A substrate storage container includes a container main body having an opening at the front, a support portion for supporting a substrate in the interior thereof, and a substrate receiving portion positioned more toward a rear wall than the support portion, an a lid on which a substrate pressing portion for pressing the substrate is formed. The substrate receiving portion and the substrate pressing portion are present within a range of greater than or equal to 0 mm and less than or equal to 80 mm in the horizontal direction from a vertical center line that passes through the center of the container main body when the lid is viewed from the front.

A container for consumables includes multiple holding portions, a partition plate and a fixer. The multiple holding portions are configured to respectively accommodate the consumables, each of which is loaded into and unloaded from one direction. The partition plate includes a first portion formed to be disposed between a light emitting part and a light receiving part of a detector, and the partition plate is accommodated in one of the multiple holding portions. The fixer is configured to fix the container so that the consumables are arranged on a transfer path to be loaded into and unloaded from the multiple holding portions.

The present disclosure relates to systems and methods for affixing and/or removing a fastener from a wafer-carrying pod. The system includes a robotic arm with a screw tool assembly disposed at the far end of the robotic arm. The screw tool assembly includes a lower sleeve configured to receive a fastener. A screwdriver is disposed within an upper sleeve of the screw tool assembly, and a motor is provided to rotate the screwdriver. In use, the screw tool assembly is positioned over the fastener so the lower sleeve surrounds the fastener and the screwdriver engages the fastener. The screwdriver unscrews the fastener form the pod, and the fastener head is received within the lower sleeve.

A wafer storage box, wafer transfer device and wafer storage box and transfer assembly. The wafer storage and transfer assembly includes a chassis which is capable of translating or rotating, a sliding shaft, connecting levers, arms and at least two positioning sidewall. The chassis includes a groove. The sliding shaft can translate along the groove. The connecting levers are connected to the sliding shaft. Each arm extends from a connecting lever. The two positioning sidewall are respectively arranged on opposite sides of the chassis. Each positioning sidewall includes tracks accommodating the pins of connecting levers. The width of each of the tracks reduces from the front end of the positioning sidewall to the back end of the positioning sidewall. The wafer storage and transfer assembly can vacuum adsorb several wafers to achieve high efficiency of wafer storing and transferring.

Wafer cassettes and methods of use that provide heating a cooling to a plurality of wafers to decrease time between wafer switching in a processing chamber. Wafers are supported on a wafer lift which can move all wafers together or on independent lift pins which can move individual wafers for heating and cooling.

A wafer container includes at least one shelf and a frame. The shelf is capable of holding at least one wafer, and has at least one opening therein. The opening is at least partially exposed by the wafer when the wafer is hold by the shelf. The frame carries the shelf and allows access to the shelf.

A back side substrate support portion 6 includes a lower side inclined face 622 on which an end of a back face of a substrate W slides, and a substrate support portion 632 that is located above the lower side inclined face 622 and can support an edge portion of the substrate W. When a container main body opening portion 21 is closed by a lid body 3, the edge portion of the substrate W slides on the lower side inclined face 622 and reaches the substrate support portion 632. At least a portion of the lower side inclined face 622 is configured from a second member that is different from a first member that configures the substrate support portion 632, and the second member has a lower maximum static friction coefficient and lower wear resistance than the first member.

The present disclosure relates to systems and methods for affixing and/or removing a fastener from a wafer-carrying pod. The system includes a robotic arm with a screw tool assembly disposed at the far end of the robotic arm. The screw tool assembly includes a lower sleeve configured to receive a fastener. A screwdriver is disposed within an upper sleeve of the screw tool assembly, and a motor is provided to rotate the screwdriver. In use, the screw tool assembly is positioned over the fastener so the lower sleeve surrounds the fastener and the screwdriver engages the fastener. The screwdriver unscrews the fastener from the pod, and the fastener head is received within the lower sleeve.

The present invention relates to a container for storing a wafer, particularly to a container for storing a wafer in which a plurality of purging areas is vertically partitioned in the interior of a storage chamber, and a purge gas is sprayed into the plurality of purging areas, thereby allowing not only uniform purging of the wafer to be assured but also efficient purging of the wafer without waste of the purge gas to be achieved.

The present disclosure describes a method for substrate storage. The method can include respectively placing a plurality of substrates into a plurality of slots formed by a plurality of fin structures on a panel of a storage device. The method can further include binding each of the plurality of substrates to an corresponding one of the plurality of fin structures. The method can further include moving the storage device from a first location to a second location. The method can further include un-binding the plurality of substrates from the plurality of fin structures.