A substrate processing apparatus includes: a batch processor configured to collectively process a lot including plural substrates; a single-wafer processor configured to process the substrates included in the lot one by one; and a transport portion configured to deliver the substrates one by one between the batch processor and the single-wafer processor. The batch processor includes a processing tank configured to store a processing liquid including a rinsing liquid. The transport portion includes a fluid supplier configured to supply, after receiving the substrates included in the lot in the processing tank and until delivering the substrates to the single-wafer processor, a low surface tension fluid having a lower surface tension than the rinsing liquid to at least one of the processing tank and the substrates.

A system, includes, a semiconductor processing unit, an Automated Materials Handling System (AMHS) vehicle, and a warehouse apparatus, wherein the warehouse apparatus comprises at least one input port, at least one output port, and at least one load/unload port, wherein the warehouse apparatus is configured to perform one of the following: receiving a plurality of tray cassette containers from the AMHS vehicle at the at least one input port, transporting at least one tray cassette in each of a plurality of tray cassette containers to the at least one load/unload port via the at least one input port, transporting at least one first tray from the at least one tray cassette to the semiconductor processing unit via a tray feeder conveyor, and receiving at least one second tray from the semiconductor processing unit via the tray feeder conveyor.

A conveyor system for moving a plurality of targets is provided. The conveyor system includes at least one input group to input the target, at least one output group to output the target, and at least one bridge group to connect the input group with the output group. Each of the input group, the output group, and the bridge group includes a plurality of nodes having a size corresponding to a size of one target. The conveyor system further includes a control unit to align the target moving on the conveyor system.

A portable robotic semiconductor pod loader may detect, with at least one sensor, receipt of a semiconductor pod on a load port of the portable robotic semiconductor pod loader. The at least one sensor is supported by the load port. The portable robotic semiconductor pod loader may cause a robot, of the portable robotic semiconductor pod loader, to align with the semiconductor pod provided on the load port. The portable robotic semiconductor pod loader may cause the robot to attach to the semiconductor pod, and may cause the robot to provide the semiconductor pod from the load port to a staging area of a semiconductor processing tool.

A storage system includes an overhead stocker having a first overhead track, a rack including a plurality of storages arranged vertically, and a crane that travels along the first overhead track and delivers and receives an article to and from the storages; and an overhead transport vehicle system having a second overhead track provided below a lower end of the overhead stocker, and an overhead transport vehicle that travels along the second overhead track and delivers and receives an article to and from a predetermined transfer destination, wherein the first overhead track has an elevating track capable of supporting and lowering the crane that is stopped traveling at a portion deviated from the second overhead track in planar view.

A system and an operating method for automated wafer carrier handling are provided. The system includes a storage rack including a standby position and a storage position separated from each other, a first and second moving mechanism, and a controller operatively coupled to the first and second moving mechanism to control operations of the first and second moving mechanism. The storage position is for buffering a wafer carrier awaiting transfer to a load port. The first moving mechanism is movably coupled to the storage rack and provides at least one degree of freedom of movement to transfer the wafer carrier from the storage position to the standby position. The second moving mechanism is disposed over the storage rack, operatively coupled the storage rack to the load port, and provides at least one degree of freedom of movement to transfer the wafer carrier from the standby position to the load port.

According to one embodiment, a substrate storage container includes a transport component configured to be mountable to a container body by being relatively displaced with respect to the container body from the rear side to the front side. The container body has a container body-side protrusion protruding upward. The transport component has a transport component-side protrusion protruding downward. In a mounted state, the transport component-side protrusion is engaged with the front side of the container body-side protrusion to be restricted from being displaced backwards. When a predetermined load is applied to the transport component-side protrusion upwardly, the transport component-side protrusion is displaced by a smaller amount than the container body-side protrusion displaced when the predetermined load is applied to the container body-side protrusion downwardly.

The object is to provide a vehicle system capable of suppressing a decrease in article transport efficiency while ensuring a route of an operator. The vehicle system includes a grid-patterned rail, a vehicle traveling on the rail, a controller that controls the vehicle, a work terminal that transmits identification information indicating an actual location to the controller, and a scaffold for allowing an operator carrying the work terminal to walk below the rail, the scaffold being provided below the rail. If entry permission to one or more cells formed by the rail is obtained from the controller, the vehicle enters the one or more cells. If entry permission to the one or more cells is not obtained from the controller, the vehicle does not enter the one or more cells. The controller performs blocking so as not to grant the vehicle the entry permission at least to a cell corresponding to the actual location indicated by the identification information transmitted from the work terminal, among a plurality of cells corresponding to a route of the operator from the entrance to the scaffold to the destination.

A storage system includes shelves each with a nozzle to supply clean gas into containers, flow amount controllers to control a supply amount of clean gas to a nozzle, a transport apparatus to transfer the containers to and from the shelves, and a controller to control the transport apparatus and the flow amount controllers. The controller makes an assignment of at least one shelf in preparation to store an incoming container and before the occurrence of the incoming container, and controls a flow amount controlling device to supply clean gas to the nozzle in the at least one shelf, based upon the assignment.

A wafer pod transfer assembly is provided. The wafer pod transfer assembly includes a wafer pod port to receive a wafer pod, a transfer axle coupled to the wafer pod port, a shaft receiver, a shaft coupled to the transfer axle and to the shaft receiver, a pin through the shaft receiver and through the shaft, wherein the pin comprises a first end and a second end, opposite the first end, and a pin buckle including a first loop and a second loop. The pin buckle is coupled to the pin, the first loop encircles the first end of the pin, and the second loop encircles the second end of the pin.