One embodiment can provide an intelligent robotic system. The intelligent robotic system can include at least one multi-axis robotic arm, at least one gripper attached to the multi-axis robotic arm for picking up a component, a machine vision system comprising at least a three-dimensional (3D) surfacing-imaging module for detecting 3D pose information associated with the component, and a control module configured to control movements of the multi-axis robotic arm and the gripper based on the detected 3D pose of the component.

A space-saving floating joint including a locking mechanism that locks a swing of a movable base with respect to a fixed base is provided. A floating joint includes: a fixed base; a movable base; a floating mechanism that floatingly supports the movable base swingably with respect to the fixed base; and a locking mechanism that fixes the movable base in a state of not being swingable with respect to the fixed base. The floating mechanism includes a spherical bearing having a spherical surface, and a spherical washer part that supports the spherical surface slidably. The locking mechanism is provided in an inner part of the spherical bearing.

A portable work module includes a combination of prismatic and revolute joints (47/45) for positioning and orienting a robotic end effector for performing a task within confined space (17). For example, the portable work module may include telescoping arm (52) integrated with wrist (70) having a plurality of degrees of freedom with respect to telescoping arm (52). The portable work module includes an insert that is secured with respect to an access port of confined space (17), said access port serving as a reference location for calculating the position of the robotic end effector within confined space (17). The portable work module is configured to have a compacted configuration for insertion into confined space (17), and an extended configuration for performing tasks within confined space (17). In some examples, the portable work module is modular, such that the robotic end effector or other components may be selectively removed and replaced.

A robotic apparatus including a plurality of rigid body sections that move relative to each other by one or more multi-degree of freedom joints. The robotic apparatus can traverse a fixed frame by attaching its distal ends to the frame and moving the rigid body sections relative to each other.

Provided is a three-axis robot including a base plate, a first guiding unit extending along first direction, a first slider, a first driver driving the first slider to move along first direction, a second guiding unit extending along second direction, a second slider, a second driver driving the second slider to move along second direction, a third guiding unit extending along third direction, and the first, second and third directions are perpendicular to each other, a third slider, and a third driver driving the third slider to move along third direction. The first guiding unit and the first driver are provided on the base plate, the second guiding unit and the second driver are provided on the first slider, and the third guiding unit and the third driver are provided on the second slider, so that the three-axis robot has compact structure, improved rigidity and occupies less space.

A robot includes a robot main body including an A-arm which rotates around an A-rotation axis, a B-arm which is cantilevered off the A-arm and rotates around a B-rotation axis, and a C-arm which is connected to the B-arm, to which an end effector is attached, and which rotates around a C-rotation axis. The A-arm includes a first restriction that is not exposed to the outside of the robot main body. The B-arm includes a clamp which is connected to the end effector and restricts a position of a flexible wiring or pipe, a second restriction that is not exposed to the outside of the robot main body and contacts on the first restriction, and a hole through which the wiring or the pipe is inserted. The C-arm includes a through-hole which penetrates the C-arm along the axial direction of the C-rotation axis.

The invention relates to an improved robotic arm apparatus and associated method which improves a robot configured in a delta arrangement. The robotic arm apparatus is arranged with three substantially identical movable arm assemblies connected together with three linear actuators in a triangular configuration such that each end of each linear actuator has at least one translational degree of freedom.

A work device includes a work device body and a contact preventer. The work device body includes a linear motion unit having three degrees of freedom and a rotary unit having three degrees of freedom. An end effector is mounted on an output portion of the rotary unit. The contact preventer separates a working region in which the work device body is installed, from a non-working region outside the working region. The contact preventer includes: an entry allowing portion allowing an object to enter the working region therethrough; and an entry allowing portion entry detection sensor configured to detect entry of an object into the working region through the entry allowing portions.

A substrate transport apparatus including; a frame, a substrate transport arm connected to the frame, the substrate transport arm having an end effector, and a drive section having at least one motor coupled to the substrate transport arm, wherein the at least one motor defines a kinematic portion of the drive section configured to effect kinematic motion of the substrate transport arm, and the drive section includes an accessory portion adjacent the kinematic portion, wherein the accessory portion has another motor, different and distinct from the at least one motor, the another motor of the accessory portion is operably coupled to and configured to drive one or more accessory device independent of the kinematic motion of the substrate transport arm.

A robot includes a first member, a second member that is provided to be turnable about a turning axis with respect to the first member, marks that are disposed around the turning axis on a surface of the second member, and a mark detection portion that is disposed in the first member and detects the marks.