Apparatus and methods for providing a robotic arm cart for transporting, delivering, and securing robotic arms to a surgical table having a tabletop on which a patient can be disposed are described herein. In some embodiments described herein an arm cart can contain multiple robotic arms. A robotic arm can be selected and moved from a storage position within the arm cart to a deployment position in which at least a portion of that robotic arm protrudes from the arm cart. A robotic arm in a deployment position can be coupled to a surgical table and decoupled from the arm cart.

A center of gravity of a robot device is estimated without utilization of a force sensor or the like. An information processing device including a center-of-gravity estimation unit that calculates, on the basis of torque applied to one or more joints included in each of a plurality of leg portions, reaction force applied from a ground contact surface to each of the plurality of leg portions, and that estimates a center of gravity of a robot device including the plurality of leg portions on the basis of the calculated reaction force on the plurality of leg portions.

Systems and methods for determining a location of a robot are provided. A method includes receiving, by a processor, a signal from a deformable sensor including data with respect to a deformation region in a deformable membrane of the deformable sensor resulting from contact with a first object. The data associated with contact with the first object is compared, by the processor, to details associated with contact with the first object to information associated with a plurality of objects stored in a database. The first object is identified, by the processor, as a first identified object of the plurality of objects stored in the database. The first identified object is an object of the plurality of objects stored in the database that is most similar to the first object. The location of the robot is determined, by the processor, based on a location of the first identified object.

A robot arm comprising a plurality of limbs articulated relative to each other, the robot arm extending from a base to a distal limb carrying a tool or an attachment point for a tool, the distal limb being attached by a revolute joint to a second limb, and the robot arm comprising a motor having a body and a drive shaft configured to drive rotation of the distal limb relative to the second limb about the revolute joint, wherein the body of the motor is fast with the distal limb.

A robot control device for a robot comprises a case and a connector board which is coupled to the case and includes a plurality of connectors which are disposed in a first region and a second region adjacent laterally to the first region. The plurality of the connectors may comprise a power connector which is disposed at a bottom of one of the first region or the second region and is coupled with a power supplier; and a processor connector which is disposed in a region different from that of the power supplier and is coupled with a processor.

A chassis for an autonomous mobile robot comprises a moulded frame having a stable support for any payload or additional machinery loaded on top of the mobile robot, while ensuring a rigidity of the chassis which again ensures that the supporting elements for the sensors are kept in a stable position relative to each other. The chassis has several separated compartments for EEE placement. These EEE compartments are accessible from the sides and ends of the mobile robot by removing detachable cover parts. A removable top cover is mounted on top of the moulded frame providing a top covering for central inside compartment and outside side compartments. Side covers and end covers are provided for outside compartments and are removable.

A telescopic device (100) and a carrying robot (1000). The telescopic device (100) comprises: a loading base plate (10), telescopic arm assemblies (20), and a driving mechanism (30). The telescopic arm assembly (20) comprises at least two which are provided opposite to each other in a width direction of the loading base plate (10); each telescopic arm assembly (20) comprises a fixed arm (21) and a first sliding arm (22), the fixed arm (21) is mounted at the loading base plate (10), and the first sliding arm (22) is slidably provided at the inner side of the fixed arm (21). The driving mechanism (30) is used for driving the first sliding arm (22) to slide with respect to the fixed arm (21) along a length direction of the loading base plate (10). Because the telescopic device can achieve bi-directional extension and retraction, thereby improving carrying efficiency of the carrying robot.

In order to allow for the mounting of two transported objects without increasing the width of a transport vehicle, a mobile manipulator (1) is provided with: an unmanned transport vehicle (2); a robot base portion (3) mounted on the unmanned transport vehicle; a robot arm (4) mounted on the robot base portion; and brackets (5), (6) for mounting cassettes (11) over the robot base portion. The bracket (5) holds the cassettes in an inclined state, and a part of the bracket (6) overlaps the bracket (5) in plan view.

A robotic arm includes a tool located at an end of the robotic arm that delivers a material to a surface. A hose attachment manifold is mounted to the robotic arm. The hose attachment manifold includes an array of openings that extend through a manifold body of the hose attachment manifold. Fittings are mounted to the manifold body and within the openings. A plurality of upstream hoses are mounted to the fittings at a side of the manifold body. A plurality of downstream hoses are mounted to the fittings at an opposite side of the manifold body. The plurality of downstream hoses are fluidly connected to the tool for delivering a fluid material received from the plurality of upstream hoses.

A support assembly is provided. The support assembly includes: a lower frame configured to be mountable on one surface of a moving object; a guide frame configured such that one end is coupled to an upper surface of the lower frame, and at least a part of another end is curved toward where the lower frame is located; a connection frame configured such that one side includes a plurality of rollers spaced apart at a predetermined interval, and the plurality of rollers slide along the curved part of the guide frame; and an upper frame coupled to another side of the connection frame and configured to move in response to the plurality of rollers sliding along the curved part of the guide frame.