According to one embodiment, a transfer apparatus includes a suction hand, a moving device, a first detector, and a controller. The suction hand includes a first and second suction units. The first and second suction units are configured to contact with an article in a first direction and a second direction, respectively. the first suction unit and the second suction unit each are provided multiply in a third direction. The controller performs at least a first operation and a second operation. In the first operation, the first suction units respectively suction first surfaces of the articles, the second suction units respectively suction second surfaces of the articles, and the articles are moved. In the second operation, one of the first suction units suctions the first surface of one of the articles, the second suction units do not suction the articles, and the one of the articles is moved.

Techniques are disclosed to perform robotic handling of soft products in non-rigid packaging. In various embodiments, sensor data associated with a workspace is received. An action to be performed in the workspace using one or more robotic elements is determined, the action including moving an end effector of one of the robotic elements relatively quickly to a location in proximity to an item to be grasped; actuating a grasping mechanism of the end effector to grasp the item using an amount of force and structures associated with minimized risk of damage to one or both of the item and its packaging; and using sensor data generated subsequent to the item being grasped to ensure the item has been grasped securely. Control communications are sent to the robotic element via the communication interface to cause robotic element to perform the action.

A robot hand is a robot hand to transfer an article, which includes a holder to move the article in a first direction while holding the article, a driving belt having a transferring surface on which the article is placed and driven to move the transferring surface in the first direction, and a first driver to drive the driving belt. The holder moves in the first direction to place the held article onto the transferring surface.

A computer positions an object using a computer-controlled positioning device. The computer is operatively associated with the positioning device via a control interface. The positioning device has a substantially-hollow interior chamber. The computer identifies a selected object located at a primary location within the interior chamber and having a primary orientation with respect thereto. The computer identifies a first array of elements constructed and arranged to generate contact-free support forces sufficient to maintain the selected object at the primary location. The computer identifies a second array of elements constructed and arranged to provide contact-free interaction forces sufficient to move the selected object within the interior chamber. The computer interacts with the selected object, using the control interface to adjust at least one of either the supporting forces and the interaction forces, to place the selected object into at least one of a secondary location or a secondary orientation.

The present disclosure generally relates to a robotic gripping system and method that utilizes vacuum suction and finger grasping, wherein the suction and grasping are actuated based on a dynamic collision model. In an exemplary embodiment, the present disclosure is directed to generating collision scenes of a surrounding environment which is used to determine possible collisions in a motion path, and which is used to selectively actuate the vacuum suction and/or finger grasping.

A method for operating a transport robot includes receiving image data representative of a group of objects. One or more target objects are identified in the group based on the received image data. Addressable vacuum regions are selected based on the identified one or more target objects. The transport robot is command to cause the selected addressable vacuum regions to hold and transport the identified one or more target objects. The transport robot includes a multi-gripper assembly having an array of addressable vacuum regions each configured to independently provide a vacuum. A vision sensor device can capture the image data, which is representative of the target objects adjacent to or held by the multi-gripper assembly.

Systems and methods related to intelligent grippers with individual cup control are disclosed. One aspect of the disclosure provides a method of determining grip quality between a robotic gripper and an object. The method comprises applying a vacuum to two or more cup assemblies of the robotic gripper in contact with the object, moving the object with the robotic gripper after applying the vacuum to the two or more cup assemblies, and determining, using at least one pressure sensor associated with each of the two or more cup assemblies, a grip quality between the robotic gripper and the object.

An emblem installation system for installing emblems on a work piece includes an end effector for a robotic arm. The end effector has a base and multiple vacuum gripper modules repositionable along the base in different configurations. The vacuum gripper modules are configured to simultaneously grip multiple emblems and individually release the emblems. An emblem installation method includes applying a force within a first range of forces to the multiple emblems individually and in succession via vacuum gripper modules of an end effector on a robotic arm, with the emblems disposed at a first location, applying a vacuum to the vacuum gripper modules to grip the emblems with the vacuum gripper modules, and moving the robotic arm from the first location to a second location adjacent a workpiece with the emblems gripped by the vacuum gripper modules.

According to one embodiment, a handling system includes a movable arm, a holding unit, a sensor, and a controller. The holding unit is attached to the movable arm and capable of holding an object by selecting one or more of a plurality of holding methods. The sensor is capable of detecting a plurality of the objects. The controller controls the movable arm and the holding unit. The controller calculates a score based on a selected holding method for each object and each holding method on the basis of information acquired from the sensor. The controller selects a next object to be held and a holding method on the basis of the score. The controller calculates a position at which the selected object is held and a posture of the movable arm.

According to an embodiment, a grasping control device controls a grasping device including grasping members to grasp an object. The grasping control device includes a selector, a first determination unit and a controller. The selector selects at least one grasping form for the object based on first information relating to the object, from among a plurality of grasping forms determined by a number and an arrangement of the grasping members. The first determination unit determines a usage form realizing the selected grasping form, from among a plurality of usage forms determined by at least one of second information relating to the grasping device and third information relating to an obstacle. The controller controls the grasping device such that at least one of grasping members grasps the object according to the determined usage form.