Exemplary substrate processing systems may include a transfer region housing defining a transfer region fluidly coupled with a plurality of processing regions. A sidewall of the transfer region housing may define a sealable access for providing and receiving substrates. The systems may include a transfer apparatus having a central hub including a shaft extending at a distal end through the transfer region housing into the transfer region. The transfer apparatus may include a lateral translation apparatus coupled with an exterior surface of the transfer region housing, and configured to provide at least one direction of lateral movement of the shaft. The systems may also include an end effector coupled with the shaft within the transfer region. The end effector may include a plurality of arms having a number of arms equal to a number of substrate supports of the plurality of substrate supports in the transfer region.

Exemplary substrate processing systems may include a transfer region housing defining a transfer region fluidly coupled with a plurality of processing regions. A sidewall of the transfer region housing may define a sealable access for providing and receiving substrates. The systems may include a transfer apparatus having a central hub including a shaft extending at a distal end through the transfer region housing into the transfer region. The transfer apparatus may include a lateral translation apparatus coupled with an exterior surface of the transfer region housing, and configured to provide at least one direction of lateral movement of the shaft. The systems may also include an end effector coupled with the shaft within the transfer region. The end effector may include a plurality of arms having a number of arms equal to a number of substrate supports of the plurality of substrate supports in the transfer region.

A head mechanism includes a base connectable to a body of a robot, a mounting member arranged above the base, a connecting member rotatably connected to the base and the mounting member. The connecting member, together with the mounting member, is rotatable relative to the base about a first axis, and the mounting member is rotatable relative to the connecting member about a second axis. The first axis and the second axis extend in different directions. The head mechanism further includes two first actuating mechanisms fixed to the base, and the two first actuating mechanisms are configured to drive the mounting member to rotate with respect to the base.

An objective of the present invention is to reduce the downtime which occurs when changing a servo motor device. A servo motor device includes a motor section and a reduction gear configured to output a driving force by reducing a speed of rotation of the motor section, wherein a control device includes a detecting section configured to acquire detected information about operation of the motor section, and a computing section configured to generate an approximate curve based on a behavior for a time sequence of a parameter and to calculate predicted lifetime information of the servo motor device based on the approximate curve thus generated, wherein the parameter has been calculated by means of the detected information.

Embodiments relate to robotic arm assemblies. The robotic arm assembly includes an end-effector assembly. The end-effector assembly includes an instrument assembly. The instrument assembly includes an instrument and instrument driven portion. The elongated body includes an instrument central axis. The instrument driven portion includes a first central axis. The instrument driven portion is secured to a proximal end of the instrument in such a way that, when the instrument driven portion is driven to rotate, the instrument rotates relative to the first central axis. The end-effector assembly includes an instrument drive assembly. The instrument drive assembly includes an instrument drive portion. The instrument drive portion includes a second central axis. The instrument drive portion is configured to drive the instrument driven portion to rotate the distal end of the instrument relative to the first central axis. The second central axis intersects with and orthogonal to the first central axis.

A robot and a method of capturing an image applied to the robot, an electronic device for implementing the method of capturing the image, and a computer-readable storage medium are provided. The robot includes: a robot body; a workbench; a telescopic structure having one end pivotally connected to the robot body and the other end connected to the workbench; a driving mechanism arranged on the robot body and configured to drive the telescopic structure to extend, retract and/or move relative to the robot body; and an image capture device arranged on the workbench. The telescopic structure is configured to allow the image capture device to capture an image of a target object from different angles with the extension, retraction and/or movement of the telescopic structure.

Provided is a robot which can improve accuracy of calibration of a rotation sensor for detecting a movement of an actuator included in the robot. The robot (1) includes a connection frame (63) that supports a rolling actuator (13). The connection frame (63) has a first attached portion (63g) attached to a rotation outputting section (12c) of an actuator (12) and a remaining portion (a first arm portion (63b), a supporting portion (63a), and a second arm portion (63c)) connected to the first attached portion (63g). A sensor rotation portion (16a) of a rotation sensor (16) is attached to the first attached portion (63g). The first attached portion (63g) and the rotation outputting section (12c) are rotatable over an angle greater than 360 degrees in a state in which the first attached portion (63g) is attached to the rotation outputting section (12c) and in which the remaining portion of the connection frame (63) is removed from the first attached portion (63g).

Compositions and methods for treating or preventing the progression of neurodegenerative diseases are provided herein. Exemplary compositions include bacterial compositions having an effective amount of viable, non-pathogenic microbes, viable, non-pathogenic bacteria, wherein at least one of the bacteria is a predatory bacteria such as Bdellovibrio bacteriovorus. The disclosed bacterial compositions can be used to treat or prevent the progression of neurodegenerative diseases such as ALS, Alzheimer's disease, Huntington's disease, and Parkinson's disease.

An electronic device is disclosed, including: a spherical housing, and a first driving device disposed in the spherical housing and configured to cause a rolling motion of the spherical housing, the first driving device including: first and second wheels contacting an inner spherical surface of the spherical housing, the first and second wheels respectively disposed at opposite sides of an axis of rotation, at least one motor configured to transmit power to the at least one of the first wheel and the second wheel, a balance weight, a first surface that is spaced apart from the axis of rotation in a direction of gravity by balancing of the balance weight, and facing the inner spherical surface, and at least one rolling element disposed between the inner spherical surface and the first surface.

The disclosure describes devices, systems and methods relating to a transfer chamber for an electronic device processing system. For example, a robot can include a first mover configured to be driven by a platform of a linear motor, a support structure disposed on the first mover, a first robot arm attached to the first end of the support structure at a shoulder axis, and a first arm drive assembly. The first drive assembly can include a first pulley attached to a first end of the support structure and to the first robot arm at the shoulder axis, a second pulley attached to a second end of the support structure, a first band connecting the first pulley to the second pulley, and a second mover configured to be driven by the platform of the linear motor, where the second mover is connected to the first band, and where motion of the second mover relative to the first mover causes the first band to a) rotate the first pulley and the second pulley and b) rotate the first robot arm around the shoulder axis. Also disclosed are systems and methods incorporating the robot.