A wafer stocker capable of further improving an environment around wafers is provided. The wafer stocker includes a housing, a loading device provided on a front surface of the housing, a wafer cassette shelf arranged in the housing, a wafer transfer robot configured to move the wafers from a transfer container mounted on the loading device to a wafer cassette in the wafer cassette shelf, a wafer cassette delivery device configured to move the wafer cassette in the wafer cassette shelf to a stage having a different height, and a fan filter unit configured to generate a laminar flow in a wafer transfer space and in a wafer cassette transfer space.

A substrate container including substrate supports, such as concentric rings, adapted to receive substrates in a substrate stack. The container includes a base and a top cover to enclose the substrate stack. A latching mechanism is adapted to latch the top cover to the base and secure the substrate stack within the container. The latching mechanism includes resilient corner flanges on an outside portion of the container, the flanges acting as springs to exert a biasing force on the cover and on the substrate stack. The flanges hold the stack within the container while accommodating stack-up uncertainty caused by the accumulation of uncertainties due to component machining tolerances. In some embodiments, a gap is created between a side wall of the top cover and the base of the container to assure compression of the substrate stack. Deflection limiters may be implemented to prevent over-deflection of the flanges.

A wafer transportation pod includes a body, a main compartment enclosed by the body, the main compartment to provide a controlled environment, a holding device within the main compartment, the holding device to hold a plurality of semiconductor wafers, a top latching mechanism configured to connect to another pod or a carrier mechanism of an overhead hoist transfer (OHT) system, a bottom latching mechanism configured to connect to another pod, the bottom latching mechanism being similar to the latching mechanism on the carrier.

A robot gripper for moving wafer carriers and packing materials and a method of operating the same are provided. The robot gripper includes two opposing clamp assemblies. The two clamp assemblies are configured to move close to or away from each other. Each of the clamp assemblies includes a movable support pin at a bottom of the clamp assembly.

This substrate storage container comprises: a lid body-side substrate support part which is capable of supporting an edge part of a substrate when the substrate storage container is closed; a depth-side substrate support part which is disposed so as to form a pair with the lid body-side substrate support part and is capable of supporting the edge part of the substrate; and a substrate edge part auxiliary part which is disposed at a portion opposing a substrate storage space when the substrate storage container is closed, and in which are formed a plurality of auxiliary grooves having an opening that is wider than the thickness of the edge part of the substrate so that the edge part of the substrate can be inserted therein. The auxiliary grooves each have opposing groove forming surfaces, and an edge part of one of a plurality of the substrates is inserted into each auxiliary groove when the container is closed. The edge part of the substrate is inserted into the auxiliary groove in a non-contact state in which a space is formed between the edge part of the substrate and the groove forming surfaces and the edge part of the substrate is not contacting the groove forming surfaces when the container is closed.

Proposed are article storage equipment in a semiconductor fabrication facility, the article storage equipment being capable of power supply with a more simplified configuration, and a logistics system of a semiconductor fabrication facility including the same. Article storage equipment in a semiconductor fabrication facility according to one aspect includes a storage unit installed around a rail that provides a travel route of a transport vehicle and configured to store a transport container in which a wafer is accommodated, a purge unit configured to supply an inert gas into the transport container, a control unit configured to identify the transport container stored in the storage unit and control the purge unit to supply the inert gas into the transport container, and a power supply unit configured to supply a current induced from a power supply cable installed along the rail to the control unit.

A purge configurable wafer shipper. The container includes an enclosure portion with an open side or bottom, a door to sealing close the open side or bottom. One of the door and the container portion includes an opening formed in the enclosure to provide a fluid passageway from an interior of the wafer shipper to an exterior region. The opening may include a module receiving structure that defines the fluid passageway. A sealing member is included for insertion into the module receiving structure. The sealing member has a body portion including a support flange positioned proximate a lower portion of the body portion, a circumferential groove in the exterior surface of the body portion, and an O-ring positioned at least partially within the circumferential groove.

A reticle container for containing a reticle including a base plate having one or more windows. Each of the windows can include mounting recess having a recess sidewall including an undercut defined therein. A transparent substrate can be disposed in the mounting recess and is retained therein by a retention member having an arcuate portion extending between a first end portion and a second end portion. At least the first end portion of the retention member can be positioned in the undercut defined in the recess sidewall such that the arcuate portion of the retention member contacts the transparent substrate to retain the transparent substrate in the mounting recess.

The disclosure provides an adjustable device including plates and at least two adjustable modules connect with two adjacent of the plates. The adjustable module can stretch or shrink to change a distance between plates. The disclosure also provides an adjustable storage box including an upper cover and a lower cover. A storage space is formed by the upper cover and the lower cover and for the accommodating of the adjustable device. When the upper cover moves upward relative to the lower cover, the adjustable modules changes from a compression state to a stretch state and increase a distance between plates. Whereby, it is easy to pick and place object when a distance of two adjacent plates increases. The overall volume of the adjustable device is reduced when a distance of two adjacent plates decrease, thereby saving the working space.

The upper wall is provided with a recess indented from the outside toward the inside of the container main body, and a protrusion projecting outward on the inside of the recess. The top flange is provided with an insertion part which can be inserted into the recess from the outside of the upper wall. The insertion part is provided with a through-hole capable of penetrating from the side further from the upper wall to the side nearer the upper wall. With the recess in the upper wall opening upward and the insertion part of the top flange inserted into the recess, a molten resin poured into the through-hole of the insertion part from above fills the recess from the bottom surface thereof up to the outer peripheral surface of the protrusion and the inner peripheral surface of the through-hole.