Certain aspects relate to systems and techniques for driving axial motion of a shaft of a medical instrument using a drive device. Axial motion can include insertion and/or retraction of the instrument. For example, a robotic medical system can include a medical instrument comprising an instrument base and a flexible shaft configured for insertion into a patient, and a first robotic arm attachable to the instrument base of the medical instrument. The system also includes a drive device configured to engage the flexible shaft, and a second robotic arm attachable to the drive device. The second robotic arm is configured to operate the drive device to drive axial motion of the flexible shaft, and the first robotic arm is configured to move in coordination with operation of the drive device.

Certain aspects relate to systems and techniques for driving axial motion of a shaft of a medical instrument using a drive device. A robotic medical system can include a drive device comprising a pair of rollers configured to engage a shaft of a medical instrument and a processor configured to operate the rollers to drive insertion of the shaft at a first rate during a first insertion period when a distal tip of the shaft is positioned within an access sheath inserted into the patient, and operate the rollers to transition to driving insertion of the shaft at a second rate that is slower than the first rate during a second insertion period when the distal tip of the shaft is positioned beyond a distal tip of the access sheath.

A shelving block comprises a first and second shelving units facing from opposite sides of an aisle. The first shelving unit defines a first crate storage location and a second crate storage location that different in height. The first crate storage location is accessible to a robot between a pair of neighboring horizontal rails having a first vertical spacing between them defining a height of the first crate storage location. The second crate storage location is accessible to the robot between another pair of neighboring horizontal rails having a second vertical spacing between them defining a height of the second crate storage location. The first vertical spacing is larger than the second vertical spacing. The robot carries crates according to instructions from a computerized control.

A device is provided. The device includes a worm drive comprising a worm and a worm gear. The device also includes an actuator comprising a motor, a shaft, and the worm, wherein the shaft is configured to rotate about a shaft axis, and the actuator is configured to (i) drive the worm drive, and (ii) move linearly along the shaft axis. The device also includes a first spring and a second spring, wherein the second ends are fixed, and wherein the first and second springs are configured to resist movement of the actuator along the shaft axis in opposite directions as a result of forces transmitted through the worm drive. The device further includes a linear position encoder configured to determine a position of the actuator along the shaft axis.

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.

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.

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 through a network of tracks comprising intersecting vertically and horizontally oriented tracks. 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 direction switching module for lift robots using a pair of pinions coupled to a rack for propelling vertically and horizontally according to the track's orientation, is disclosed. In a linear motion mode both pinions rotate in the same velocity. In a direction switching mode, when changing from vertical to horizontal motion mode and vise versa, the module is capable of propelling one pinion on a vertical track and its counterpart on a horizontal track, simultaneously, each pinion in a different velocity. A bogie propelled by two pairs of said module is also disclosed, and a controller configured to drive both pinions in same velocity during linear motion and each pinion in a separate appropriate velocity during the direction switching mode. A method for turning a pinion-driven lift-robot in an intersection of rails and a controller for controlling the linear motion modes and the direction switching modes of the lift robot are also disclosed.

A mobile robot includes a movable platform including wheels, and a manipulator having a base supported by the movable platform and an arm attached to the base, wherein a base attachment surface to which the base is attached is inclined relative to a movement surface on which the movable platform is to move.

Manual, automated, or semi-automated articulating arm programmable tank cleaning nozzle systems, devices and methods for providing safe and efficient methods for removing paint, rust, scale, debris, and contaminants as well as methods to apply new coatings to tanks. A hydraulically controlled articulating arm can have up to 11 or more degrees of freedom and a working envelope ranging from approximately 10approximately 10approximately 10 up to approximately 50approximately 50approximately 50. Modularity and light weight components allow quick setup with minimal manpower, and therefore, make relocation in confined tanks feasible. Simplified programming with scanning methods can aide in quick generation of toolpaths. Dust free blasting techniques can be employed, making the operation safer, cleaner, and more efficient. Surface coatings can be applied with the same device further increasing efficiencies. The systems, devices and methods can work in the presence of flammable vapors and dust.