Presented are automatic end-of-arm tool changing devices, methods for making/using such tool changing devices, and automated robotic systems with such tool changing devices. A tool changing device for an automated robotic system includes a quick-change (QC) interlock subassembly that attaches to an end effector. The QC subassembly includes a housing, one or more locking pins movable on the QC housing, and one or more anchor pins projecting from the QC housing. A finger block (FB) subassembly, which performs a task on a target object, includes a housing, a robot tool mounted to the FB housing, and one or more key slots and one or more pin holes in the FB housing. Each key slot receives an anchor pin; once the anchor pin is slid to a locking end of the key slot, each locking pin automatically slides into a pin hole to thereby lock together the QC and FB subassemblies.

A picking apparatus is configured to pick up a plurality of micro elements. The picking apparatus includes a main body and a plurality of picking portions. The picking portions connect with and protrude from the main body. Each of the picking portions has a first surface. The first surfaces are away from the main body and configured to pick up the micro elements. The main body has a second surface at least partially located between the picking portions. Each of the first surfaces has a first viscosity. The second surface has a second viscosity. The second viscosity is less than the first viscosity.

An end-effector is disclosed for a programmable motion device. The end effector includes a body that includes a vacuum portion through which a vacuum is applied to an object, and a gripping portion that is adapted to engage the object, the vacuum portion being generally orthogonal to the gripping portion.

A tool interchange for a submersible remote operated vehicle (ROV) arm includes a first interchange body that affixes to an ROV arm. A second interchange body is carried by the first interchange body to rotate on a rotation axis. The second interchange body includes a tool mount actuable between gripping an ROV tool to the second interchange body and releasing the ROV tool from the second interchange body. An inductive power coupling part is provided in the tool mount. The inductive power coupling part is presented outwardly in the tool mount opposite the first interchange body, resides on the rotation axis and is fixed with respect to the first interchange body while the second interchange body rotates. The inductive power coupling part is adapted to inductively communicate power with a corresponding inductor power coupling part of the ROV tool when the ROV tool is docked in the tool mount.

Provided herein is an apparatus and system to increase the capacity for grasping or engagement of an object using an accessory tool. Methods of increasing the capacity of a tool can include: engaging an accessory tool with a tool, where the tool includes a first vacuum cup and the accessory tool includes one or more second vacuum cups; securing the tool to the accessory tool with a securing mechanism; drawing a vacuum through the first vacuum cup, where the vacuum is drawn through the one or more second vacuum cups in response to drawing a vacuum through the first vacuum cup while the accessory tool is engaged with the tool; and grasping an object with the second one or more vacuum cups in response to vacuum drawn through the one or more second vacuum cups and the one or more second vacuum cups engaging a surface of the object.

A tool interchange for a submersible remote operated vehicle (ROV) arm includes a first interchange body that affixes to an ROV arm. A second interchange body is carried by the first interchange body to rotate on a rotation axis. The second interchange body includes a tool mount actuable between gripping an ROV tool to the second interchange body and releasing the ROV tool from the second interchange body. An inductive power coupling part is provided in the tool mount. The inductive power coupling part is presented outwardly in the tool mount opposite the first interchange body, resides on the rotation axis and is fixed with respect to the first interchange body while the second interchange body rotates. The inductive power coupling part is adapted to inductively communicate power with a corresponding inductor power coupling part of the ROV tool when the ROV tool is docked in the tool mount.

A coupling device is described herein having a body situated between a mounting member and a receiving member. The mounting member mounts to a portion of a machine and the receiving member receives a tool to couple the tool to the machine. The body includes a housing having a locking pin disposed therein. The locking pin includes a plurality of teeth radially positioned about an outer surface of the locking pin. A plurality of pawls disposed in the body engage with the plurality of teeth to lock a rotational position of the locking pin. A lever connected to the locking pin allows a user to rotate the locking pin. Upon rotation of the lever, components in the body cause the locking pin to rotate and translate towards the tool to impose a force on a portion of the tool to rigidly connect the tool to the machine.

Devices, systems, and methods for automatically exchanging a first end-effector on a robot arm with a second end-effector housed in a docking station. The first end-effector has a clamp that either engages or disengages the robot arm based upon an application of force of the robot arm onto the end-effector. The clamp has a spring loaded clip that disengages the first end-effector to allow the robot arm to move away from the released first end-effector. The robot arm is configured to automatically move to a port of a docking station housing the desired second end-effector using magnetic coils on the robot arm and the docking station to guide the robot arm.

The system includes a robot interface disposed on a robot arm, and an end effector configured to selectively couple to the robot arm via the robot interface. The end effector includes an upper jaw, a lower jaw, and a pair of arms configured to carry a substrate. The upper jaw and the lower jaw are spaced apart in a first direction and biased together, and the pair of arms are spaced apart in a second direction orthogonal to the first direction. When the end effector is coupled to the robot arm, the robot interface is disposed between the upper jaw and the lower jaw. To exchange the end effector, the upper jaw and the lower jaw can be separated to release the robot interface.

A clamp device for retaining a container in a container-handling apparatus, for example for retaining a drinks container in a container-handling apparatus of a bottling plant, includes two clamp arms which can be moved relative to one another, wherein at least one clamp arm has an interchangeable clamp jaw with a retaining portion for retaining the container which is to be retained, wherein the clamp jaw has a latching element for undergoing a form fit with a recess formed in the associated clamp arm. A clamp jaw and a container-handling apparatus are also described.