An automated painting system that includes a robotic arm and a painting end effector coupled at a distal end of the robotic arm, with the painting end effector configured to apply paint to a target surface. The painting system can also include a computing device executing a computational planner that: generates instructions for driving the painting end effector and robotic arm to perform at least one painting task that includes applying paint, via the painting the end effector, to a plurality of drywall pieces, the generating based at least in part on obtained target surface data; and drives the end effector and robotic arm to perform the at least one painting task.

An autonomous robot for harvesting produce from a plant include a base, an arm coupled to the base, and an end-effector coupled to the arm. The end-effector includes one or more grippers, each having a first cutter, second cutter, and a compliant member between the first cutter and the second cutter. The first cutter is configured to cut a stem of the produce at a first location. The second cutter is configured to cut the stem of the produce at a second location. The compliant member is configured to plastically deform to hold the stem of the produce.

A robotic ticket scratching system includes a controller configured to receive a dispense command for a ticket dispensing machine; cause the ticket dispensing machine to dispense, based on the dispense command, a ticket having a scratching area; and receive user-provided signing data and user-provided scratching data from the application server. The robotic ticket scratching system further includes a robotic scratching mechanism configured to scratch, or remove an opaque substance from, the scratching area of the ticket in accordance with the user-provided scratching data.

A tree and shrub cutting and trimming device having multiple robotic arms FIG. 2B and M for gross and fine movements, a wheeled movable base FIG. 3 and an electric cutting or trimming tool. This device allows the operator to be on the ground level, a substantial distance from the cutting surface and will not be holding the cutting or trimming device FIG. 6. This device drastically reduces insurance costs and labor cost, thus a less expensive much safer device to perform these tasks is provided in this field of endeavor.

A collaborative robot cutting system for the assembly, construction, fabrication, and/or the completion of structural components for manufactured assemblies. A method of preparing work pieces and materials for further manufacturing operations employing the intuitive graphical interactive programming features of a robot cutting system user interface to enhance productivity and versatility in high mix, low volume fabrication environments with minimal operator training.

A system includes a first fixture to support one side of a part and a robot that has a second fixture to support an opposite side of the part with respect to the one side. One of the part sides has a target on a surface that indicates a location for the operation. The system has a sensor to measure the target in 3-dimensional space. A tool performs the operation at the location, and a controller moves the robot to pick up the part from the first fixture using the second fixture. The controller presents the target to the sensor for measuring the x,y,z coordinates and the yaw, pitch and roll of the target. The controller moves the second fixture with the part to the tool based upon the measurement.

A waterjet system in accordance with at least some embodiments includes a carriage, a motion assembly configured to move the carriage horizontally relative to a workpiece, and a cutting head carried by the carriage. The waterjet system can also include a kinematic chain through which the cutting head is operably connected to the carriage. The kinematic chain can include first, second, and third joints rotatably adjustable about different first, second, and third axes, respectively. The carriage and the first and second joints can be configured to move the cutting head along a path relative to the workpiece while the cutting head directs a jet toward the workpiece to form a product. The third joint can be configured to shift a kinematic singularity away from the path to reduce or eliminate delay and corresponding reduced cutting accuracy associated with approaching the kinematic singularity.

The present invention disclose a tool-holder (10) comprising a first part (10a) and a second part (10b), wherein a wedge shaped locking mechanism is arranged partly on a first surface of the first part (10a) operable to be joined with further parts of the wedge shaped locking mechanism arranged on a second surface of the second part (10b).

A robotic drill system and a method of drilling with a robotic drill system. This includes inserting a tool head of the robotic drill within a hole of a drill template along an initial insertion trajectory with a robotic manipulator arm that is moved by at least one robotic actuator for causing robotic insertion of the tool head. In response to sensing binding of the tool head to a wall of the hole while inserting the tool head along the initial insertion trajectory, the disclosure includes stopping robotic insertion of the tool head and activating a self-centering device of the tool head to reorient the tool head to a corrected alignment of the tool head axis relative to the hole. The self-centering device may include an expandable collet.

A robotic cutting device includes a cutting tool responsive to a mobile actuator adapted to apply a cutting force in a 3-dimensional (3D) space, and scanning logic configured to identify a cutting path denoted on an article for cutting. Using the cutting path, a mobile actuator is responsive to positioning logic for disposing the cutting tool along the cutting path for performing a prescribed cut on the article. The mobile actuator is a robotic arm responsive to an independent coordinate frame based on a position and orientation of a mobility vehicle supporting the mobile actuator. The mobility vehicle is typically a tracked or all-terrain capable chassis adapted to be disposed adjacent to the article such that the article is within range of the actuator. The mobility vehicle transports the robotic cutting device adjacent to the article to be cut, such that the cutting path is within reach.