A transfer system in the form of a robot line used in one embodiment to transfer products, such as slices of meat or other fresh food, while complying with the hygienic requirements. The robot line may transfer the products, simply and with little constructive and financial effort. The robots used for this purpose may be very simply constructed with only one swivel arm and the robot base may be guided below the working plane, and only the swivel arm and the gripper may be disposed above the working plane.

A vehicle or another object is grasped by a robotic arm of a handling system and caused to undergo one or more movements or manipulations resulting in a change of position, orientation, velocity or acceleration of the vehicle. Sensors provided in the robotic arm capture data representative of forces or torques imparted upon the robotic arm by the vehicle during or after the movement, or power or energy levels of vibration resulting from the movement. A signature representative of an inertial or vibratory response of the vehicle to the movement is derived based on the data. The signature may be compared to a baseline signature similarly derived for a vehicle that is known to be structurally and aerodynamically sound. If the signature is sufficiently similar to the baseline signature, the vehicle may also be determined to be structurally and aerodynamically sound.

A vehicle or another object is grasped by a robotic arm of a handling system and caused to undergo one or more movements or manipulations resulting in a change of position, orientation, velocity or acceleration of the vehicle. Sensors provided in the robotic arm capture data representative of forces or torques imparted upon the robotic arm by the vehicle during or after the movement, or power or energy levels of vibration resulting from the movement. A signature representative of an inertial or vibratory response of the vehicle to the movement is derived based on the data. The signature may be compared to a baseline signature similarly derived for a vehicle that is known to be structurally and aerodynamically sound. If the signature is sufficiently similar to the baseline signature, the vehicle may also be determined to be structurally and aerodynamically sound.

A system for verifying quality of a part using an arm robot includes an arm robot, which includes a camera to acquire image data of a part assembled in each manufacturing process of a vehicle, a carrier, which includes a sliding rail allowing the arm robot to be movable around the vehicle along the sliding rail to acquire the image data, and a server which receives the image data acquired by the camera, compares the image data with modeling data of the vehicle, which is stored in a database, and determines whether the assembled part satisfies a preset inspection item, to verify quality of the assembled part, verifying the quality of the part in each process before the vehicle is completely manufactured.

An intelligent cleaning robot is provided by the present application, to clean dust on a surface of a photovoltaic cell assembly and lower a labor cost, and a walking posture of the intelligent cleaning robot may be adjusted according to needs. The intelligent cleaning robot includes a frame, a sweeping device installed on the frame to perform sweeping operations, a first walking wheel located at one end of the frame and driven by a first motor to move, a second walking wheel located at another end of the frame and driven by a second motor to move, and a control system in signal communication with both the first motor and the second motor and configured to control the first motor and the second motor to rotate synchronously, or control the first motor and the second motor to rotate in different rotational speeds or different directions.

An intelligent cleaning robot is provided by the present application, to clean dust on a surface of a photovoltaic cell assembly and lower a labor cost, and a walking posture of the intelligent cleaning robot may be adjusted according to needs. The intelligent cleaning robot includes a frame, a sweeping device installed on the frame to perform sweeping operations, a first walking wheel located at one end of the frame and driven by a first motor to move, a second walking wheel located at another end of the frame and driven by a second motor to move, and a control system in signal communication with both the first motor and the second motor and configured to control the first motor and the second motor to rotate synchronously, or control the first motor and the second motor to rotate in different rotational speeds or different directions.

Various embodiments of the present disclosure are directed to, for example, a linear manipulator for a programmable stage installation. In one embodiment, the linear manipulator includes a body having an internal longitudinal channel extending parallel to an axis between two channel points, a power conductor positioned inside the channel, a drag band extending parallel to the axis, a motor that drives the drag band, and a wagon. The body further including a longitudinal opening extending between the two channel points, and a pair of rails connected to the body and extending parallel to the axis. The wagon including a pair of rail grippers for slidably engaging the pair of rails, a band connector connected to the drag band, and a power connector. The wagon attaches to equipment to be displaced along the linear manipulator and the power connector connects the equipment with the power conductor.

Various embodiments of the present disclosure are directed to, for example, a linear manipulator for a programmable stage installation. In one embodiment, the linear manipulator includes a body having an internal longitudinal channel extending parallel to an axis between two channel points, a power conductor positioned inside the channel, a drag band extending parallel to the axis, a motor that drives the drag band, and a wagon. The body further including a longitudinal opening extending between the two channel points, and a pair of rails connected to the body and extending parallel to the axis. The wagon including a pair of rail grippers for slidably engaging the pair of rails, a band connector connected to the drag band, and a power connector. The wagon attaches to equipment to be displaced along the linear manipulator and the power connector connects the equipment with the power conductor.

A robot includes a body coupled to a wheel assembly and a container retrieval device. The wheel assembly has a plurality of wheels and a drive mechanism arranged to move the body along a first set of parallel rails and along a second set of parallel rails. The container retrieval device includes an extendable and retractable grapple arranged to selectively secure an engagement feature positioned between a rim and a bottom surface of a container. The grapple thus allows the robot to lift multiple containers in a single lift.

A robot includes a body coupled to a wheel assembly and a container retrieval device. The wheel assembly has a plurality of wheels and a drive mechanism arranged to move the body along a first set of parallel rails and along a second set of parallel rails. The container retrieval device includes an extendable and retractable grapple arranged to selectively secure an engagement feature positioned between a rim and a bottom surface of a container. The grapple thus allows the robot to lift multiple containers in a single lift.