Example systems and methods are described that are capable of gripping objects. In one implementation, a method involves identifying, by a processing system, an object to be gripped at a first location, commanding, by the processing system, a robotic actuator to move a gripper in a first direction so that the gripper makes contact with the object, wherein one or more teeth in a plurality of fingers associated with the gripper mechanically engage the object, and commanding, by the proceeding system, the robotic actuator to move the gripper in a second direction that is substantially opposite to the first direction, causing the gripper to grip the object.

A banknote handling system includes an unlocking system. The unlocking system includes a camera, a first mechanical arm to which one or a plurality of keys are affixed, and a controller that determines a position of a keyhole based on an image from the camera, and controls the first arm to insert one of the one or the plurality of keys into the keyhole and turn the inserted key for unlocking. In many examples, the unlocking system is configured to unlock a banknote cashbox.

An item with fibers may be picked up and placed using a tool head with hooks that engage the fibers. The tool head may comprise at least one hook portion and at least one contact surface adjacent to the hook portion. The hooks that engage the fibers may extend from the hook portion. The tool head may be actuatable between at least a first configuration that permits the hooks to engage the fibers and a second configuration that does not permit the hooks to engage the fibers. An item may be picked up at a starting location with a tool head in the first configuration and placed at a placement location by moving the tool head and then actuating the tool head to the second configuration.

The present patent application for the invention of a device, coupled to a robot or other handling system, deals with the pressure on the container, which allows the product to be moved to be held, moving and rotating them, defining their positioning and organizing them for later palletizing or positioning for subsequent operations. The invention comprises a device (D) composed of a headstock or structure (1) made of metal or another type of material, to be coupled, by means of a coupling (2), to a robot (R1) or other handling equipment; and, in the lower part of the device (D), an elastic blanket (3) made of material such as elastic/polymer is installed, which must have the property of maintaining the integrity of the product handled, in this case the container (4), single or grouped, and allow it to be moved over the work area (A1). The device (D), according to the invention, is operated from movements for the formation of layers or mosaics (M) from a dedicated software, and this association enables the movement of the containers (4) in transverse and longitudinal axes, or swivels.

Provided is a robot hand including a movable unit, a hand that changes in shape in accordance with movement of the movable unit, and an elastic body that changes a gripping force of the hand. When the amount of movement of the movable unit is less than a predetermined value, at least the hand changes in shape, and when the amount of movement of the movable unit is more than or equal to the predetermined value, the elastic body changes in elastic force while at least a part of the hand stops changing in shape.

Disclosed is a gripper (1) for beverage cans (20). The gripper (1) comprises at least one gripping device (6) used to grip a particular beverage can (20) from underneath the top seam (5) in a form-fitting manner in the region of a top seam (5), which top seam (5) is formed by a particular beverage can (20). The gripper (1) comprises at least one centering device (30), by which at least one centering device (30) aligns the particular beverage can (20) into a defined alignment, where the at least one gripping device (6) is able to grip a particular beverage can (20) from underneath in a form-fitting manner in the region of its top seam (5).

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 3 DOFs decoupling spherical parallel mechanism provided by the present disclosure comprises: a fixed platform, a rotation assembly, a moving platform, a first arc kinematic chain, a second arc kinematic chain, a first arc rod, and a second arc rod. In the 3 DOFs decoupling spherical parallel mechanism, the rotation assembly can drive the moving platform to rotate by 360 degrees around a direction being perpendicular to the fixed platform, and the first arc rod and the second arc rod reciprocate along tangential directions of the first arc kinematic chain and of the second arc kinematic chain respectively to enable the moving platform to rotate around an axis of a plane where the first arc kinematic chain or the second arc kinematic chain is located. In this way, the rotations of the moving platform in three directions are respectively driven by driving units in three directions and being independent from each other, such that the three rotation actions of the mechanism have decoupling capability.

A robotic end effector is disclosed. The end effector is configured to grasp, move, and place one or more objects without assistance from another robot. The end effector includes a lateral member configured to be coupled to a robotic arm, a passive side member coupled substantially rigidly to the lateral member at a first distal end and configured to engage mechanically with a first recess on a first side of an object to be grasped, and an active side member coupled to the lateral member at a second distal end opposite the first distal end and configured to engage mechanically with a second recess on a second side of the object to be grasped, the second side being opposite the first side of the object to be grasped. The passive side member and the active side member each include a structure, and the structure on the passive side member and the active side member have different profiles.

Robots including a lifting actuator for lifting object are disclosed. In one embodiment, a robot includes a rail system extending in a system direction, a body structure coupled to the rail system, the body structure comprising an array of flexible tactile sensors, wherein each flexible tactile sensor of the array of flexible tactile sensors is operable to produce a signal determinative of a magnitude and a direction of a force applied to the flexible tactile sensor, and a lift actuator operable to move the body structure along the rail system.