A storage setup and method for robotic delivery and retrieval of crates from shelving blocks are disclosed. At least one shelving block in the setup comprises non-uniformly spaced apart storage surfaces. The storage surfaces are accessible to lift-robots. A computerized control system is configured to differentiate between storage locations based on which crate sizes from at least two different ranges of crate sizes a storage location can store. The storage may be automatically optimized by routing robots to store crates in storage locations sized in correlation with the size of the crate to be stored.

A robotic surgical system includes a surgical instrument and a robotic surgical assembly. The robotic surgical assembly defines an instrument opening and includes a floating plate and a drive assembly. The floating plate is movable between an extended position and a compressed position. The surgical instrument is laterally receivable in the instrument opening of the robotic surgical assembly while the floating plate is disposed in the compressed position. The floating plate is movable to the extended position to couple the surgical instrument to the robotic surgical assembly while the surgical instrument is received in the instrument opening of the robotic surgical assembly.

A joint device (1), which has a second joint body (3), which second joint body is pivotably mounted in a ball socket (9) of a first joint body (12) by means of a joint ball (8). The joint ball (8) is a hollow ball and has, on its inner peripheral surface (23), output teeth (33), with which, in the ball interior (25), the input gears (55, 56) of two drive units (4, 5) rotatably mounted on the first joint body (2) are in tooth engagement. By selective rotation of one or both drive units (4, 5), the second joint body (3) can be driven to perform a working pivoting movement (6) relative to the first joint body (2).

A surgical tool configured to receive rotary inputs from a robotic surgical system. The surgical tool comprises a distal end effector comprising jaws for clamping tissue therebetween, an intermediate shaft portion coupled to the distal end effector, and a proximal housing coupled to the intermediate shaft portion. The proximal housing comprises an arrangement of rotary drives comprising a first rotary drive. The first rotary drive comprises an input shaft configured to receive a rotary input from the robotic surgical system, a transition nut slidably positioned on the input shaft, and an output gear. The first rotary drive further comprises a high-speed gear configured to selectively drive the output gear, a high-torque gear configured to selectively drive the output gear, and a spring arrangement configured to bias the transition nut along the input shaft from a high-speed operating state to a high-torque operating state upon obtaining a threshold torque.

A robotic surgical system that comprises a closure system. The closure system comprises a first pinion drivingly coupled to a first motor, a second pinion drivingly coupled to a second motor, and a closure gear selectively driven by the first pinion and the second pinion. The robotic surgical system further comprises a control circuit configured to implement a motor crosscheck operation. The control circuit is configured to receive a first parameter indicative of a first torque generated by the first motor, receive a second parameter indicative of a second torque generated by the second motor, compare the first parameter to the second parameter, and transmit a signal to a communication device, wherein the signal is based on the comparison and indicative of a status of the closure system.

A control circuit for use with a robotic surgical system. The control circuit is configured to receive a parameter indicative of a rotary position of an articulation motor. The articulation motor is configured to drive an articulation joint of a robotic surgical tool, wherein the articulation motor is configured to move through a first range of positions and a second range of positions. The control circuit is further configured to implement a first operating state, and implement a second operating state when the parameter corresponds to a transition of the articulation motor from the first range of positions to the second range of positions. The control circuit is further configured to re-implement the first operating state when the parameter corresponds to a return of the articulation motor from the second range of positions into the first range of positions by a threshold anti-dither angle.

A construction robot for a ceiling is provided. The construction robot includes: a robot base having an upper plate; a targeting unit on the upper plate, wherein the targeting unit moves a robotic arm assembly combined with the targeting unit, and wherein the robotic arm assembly includes: a first robotic arm where a drill is mounted, wherein a first elevating unit of the first robotic arm is elevated or lowered according to information on the ceiling, a second robotic arm where an anchor bolt inserting equipment is mounted, wherein a second elevating unit of the second robotic arm is elevated or lowered according to the information, and a third robotic arm where an impact wrench is mounted, wherein a third elevating unit of the third robotic arm is elevated or lowered likewise; and a loading unit on the upper plate or the targeting unit for providing anchor bolt assemblies.

The packaging plant comprises a packaging machine and a robot which is mounted on a transport truck that is repositionable along the packaging machine. The transport truck comprises a frame, a current collector, and a plurality of operating components. The frame is mounted so as to be movable along the packaging machine, has a bearing assembly for the robot, and supports the plurality of operating components. The current collector is configured to wirelessly connect to a current source. The plurality of operating components comprise at least one wireless data transmission device and one drive.

A power supply system for at least one system for transporting and/or machining workpieces having a plurality of electric drive units is disclosed. The supply grid of the drive units is supplied via at least one recuperating energy storage device, which is electrically connected to a charging device that is fed from an alternating- or three-phase low-voltage grid. The power supply system for a transport and/or machining system draws maximally 50 percent more power from the power supply grid compared to the regular nominal supply current regardless of the occurrence of current peaks.

A method of calibrating an instrument interface of an instrument in a surgical robotic system, the surgical robotic system comprising a robot having a base and an arm extending from the base to a drive assembly for engaging with the instrument interface to transfer drive to the instrument, the instrument interface being configured to drive joints of the instrument via driving elements, the method comprising: obtaining usage data indicative of usage of a joint of the instrument; comparing the usage data with one or both of a maximum range of joint movement of the joint and a model of expected joint movement of the joint; determining, from the comparison, a calibration offset to adjust a control relationship of a driving element arranged to drive the joint; and adjusting the control relationship of the driving element using the calibration offset so as to calibrate is the instrument interface.