A gripping equipment for lifting apparatuses of the type comprising: a rigid supporting framework which is adapted to be fixed/attached to the lifting apparatus; one or more manually-operated gripping members that are firmly fixed on said rigid supporting framework and are adapted to grasp and hold a specific object to be moved; a revolving joint which is interposed between the rigid supporting framework and the lifting apparatus and which allows said rigid supporting framework to rotate with respect to the lifting apparatus about a substantially vertical, first rotation axis; and at least one adjustment assembly which is interposed between the revolving joint and the rigid supporting framework or between two rigid elements of said rigid supporting framework and allows the position/orientation of said rigid supporting framework with respect to the vertical to be manually adjusted.

Described herein are flexible truss systems and methods of transferring flexible composite parts using these systems. A flexible truss system comprises a flexible truss mechanism and composite pick-and-place mechanisms supported on the flexible truss mechanism and designed to attach to various composite parts. The flexible truss mechanism comprises flexible elongated members and slidable ribs coupled to each flexible elongated member. Specifically, each rib is slidably coupled to at least one flexible elongated member. In some examples, each rib is also fixedly coupled to another flexible elongated member. The slidable coupling allows the flexible truss mechanism to bend and follow the shape of a supported part, such that the composite pick-and-place mechanisms are able to contact and support different areas of the composite part. As such, the same flexible truss mechanism is able to support flexible composite parts having different shapes.

A multi-axis gantry system comprising a multi-axis gantry apparatus and vacuum system, and method for repositioning is disclosed. The multi-axis gantry system comprises a frame. The frame includes a plurality of curved base members, a first rail, a second rail, a bridge slidably moveable along the first rail and the second rail, a carriage including an end effector, and a first plurality of pucks and a second plurality of pucks. The vacuum system comprises a vacuum controller, a first vacuum source and a second vacuum source. Each of the first and second vacuum sources is in fluid communication with one or more pucks of the first and second pluralities of pucks. The frame is reconfigurable from a first configuration mountable on a first work surface to a second configuration mountable on a second work surface that may be different from the first work surface.

The invention relates to a handling device (1), having a drive carriage (2) that is movable relative to a carrier (3), wherein a scissor lift (7) having a plurality of scissor-lift members (8) is arranged with its first end on the drive carriage (2), wherein a carrier plate (11) that is movable relative to the drive carriage (2) by means of the scissor lift (7) is arranged at the second end of the scissor lift (7), wherein: a gripping tool is arranged on the carrier plate (11), the scissor-lift members (8) are hollow throughout and are sealingly interconnected in order to actuate the gripping tool by means of a gaseous medium.

Tooling (100) for picking up two-dimensional workpieces comprises a main body (110) and a plurality of holding elements (131, 132) arranged on the main body (110), wherein the holding elements (131, 132) are movable relative to the main body (110) independently of one another. Each of the holding elements (131, 132) is fastened in an end region of an arm (121.1 . . . 10, 122.1 . . . 10). The arms (121, 122) are movable passively relative to the main body (110) along a linear movement path in a longitudinal extension of each particular arm (121, 122). The tooling (100) comprises, for each of the arms (121, 122) a fixing apparatus, by means of which a position of each particular arm (121, 122) along the movement path is fixable. On account of its passive character, the tooling (100) according to the invention is lightweight and can be produced cost-effectively. Compared with fixedly configured tooling, reduced costs arise on account of the configurability, because different types of tooling do not have to be kept available and provided. The storage area for replacement tooling is saved, and also an automatic tooling changing station or a manual tooling change become superfluous. As a result of the geometry according to the invention, the tooling (100) can be set easily, no complex movements and accordingly no complicated setting devices (for example multiaxial robots) are necessary.

Embodiments of a vacuum material handler or lifting device and system of this disclosure provide a modular design that allows a power pack to be mounted directly to the pad or remotely mounted on host equipment to minimize lift weight. The pad, which includes an integral, pad reservoir, may be arranged, to accept a rotator or a tilting mechanism for position when used on mobile equipment. The power pack is independent of the pad and can be transferred to multiple pads, thereby permitting a single power pack to service the different pads. The control mechanism may reside on the pad to further facilitate modularity. Safety checks used for remote operation may be used to minimize the risk of danger in the event of remote vacuum hose or vacuum failure.

Gripping equipment for lifting apparatuses of the type comprising: a rigid support framework which is adapted to be fixed/attached to the lifting apparatus; and one or more manually controlled gripping members that are firmly fixed to said rigid support framework, and are adapted to grasp and hold a specific object to be moved; said rigid support framework comprising at least one rectilinear tubular element with polygonal cross-section, which is made of metal and has a sectional modular structure.

This disclosure presents a manipulator for lifting objects and an upwards open container within which the objects are at least partly arranged. The manipulator includes a first object engaging device for engaging a first object, a second object engaging device for engaging a second object. The manipulation is configured for forcing the first and second objects apart when engaged by the first and second object engaging devices, such that the objects exert an internal force on the container. The disclosure also presents a method for lifting objects and an upwards open container.

Solar panels are prepared for installation on an array frame by initially tipping packages of palletized, bundled, vertically-oriented panels in a preparation area to form a vertical stack of horizontally oriented panel separated from the pallet and packaging material for placement on the upper supporting surface of the transport deck. The transport deck is displaced longitudinally alongside a rack of the array frame, together with a lifting machine having a lifting head on a lifting arm for transferring solar panels from a longitudinal row of stacked solar panels on the transport deck to the array frame. The lifting head may be adapted to support one panel from each of the stacks on the transport deck for simultaneous transfer from the transport deck to the array frame.

Described herein are flexible truss systems and methods of transferring flexible composite parts using these systems. A flexible truss system comprises a flexible truss mechanism and composite pick-and-place mechanisms supported on the flexible truss mechanism and designed to attach to various composite parts. The flexible truss mechanism comprises flexible elongated members and slidable ribs coupled to each flexible elongated member. Specifically, each rib is slidably coupled to at least one flexible elongated member. In some examples, each rib is also fixedly coupled to another flexible elongated member. The slidable coupling allows the flexible truss mechanism to bend and follow the shape of a supported part, such that the composite pick-and-place mechanisms are able to contact and support different areas of the composite part. As such, the same flexible truss mechanism is able to support flexible composite parts having different shapes.