Disclosed are semiconductor carrier storage systems, semiconductor fabrication systems including the same, and/or semiconductor fabrication methods using the same. The semiconductor carrier storage system comprises storage ports each of which accommodates a semiconductor carrier, a shuttle rail that extends in a horizontal direction on a side of the storage ports, an internal carrier shuttle that moves along the shuttle rail and transfers a semiconductor carrier to each of the storage ports, and an upper transport that receives the semiconductor carrier from an overhead hoist transport (OHT). The internal carrier shuttle includes a shuttle body coupled to the shuttle rail, a transfer wheel that connects the shuttle body to the shuttle rail, a gripper that holds the semiconductor carrier, and a hoist that vertically extends between the shuttle body and the gripper and drives the gripper to vertically move.

An overhead transport vehicle system includes an overhead transport vehicle including a traveler and a body supported by the traveler via a suspension to hold an object to be transported, and a traveling rail including a slit, through which the suspension is movable when the traveler travels, and rolling portions along which traveling wheel rolls, and having a tubular shape including an internal space through which the traveler travels. In the internal space in a curved section, above a passing area through which the traveling wheel rolling on the rolling portion on an outer side of a curve passes, a rising restriction portion, with which the traveling wheel having risen by a predetermined amount from the rolling portion comes into contact, extends along an extending direction of the traveling rail.

A transport system, including: a sensor, a controller and a power panel. The sensor determines a zone and sends a quantity information in response to a quantity of vehicles in the zone. The controller is arranged to send an output signal in accordance with the quantity information. The power panel is arranged to output a current in accordance with the output signal for driving vehicles in the zone, wherein the current is outputted to a cable extending through the zone.

The article transport vehicle includes a travel section, a holding section, an elevating device, an inclination detection device, an inclination adjustment device, and an inclination control device for controlling the inclination adjustment device. The inclination adjustment device is configured to act on a target belt among a plurality of suspension belts to adjust an inclination of the holding section by adjusting a suspension height at which the holding section is held by the target belt. During the lowering of the holding section to the transfer position by the elevating device, the inclination control device executes an adjustment operation during lowering, in which the inclination of the holding section is detected by the inclination detection device, and based on the result of the detection performed by the inclination detection device, the inclination adjustment device is controlled to adjust the inclination of the holding section.

A substrate transfer system capable of performing efficient distribution exchange between fabricating facilities is provided. The substrate transfer system includes a lower rail, an upper rail which is located above the lower rail from a ground plane, and extends to be parallel to the lower rail, a conveyor which extends to intersect the lower rail and the upper rail, below the lower rail, a first lower transport unit which transports a first carrier along the lower rail and unloads the first carrier onto the conveyor, and a first upper transport unit which transports a second carrier along the upper rail and unloads the second carrier onto the conveyor, wherein the conveyor includes a linear module which moves the first carrier and the second carrier in a linear direction, and a turning module which turns the first carrier and the second carrier.

An automated warehouse includes a placement section module that is slidably supported by a frame member via a slide mechanism. The slide mechanism supports the placement section module in such a manner that the placement section module is slidable relative to the frame member between a reference position and a protruding position. A cover member covers a face of the placement section module on a back face side in a depth direction. When the placement section module is at the protruding position, an upper side of storage regions is exposed.

An embodiment is a processing system for processing a substrate. The processing system includes a Front Opening Unified Pod (FOUP) load lock (FLL) and a vacuum system. The FLL has walls defining an interior space therein. The FLL includes load lock isolation and tunnel isolation doors. The load lock isolation door is operable to close a first opening in a first sidewall of the FLL. The first opening is sized so that a FOUP is capable of passing therethrough. The tunnel isolation door is operable to close a second opening in a second sidewall of the FLL. The second opening is sized so that a substrate is capable of passing therethrough. The vacuum system is fluidly connected to the interior space of the FLL and is operable to pump down a pressure of the interior space of the FLL.

Methods and systems for improving the efficiency of an automated material handling system (AMHS) include providing an apparatus operatively coupled to a load port of a processing apparatus, where the apparatus is configured to remove a first work-in-process from the load port and to move the first work-in-process along a first direction to displace the first work-in-progress from the load port while a second work-in-progress is transferred to the load port from an AMHS vehicle along a second direction that is perpendicular to the first direction, and transferring the first work-in-progress to an AMHS vehicle along the second direction. The methods and systems may be used for loading and unloading wafer storage containers, such as front opening unified pods (FOUPs), in a semiconductor fabrication facility.

Methods and systems for improving the efficiency of an automated material handling system (AMHS) include providing an apparatus operatively coupled to a load port of a processing apparatus, where the apparatus is configured to remove a first work-in-process from the load port and to move the first work-in-process along a first direction to displace the first work-in-progress from the load port while a second work-in-progress is transferred to the load port from an AMHS vehicle along a second direction that is perpendicular to the first direction, and transferring the first work-in-progress to an AMHS vehicle along the second direction. The methods and systems may be used for loading and unloading wafer storage containers, such as front opening unified pods (FOUPs), in a semiconductor fabrication facility.

A system for a semiconductor fabrication facility includes a maintenance tool, a control unit, a first track, a second track, a maintenance crane movably mounted on the first track, a plurality of first sensors disposed on the first track, an OHT vehicle movably mounted on the second track, and a second sensor on the OHT vehicle. The first sensors detect a location of the maintenance crane and generate a first location data to the control unit. The second sensor generates a second location data to the control unit.