A robotic vehicle is provided with an extendable arm and a mandible structure. The mandible structure includes a pair of mandibles with toothed portions that cooperatively engage such that the mandibles may be opened and closed by applying a force to only one of the pair of mandibles. The mandible structure hangs freely from the extendable arm and is balanced so that the mandible structure naturally maintains a substantially vertical orientation. In the closed position, the mandible structure defines an interior cavity suitable for securely grasping a ring.

A box transfer apparatus for an automated harvesting system is provided, the box transfer apparatus comprising: a frame; a plurality of trays to support a plurality of boxes; and a box gripper moveable within the frame using a gantry coupled to the frame; wherein the box gripper is configured to grasp boxes and move the grasped boxes between the frame and an adjacent frame used to convey the boxes to be used in receiving picked items from the automated harvesting system. A stem gripper for an automated harvesting system is also provided, the stem gripper comprising: a housing comprising at least one motor; a pair of contoured fingers operable by the at least one motor to rotate above a common axis to grasp stems of items picked by the automated harvesting system; and a drive mechanism to move the stem gripper from a discard bin to a box for loading.

A robotic gripper for grasping a target object includes a linear actuator and a gripping assembly. The gripping assembly is coupled to the linear actuator and includes a plurality of fingers that are positioned to selectively grasp and release the target object. The linear actuator includes an air cylinder and a linearly movable rod that reciprocates within the air cylinder between a retracted position and an extended position. The gripping assembly includes a finger holder and a finger closer. The fingers are affixed to the finger holder and extend from the finger holder through openings formed in the finger closer. The finger closer is coupled to the linearly movable rod which reciprocatingly drives the finger closer over the fingers to adjust the fingers between a first position in which the fingers grasp the target object and a second position in which the fingers release the target object.

An end effector, for adhesively attaching a first part to a second part, comprises a support, a first nozzle, movable relative to the support, and a second nozzle, movable relative to the support. The first nozzle comprises a first-nozzle-body outlet port and a first-nozzle separator plate. The second nozzle comprises a second-nozzle-body outlet port and a second-nozzle separator plate. The end effector additionally comprises a first ultrasonic-sensor roller that is rotatable relative to the support and located between the first nozzle and the second nozzle. The end effector also comprises a second ultrasonic-sensor roller that is rotatable relative to the support and located between the first ultrasonic-sensor roller and the second nozzle.

A construction equipment accessory can include a construction equipment attachment portion, which can include a mechanical interface, a hydraulic interface, and a center section coupled to the mechanical interface, first and second support arms pivotably coupled to the construction equipment attachment portion's center section, and first and second finger grapples. The first and second finger grapples can each include two or more opposing fingers and can be hydraulically movable between open and closed positions. By attaching the construction equipment accessory to construction equipment with the construction equipment attachment portion, an operator can move elongate objects such as pipes, poles, and erosion control products.

A compliant adaptive robot grasper comprises a multi-bar finger linkage, including a fingertip link, at least one base link, and front and rear links joining the base link via a first set of joints with the fingertip links via a second set of joints. The base link includes a mounting structure, allowing it to be mounted on a mounting block for rotary actuation. Linear connections between the joints form a shape substantially in the form of a parallelogram allowing the linear connections across the front and rear links to remain substantially parallel to one another as the front and rear links pivot about the base link without substantially changing the orientation of the fingertip link until and unless the multi-bar finger linkage contacts an external object.

An agricultural manipulator, configured to perform agricultural processing from a group, at least including harvesting and pruning. The manipulator includes-a carrier, a connector arranged on the carrier and configured to connect the manipulator to a robot arm, and at least one manipulating device on the carrier from a group, at least comprising a gripper and a cutter. An assembly of such a manipulator with a robot arm, in particular an industrial robot arm.

A robotically-operated gripping device is provided and includes a frame assembly, a vacuum device, a clamping device, and a robotic arm. The vacuum device is connected to the frame assembly and configured to selectively attach to and position at least a portion of an object. The clamping device is connected to the frame assembly and provided for selectively clamping the object attached to the vacuum device. The robotic arm is connected to the frame assembly and provided for selectively positioning the vacuum device and the gripping device.

The present invention provides a prosthetic device (10) having an anchor portion (30) in combination with a base portion (12) which is connected to the anchor portion (30). An elongate digit (14) is coupled to a first portion of a pivot connection (16a) mounted on the base portion (12), whilst a second portion of a pivot connection (16b) is mounted on the proximal end (14a) of the digit (14) and is connected to the first portion (16a) of the pivot connection (16). A linear actuator (40) within the elongate digit (14) has a first portion (40a) secured to the elongate digit (14) for movement therewith and a second portion (40b) remote therefrom and axially movable relative thereto and is operable with said pivot connection (16) to cause pivotal movement of the digit (14) around the pivot connection (16a, 16b) upon axial movement of the second portion (40b) of the linear actuator (40).

A robotic gripper for grasping a target object includes a linear actuator and a gripping assembly. The gripping assembly is coupled to the linear actuator and includes a plurality of fingers that are positioned to selectively grasp and release the target object. The linear actuator includes an air cylinder and a linearly movable rod that reciprocates within the air cylinder between a retracted position and an extended position. The gripping assembly includes a finger holder and a finger closer. The fingers are affixed to the finger holder and extend from the finger holder through openings formed in the finger closer. The finger closer is coupled to the linearly movable rod which reciprocatingly drives the finger closer over the fingers to adjust the fingers between a first position in which the fingers grasp the target object and a second position in which the fingers release the target object.