction cup and the at least one rigid gripper engage a surface of the item based on vacuum suction force generated through the at least one flexible suction cup or the at least one rigid gripper.

The present invention provides systems, methods, and apparatus for a vacuum tool having a switchable plate, such that a common vacuum tool may be adapted with different plates. A switchable plate may form the entirety of the vacuum tool's material contacting surface or a switchable plate may form a portion of the material contacting surface. The vacuum tool is effective for picking and placing one or more manufacturing parts utilizing a vacuum force.

The invention provides a motion device, including: a tray; a rotary stage located below the tray and with an annular upper cavity provided on the upper surface thereof, and with a lower cavity provided on the lower surface thereof, wherein the projections of the annular upper cavity and the lower cavity in the projection direction perpendicular to the upper surface of the rotary stage are not overlapped with each other; a rotary motor accommodated in the annular upper cavity and including a rotor of the rotary motor and a stator of the rotary motor, the stator of the rotary motor being fixed with respect to the rotary stage, and the rotor of the rotary motor being fixed with respect to the tray; a vertical movable device located in the lower cavity and configured to drive the rotary stage to move vertically; a magnetic levitation gravity offsetting device located in the lower cavity and configured to offset the gravity of the rotary stage. Compared with the prior art, the vertical size of the motion device of the present invention is significantly reduced, and with the application of the magnetic levitation gravity offsetting device, the vertical movement precision of the motion device is significantly improved.

A support frame for a handling device comprising a base body and at least two structural elements extending away from the base body, at least two structural elements being constructed similarly to each other in that they have at east the following common characteristics: a radial beam which is elongated and has a first end and a second end, the second end having a connecting section for connection to a pneumatically actuatable gripping element, a lattice wing which is integrally connected with the radial beam and runs between the first end of the radial beam and the second end of the radial beam, the lattice wing extending flatly away from the radial beam, wherein for each of the at least two structural elements the first end of the radial beam is integrally connected with the base body in a manner that the radial beam extends away from the base body.

Aspects relate to systems, methods, and apparatus for a manufacturing tool. The manufacturing tool is comprised of a vacuum tool and an ultrasonic welder as a unified manufacturing tool. The manufacturing tool may be used to pick and position a manufacturing part that is then welded with the associated ultrasonic welder.

An end effector for a robotic arm. The end effector includes an angle compensator for attaching a suction cup, a vacuum control valve, a vacuum generator, a level compensator, and an extension tube which are sequentially connected along a central axis and in fluid communication, and a vacuum sensor connected to the vacuum control valve for measuring vacuum, a proximity sensor attached to the extension tube 121 for determining position of the level compensator. The vacuum is generated when compressed air passes the extension tube, the level compensator and the vacuum generator along the central axis. The level compensator provides compensation along the central axis.

This two-stage ejector comprises a body (16) including: a compressed air intake (E); a compressed air injection nozzle (17) placed downstream of the air intake; a central duct (18); and an outlet mixer (19).

The injection nozzle (17), the central duct (18) and the outlet mixer (19) are disposed along an axis (X-X′) of the ejector so that the ends of the axial duct are respectively spaced apart from the nozzle and from the mixer so as to form a first and a second suction zone (23, 25) that communicates with a single common air suction chamber (21).

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 swirl-flow forming body includes a through-hole; a jetting port that is formed on an inner periphery facing the through-hole; a fluid passage that allows fluid to be discharged into the through-hole via the jetting port so as to form a swirl flow that generates negative pressure for applying suction to a target object; and a flange portion that is formed so as to protrude from the inner periphery, the flange portion allowing passage of fluid to which suction is applied by the negative pressure while preventing the fluid discharged via the jetting port from flowing out of the through-hole towards the target object. The inner periphery is formed so as to guide the fluid discharged via the jetting port, in a direction away from the target object, to be discharged from the through-hole.