A dowel basket assembly apparatus includes a jig table rotationally supported on a bearing assembly, which supports a table top assembly having arms extending radially outwardly and supporting first, second and third jig table bases. The bases move through first, second and third stations by rotating the assembly. First jig table is positioned at first station, second jig table at second station, and third jig table at third station. Rods are located in receptacles on first jig table base at first station. Simultaneously, rods are welded to form a dowel basket on second jig table base at second station. Simultaneously, a welded dowel basket is unloaded from third jig table base at third station. After completion of the steps of locating, welding and retrieving, the apparatus is rotated to advance the jig tables to the next station.

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.

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.

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.

Transfer system for removing sleeve-shaped workpieces from a first conveyor and for pushing the sleeve-shaped workpieces onto a second conveyor, with a linearly movable coupling rod, with which a gear unit is associated, which includes a swivel body mounted so as to be pivotable about an axis of movement, on which a first workpiece gripper mounted so as to be rotatable about a first axis of rotation and a second workpiece gripper are arranged, wherein the gear unit has an adjuster for initiating an actuating movement for setting a distance between a first gripping region of the first workpiece gripper, which is arranged at a radial distance from the axis of movement, and a second gripping region of the second workpiece gripper, which is arranged at a radial distance from the axis of movement, as well as with a swivel drive for actuating the adjuster for initiating a forced swivel movement connected to the swivel movement of the swivel body onto the first workpiece gripper.

A device for aligning and optically inspecting a semiconductor component arranged on a receiving tool that is arranged on a turning mechanism. The device aligns the semiconductor component in relation to a center of the receiving tool in at least one axis direction and/or a direction of rotation. The turning mechanism is designed to rotate about a turning axis and to move the semiconductor component out of a receiving position into an offset position, with two slides that can be moved towards and away from each other and comprise slide sections, the two slide sections coming to rest on two lateral surfaces of the semiconductor component, at least in sections, in order to align the semiconductor component arranged on the receiving tool, the slide being defined such that it slides and/or rotates the semiconductor component into an inspection position, while the receiving tool holds the semiconductor component.

An aligning and conveying apparatus includes a rotating disk having a bottom wall, a first ring having a first circumferential wall, a second ring having a second circumferential wall. First and second conveying parts are respectively provided in upper parts of the first and second circumferential walls. In the rotating disk and the first ring, the bottom wall is positioned lower than the first conveying part to form a retaining space for retaining preparations inside the first ring. The respective rotational axes are relatively inclined such that the preparations move from the bottom wall to the first conveying part at a first delivery position. In the first and second rings, the first conveying part is positioned lower than the second conveying part, and the respective rotational axes are relatively inclined such that the preparations move from the first conveying part to the second conveying part at a second delivery 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.

Method and apparatus for automatically preparing seeds with an additive to be deployed together with the seeds, wherein the seeds are opened and a predefined amount of additive is introduced into the seeds through the opening.