A collision-proof spring transfer takes place in the process, which comprises a continuous transfer of coil springs from the pipeline through an exit opening of the pipeline into assigned spring receptacles, and an automatic prevention of any re-entry of coil springs that have passed through the exit opening in the direction of the spring receptacle and rebound from the region of the spring receptacle back into the pipeline.

A collision-proof spring transfer takes place in the process, which comprises a continuous transfer of coil springs from the pipeline through an exit opening of the pipeline into assigned spring receptacles, and an automatic prevention of any re-entry of coil springs that have passed through the exit opening in the direction of the spring receptacle and rebound from the region of the spring receptacle back into the pipeline.

A chip transfer apparatus includes: a chip storage module in which a plurality of micro-semiconductor chips and a suspension including impurities are stored; a chip filtration module separating a first suspension including the plurality of micro-semiconductor chips and a second suspension including the impurities in the suspension; and a chip supply module configured to supply the first suspension onto the transfer substrate such that the first suspension is introduced from the chip filtration module and the plurality of micro-semiconductor chips are flowable on the transfer substrate.

A chip transfer apparatus includes: a chip storage module in which a plurality of micro-semiconductor chips and a suspension including impurities are stored; a chip filtration module separating a first suspension including the plurality of micro-semiconductor chips and a second suspension including the impurities in the suspension; and a chip supply module configured to supply the first suspension onto the transfer substrate such that the first suspension is introduced from the chip filtration module and the plurality of micro-semiconductor chips are flowable on the transfer substrate.

An apparatus for packaging of loose product includes a loading station, a box forming station and an uploading station. The loading station includes moveable chutes in spaced apart relation. Each chute has an open top, an open upstream end, and an open downstream end. The open top is configured to receive loose product while moving along a first feed path. The box forming station is operable to partially erect boxes in spaced apart relation with first and second open sides and align the first open side of each box with the downstream end of a corresponding chute while moving along a second feed path. The unloading station includes a stationary vacuum head in communication with the second open side of each box. The vacuum head provides a continuous vacuum source along the second feed path operable to move loose product from the chute into the boxes.

An air-driven container twisting system is configured for changing orientation of containers moving through a material-handling system. The air-driven container twisting system may include a container guide that extends through an air drive arrangement with the container guide configured to direct containers longitudinally while simultaneously rotating the containers while moving through the air-driven container twisting system without the need of declining elevation change and gravity assist.

An air-driven container twisting system is configured for changing orientation of containers moving through a material-handling system. The air-driven container twisting system may include a container guide that extends through an air drive arrangement with the container guide configured to direct containers longitudinally while simultaneously rotating the containers while moving through the air-driven container twisting system without the need of declining elevation change and gravity assist.

An automated method and system for transitioning a bottle from a horizontal belt conveyor to the entrance of an air conveyor, and vice versa, from an air conveyor to a horizontal belt conveyor. An indexer in a circular arrangement moves around 180 degrees clockwise until the bottle drops into the air conveyor (e.g., pneumatic tube). This motion controls the bottle's movement; otherwise, the bottle would free-fall off the conveyor. The indexer rotary device provides control of the vial transition, keeping it vertical so it goes into the tube in a controlled manner.

An automated method and system for transitioning a bottle from a horizontal belt conveyor to the entrance of an air conveyor, and vice versa, from an air conveyor to a horizontal belt conveyor. An indexer in a circular arrangement moves around 180 degrees clockwise until the bottle drops into the air conveyor (e.g., pneumatic tube). This motion controls the bottle's movement; otherwise, the bottle would free-fall off the conveyor. The indexer rotary device provides control of the vial transition, keeping it vertical so it goes into the tube in a controlled manner.

A vehicle waste disposal system connected to a vehicle, the vehicle waste disposal system including a waste receiving container connected within a passenger compartment of the vehicle to receive at least one waste item therein, a waste storage container connected within a trunk of the vehicle to receive the at least one waste item from the waste receiving container and store the at least one waste item therein, a pipe connected at a first end to at least a portion of the waste receiving container and connected at a second end to at least a portion of the waste storage container, and an air dispensing unit connected to at least a portion of the waste receiving container and the pipe to move the at least one waste item from the waste receiving container to the waste storage container in response to extracting air from the waste receiving container and expelling the air into the pipe toward the waste storage container.