A gripping apparatus includes an impermeable layer defining a vacuum port, a first flow media layer associated with the impermeable layer, and a second flow media layer opposed from the first flow media layer to define a receiving space therebetween.

Methods and apparatus for determining a grasp strategy to grasp an object with a gripper of a robotic device are described. The method comprises generating a set of grasp candidates to grasp a target object, wherein each of the grasp candidates includes information about a gripper placement relative to the target object, determining, for each of the grasp candidates in the set, a grasp quality, wherein the grasp quality is determined using a physical-interaction model including one or more forces between the target object and the gripper located at the gripper placement for the respective grasp candidate, selecting, based at least in part on the determined grasp qualities, one of the grasp candidates, and controlling the robotic device to attempt to grasp the target object using the selected grasp candidate.

A system moves items, like containers and/or pallets, through a label printing station. The station has a label printer that prints adhesive labels; and a robot arm terminating at a movable end with a suction pad or vacuum device and sensors. The station has sensors configured to measure a height of the item; and a processor coupled to receive the height of the item, to control the robot arm and label printer, and to receive label information from a server. The processor has a memory containing code that computes desired label positions based on height of the container/pallet. A method of labeling an item includes printing an adhesive label with the label information obtained from a server; receiving the adhesive label on a suction pad or vacuum device attached to a movable end of a robot arm, and determining a first labeling position from measured height of the container/pallet.

A vacuum cup assembly that generates a local vacuum using a prime mover that may be an electrical motor or a solenoid. The vacuum cup may have one or more ports to remove and vent air between the cup and the atmosphere. The prime mover drives a piston or a flexible membrane, which may be a diaphragm, through one or more reciprocating cycles to generate the local vacuum. The vacuum cup assembly may be used to form a temporary attachment to a work piece, the act on the work piece, such as by moving the work piece, and then release the work piece from the vacuum cup assembly. The vacuum cup assembly disclosed herein is self-contained inasmuch as the assembly may have a power source, such as a battery, located on a housing. This makes its operation quiet and effective.

A compliant end effector includes a robot mounting bracket and a component support member. The component support member includes a side surface and a top surface. A component clamping system includes a first clamp member operable to move toward the side surface of the component support member and a second clamp member operable to move toward the top surface of the component support member. A controller is operatively connected to the clamping system. The controller is configured to engage the first and second clamp members as the component gripping and manipulating system is in a set position and release the first clamp member and the second clamp member allowing a portion of a component held by the component clamping system to move with one or more degrees of freedom when the component gripping and manipulating system is moving to the set position.

Examples relating to controlling extendable legs of a robotic device for use of a mechanical gripper are described herein. A robotic device may include one or more legs configured with a mechanical gripper coupled to the leg at a first position away from the distal end of the leg. The mechanical gripper may transition between the first position and a second position on the leg proximate to the distal end that enables the robotic device to use the mechanical gripper to perform grip operations. A control system of the robotic device may modify an orientation of the robotic device to at least position the robotic device on one or more legs other than the leg comprising the mechanical gripper, and transitions the mechanical gripper from the first position to the second position to perform the given grip operation of the input.

The invention relates to a device for installing a windscreen of a vehicle, which device comprises a support which stands vertically and is adjustable in height, a beam which extends away from the support, and one or more suction cups for holding the windscreen. The one or more suction cups are in each case movably connected by means of a plurality of rods and ball joints to the beam. The rods and ball joints enable a simple movement in all directions relative to the support of a windscreen by a single person, as a ball joint is disposed between a suction cup and a rod, in each case between two rods and between a rod and the beam in each case, and enables a local movement in all directions at each of these articulation points. The movement of the windscreen can take place either manually, pneumatically or hydraulically.

A picking device includes: a workpiece holder in which a plurality of workpieces is stacked; a light receiver that receives reflected light from a workpiece stacked in the workpiece holder; a mover that relatively moves the light receiver with respect to the workpiece in such a manner that a distance between the light receiver and the workpiece is adjustable; an arm that picks the workpiece; a first hardware processor that calculates a distance between the light receiver and at least one workpiece among the plurality of workpieces; a second hardware processor that specifies a workpiece as a picking target among the plurality of workpieces or a region where the workpiece exists; and a third hardware processor that adjusts a distance between the light receiver and the workpiece calculated by the first hardware processor by controlling the mover in the region specified by the second hardware processor.

A system for handling a first component includes: a main-device and a module-device, the module-device having a pressing section arranged to form an outer surface of the module-device, the module-device configured to releasably receive the first component, such that a connection section of the first component is attachable to the pressing section of the module-device. The module-device is releasably connected to a second component, wherein the main-device includes a grabbing unit adapted for releasably connecting the module-device, such that the pressing section is arranged to form a first outer surface section of the main-device, and wherein the main-device includes a connector for connecting to a handling-unit for arranging the main-device at the second component, such that the connection section of the first component, if attached to the pressing section of the module-device, is at least indirectly attachable to a front surface of the second component.

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.