Embodiments of an active object mounting system secure an object of interest to a surface of a secured-to object using one or more vacuum mounting modules, wherein each vacuum mounting module comprises at least one vacuum pump controllably coupled to a microcontroller, a vacuum cup fluidly coupled to the at least one vacuum pump, and a transceiver that receives an instruction corresponding to one of a vacuum cup actuation signal or a vacuum cup release signal.

A vacuum gripper comprises a rigid base element and a loop-shaped vacuum seal element. The base element has first and second opposite sides. The seal element is attached at least indirectly to the second side and protruding therefrom in a direction away from the first side. The seal element comprises a contact surface that at least partially contacts with an object surface and an encircling surface oriented transversely to the contact surface so as to define a chamber. The seal element is elastically deformable at the contact surface to enable conforming to the object surface when pressed thereagainst. The vacuum gripper comprises an air extraction means mounted to the first side to be in fluid communication with the chamber through the base element, and configured to continuously extract air from the chamber to cause the contact surface to be urged towards and grip the object surface when pressed thereagainst.

An operating device for a handling device, with a gripping section and a coupling for a gripping device, with at least a part of the coupling being at or in the gripping section, so that it is rotatable about an axis of rotation, with a reading device for reading out an information carrier with coded data being placed on the side of the griping section facing the coupling, where the reading device is designed to read out an information carrier of a gripping device coupled to the coupling regardless of the rotational position of the coupling.

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.

A system and method for moving objects such as drill, pipe with vacuum power. A vacuum beam (14) is mounted on a boom. A vacuum pad (12) is pivotally attached to the vacuum beam (14). A power device (18) is operatively connected to a vacuum pump (16) with a drive belt (32) for creating vacuum pressure. Vacuum pressure from the vacuum pad (12) is used to grasp and release the object, e.g., the drill pipe.

A material lifter comprising a vacuum pump, a frame containing the vacuum pump, an arm located on each of two opposing sides of the frame, each arm including an upper end pivotally connected to the frame, a cylinder located on each of the two opposing sides of the frame including an end connected to the frame and an end connected to a respective arm, a vacuum pad located on each of the two opposing sides of the frame and removably connected to a respective arm, the vacuum pads being moveable along the arm to a first location and a first orientation and a second different location and a second different orientation, wherein as the cylinders extend and retract the arms pivot toward and away from one another between a first position and a second different position and the vacuum pads remain in a same orientation during the pivot.

The disclosure relates to a vacuum lifting arrangement comprising a vacuum pump, a valve arrangement, a support structure, and a flexible lifting tube comprising a suction foot. The vacuum pump is connected to the valve arrangement and to the flexible lifting tube. The valve arrangement is arranged to extend and retract the flexible lifting tube. The valve arrangement is arranged separate from the suction foot, between the vacuum pump and the suction foot. The disclosure also relates to a method of providing a vacuum lifting arrangement.

The disclosure relates to a device for automatically lifting a packing material comprising a lifting element movable between a lower removal position and an upper transfer position, a vacuum source configured to create a negative pressure, a drive element, and a suction element, which has at least one opening of a vacuum line and is mechanically connected to the lifting element and is fluidically connected to the vacuum source by means of the vacuum line. The lifting element is configured to place the suction element on an uppermost packing material of a stack of packing materials by its weight force in the lower removal position, wherein the opening of the vacuum line can be closed in an airtight manner, and wherein the lifting element is configured to move together with the sucked packing material into the upper transfer position.

A control system and method for a vacuum attachment system has a programmable controller that interprets feedback from vacuum level sensors and battery sensors to responsively provide warnings and limit or alter machine functions to reduce risk exposure. Vacuum levels and vacuum level change over time are used to evaluate conditions such as vacuum generator function, excessive altitude, vacuum system condition and leakage due to incompatibility of attachment device and load. Warnings are engaged if parameters or limits are not met. At designated/calculated thresholds and conditions the device can adjust its utilization of resources to ensure the safest condition. If conditions are detected that indicate a reduced ability to maintain the attachment, the programmable controller may limit functions such as preventing the operator from initiating another attachment.

A system including a programmable motion device and an end effector for grasping objects to be moved by the programmable motion device is disclosed. The system includes a vacuum source that provides a high flow vacuum such that an object may be grasped at an end effector opening while permitting a substantial flow of air through the opening, and a dead-head limitation system for limiting any effects of dead-heading on the vacuum source in the event that a flow of air to the vacuum source is interrupted.