A suction apparatus includes a suction unit, a negative pressure detection unit, a suction abnormality determination unit, and a notification unit. The suction unit suctions and holds merchandise with a negative pressure. The negative pressure detection unit detects a negative pressure value in the suction unit whenever the suction unit suctions the merchandise. The suction abnormality determination unit determines that the suction unit is abnormal in a case where the detected negative pressure value is lower in negative pressure degree than a predetermined suction determination negative pressure value continuously by a predetermined number of times of determination or more. The notification unit provides a notification in a case where the suction unit is determined to be abnormal.

Provided is an apparatus for piston insertion, including an insertion robot having a plurality of robot arms connected by a plurality of articulated joints, a piston insertion module directly mounted on the insertion robot, gripping a piston assembly, and inserting the piston assembly into a cylinder bore of a cylinder block, and a controller controlling an operation of the insertion robot and an operation of the piston insertion module.

A vacuum gripping system for grabbing and releasing an object has a base frame for operably engaging a robotic arm. The base frame includes a pneumatic source connector. The system also includes an extendable member configured to extend and retract relative to the base frame. The extendable member has a distal end and a proximal end. The extendable member also has an extended position and a retracted position defining a range of motion therebetween. The system further includes a vacuum cup coupled to the distal end of the extendable member. Still further, the system includes a pneumatic pathway extending from the vacuum cup to the pneumatic source connector. The pneumatic pathway passes through the extendable member such that the vacuum cup remains in pneumatic communication with the pneumatic source connector throughout the range of motion of the extendable member.

A vacuum-based end effector for engaging parcels includes a base plate, one or more vacuum cups of a first type, and one or more vacuum cups of a second type. Each vacuum cup of the vacuum-based end effector is configured to be placed in fluid communication with a vacuum source to provide the vacuum cup with a suction force which can be used to engage and grasp parcels. Each vacuum cup includes a bellows defining a pathway for a flow of air and a lip connected to the bellows. Each lip of the one or more vacuum cups of the first type comprises a foam lip, and each lip of the one or more vacuum cups of the second type comprises an elastomeric lip. The vacuum-based end effector can be combined with a robot to provide an improved system for engaging parcels.

A handling device according to an embodiment has an arm, a holder, a storage, and a controller. The arm includes at least one joint. The holder is attached to the arm and is configured to hold an object. The storage stores a function map including at least one of information about holdable positions of the holder and information about possible postures of the holder. The detector is configured to detect information about the object. The controller is configured to generate holdable candidate points on the basis of the information detected by the detector, to search the function map for a position in an environment in which the object is present, the position being associated with the generated holdable candidate points, and to determine a holding posture of the holder on the basis of the searched position. The function map associates a manipulability with each position in the environment in which the object is present. The manipulability is a parameter calculated from at least one joint angle of the holder.

A system and method palletize containers having electrical terminals for charging electronic devices packaged therein. First, a stacking pattern is determined on the basis of the sizes, shapes, and locations of electrical terminals on both the pallets and the containers to be stacked. These data may be read, for example, with a computer vision system that uses an articulating robotic arm, and may be encoded in a two-dimensional barcode on each pallet and/or container. Next, the robotic arm stacks the container so that its terminals make electrical contact with terminals on the pallet, or on a previously-stacked layer of containers. Then, the placement is tested to ensure that a good electrical connection exists vertically through the entire stack. Once the pallet is finalized, all electronic devices carried thereon may be simultaneously charged during transit or storage.

A method for transferring at least one filling needle of a number of filling needles into an isolator which has a transfer lock, the method having the following steps: providing a first needle carrier within the transfer lock, said needle carrier carrying the number of filling needles; providing a second needle carrier in a first position within the isolator; robot-assisted transferring of the at least one filling needle of the number of filling needles from the first needle carrier to the second needle carrier; and robot-assisted placing of the at least one filling needle of the number of filling needles in the second needle carrier, wherein the at least one filling needle of the number of filling needles is held directly during the robot-assisted placing. A transfer system, in which such a method can be conducted, is also disclosed.

The automated gripping tool enables a user to move a food product from a first position to a second position while maintaining the integrity and appearance of the food product. The automated gripping tool makes use of flexible gripping elements on the ends of banks of opposing pairs of gripping arms. The flexible gripping elements are positioned to cradle a stacked food product between them with sufficient force to allow the food product to be repositioned and without damaging the integrity of the food product.

The technology disclosed relates a robotic workstation for packaging wood products. The robotic packaging workstation can achieve can handle efficiently wrapping/packaging product stacked into units. In one configuration, the robotic packaging workstation includes a robot manipulator capable of moving an end effector to points in a three-dimensional work volume under programed control of a programmable robot controller executing stored instructions. A fastener and wrapping tool head is affixed to the end effector adapter plate. The fastener and wrapping tool head further includes a support structure, a fastener applicator, a fastener storage, and a one or more grippers for grasping wrapping material.

An end effector for handling objects in an isolator. The end effector comprises a first receptacle for a first object, a second receptacle for a second object, and a displacement member, wherein the receptacles are arranged on opposite sides of the end effector in a longitudinal direction. Each receptacle is displaced between a receiving position, in which the respective object can be received, and a gripping position, in which the respective object can be gripped. Each receptacle has a first gripping portion, wherein the first gripping portion of the first receptacle is located at a first end of the displacement member and the first gripping portion of the second receptacle is located at an opposite second end of the displacement member. The displacement member is displaceable such that the first and second receptacles can each be displaced between the receiving and gripping positions. A robot, a system and a method are also disclosed.