A robot head for withdrawing and transferring glass containers between two different conveyor groups includes a series of gripping members for withdrawing the glass containers carried by a first conveyor and releasing the containers on a second conveyor, wherein the gripping members of the robot head withdraw together all the glass containers carried by the first conveyor when the movement of the conveyor is stopped so as to enable a withdrawal of the containers. The robot head further includes a mechanism for the movement and variation in position of the gripping members with respect to each other, wherein the mechanism moves the gripping members of the glass containers from a first distance corresponding to the extraction distance from the first conveyor to a second depositing distance of the containers on the second conveyor.

A robot configured to use a gripper to grasp one or more tools is disclosed. In various embodiments, the robot comprises a robotic arm having a gripper disposed at a free moving end of the robotic arm, and a set of two or more tools configured to grasped or otherwise engaged by the gripper. Each tool in the set of two or more tools may be disposed in a corresponding tool holder, optionally attached to the robot or situated near the robot. The robot is configured to use the gripper to retrieve a selected tool from its tool holder to perform a task; use the tool to perform the task; and return the tool to its tool holder.

A robotic system includes a robotic manipulator having one or more contact pads. The contact pads have features therein that are detectable to determine or measure a degree to which they have worn down. Such features may include fluorescent materials, colorful materials, and/or RFID tags. A robotic environment may include one or more sensors to detect such features, and may be configured to generate a signal indicating that one or more contact pads are in need of maintenance.

A robot hand includes a motor with a rotary shaft, an accommodating member accommodating a distal end of the rotary shaft, a plurality of swing members swinging with respect to the accommodating member due to rotation of the rotary shaft, and a plurality of claw members swinging with the plurality of swing members.

Various aspects of robotic grippers are disclosed herein. In one aspect, a robotic gripper may include three gripper fingers arranged on a mechanical end effector, the three gripper fingers configured to translate radially when actuated to contact and align with a gripper interface located on a part to enable manipulation of the part. In various embodiments, each gripper finger may include an elongated portion configured to contact an outer surface of the gripper interface when the gripper fingers are actuated. Each gripper finger may further include a hook portion configured to contact an inner surface of the gripper interface opposing the outer surface. In various embodiments, the hook portion may include a receptacle positioned to align with a complementary protrusion on the gripper interface.

Modular gripping finger for arrangement on a movable gripper jaw of a gripping device, having at least two rigidly interconnected finger modules, the finger modules including one or more base modules for forming a geometric shape of the gripping finger and including an end module having a gripping surface, the end module including an electrical end module interface and at least one sensor which is or can be connected to the end module interface.

The invention relates to a gripper jaw for a robot gripper, the gripper jaw having a first gripper jaw interface corresponding with the robot gripper and a second gripper jaw interface corresponding with tools of a tool set, the gripper jaw interfaces each being used as a mechanical interface, as a signal interface and as a power interface; to a tool for a gripper jaw of this type the tool having a tool interface corresponding with the second gripper jaw interface; to a tool system, the tool system comprising at least one gripper jaw of this type and a tool set with tools of this type; and to a method for operating a tool system of this type, wherein first a tool is selected, thereafter said tool is picked up from a predefined position, thereafter said tool is used and thereafter said tool is deposited in the predefined position.

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 robot configured to use a gripper to grasp one or more tools is disclosed. In various embodiments, the robot comprises a robotic arm having a gripper disposed at a free moving end of the robotic arm, and a set of two or more tools configured to grasped or otherwise engaged by the gripper. Each tool in the set of two or more tools may be disposed in a corresponding tool holder, optionally attached to the robot or situated near the robot. The robot is configured to use the gripper to retrieve a selected tool from its tool holder to perform a task; use the tool to perform the task; and return the tool to its tool holder.

A robotic system including a long-stroke and force-control parallel gripper. The parallel gripper may include an electric motor and siding mechanism to allow the length of the stroke of the fingers to be greater than the distance traveled. The parallel gripper also includes interchangeable fingers that may be engaged and disengage by the robotic system using a secured finger housing and latching mechanism.