A conveyance apparatus for electronic components capable of suppressing the adhesion of electronic components to a storing member by static electricity. The conveyance apparatus for electronic components includes: a storing member which includes cavities for storing electronic components respectively; an electronic component supply mechanism which supplies the electronic components in a state where the electronic components are brought into contact with the storing member; and a moving unit which moves the storing member in a predetermined moving direction in a relative relationship with the electronic component, wherein a recessed portion for reducing a contact area of the storing member with the electronic components is formed in a region where the cavities are not formed on a main surface of the storing member on a side where the electronic components are supplied.

This apparatus includes a carrying path for an electronic component, a holder unit holding and releasing the electronic component, and N number of rotary pickups including the multiple holder units, and intermittently rotating around the rotation axis. At least one of the rotary pickups is a first carrying structure. The rotary pickup adjacent to the first carrying structure is a second carrying structure installed so as to not overlap with each other, to have the respective rotation axes orthogonal to each other. The holder unit of the first carrying structure and that of the second carrying structure are each a sucking nozzle. The holder units of the first carrying structure and of the second carrying structure have a common stop position, and the electronic component is transferred at only a transfer point that is the stop position.

An apparatus including a carrier substrate configured to move a microelectronic device. The apparatus further includes a rotatable body configured to receive the microelectronic device. Additionally, the apparatus includes a second substrate configured to receive the microelectronic device from the rotatable body.

A quick-change vacuum starwheel assembly including at least one of a quick-change height adjustment assembly or a quick-change vacuum starwheel mounting assembly.

There is provided an automated removal apparatus for selectively removing one or more trimmed portions of a laminated ply in a ply-by-ply fabrication process. The automated removal apparatus includes a rotatable reel having a plurality of retractable vacuum panels attached around the rotatable reel. Each retractable vacuum panel has one or more retractable vacuum pad assemblies, and each retractable vacuum pad assembly has a vacuum pad with a vacuum port and a self-sealing valve. The automated removal apparatus further includes actuator assemblies attached to the plurality of retractable vacuum panels, friction reducing elements attached around the rotatable reel, a drive assembly attached to the rotatable reel, and a pneumatic system attached to the rotatable reel and including a valve manifold operable to control an air flow to the actuator assemblies and to one or more vacuum generators to generate a vacuum flow.

The present invention relates to a transport wheel arrangement for handling cylindrical bodies, comprising a base body (104), a negative pressure source which is intended to provide a negative pressure for holding the cylindrical bodies, a disc-shaped wheel body (102) which is rotatably mounted about its central axis (R1) on the base body (104), a drive device which is designed to set the wheel body (102) in rotary motion, at least one receiving assembly (112) for holding a cylindrical body, comprising a shaft (114) which receives a line (120) for conducting the negative pressure, a contact member (116) provided radially outside the shaft (114) which is designed to present a contact surface for a held cylindrical body, and a suction cup member (116) which is connected to the line (120) for conducting the negative pressure and is designed to hold a cylindrical body by means of this negative pressure; and a control unit which is designed to control the operation of the drive device and, if necessary, the vacuum source, wherein the transport wheel arrangement further comprises a displacement apparatus (122) which is designed to displace the contact element (116) and the suction cup element (118) of the receiving assembly (112) or at least one of the plurality of receiving assemblies (112) in a coordinated manner with respect to the wheel body (102).

Transport unit for transporting circular-cylindrical profiled workpieces, including a loading drum which is rotatably mounted about an axis of rotation on a bearing journal and which is provided on an outer surface with a plurality of loading slides, wherein each loading slide is received on the outer surface so as to be linearly movable along the axis of rotation and has a workholder with a recess profiled in the form of a circular section along the axis of rotation, wherein profile axes of the recesses each intersect a circumference arranged coaxially to the axis of rotation and wherein it is provided that the workholder is received on the loading slide so as to be linearly movable along a radial direction aligned perpendicularly to the axis of rotation between a radially inner first functional position and a radially outer second functional position.

A transfer device, for transferring components at high speed and inspecting the components, includes a first transfer mechanism including a first transfer section including a first transfer surface that moves along a first transfer path connecting a loading position to a delivery position, and a second transfer mechanism including a second transfer section that moves along a second transfer path connecting a receiving position spaced from the delivery position by a first distance to a discharging position. The second transfer section includes a second transfer surface that continuously rotates about a rotation axis along the second transfer path. A moving direction of the first transfer surface at the delivery position intersects a moving direction of the second transfer surface at the receiving position in a plan view of the first transfer surface. The second transfer mechanism includes a generator that generates an attraction force toward the second transfer surface.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.

An apparatus and method for manufacturing glass containers handles the containers individually after a hot forming process and annealing to prevent glass-to-glass contact. By handling the containers individually and preventing glass-to-glass contact damage to the containers in the form of checks and scratches is avoided. To prevent contact of the containers and damage arising from the contact, the equipment including conveyors, pushers, starwheels, shuttles, and transfer heads that move the glass containers through the apparatus maintains the glass containers in uniform spaced relationship at each stage of container processing until the containers are packaged.