Baffle plate to be attached to fluid flow-forming body includes baffle plate main body that is attachable to and detachable from fluid flow-forming body. Baffle plate main body allows a fluid to which suction is applied by negative pressure generated by fluid flow-forming body to pass through, while preventing a member from entering concave part of fluid flow-forming body. Baffle plate also includes support member that is attached to main body of fluid flow-forming body at one end thereof, and supports baffle plate main body at the other end thereof such that baffle plate main body opposes end face of fluid flow-forming body. Support member supports baffle plate main body such that a gap between end face and baffle plate main body is maintained, and a fluid path is formed that allows a fluid flowing out of concave part to flow.

Gas is circulated in an entire transportation space. A robot transport device includes a transportation space in which a transport robot is provided and circulation passages by which gas in the transportation space is circulated. Around the transportation space, surrounding spaces are provided. To these surrounding spaces, an object is transported by the transport robot. The transportation space communicates with each of the surrounding spaces via each of openings. The circulation passages are provided to sandwich the transportation space to avoid a working area of the transport robot, including the openings. The circulation passages are provided in pillar portions forming the transportation space.

Gas is circulated in an entire transportation space. A robot transport device includes a transportation space in which a transport robot is provided and circulation passages by which gas in the transportation space is circulated. Around the transportation space, surrounding spaces are provided. To these surrounding spaces, an object is transported by the transport robot. The transportation space communicates with each of the surrounding spaces via each of openings. The circulation passages are provided to sandwich the transportation space to avoid a working area of the transport robot, including the openings. The circulation passages are provided in pillar portions forming the transportation space.

A substrate processing system comprising: a first chamber comprising loading tables, on which a plurality of substrates are to be loaded; a second chamber comprising loading tables, on which a plurality of substrates are to be loaded; a first transfer device comprising a plurality of blades configured to hold a plurality of substrates in a lengthwise direction thereof, and configured to transfer a plurality of substrates loaded on the loading tables of the first chamber to the loading tables of the second chamber with the substrates held at the same height; a substrate sensor provided on paths, along which the blades enter the second chamber, and configured to detect a substrate held by the blades; and a controller configured to control the first transfer device.

An industrial robot for use with an object may include a hand on which the object is mounted; an arm having a distal end to which the hand is rotatably connected; a body part to which a base end of the arm is rotatably connected; and an installation member structured to install the body part on a floor surface. The body part may include an elevating body having an upper surface to which the base end of the arm is rotatably connected, a casing configured to hold the elevating body such that the elevating body is movable up and down and to accommodate at least a part of a lower end of the elevating body, and an elevating mechanism configured to move the elevating body up and down. The elevating mechanism may be accommodated in the casing so as to overlap the elevating body when viewed in an up-down direction.

An industrial robot for use with an object may include a hand on which the object is mounted; an arm having a distal end to which the hand is rotatably connected; a body part to which a base end of the arm is rotatably connected; and an installation member structured to install the body part on a floor surface. The body part may include an elevating body having an upper surface to which the base end of the arm is rotatably connected, a casing configured to hold the elevating body such that the elevating body is movable up and down and to accommodate at least a part of a lower end of the elevating body, and an elevating mechanism configured to move the elevating body up and down. The elevating mechanism may be accommodated in the casing so as to overlap the elevating body when viewed in an up-down direction.

An apparatus, system and method for providing a Bernoulli-based wafer pre-aligner. The pre-aligner may be capable of accommodating semiconductor wafers of varying sizes, and may include: a wafer support; a bearing arm capable of interfacing with at least one robotic element, and at least partially bearing the wafer support at one end thereof; and a plurality of Bernoulli pads on the wafer support for providing an interface between the wafer support and a one of the semiconductor wafers, wherein the interface comprises a gap there between.

The EFEM comprises: a transfer chamber in which a transfer robot is disposed, a first fan that forms a downward air flow in the transfer chamber, a gas return space that circulates the gas flowing downward in the transfer chamber above the first fan, a box that communicates with the transfer chamber and is provided with a gas outlet, and a connecting and disconnecting means configured to switch connection and disconnection of the box to and from the transport chamber. A circulation path in which gas circulates is formed by the transfer chamber, the gas return space, and the box. When the transfer chamber and the box are separated by the connecting and disconnecting means, a shortened circulation path is formed in which the gas circulates without passing through the box.

The EFEM comprises: a transfer chamber in which a transfer robot is disposed, a first fan that forms a downward air flow in the transfer chamber, a gas return space that circulates the gas flowing downward in the transfer chamber above the first fan, a box that communicates with the transfer chamber and is provided with a gas outlet, and a connecting and disconnecting means configured to switch connection and disconnection of the box to and from the transport chamber. A circulation path in which gas circulates is formed by the transfer chamber, the gas return space, and the box. When the transfer chamber and the box are separated by the connecting and disconnecting means, a shortened circulation path is formed in which the gas circulates without passing through the box.

A conveying unit includes a housing; a collision prevention mechanism disposed on a sidewall of the housing; a gripping member configured to hold a carrier for carrying a semiconductor structure; a sensor disposed on the gripping member and configured to measure and collect data associated with vibration of the gripping member; and an unit controller disposed on the gripping member and configured to analyze the data from the sensor and control a movement of the conveying unit.