The invention relates to an arrangement of a gripper finger and a clamp for use in an automated parallel gripper comprising first and second gripper fingers that are moveable in a direction of translation (y), whereby the clamp is connected to the gripper finger at an underside thereof, so as to be rotational about a vertical axis of rotation (135). The clamp has a front face with a contact surface for engagement with a lateral edge of an item to be gripped and has a default orientation in which the front face is parallel to a lateral direction (x) that is perpendicular to the direction of translation (y) and to the vertical rotation axis (135). The arrangement is additionally provided with a self-alignment feature which comprises first and second biasing mechanisms arranged at either side of the rotation axis (135) in lateral direction (x). Each biasing mechanism has a first part (151, 152) connected to the finger and a second part (131, 132) connected to the clamp and is configured to exert a centering force that urges the first and second parts of each biasing mechanism into alignment with each other. When the clamp is in the default orientation, each biasing mechanism is preloaded to exert an equal moment load on the clamp in the direction of translation (y).

The invention relates to a method for assembling a motor vehicle heating, ventilation and/or air conditioning device, comprising a step of moving at least one part by a manipulator (I) provided with gripping means (2), the gripping means (2) comprising at least one first finger (3) delimiting a triangular shape, said part comprising an element of shape complementary to the trian-gular shape of the finger of the manipulator, termed counter shape, so that, during the movement step, the manipulator (I) grasps the part using the gripping means (2), the counter shape of the part en-gaging with the triangular shape of the finger (3).

A system includes a processor, a robotic arm comprising an end effector, wherein the end effector comprises a plurality of ridges, a sensor configured to detect vibrations from the plurality of ridges, and a memory module. The memory module stores machine-readable instructions that cause the processor to perform operations including contacting, with the plurality of ridges, a target object, detecting, with the sensor, vibrations from the plurality of ridges caused by a movement between the target object and the plurality of ridges, determining an attribute of the movement based on the detected signals, and adjusting the end effector based on the attribute of the movement.

A bottle gripping assembly including a pair of bottle gripping arms each having a grip member for gripping a bottle therebetween. The bottle gripping assembly also includes a base supporting the bottle gripping arms, with the base having a top surface and a recess into the top surface, a wear pad located in the recess of the base, with the wear pad and the base under the upper surface of the recess having a pair of aligned fastener holes, a pair of fasteners, with each one of the fasteners extending through one of the bottle gripping arms and into one of the fastener holes to connect the bottle gripping arms to the wear pad and the base, and a pair of wear bushings, with each of the wear bushings having a tubular portion that extends into one of the bottle gripping arms and surrounds a portion of the fasteners.

A system connects an assembly with at least one actuator and at least one sensor to a controller. The assembly is guided by a handling apparatus. The controller includes a radio master spatially separate from the handling apparatus and has a sending and receiving unit. The assembly is supplied with supply voltage by the handling apparatus. In or on the assembly, the supply voltage is transformed into a direct current target voltage with the aid of a DC/DC or AC/DC transformer. The direct current target voltage supplies the sending and receiving unit of the assembly.

A robotic kitchen assistant for frying includes a robotic arm, a fryer basket, and a robotic arm adapter assembly allowing the robotic arm to pick up and manipulate the fryer basket. The robotic arm adapter includes opposing gripping members to engage the fryer basket. A utensil adapter assembly is mounted to the handle of the fryer basket, and the opposing gripper members are actuated to capture a three-dimensional (3D) feature of the utensil adapter assembly. The robotic arm adapter assembly can include an agitator mechanism to shake the fryer basket or another utensil as desired. Related methods are also described.

A gripper mechanism includes a pair of gripper jaws, a linear actuator, and a rocker bogey. The linear actuator drives a first gripper jaw to move relative to a second gripper jaw. Here, the linear actuator includes a screw shaft and a drive nut where the drive nut includes a protrusion having protrusion axis expending along a length of the protrusion. The protrusion axis is perpendicular to an actuation axis of the linear actuator along a length of the screw shaft. The rocker bogey is coupled to the drive nut at the protrusion to form a pivot point for the rocker bogey and to enable the rocker bogey to pivot about the protrusion axis when the linear actuator drives the first gripper jaw to move relative to the second gripper jaw.

Embodiments of the present disclosure provide an apparatus and a method for operating a twistlock and an associated robot. The apparatus comprises a clamping assembly comprising a plurality of pairs of clamping portions spaced apart by different distances and adapted to engage with different types of twistlocks, respectively; and an operating assembly adapted to drive one of the plurality of pairs of clamping portions to clamp the twistlock and to drive the clamped twistlock to rotate, to allow the clamped twistlock to be mounted on or removed from a container. In this way, the apparatus according to embodiments of the present disclosure can be applied to most types of twistlocks without changing the clamping assembly, thereby improving the operation efficiency and reducing the costs.

A precision clamping assembly has a body, two clamping arms, and a drive device. The body has a first direction, a second direction, a chamber formed in the body, and an opening formed through an outer side of the body along the second direction and communicating with the chamber. The clamping arms are pivotally and movably connected to the body, and each clamping arm is disposed in the chamber and has a pivot end and a clamping end extended out of the body via the opening. The clamping ends are selectively moved toward or away from each other along the second direction and selectively moved same or opposite from each other along a third direction. The drive device is connected to the body and the two clamping arms, and has two driving sets disposed in the body and respectively connected to the two clamping arms.

A gripper mechanism includes a pair of gripper jaws, a linear actuator, and a rocker bogey. The linear actuator drives a first gripper jaw to move relative to a second gripper jaw. Here, the linear actuator includes a screw shaft and a drive nut where the drive nut includes a protrusion having protrusion axis expending along a length of the protrusion. The protrusion axis is perpendicular to an actuation axis of the linear actuator along a length of the screw shaft. The rocker bogey is coupled to the drive nut at the protrusion to form a pivot point for the rocker bogey and to enable the rocker bogey to pivot about the protrusion axis when the linear actuator drives the first gripper jaw to move relative to the second gripper jaw.