An operating device for placing or retrieving bottle-like piece goods onto or from storage places of a picking device is provided. The operating device includes a gripping jaw assembly having two profile-rod shaped gripping jaws with opposite lying inner surfaces extending in a first horizontal direction corresponding to a direction for placing and retrieving piece goods. The gripping jaws are configured so that the distance of the inner surfaces from each other tapers in the downward direction at least in sections and the bottle-like piece goods can be lifted from below. The operating device also includes an actuation unit coupled to the gripping jaw assembly for moving the gripping jaw assembly in the first horizontal direction.

A collaborative device includes: a robotic arm including at least one motor; a tool secured to a free end of the robotic arm; a computer unit connected to the robotic arm to transmit instructions for controlling the robotic arm; and a joint having a flexible connection. The device integrates at least one sensor parameterised to detect forces exerted on the flexible connection. The computer unit is configured to: receive data from the sensor; translate the data into torques applied at the motor(s) of the robotic arm; generate instructions for attenuating the applied torques; and control the motor(s) of the robotic arm with the attenuation instructions.

A gripping device for a robot for gripping objects, including at least two gripping units each having a gripping finger and being transferable by a controlled movement between a release position and a gripping position gripping an object, the gripping units each having gripper elements which, in the gripping position, can be brought into contact with the object to be gripped, in which the gripper elements are rotatably mounted on the gripping fingers of the gripping device.

Structural designs and operational methods for object grasping and within-hand manipulation of an object is provided using rolling structures. The use of rolling structures reduces the need of finger gaiting, which is the periodic relocation of fingers on the object while maintaining a grasp, during manipulation. Embodiments of the invention provide a more efficient method of in-hand manipulation and grasping. In one example, two degrees of freedom rollers allow the object being manipulated in any direction in 3D space while remaining contact with the object.

Provided are methods and apparatus for environment-adaptive robotic disinfecting. In an example, provided is a method that can include (i) creating, from digital images, a map of a structure; (ii) identifying a location of a robot in the structure; (iii) segmenting, using a machine learning-based classifying algorithm trained based on object affordance information, the digital images to identify potentially contaminated surfaces within the structure; (iv) creating a map of potentially contaminated surfaces within the structure; (v) calculating a trajectory of movement of the robot to move the robot to a location of a potentially contaminated surface in the potentially contaminated surfaces; and (vi) moving the robot along the trajectory of movement to position a directional decontaminant source adjacent to the potentially contaminated surface. Other methods, systems, and computer-readable media are also disclosed.

A laundry sorting and evaluation system includes a housing having an opening and defining a laundry path. First and second platforms are positioned within the housing, each operably connected to a motor. First and second cameras are respectively associated with the platforms and are configured to acquire at images of an item of laundry on each of the first and second platforms. A controller is configured to receive the images and produce an evaluation of a condition of the item of laundry based upon the received images.

A robot head for withdrawing and transferring glass containers between two different conveyor groups includes a series of gripping members for withdrawing the glass containers carried by a first conveyor and releasing the containers on a second conveyor, wherein the gripping members of the robot head withdraw together all the glass containers carried by the first conveyor when the movement of the conveyor is stopped so as to enable a withdrawal of the containers. The robot head further includes a mechanism for the movement and variation in position of the gripping members with respect to each other, wherein the mechanism moves the gripping members of the glass containers from a first distance corresponding to the extraction distance from the first conveyor to a second depositing distance of the containers on the second conveyor.

The invention discloses a fully automatic intelligent rubber tapping robot, which comprises a moving platform and a rubber tapping robot arm. The rubber cutting mechanical arm is installed on the moving platform. tapping robot arm is installed on the moving platform. The tapping robot arm is specially designed for rubber cutting operation, the end of the tapping robot arm is equipped with an end actuator, which is composed of a tree-hugging fixed device and a sliding rubber tapping device. The invention can carry out the rubber cutting operation independently without manual intervention, which greatly reducing the manual input, and obviously improving the rubber cutting efficiency and time economy conversion efficiency. The movable system can work alone in a whole rubber forest with a large working area and reduces the average input cost per tree. The technical indexes of the rubber tree, such as cutting depth, cutting skin consumption and cutting smoothness, all meet the requirements of traditional rubber cutting technology and have good popularization and application value.

A locator of a surgical port of a surgical robot system, the surgical robot system comprising an instrument attached to a robot arm, the instrument having an instrument shaft able to pass through the surgical port to a surgical site, the locator comprising: an interface configured to couple to the surgical port; a mechanism configured to permit relative linear and/or rotational motion of the interface and the instrument shaft; and a controller comprising a processor operable to estimate the position of a part of the robot arm, the controller configured to control the mechanism in dependence on the estimated position of the part of the robot arm such that as the robot arm retracts the instrument from the patient, the locator moves the port away from the robot arm and provides a reaction force to keep the port in place.

A robot hand includes: a palm section; a first finger extending from the palm section to distal side, and having a finger pad surface opposed to a central axis of the palm section; and a second finger extending from the palm section to the distal side, and having a finger pad surface opposed to the finger pad surface of the first finger with the central axis of the palm section interposed therebetween. The palm section includes a proximal joint that couples the second finger to the palm section pivotably about a first axis. The first finger does not have degrees of freedom in bending and stretching directions. The second finger includes a base phalanx section provided close to the palm section, a distal phalanx section provided closer to the distal side than the base phalanx section, and a middle phalanx section provided between the base phalanx section and the distal phalanx section. Furthermore, the second finger includes a middle joint and a distal joint, the middle joint that couples the middle phalanx section to the base phalanx section bendably and strechably about a second axis, and the distal joint that couples the distal phalanx section to the middle phalanx section bendably and strechably about a third axis.