A robotic gripper configured to mount to a robotic arm is described herein. The robotic gripper includes a base configured to mount to the robotic arm and spin about an axis of the base. The robotic gripper also includes at least two gripping elements coupled to the base. Each gripping element extends from the base in a direction parallel to the axis of the base and is movable relative to the base between an open position and a closed position to grasp an object. A first gripping element of the at least two gripping elements defines a first element axis laterally spaced from the axis of the base by a first distance. At least one other gripping element defines another element axis that is laterally spaced from the axis of the base by a second distance that is smaller than the first distance.

A robotic gripper apparatus for an automated additive manufacturing production system (AAMPS) includes a pair of gripping assemblies. Each gripping assembly is moveable in a transverse direction between a first position in which the gripping assembly engages an AAMPS workpiece and a second position in which the gripping assembly is disengaged from the AAMPS workpiece. Each gripping assembly includes a gripping element that defines an interface slot configured to receive the AAMPS workpiece. The interface slot is defined by a pair of transversely extending edges of the gripping element and a longitudinal edge of the gripping element disposed between the pair of transversely extending edges.

A parallel-type gripper according to an embodiment of the present invention includes: a pair of jaws that are opposite to each other; and a parallel-type driving module in which the pair of jaws are movably connected in a horizontal direction such that they approach or move away from each other, and moving the pair of jaws in the horizontal direction so that the pair of jaws grip an object.

A slide rack gripper apparatus is provided that simultaneously conveys a plurality of glass slides in the protection of a slide rack within a digital slide scanning apparatus. The slide rack gripper apparatus conveys the plurality of glass slides from a slide rack carousel to a scanning stage for processing. The slide rack gripper includes a first motor attached to a base configured to drive a finger mount attached to the base along a first linear axis. The slide rack gripper apparatus also includes a second motor attached to the finger mount and configured to drive opposing gripper fingers attached to the finger mount along a second linear axis. The second motor is also configured to drive individual gripper fingers along a third linear axis to move the gripper fingers toward each other and away from each other to grasp or release a slide rack.

An apparatus for provisioning, in particular automatically, a complete tool having a toolholder and a tool, in particular a drilling and/or milling tool. The apparatus has a spindle that can be driven in rotation by a driving device. The spindle has a holding device for holding a toolholder. A measuring device, in particular an optical measuring device, measures a complete tool, held on the spindle. A heating device in the region of the spindle heats a shrink-fit chuck of the toolholder held on the spindle. A cooling device, in particular a cooling device associated with the spindle, enables the spindle and/or the complete tool held on the spindle, to be cooled.

Systems and methods relating to an end-of-arm-tool that can be used in connection with the automated handling of vehicles, such as unmanned aerial vehicles (UAV), are disclosed. The described systems and methods can include an end-of-arm-tool which may include a load cell coupled to an end effector, such that forces and torques exerted on the end effector are translated onto the load cell. The measurement of forces and torques exerted on the end effector can facilitate determining various information in connection with the aerial vehicle, such as inertial properties or parameters associated with the aerial vehicle, the quality of the engagement between the end effector and the aerial vehicle, as well as diagnostic information in connection with the aerial vehicle. Additionally, the use of a load cell to measure forces and torques exerted on the end effector can eliminate the need to utilize traditional contact sensors typically required on the contact surfaces of an end-of-arm tool.

The invention relates to a device or tool (1) for gripping a liner in order to carry out a method of removing same from, and installing same in, the shell of a mill, which comprises a rigid structure or frame (2) forming a support for containing the components needed for the operation thereof, a coupling element (6) that allows the device to be secured or disposed on at least one end of a manipulation device, such as a robotic manipulator, comprises at least one claw or pincer (7) for holding at least one bolt by the head, the tool being designed to allow the adjustment of the relative position thereof in order to align the pincers to the positions of the holes of each liner, the at least one pincer (7) having a configuration allowing said claws to open and close so as to adjust the size thereof to the size of the bolt being gripped, wherein the at least one pincer or claw (7) has at least one sensor, thereby enabling mill liners to be installed and removed, the tool being based on the fastening elements that hold the liners in position.

A chuck unit includes a first pressure chamber and a second pressure chamber disposed on both sides of a piston for driving fingers. A valve unit includes a first output air flow path connected to one of the first and second pressure chambers, a second output air flow path connected to the other thereof, a first solenoid valve connected to the first output air flow path, and a second solenoid valve connected to the second output air flow path. The first solenoid valve connects the first output air flow path to an air supply source when energized and opens the first output air flow path to atmosphere when de-energized, and the second solenoid valve opens the second output air flow path to atmosphere when energized and connects the second output air flow path to the air supply source when de-energized.

This box assembling and packing system is provided: a first jig which is fixed at a predetermined position and against which a side part of a body of a packing box is thrust; a second jig which is fixed at a predetermined position and against which a flap part and a tuck part of the packing box are thrust; and a robot having two articulated arms. A first articulated arm of the two articulated arms holds and moves the packing box in a flatly collapsed form by a packing box holding mechanism, folds and raises the body of the flatly collapsed packing box into a rectangular tubular shape in cooperation with the first jig, and maintains the folded and raised body of the packing box in the rectangular tubular shape by a packing box rectangular tubular shape maintaining mechanism. The second articulated arm moves a folding member into contact with the flap part and the tuck part of the packing box being held by the packing box holding mechanism of the first articulated arm, forms each of a bottom and a lid of the packing box in cooperation with the second jig, and moves an object-to-be-packed being grasped by an object-to-be-packed grasping mechanism and inserts it into the body from an end portion at a timing between forming the bottom and forming the lid.

A system and methods are disclosed for precision placement or insertion of an object using robotic manipulation. A robotic tool includes at least three members, including a first member and a second member that grip the object between opposing faces and a third member that exerts a force on a proximate end of the object to push the object out of the robotic tool. A series of maneuvers is performed with the robotic tool in order to place the object on a surface or insert the object in a hole. The maneuvers include positioning the object against the surface, rotating the object around a contact point between the object and the surface, rotating the robotic tool around a contact point between the object and either the first or second member of the robotic tool, sliding the object horizontally along a surface, and tucking the object into a final desired position.