A conveyance apparatus includes two clamp mechanisms. Each of the clamp mechanisms is configured to freely change its state among a fully clamping state, a semi-clamping state, and a non-clamping state. When an object is delivered from a first clamp mechanism that is holding the object to a second clamp mechanism, the second clamp mechanism is brought into the semi-clamping state to temporarily hold the object. Then, the first clamp mechanism is brought into the non-clamping state and the second clamp mechanism is brought into the fully clamping state.

An alignment device includes a holding device capable of holding the second workpiece, a moving device that moves the holding device toward the first workpiece, a mirror member capable of reflecting the second workpiece, the mirror member being arranged adjacent to the first workpiece, an image sensor arranged to be able to simultaneously and continuously capture the first workpiece and a mirror image of the second workpiece reflected on the mirror member, and a control device that performs feedback control of the moving device based on the calculated position of the second workpiece with respect to the first workpiece based on the first workpiece and the mirror image of the second workpiece, which are captured by the image sensor, to align the second workpiece with the first workpiece.

A method and system for preventing a collision between mechanical arms (21), and a medical robot, belonging to the field of medical robot technology. The method includes: arranging (S10) discrete points (m, n) at a mechanical arm (21); acquiring (S40) an interaction force (F.sub.m,n) corresponding to each discrete point (m, n) according to a calculated relative distance (L) between the discrete points (m, n) respectively on different mechanical arms (21), to obtain (S50) a resultant force of the interaction forces (F.sub.m,n) each of which corresponds to each discrete point (m, n), and then obtaining a Cartesian force (F.sub.d) corresponding to each mechanical arm (21), and making (S60) an operator perceive the Cartesian force (F.sub.d) in real time, thereby effectively reducing the risk of interference and collision between the mechanical arms (21).

A gas cylinder transfer apparatus and a gas cylinder logistics system including the same are disclosed. The gas cylinder transfer apparatus includes a transfer vehicle for transferring a gas cylinder and a transfer robot disposed on the transfer vehicle. The transfer robot includes a robot hand for supporting a lower surface portion of the gas cylinder and a hand drive unit for moving the robot hand in horizontal and vertical directions.

Disclosed herein is a system for transporting items having two or more robots configured to transport items throughout a facility, each robot transfers the items along a designated robot route, one or more automated carts configured to transport the item received from one or more robots, the automated carriage configured to transport the items along a designated cart route, a communication unit configured to provide the designate robot route to the robots and the designated cart route to the automated cart, and at least one processor configured to assign the robots to collect the items, assign the automated cart to receive the items; generate the robot route, designate a destination of the automated cart and, generate the cart route for the automated cart.

Provided are a handling robot (600) and a handling assembly (100) thereof, and the handling assembly (100) includes a base component (10), a handling arm component (20), a hook (31) and a driving component (40). The handling arm component (20) is slidably mounted to the base component (10), and may perform a reciprocating linear movement on the base component (10). The driving component (40) is connected with the handling arm component (20), for driving the handling arm component (20) and the hook (31) to perform a reciprocating linear movement. Through the above structure, the handling assembly (100) pulling and pushing the material box (500) is realized without extending into two sides of the material box (500), thereby saving working space of the handling assembly (100), enabling the material boxes (500) of the warehousing to be placed next to each other, and improving the storage density of the warehouse.

A handling robot (100), which relates to the field of warehouse logistics, comprises: a mobile chassis (10); a storage shelf (20) mounted to the mobile chassis (10), the storage shelf (20) comprising a plurality of layered plate components (21) distributed at different heights, each layered plate component (21) comprising a layered plate (210) for placing materials; a handling device (40), comprising a handling assembly (42), the handling assembly (42) being configured to handle a material to a layered plate (210) at the same height as the handling assembly (42), or to handle a material out of a layered plate (210) at the same height as the handling assembly (42); and a lift component (30), configured to drive the handling device (40) to lift relative to the storage shelf (20) so that the handling assembly (42) is at the same height as one layered plate (210).

A gripper for a laboratory container sorting device includes a vacuum gripper and a mechanical gripper. The vacuum gripper includes a suction cup and is configured to move the suction cup between a pickup position and a transfer position. The suction cup is configured to pick up a laboratory container when the suction cup is in the pickup position and to transfer the laboratory container when the suction cup is in the transfer position. The mechanical gripper is configured to grip and release the laboratory container when the suction cup is in the transfer position. A laboratory container sorting device, a laboratory system, and a method of operating the laboratory system are also disclosed.

A task hierarchical control method as well as a robot and a storage medium using the same are provided. The method includes: obtaining a task instruction for a robot, where the task instruction is for determining a target task card including an amount of selection matrices for dividing a target task into the amount of hierarchical subtasks and a controller name for executing each of the hierarchical subtasks; obtaining a null space projection matrix of each of the hierarchical subtasks based on the corresponding selection matrix; generating control finks of the amount according to the corresponding controller of each of the hierarchical subtasks and the corresponding null space projection matrix; calculating a control torque of each of the control links and obtaining a hierarchical control output quantity by adding ail the control torques; and controlling the robot to perform the target task using the hierarchical control output quantity.

A hand-eye calibration system and method are provided. The system includes a robot on which a small pattern is mounted, a camera configured to photograph the robot, a memory, and a processor configured to move the robot, acquire posture information of the moved robot, acquire an image from the camera, move the camera after performing the robot movement, the posture information acquisition, and the image acquisition a first predetermined number of times, and perform hand-eye calibration for the robot based on the posture information and the images, which are obtained by repeatedly performing of the robot movement, the posture information acquisition, the image acquisition, and the camera movement.