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 braking robot for a braking test of a vehicle is provided. The braking robot includes: a plurality of motors, having same individual output powers, combined with a robot body installed in the vehicle; a motion shaft combined with a pedal presser for applying pedal effort to a brake pedal of the vehicle; a driving force converter which converts rotational forces of the motors, corresponding to the individual output powers of the motors, into a translational force and thus transmits the translational force to the motion shaft; a load sensor, installed on the motion shaft, for detecting the pedal effort applied to the brake pedal by the motion shaft; and a controller for controlling operations of the motors by referring to (1) a scenario for the braking test and (2) information on the pedal effort detected from the load sensor.

Certain aspects relate to systems and techniques for driving axial motion of a shaft of a medical instrument using a drive device. A drive device configured to facilitate axial motion of an elongated shaft of a medical instrument can include a body comprising a channel configured to receive the elongated shaft of the medical instrument, a roller configured to engage with the elongated shaft such that, when rotated, the roller drives axial motion of the elongated shaft received in the channel, a first drive input coupled to the body, wherein the first drive input is operable by a robotic system to rotate the roller, a cover configured to selectively open or close the channel, and a second drive input coupled to the body, wherein the second drive input is operable to actuate the cover.

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.

A mechanism for holding surgical instruments includes a carrier mounted on a machine tool and multiple holding modules mounted on the carrier. At least one of the holding modules is selected to be used during surgical operation. A swing element of the selected holding module enables a guidance sleeve to be swung to allow a guidance hole on the guidance sleeve to face toward a surgical operation region. The guidance sleeve is provided to hold one surgical instrument for surgical operation.

A robotic surgical tool includes a drive housing having a first end, a second end, and a lead screw extending between the first and second ends, a carriage movably mounted to the lead screw, and an activating mechanism coupled to the carriage. The activating mechanism includes a motor mounted to the carriage and operable to rotate a drive gear, and a driven gear engageable with the drive gear such that rotation of the drive gear causes the driven gear to rotate and thereby actuate the activating mechanism.

A robotic surgical tool includes a handle having a first end and a second end opposite the first end, an exoskeleton extending between the first and second ends and having a non-circular cross-section and a carriage movably arranged within the exoskeleton and having a non-circular cross-section compatible with the non-circular cross-section of the exoskeleton. The robotic surgical tool also includes an elongate shaft extending from the carriage and penetrating the first end, the shaft having an end effector arranged at a distal end thereof The carriage is movable between the first and second ends to advance or retract the end effector relative to the handle where the exoskeleton guides the carriage between the first and second ends.

A method of assembling a robotic surgical tool includes providing a handle having first and second ends, a lead screw, and a spline extendable between the first and second ends. The lead screw is rotated in a first direction to translate an elevator layer of a carriage proximally along a longitudinal axis of the handle, the elevator layer being movably mounted to the lead screw at a carriage nut. One or more additional layers of the carriage are removably coupled to the elevator layer and an elongate shaft extends distally from the additional layers, and an end effector is arranged at a distal end of the shaft. The elevator layer is penetrated by the end effector and the shaft upon coupling the additional layers to the elevator layer, and the lead screw is rotated in a second direction opposite the first direction to translate the carriage distally.

A robotic surgical tool comprises a stage assembly and a core assembly removably mountable to the stage assembly. The stage assembly may comprise a lead screw and at least one spline extendable between first and second ends of the stage assembly, and a nut rotatably mounted to the lead screw to translate between the first and second ends upon rotation of the lead screw. The core assembly may comprise a drive housing that is movably mountable to the stage assembly to translate, with the nut, between the first and second ends of the stage assembly. The surgical tool may also comprise a shroud assembly having a primary shroud and a secondary shroud, the primary shroud at least partially enclosing the core assembly when installed on the stage assembly, and the secondary shroud being movable between a first position, where the secondary shroud occludes an opening in the primary shroud, and a second position, where the opening in the primary shroud is exposed. The secondary shroud may be pivotally attached to the primary shroud at a hinge. The secondary shroud may be slidingly attached to the primary shroud, such that the secondary shroud is circumferentially revolvable relative to the primary shroud between the first and second positions. The secondary shroud may be slidingly attached to the primary shroud, such that the secondary shroud is axially slidable relative to the primary shroud between the first and second positions.

A manipulator including a shaft driven by a first motor, a rotatable unit, a linear slider, and a gripper is provided. The rotatable unit is coupled to the shaft, wherein the rotatable unit rotates with rotation of the shaft. The linear slider disposed on a first surface of the rotatable unit configured to slide from an initial position proximate to an outer edge of the rotatable unit to intermediate positions and to a final position proximate to a center of the rotatable unit. The gripper coupled to the linear slider to facilitate movement of the gripper along a first plane defined by the first surface of the rotatable unit.