It is an object of the present invention to provide a weighing device in which dropping of articles from gripping means and reductions in weighing precision are suppressed. In a weighing device (100), when at least one of an operation state of grippers (30) and weighing results from weighing units (40) fulfills any condition from among “a weight value of articles (A) weighed by the weighing units (40) not being a preset target weight value,” “an operating distance in an operation in which the articles (A) are held by gripping members (32) being greater than a prescribed range,” and “the operating distance in the operation in which the articles (A) are held by the gripping members (32) being less than the prescribed range,” the articles (A) gripped by the grippers (30) are returned to an article group accommodation container (52) by a control unit (70) without said articles (A) being discharged to a discharge chute. As a result, a situation where the grippers (30) operate while still holding “articles for which the weight value is not the target weight value” is avoided.

A method of inverting workpieces in a mass production process includes: advancing an end effector in electronic synchronization with advancement of a carrier to synchronize arrival of the carrier at a stop position with arrival of the end effector at an unloading position, in which the end effector is in alignment with a workpiece held by the carrier for engaging the workpiece; while the end effector is in engagement with the workpiece, retracting the end effector away from the carrier to unload the workpiece from the carrier and advancing the end effector back toward the carrier to load the workpiece back into the carrier; and rotating the end effector relative to the carrier to invert the workpiece in electronic synchronization with the retracting and advancing of the end effector for loading the workpiece back into the carrier when inverted.

A dialyzer housing manufacturing system includes a molding device configured to mold a dialyzer housing, and a tool coupled to a robotic arm and configured to retrieve the dialyzer housing from the molding device after the dialyzer housing is molded. The tool includes a frame, a first suction cup connected to a first portion of the frame, and a second suction cup connected to a second portion of the frame, the second suction cup being oriented about 70 degrees to about 110 degrees relative to the first suction cup.

End effectors for use with a robotic object-gripping system, and related systems and methods, are disclosed herein. In some embodiments, the end effector includes a first mounting structure, a force sensor coupled to the first mounting structure, a second mounting structure coupled to the force sensor, and a gripper assembly coupled to the second mounting structure. The force sensor is beneath the longitudinal plane and is configured to measure forces along a vertical axis. The end effector also includes a first bracket coupled to the first mounting structure and a second bracket coupled to the second mounting structure. The first and second brackets are configured to connect to the connection tubes to isolate the connection tubes, and any forces therein, to a longitudinal direction between the first bracket and the second bracket, thereby reducing the noise on the force sensor from the connection tubes during operation.

Disclosed are a vehicle headliner assembly system and a vehicle headliner assembly method wherein position correction based on image capture and full process automation resolve nonuniformity of assembly quality which may occur if operators manually mount and assembly vehicle headliners individually with regard to various vehicle types, and manpower required for processes is reduced, thereby improving productivity.

The disclosure concerns a pivoting unit for a handling robot for opening a flap (e.g. door) of a motor vehicle body, comprising a mounting flange, a gripper arm and a first gripping tool for gripping an engagement on the flap to be opened, the first gripping tool being mounted on the gripper arm, and a pivoting head for pivoting the gripper arm between an initial position and an engaged position. The disclosure provides that a second gripping tool is also mounted on the gripper arm, and that the two gripping tools on the gripper arm are adapted to be inserted in different insertion directions into engagement with the openable flap of the motor vehicle body, in particular from top to bottom for the first gripping tool and from bottom to top for the second gripping tool. The disclosure further comprises an associated method.

In an embodiment, a method for handling an order includes determining a plurality of ingredients based on an order, received from a user over a network, for a location having a plurality of robots. The method further includes planning at least one trajectory for at least one robot based on the plurality of ingredients and utensils available at the location, and proximity of each ingredient and utensil to the at least one robot. Each trajectory can be configured to move one of the plurality of ingredients into a container associated with the order. In an embodiment, the method includes executing the at least one trajectory by the at least one robot to fulfill the order. In an embodiment, the method includes moving the container to a pickup area.

An automatic wheel changer robot has a includes a drive assembly, a torque gun, a sensor assembly, and a controller. The drive assembly has a mobile base and two wheel-clamping assemblies, each configured to engage a wheel. The controller generates a set of instructions based, at least in part, on information obtained from the sensor assembly. The drive assembly uses the set of instructions to cooperatively remove respective wheels from respective hubs on a vehicle and/or attach respective wheels to respective hubs on a vehicle. The device may have lidar sensors and Mecanum wheels that the controller is programmed to use to move between respective hubs and wheel storage locations install wheels, replace wheels, rotate tires, and perform similar operations.

A system for part transfer and transport, the system including: a first conveyor system for transporting a plurality of trays containing a two-dimensional grid of parts; a second conveyor system for transporting the parts to a predetermined destination in a linear arrangement; and a selection apparatus for transferring a linear array of parts selected from the grid of the first conveyor system to the linear arrangement of the second conveyor system, the selection apparatus comprising: a pick and place apparatus which may be cam driven for moving the parts; and a feed screw defining a plurality of singulated part spaces separated by a part pitch along the second conveyor to facilitate insertion of the linear array of parts into the linear arrangement.

An example apparatus of the present disclosure may include an end effector. The end effector may include a pair of actuator-driven fingers that each include a compliant tip. The compliant tips may be used to scoop underneath items as part of item manipulation.