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.

Apparatuses for mounting medical aid devices to anatomical structures and methods of use are disclosed. Mounting apparatuses may include femoral clamps or clamps configured to be affixed to other bone structures. Mounting apparatuses may include a pair of opposing arms configured to be compressed around a portion of a bone structure via a clamping force provided by a clamping assembly to affix the mounting apparatus to the bone structure. Clamping assemblies may include a magnetically-actuated clamping assembly, a mechanically-actuated clamping assembly, or a spring-actuated clamping assembly. A magnetically-actuated clamping assembly may generate a clamping force via alignment of magnetic fields within the clamping apparatus. A mechanically-actuated clamping assembly may generate a clamping force via a linkage-tensioning system, a rack-and-pinion system, or a lever-locking system. A spring-actuated clamping assembly may generate a clamping force via a torsion spring having arms that bias the pair of opposing arms toward the bone structure.

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 refuse vehicle includes a chassis, tractive elements, a lift apparatus, and a reach assembly. The tractive elements couple with the chassis and support the refuse vehicle. The lift apparatus includes a track and a grabber assembly. The track includes a straight portion and a curved portion. The grabber assembly releasably grasps a refuse container and ascends or descends the track to lift and empty refuse into a body of the refuse vehicle. The reach assembly includes an outer member, a first extendable member, and a second extendable member. The first extendable member is received within an inner volume of the outer member and translates relative to the outer member. The second extendable member is received within an inner volume of the first extendable member and translates relative to the first extendable member. The lift apparatus is fixedly coupled at an outer end of the second extendable member.

A robotic surgical instrument comprising a shaft, an articulation attached to a distal end of the shaft, the articulation configured to articulate an end effector, the articulation driveable by a distal driving element, a driving mechanism comprising an instrument interface element secured to an end of a proximal driving element and configured to engage a drive interface element of a drive assembly, wherein motion of the drive interface element results in a first displacement of the end of the proximal driving element and a gearing mechanism engaging the proximal driving element and the distal driving element and being configured to transfer the first displacement of the end of the proximal driving element to a different second displacement of an end of the distal driving element.

A sterile interface module for coupling an electromechanical robotic surgical instrument to a robotic surgical assembly is provided. The surgical instrument includes an end effector and is configured to be actuated by the robotic surgical assembly. The sterile interface module includes a body member and a drive assembly. The body member is configured to selectively couple the surgical instrument to the robotic surgical assembly. The body member is formed of a dielectric material. The drive assembly is supported within the body member and is configured to transmit rotational forces from the robotic surgical assembly to the surgical instrument to actuate the surgical instrument to enable the surgical instrument to perform a function.

A motor module comprising a primary pinion rotatably driveable by a primary motor, a first primary rack moveably engageable with the primary pinion and a second primary rack moveably engageable with the primary pinion. Rotation of the primary pinion causes movement of the first primary rack in a first direction, and movement of the second primary rack in a second direction, whereby the first and second primary racks and the primary pinion together form an antagonistic rack and pinion mechanism.

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 boom working device has a boom, mounted on and extending from a boom support, on which an end effector mounting interface is formed. The boom is equipped with two linear output structures, each in engagement with one of two drive wheels of the boom support. With respect to the boom support, the boom is both pivotable around a main axis and also capable of linear movement at right-angles to the main axis. Through harmonised rotary actuation of the drive wheels an operating movement of the boom may be generated, consisting either of a pivoting movement alone or of a linear movement alone or of the pivoting movement with simultaneously superimposed linear movement.

For robotically operating a catheter, translation and/or rotation manipulation is provided along the shaft or away from the handle, such as near a point of access to the patient. A worm drive arrangement may allow for both translation and rotation of the shaft. Some control may be provided by robotic manipulation of the handle, while other control (e.g., fine adjustments) are made by robotic manipulation of the shaft.