A method for automatically handling a plurality of product containers includes the steps of: providing a container exchange apparatus having at least one platform for temporarily hosting containers to be transferred; moving the at least one platform along a conveyor device and a shelving unit; and driving shifting means for exchanging containers from the conveyor device to the shelving unit, and vice-versa, via the at least one platform.

A method for automatically handling a plurality of product containers includes the steps of: providing a container exchange apparatus having at least one platform for temporarily hosting containers to be transferred; moving the at least one platform along a conveyor device and a shelving unit; and driving shifting means for exchanging containers from the conveyor device to the shelving unit, and vice-versa, via the at least one platform.

The present invention provides a ball container utilized in conjunction with existing standard storage bins for storing and dispensing sporting balls to the upper opening of the storage bins. The present invention further provides a ball container utilized by hanging from a stand for storing and dispensing sporting balls to the upper opening of the ball container.

The present invention provides a ball container utilized in conjunction with existing standard storage bins for storing and dispensing sporting balls to the upper opening of the storage bins. The present invention further provides a ball container utilized by hanging from a stand for storing and dispensing sporting balls to the upper opening of the ball container.

An automated biological or chemical sample processing system includes a dock frame and at least one dock frame module. The dock frame includes at least one docking interface that operably couples and interfaces the dock frame with laboratory equipment. The dock frame defines a spine structure of the system alongside which a variable number of laboratory equipment are arrayed. The dock frame extends longitudinally and has a variable elongated configuration and longitudinal length. The at least one dock frame module includes the docking interface, where each module is interchangeable with another module, and has control features with a predetermined relationship to a reference datum of the dock frame module and with a reference datum of the dock frame so that the at least one dock frame module is interchangeably coupled in linear configuration with at least the other dock frame module to select the variable elongated configuration and longitudinal length.

An automated biological or chemical sample processing system includes a dock frame and at least one dock frame module. The dock frame includes at least one docking interface that operably couples and interfaces the dock frame with laboratory equipment. The dock frame defines a spine structure of the system alongside which a variable number of laboratory equipment are arrayed. The dock frame extends longitudinally and has a variable elongated configuration and longitudinal length. The at least one dock frame module includes the docking interface, where each module is interchangeable with another module, and has control features with a predetermined relationship to a reference datum of the dock frame module and with a reference datum of the dock frame so that the at least one dock frame module is interchangeably coupled in linear configuration with at least the other dock frame module to select the variable elongated configuration and longitudinal length.

Various embodiments are directed to a shuttle configured for use in an AS/RS. In various embodiments, the shuttle comprises: a first load arm and a second load arm configured to retractably extend away from a shuttle body in parallel directions, the first and second load arms each being extendable between a retracted configuration and an extended configuration; a load bed including a load area configured to receive the object; and a retractable mechanical finger provided at a distal portion of the first load arm and configured to facilitate handling of the object, the mechanical finger being hingedly connected to the first load arm using a one-way hinge component that defines a portion of the range of rotational movement of the mechanical finger relative to the first load arm and comprising a spring element that facilitates rotational movement of the finger between an expanded finger position and a retracted finger position.

Various embodiments are directed to a shuttle configured for use in an AS/RS. In various embodiments, the shuttle comprises: a first load arm and a second load arm configured to retractably extend away from a shuttle body in parallel directions, the first and second load arms each being extendable between a retracted configuration and an extended configuration; a load bed including a load area configured to receive the object; and a retractable mechanical finger provided at a distal portion of the first load arm and configured to facilitate handling of the object, the mechanical finger being hingedly connected to the first load arm using a one-way hinge component that defines a portion of the range of rotational movement of the mechanical finger relative to the first load arm and comprising a spring element that facilitates rotational movement of the finger between an expanded finger position and a retracted finger position.

An inverted carrier lift and method is disclosed. The inverted carrier lift includes a trolley movable along an overhead conveyor and a carrier for supporting a workpiece to undergo an assembly or manufacturing process. The carrier is movable relative to the trolley from a raised position to a lowered position by a motor mounted engaged with a lifting mechanism onboard the trolley. On rotation of the motor, the carrier and supported workpiece is lowered or raised to position the workpiece in the workstation for processing. The workpiece may be disengaged by the carrier for support of the workpiece by one of many different fixtures depending on the processing. Following processing, the workpiece is re-engaged by the carrier, moved to a raised position and the trolley is transferred to a subsequent workstation.

An inverted carrier lift and method is disclosed. The inverted carrier lift includes a trolley movable along an overhead conveyor and a carrier for supporting a workpiece to undergo an assembly or manufacturing process. The carrier is movable relative to the trolley from a raised position to a lowered position by a motor mounted engaged with a lifting mechanism onboard the trolley. On rotation of the motor, the carrier and supported workpiece is lowered or raised to position the workpiece in the workstation for processing. The workpiece may be disengaged by the carrier for support of the workpiece by one of many different fixtures depending on the processing. Following processing, the workpiece is re-engaged by the carrier, moved to a raised position and the trolley is transferred to a subsequent workstation.