Systems and methods for transferring solar cells while maintaining a controlled micro-environment are provided. In particular, such systems provide automated loading and unloading of solar cells by use of a conveyor and elevator within a tank receptacle sealingly connected with a solar cell carrying pods and a flow tube of solar cell components in a solar cell fabrication process. The tank receptacle can include one or more ports for sealingly and operably coupling with a cover of a solar cell carrying pod, each port having an elevator for withdrawing a removable base of the pod along with a solar cell carrying cassette into the tank and a conveyor to facilitate loading and/or unloading of solar cells with the cassette by coordinated movement of the elevator and conveyor. Such systems can further include a robotic arm having a gripper and nozzle to maintain a micro-environment within the pod during transport.

Methods for processing semiconductor wafers, methods for loading semiconductor wafers into wafer carriers, and semiconductor wafer carriers. The methods and wafer carriers can be used for increasing the rigidity of wafers, e.g., large and thin wafers, by intentionally bowing the wafers to an extent that does not break the wafers. In some examples, a method for processing semiconductor wafers includes loading each semiconductor wafer into a respective semiconductor wafer slot of a semiconductor wafer carrier, horizontally bowing each semiconductor wafer, and moving the semiconductor wafer carrier into a processing station and processing the semiconductor wafers at the processing station while the semiconductor wafers are loaded into the semiconductor wafer carrier and horizontally bowed.

A substrate liquid treatment apparatus includes an inner tank configured to store a treatment liquid and having an upper opening, an outer tank disposed outside the inner tank, and a lid movable between a close position for closing the upper opening of the inner tank and an open position for opening the upper opening of the inner tank. The lid includes a main portion that covers the upper opening of the inner tank when the lid is positioned at the close position, and a splash shielding portion connected to the main portion. When the lid is positioned at the close position, the splash shielding portion extends from a position higher than an upper end of a side wall of the inner tank adjacent to the splash shielding portion to a position which is lower than the upper end of the side wall and which is on the outer tank side of the side wall.

Described herein is a technique capable of shortening the time required to reduce the oxygen concentration in a transfer chamber. According to the technique described herein, there is provided a substrate processing apparatus including: a transfer chamber wherein a substrate from a container is transported; a transfer robot configured to transfer the substrate through the transfer chamber; a purge gas supply mechanism configured to supply a purge gas into the transfer chamber; and a pressure control mechanism configured to control an inner pressure of the transfer chamber wherein the pressure control mechanism is provided at an exhaust channel wherethrough an inner atmosphere of the transfer chamber is exhausted, the pressure control mechanism including: an exhaust damper configured to fully open or fully close the exhaust channel; and an adjusting damper provided in the exhaust damper and configured to maintain the inner pressure of the transfer chamber at predetermined pressure.

Semiconductor wafer carriers, methods for manufacturing the semiconductor wafer carriers, and methods for using the semiconductor wafer carriers. The semiconductor wafer carriers can include features for avoiding double-slotting, for preventing glove marks on semiconductor wafers, and for providing additional sitting and storage options for the wafer carrier. In some examples, a semiconductor wafer carrier includes multiple notched left-side rods that are parallel in a vertical direction and multiple notched right-side rods that are parallel in the vertical direction. The semiconductor wafer carrier includes one or more bottom rods. The left-side rods, the right-side rods, and the one or more bottom rods are joined to define semiconductor wafer slots.

Methods for processing semiconductor wafers, methods for loading semiconductor wafers into wafer carriers, and semiconductor wafer carriers. The methods and wafer carriers can be used for increasing the rigidity of wafers, e.g., large and thin wafers, by intentionally bowing the wafers to an extent that does not break the wafers. In some examples, a method for processing semiconductor wafers includes loading each semiconductor wafer into a respective semiconductor wafer slot of a semiconductor wafer carrier, horizontally bowing each semiconductor wafer, and moving the semiconductor wafer carrier into a processing station and processing the semiconductor wafers at the processing station while the semiconductor wafers are loaded into the semiconductor wafer carrier and horizontally bowed.

Semiconductor wafer carriers, methods for manufacturing the semiconductor wafer carriers, and methods for using the semiconductor wafer carriers. The semiconductor wafer carriers can include features for avoiding double-slotting, for preventing glove marks on semiconductor wafers, and for providing additional sitting and storage options for the wafer carrier. In some examples, a semiconductor wafer carrier includes multiple notched left-side rods that are parallel in a vertical direction and multiple notched right-side rods that are parallel in the vertical direction. The semiconductor wafer carrier includes one or more bottom rods. The left-side rods, the right-side rods, and the one or more bottom rods are joined to define semiconductor wafer slots.

Presented herein is a device processing boat comprising a base and at least one unit retainer disposed in the base. The device further comprises a cover having at least one recess configured to accept and retain at least one unit. The at least one recess is aligned over, and configured to hold the at least one unit over, at least a portion of the at least one unit retainer. The cover is retained to the device processing boat by the at least one unit retainer. At least one pressure sensor having at least one sensel is disposed in the base. The sensel is configured to sense a clamping force applied by the cover to the at least one unit.

A substrate holder mounting device is provided that is compact and has a simple structure. The substrate holder mounting device according to the present invention is provided with: a first and a second mounting mechanisms (5, 7) that are housed in a chamber and that are respectively configured to be capable of mounting a plurality of substrate holders along a row; row direction drive means that moves the first mounting mechanism to a row direction relatively with respect to the second mounting mechanism; a shifting mechanism (30) that shifts the substrate holders between the first and second mounting mechanisms; and a link-up mechanism that changes positions of the substrate holders in the row direction in the first or second mounting mechanism by a linkage between the shifting mechanism and the above-described row direction drive means.

Described herein is a technique capable of shortening the time required to reduce the oxygen concentration in a transfer chamber. According to the technique described herein, there is provided a substrate processing apparatus including: a transfer chamber wherein a substrate from a container is transported; a transfer robot configured to transfer the substrate through the transfer chamber; a purge gas supply mechanism configured to supply a purge gas into the transfer chamber; and a pressure control mechanism configured to control an inner pressure of the transfer chamber wherein the pressure control mechanism is provided at an exhaust channel wherethrough an inner atmosphere of the transfer chamber is exhausted, the pressure control mechanism including: an exhaust damper configured to fully open or fully close the exhaust channel; and an adjusting damper provided in the exhaust damper and configured to maintain the inner pressure of the transfer chamber at predetermined pressure.