Systems and methods are disclosed herein for a robotic manipulator arm deployment and control system. The system comprises at least a vertical mast, a mast deployment system comprising at least two cams, an elbow, an arm wherein the arm is operable to deploy tools, and one or more sensors including a non-contact sensor and a dynamic measurement unit. The cams cause the vertical mast and the arm to remain vertical during deployment into an operating space. The non-contact sensor may be used for measuring range and bearing to objects in the operating space in polar coordinates. The dynamic measurement unit comprises accelerometers and rate sensors and is configured as a six degree of freedom three axis sensor operating in a Cartesian coordinate system. The system further comprises a controller operable to receive the polar and Cartesian coordinates from the sensors and convert them to a Cartesian coordinate system.

A maintenance apparatus, in particular for lifting and moving components of a system for processing semiconductor devices. The apparatus comprises a beam and an arm with means for lifting a component, the arm being mounted to the beam via a connecting unit and so as to be pivotable in a horizontal plane, wherein the connecting unit is displaceable along the beam, and wherein the arm is displaceable perpendicularly to the beam, and wherein a load accommodation means is provided on the pivotable arm.

A linear extension and retraction mechanism includes a first connection piece string including a plurality of first connection pieces; a second connection piece string including a plurality of second connection pieces; a linear gear consisted of a plurality of teeth and provided on a back face of each of the first connection piece;

an ejection section adapted to support a columnar body formed by joining together the first and second connection piece strings and; and a drive gear adapted to be meshed with the linear gears, wherein gear-end teeth located adjacent to each other across a junction between adjacent first connection piece string are provided in such a way as not to overlap each other when viewed along a center axis of the columnar body.

A cart for housing components of a medical navigation system is provided. The cart comprises a frame including a substantially horizontal base having a bottom side and a top side with wheels attached to the bottom side, a substantially vertical column attached to the top side of the base, and a ballast attached to the base to function as a counterweight to avoid tipping of the cart.

A telescoping linear extension robot includes a base configured to support the telescoping linear extension robot, a first driven platform, drivingly coupled to the base, a second driven platform, drivingly coupled to the first driven platform, and a floating intermediate platform. The intermediate platform is configured to increase the extendable range of the driven extensions by facilitating additional extension using force generated by the driven platforms of the robot. This, in turn, allows for long-reach robot solutions with reduced physical footprint, complexity and cost.

An autonomous mobile device (AMD) includes a telescoping mast with sensors on top that are connected to a cable running through the mast. An inner section of the mast includes a bobbin that secures cables. The bobbin has a shaft and features that guide cables to helically wind around the shaft. The bobbin reduces stress on the cable as the mast moves. The mast is lifted by a rack that includes a portion with teeth and a portion without. The portion with teeth is driven by a motor. The portion without teeth connects the rack to a spool. The toothless section reduces stress on the toothed portion of the rack as it spools or unspools. The AMD includes a hinge to tilt a display. To securely position the hinge on a shaft, the shaft is spun after assembly so that a push nut cuts a retention groove in the shaft.

Disclosed embodiments include a robotic arm for moving one or more objects fixed to the robotic arm. The robotic arm may have a telescoping arm the extends out from and contracts into a base platform and two joints for precisely moving an attachment platform. In various embodiments, a camera is mounted to the robotic arm and a computer included in the robotic arm may execute a control path to move the camera within a scene. The robotic arm may include one or more motors for automatically moving components of the robotic arm. The robotic arm may be synchronized with a camera to perform an automated photoshoot that captures various perspectives and angles of a scene.

A robotic arm control system including a robotic arm configured to deploy one or more tools in an operating space, one or more sensors, and a control system operably configured to: scan the operating space with the one or more sensors, identify a surface of the operating space based at least in part upon information sensed by the one or more sensors, establish a virtual barrier offset from the surface, and limit movement of the robotic arm based at least in part upon the virtual barrier.

The invention relates to a modular exoskeleton structure that provides force assistance to a user, comprising a base module (1) comprising a lumbar belt (11) capable of surrounding the lower trunk of the user, two hip modules capable of being attached to two respective thighs of the user, and a backpack support module (14) for an exoskeleton structure, comprising: a hoop (141) designed to be anchored to the hip modules, at the hips of a user, a support rod (142) designed to extend along the back of the user and capable of being engaged in a pouch of a backpack to suspend the backpack to the backpack support module (14), wherein the rod (142) comprises a first rod element (1421) connected to the hoop (141), a second rod element (1422) capable of sliding with respect to the first rod element (1421) so as to vary a length of the rod (142), and a damper for cushioning the movement of the second rod element (1421) with respect to the first rod element (1422) caused by the walking of the user.

A rail-mounted intelligent inspection robot includes a robot body and a guide rail, the robot body being hung on the guide rail and moving along the guide rail. One side of the guide rail facing the robot body is affixed with a plurality of barcodes, and the translation mechanism is provided with a barcode reader. A control module and a translation motor are disposed within the control platform. The lifting mechanism is connected to the control platform and the detection platform, and an intelligent holder is disposed below the detection platform. The rail-mounted inspection robot of the present invention may perform continuous inspection operations, and may meet the 7*24 hours of uninterrupted work through the power supply of the sliding contact wire. The recognized dial data is more accurate, and the read information may be transmitted to the background and processed in time.