Gripper structures can be used to conform to and support complex surfaces. For example, a system described herein can include a gripper structure. The gripper structure can include a plurality of iterations in a series of layers. The series of layers can be arranged in a progression in which each successive layer is adjacent to a preceding layer. The series of layers can include an anchor layer including a single shape of the pattern. The series of layers can include intermediate layers including a plurality of shapes that are copies of the single shape and are more numerous and smaller than shapes in its preceding layer. The series of layers can include a base layer including the most and smallest shapes in the series of layers. The series of layers can also include a plurality of joints. Each shape on the base layer can include an adhesion promoting mechanism.

A programmable motion robotic system is disclosed that includes a plurality of arm sections that are joined one to another at a plurality of joints to form an articulated arm, and a hose coupling an end effector of the programmable motion robotic system to a vacuum source. The hose is attached to at least one arm section of the articulated arm by a pass-through coupling that permits the hose to pass freely through the coupling as the plurality of arm sections are moved about the plurality of joints.

A handling device according to an embodiment includes a manipulator, a normal grid generation unit, a hand kernel generation unit, a calculation unit, and a control unit. The normal grid generation unit converts a depth image into a point cloud, generates spatial data including an object to be grasped that is divided into a plurality of grids from the point cloud, and calculates a normal vector of the point cloud included in the grid using spherical coordinates. The hand kernel generation unit generates a hand kernel of each suction pad. The calculation unit calculates ease of grasping the object to be grasped by a plurality of suction pads based on a 3D convolution calculation using a grid including the spatial data and the hand kernel. The control unit controls a grasping operation of the manipulator based on the ease of grasping the object to be grasped by the plurality of suction pads.

An automated insertion system for inserting or combining one or more fastener components with a molded part. The automated insertion system can handle multiple fastener components repeatedly, and do so faster and more safely than current processes.

A vacuum-assisted product-handling system is described that includes a carrier to move an unpackaged product into a contact position. The system also includes an actuation unit to move the unpackaged product from the contact position of the carrier to a receiving container. The actuation unit may include a mechanical arm to lift the unpackaged product from the carrier and deposit the unpackaged product in the receiving container, and a vacuum tool connected to an end of the mechanical arm. The vacuum tool may be operable to hold the unpackaged product as the unpackaged product is moved by the actuation unit from the carrier to the receiving container. The vacuum tool may include one or more arrays of suction devices, where each array of suction devices is connected to a single vacuum source.

An end-effector for a programmable motion device is disclosed. The end effector includes a body that includes a contact portion, the body providing an open interior through which a vacuum may be provided to the contact portion, and the body includes at least one feature that is adapted to facilitate the contact portion to become substantially non-planar while grasping.

An example system includes a nozzle having an inlet: an outlet mechanism disposed longitudinally adjacent to the nozzle; a conduit longitudinally adjacent to the outlet mechanism where the conduit includes a distal chamber, a middle chamber, and a proximal chamber, that; are longitudinally disposed along a length of the conduit; a partition block configured to move between (i) a first position at which the partition block: is disposed laterally adjacent to the middle chamber, such that the partition block is offset from a longitudinal axis of the conduit, and (ii) a second position at which the partition block resides in the middle chamber between the distal chamber and the proximal chamber; and a deceleration structure disposed at a proximal, end of the conduit and bounding the proximal chamber, where the deceleration structure is configured to decelerate fruit feat has traversed the conduit.

A transfer device having a plurality of pick-up heads loads products into receptacles. The products are provided in a random arrangement in a pick-up area, and the position of each product is detected. To pick up the products, the transfer device is moved over the pick-up area and each pick-up head picks up an individual product at a pick-up time and in a pick-up position. The pick-up position and the pick-up time for the products are determined on the basis of the previously detected positions of the products. The placement of the products in a placement area may also occurs while the transfer device is moving relative to the receptacles.

A suction transfer device suction-holds a bag-like article with a suction component and moves the suction component suction-holding the article to thereby transfer the article. The suction component has a negative pressure chamber, one or more suction openings, and a first surface. The negative pressure chamber forms a negative pressure space inside when a negative pressure generator is driven. The suction openings communicate with the negative pressure chamber. The first surface is disposed around the suction openings and opposes an article subjected to suction. An area of the first surface is from 0.5 times to 2 times an area of a sucked surface, which opposes the first surface, of the article subjected to suction.

Pre-plating systems and related methods are disclosed. A pre-plating system includes a press, an infeed robot configured to deliver a structural member to the press, and an outfeed robot configured to remove the structural member from the press. The press is configured to secure a plate to the structural member while the structural member is held in position by at least one of the infeed robot or the outfeed robot. A pre-plating system includes a press, a transfer pedestal, a plate picking robot, and a press loading robot. The plate picking robot is configured to pick a plate from a container and position the plate on the transfer pedestal. The press loading robot is configured to transfer the plate to the press. The press is configured to press the plate into a structural member positioned within the press.