The foodstuff assembly system can include: a robot arm, a frame, a set of foodstuff bins, a sensor suite, a set of food utensils, and a computing system. The system can optionally include: a container management system, a human machine interface (HMI). However, the foodstuff assembly system 100 can additionally or alternatively include any other suitable set of components. The system functions to enable picking of foodstuff from a set of foodstuff bins and placement into a container (such as a bowl, tray, or other foodstuff receptacle). Additionally or alternatively, the system can function to facilitate transferal of bulk material (e.g., bulk foodstuff) into containers, such as containers moving along a conveyor line.

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 rotor assembly system for a manufacturing cell includes a central robotic system comprising a multi-axial central robot and a conveyor platform and one or more multi-axial auxiliary robotic systems secured at one or more locations within the cell. The conveyor platform is operable to move the central robot within the cell. The central robotic system and the one or more auxiliary robotic systems are configured to perform a plurality of rotor manufacturing processes on at least one rotor component in coordination with one another, and the central robotic system is configured to transfer the at least one rotor component between one or more rotor manufacturing processes of the plurality of rotor manufacturing processes.

According to one embodiment of the present disclosure, there is provided a transfer apparatus comprising at least one arm configured to support a substrate; at least one gear disposed at a joint that rotatably supports the at least one arm, the at least one gear rotating the at least one arm; and a detector disposed to face the at least one gear and configured to detect a temperature of the at least one gear without contacting the at least one gear.

5G and especially 6G will enable a multitude of applications for fixed-position and mobile wireless task-devices (“robots”). Most of these applications are based on the assumption that the robots know, or can determine, the locations and wireless identities of other robots in proximity, but this is an unsolved problem. Procedures are provided herein for an arbitrarily large number of fixed-position and mobile robots to autonomously identify each other, determine their locations with speed and precision substantially beyond that provided by navigation satellites, and then to collaborate in performing their tasks, while avoiding interference and collisions. Examples are provided in the fields of automated agriculture, remote oil-spill mitigation, autonomous fire-fighting, hospital management, construction site coordination, manufacturing (including fully autonomous manufacturing), major product warehousing, airport control, and emergency vehicle access.

A positioning apparatus including a base structure; a first workpiece support; a second workpiece support; a support member supporting the first workpiece support and the second workpiece support; and a drive arrangement arranged to drive the support member relative to the base structure from a first position, where the first workpiece support is positioned on a processing side of the base structure and the second workpiece support is positioned on an opposite loading side of the base structure, to a second position, where the first workpiece support is positioned on the loading side and the second workpiece support is positioned on the processing side; wherein the drive arrangement is arranged to drive the first workpiece support along a first path and the second workpiece support along a second path when driving the support member from the first position to the second position, the first and second paths being non-circular.

A robot arm (500) for positioning a tool (44) with controlled orientation. The robot arm (500) comprises an inner-arm linkage (15, 18, 29; 15, 18, 77); an outer-arm linkage (23; 81; 173; 228; 632; 384) and a first actuator (1; 249) configured to rotate the inner-arm linkage about a first axis of rotation (180). The inner-arm linkage includes a first inner link (15) that at an inner end is arranged to rotate around a fourth axis of rotation (185), and a second inner link (18) that at an inner end is arranged to rotate around a different, third axis of rotation (182, 185), wherein the axes of rotation (182, 185) are perpendicular to the first axis of rotation (180), and the rotations result in a geometric reconfiguration of the inner-arm linkage. The inner-arm linkage also includes a connection shaft (29; 77) mounted at an outer end of the first inner link and at an outer end of the second inner link by means of joints of at least one degree of freedom, is connected to the outer-arm linkage via the connection shaft, is connected to the tool and forms a first kinematic chain that gives a first degree of freedom for positioning the tool. A second actuator (2; 254) is configured to rotate the outer-arm linkage around the second axis of rotation, thereby forming a second kinematic chain giving a second degree of freedom for positioning the tool. A third actuator (3) is configured to move the outer-arm linkage by actuating the geometrically reconfigurable inner-arm linkage, resulting in a movement of the second axis of rotation around which the outer-arm linkage is arranged to rotate, thereby forming a third kinematic chain giving a third degree of freedom for positioning the tool. The robot arm also comprises one or more transmission mechanisms that in combination with the outer-arm linkage are arranged to accomplish the controlled orientation of the tool.

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.

For control about a remote center of motion (RCM) of a surgical robotic system, possible configurations of a robotic manipulator are searched to find the configuration providing a greatest overlap of the workspace of the surgical instrument with the target anatomy. The force at the RCM may be measured, such as with one or more sensors on the cannula or in an adaptor connecting the robotic manipulator to the cannula. The measured force is used to determine a change in the RCM to minimize the force exerted on the patient at the RCM. Given this change, the configuration of the robotic manipulator may be dynamically updated. Various aspects of this RCM control may be used alone or in combination, such as to optimize the alignment of workspace to the target anatomy, to minimize force at the RCM, and/or to dynamically control the robotic manipulator configuration based on workspace alignment and force measurement.

In an embodiment, a method includes determining a given material to manipulate to achieve a goal state. The goal state can be one or more deformable or granular materials in a particular arrangement. The method further includes, for the given material, determining, a respective outcome for each of a plurality of candidate actions to manipulate the given material. The determining can be performed with a physics-based model, in one embodiment. The method further can include determining a given action of the candidate actions, where the outcome of the given action reaching the goal state is within at least one tolerance. The method further includes, based on a selected action of the given actions, generating a first motion plan for the selected action.