Abstract: A high-pressure processing apparatus includes a processing vessel including a processing chamber formed therein to perform a certain process onto an object in the processing chamber; fluid feeding means which feeds a high-pressure fluid into the processing chamber; fluid discharging means which discharges the high-pressure fluid from the processing chamber; an agitating unit which is arranged in the processing chamber and is operative to flow the high-pressure fluid over the object by relative rotation to the processing vessel; a communicating channel which is formed in the processing vessel to communicate inside and outside of the processing chamber; a rotary driving member which is coupled to the agitating unit via a shaft portion provided in the communicating channel; and a sealing portion which is provided between the shaft portion and the processing vessel to disconnect the processing chamber from the rotary driving member.

Abstract: When the hatch of a substrate washing chamber 5 is opened to receive a substrate, certain valves are closed, and a valve is opened, supply CO2 to purge the substrate washing chamber 5 to and exclude air. When the hatch is closed, another valve is opened to vent substrate washing chamber 5 so that the CO2 expels any gas and unwanted air from the substrate washing chamber 5 and the conduits. Thereafter, super critical CO2 is used to wash the substrate and clean the circulation line. The flow of supercritical CO2 is sent to the substrate washing chamber 5. After flowing through the circulation line, including a circulation channel 11, it passes through a bypass channel 12 to a decompressor 7. Any chemicals or organic substances left in the circulation line are continuously sent to a separation/recover bath 8 together with the flow.

Abstract: When the hatch of a substrate washing chamber 5 is opened to receive a substrate, certain valves are closed, and one valve is opened, to supply CO2 to purge the substrate washing chamber 5 to and exclude air. When the hatch is closed, another valve is opened to vent substrate washing chamber 5 so that the CO2 expels any gas and unwanted air from the substrate washing chamber 5 and the conduits. Thereafter, supercritical CO2 is used to wash the substrate and clean the circulation line. The flow of supercritical CO2 is sent to the substrate washing chamber 5. After flowing through the circulation line, including a circulation channel 11, it passes through a bypass channel 12 to a decompressor 7. Any chemicals or organic substances left in the circulation line are continuously sent to separation/recovery bath 8 together with the flow.

Abstract: A high-pressure processing apparatus includes a processing vessel including a processing chamber formed therein to perform a certain process onto an object in the processing chamber; fluid feeding means which feeds a high-pressure fluid into the processing chamber; fluid discharging means which discharges the high-pressure fluid from the processing chamber; an agitating unit which is arranged in the processing chamber and is operative to flow the high-pressure fluid over the object by relative rotation to the processing vessel; a communicating channel which is formed in the processing vessel to communicate inside and outside of the processing chamber; a rotary driving member which is coupled to the agitating unit via a shaft portion provided in the communicating channel; and a sealing portion which is provided between the shaft portion and the processing vessel to disconnect the processing chamber from the rotary driving member.

Abstract: A high-pressure processing apparatus includes a processing vessel including a processing chamber formed therein to perform a certain process onto an object in the processing chamber; fluid feeding means which feeds a high-pressure fluid into the processing chamber; fluid discharging means which discharges the high-pressure fluid from the processing chamber; an agitating unit which is arranged in the processing chamber and is operative to flow the high-pressure fluid over the object by relative rotation to the processing vessel; a communicating channel which is formed in the processing vessel to communicate inside and outside of the processing chamber; a rotary driving member which is coupled to the agitating unit via a shaft portion provided in the communicating channel; and a sealing portion which is provided between the shaft portion and the processing vessel to disconnect the processing chamber from the rotary driving member.

Abstract: A high-pressure processing apparatus for removing unnecessary matters on objects to be processed by bringing a high-pressure fluid and a chemical liquid other than the high-pressure fluid into contact with the objects to be processed in a pressurized state is provided with a plurality of high-pressure processing chambers, a common high-pressure fluid supply unit for supplying the high-pressure fluid to each one of the high-pressure processing chambers, a common chemical liquid supply unit for supplying the chemical liquid to the each high-pressure processing chambers, and a separating unit for separating gaseous components from a mixture of the high-pressure fluid and the chemical liquid discharged from the high-pressure processing chambers after the objects are processed. Thus, a high-pressure processing apparatus which has such a compact construction as to be partly installable in a clean room and can stably perform a high-pressure processing can be provided.

Abstract: With respect to any one of processing units, a main transportation path, a developing unit, a dedicated transportation robot and a high-pressure processing unit are disposed linearly in this order in a direction. Hence, even if a processing fluid adhering to a substrate or an evaporant of the processing fluid moves toward the main transportation path while the high-pressure processing unit transports the substrate wet with the processing fluid, there are the processing units located which the processing fluid or its evaporant must arrive at before reaching the main transportation path.

Abstract: A high-pressure processing apparatus includes a processing vessel including a processing chamber formed therein to perform a certain process onto an object in the processing chamber; fluid feeding means which feeds a high-pressure fluid into the processing chamber; fluid discharging means which discharges the high-pressure fluid from the processing chamber; an agitating unit which is arranged in the processing chamber and is operative to flow the high-pressure fluid over the object by relative rotation to the processing vessel; a communicating channel which is formed in the processing vessel to communicate inside and outside of the processing chamber; a rotary driving member which is coupled to the agitating unit via a shaft portion provided in the communicating channel; and a sealing portion which is provided between the shaft portion and the processing vessel to disconnect the processing chamber from the rotary driving member.

Abstract: When the hatch of a substrate washing chamber 5 is opened to receive a substrate, certain valves are closed, and a valve is opened, supply CO2 to purge the substrate washing chamber 5 to and exclude air. When the hatch is closed, another valve is opened to vent substrate washing chamber so that the CO2 expels any gas and unwanted air from the substrate washing chamber 5 and the conduits. Thereafter, super critical CO2 is used to wash the substrate and clean the circulation line. The flow of supercritical CO2 is sent to the substrate washing chamber 5. After flowing through the circulation line, including a circulation channel 11, it passes through a bypass channel 12 to a decompressor 7. Any chemicals or organic substances left in the circulation line are continuously sent to a separation/recover bath 8 together with the flow.

Abstract: A high-pressure processing apparatus includes a processing vessel including a processing chamber formed therein to perform a certain process onto an object in the processing chamber; fluid feeding means which feeds a high-pressure fluid into the processing chamber; fluid discharging means which discharges the high-pressure fluid from the processing chamber; an agitating unit which is arranged in the processing chamber and is operative to flow the high-pressure fluid over the object by relative rotation to the processing vessel; a communicating channel which is formed in the processing vessel to communicate inside and outside of the processing chamber; a rotary driving member which is coupled to the agitating unit via a shaft portion provided in the communicating channel; and a sealing portion which is provided between the shaft portion: and the processing vessel to disconnect the processing chamber from the rotary driving member.

Abstract: A method and system for processing a substrate includes performing a wet process by supplying a working liquid to a substrate in a wet processing apparatus, transferring the substrate in a non-dry state from the wet processing apparatus to a drying apparatus, and subjecting the substrate to a supercritical drying by a supercritical fluid in the drying apparatus.

Abstract: Liquid for prevention of substrate drying is supplied into a processing chamber so that a pool of the liquid is created as an anti-drying atmosphere in advance inside a processing chamber, and substrates, as they are dipped in the pool, are kept on stand-by in a substrate board. In this manner, air drying of the substrates which are kept on stand-by is prevented. When the number of the substrates in the substrate board reaches a certain number, the anti-drying atmosphere is removed from the processing chamber, which is followed by introduction of an SCF into the processing chamber and supercritical drying (high pressure drying) of all of the plurality of substrates inside the processing chamber, namely, batch supercritical drying.

Abstract: Liquid for prevention of substrate drying is supplied into a processing chamber so that a pool of the liquid is created as an anti-drying atmosphere in advance inside a processing chamber, and substrates, as they are dipped in the pool, are kept on stand-by in a substrate board. In this manner, air drying of the substrates which are kept on stand-by is prevented. When the number of the substrates in the substrate board reaches a certain number, the anti-drying atmosphere is removed from the processing chamber, which is followed by introduction of an SCF into the processing chamber and supercritical drying (high pressure drying) of all of the plurality of substrates inside the processing chamber, namely, batch supercritical drying.

Abstract: With respect to any one of processing units, a main transportation path, a developing unit, a dedicated transportation robot and a high-pressure processing unit are disposed linearly in this order in a direction. Hence, even if a processing fluid adhering to a substrate or an evaporant of the processing fluid moves toward the main transportation path while the high-pressure processing unit transports the substrate wet with the processing fluid, there are the processing units located which the processing fluid or its evaporant must arrive at before reaching the main transportation path.

Abstract: A high-pressure processing apparatus includes a processing vessel including a processing chamber formed therein to perform a certain process onto an object in the processing chamber; fluid feeding means which feeds a high-pressure fluid into the processing chamber; fluid discharging means which discharges the high-pressure fluid from the processing chamber; an agitating unit which is arranged in the processing chamber and is operative to flow the high-pressure fluid over the object by relative rotation to the processing vessel; a communicating channel which is formed in the processing vessel to communicate inside and outside of the processing chamber; a rotary driving member which is coupled to the agitating unit via a shaft portion provided in the communicating channel; and a sealing portion which is provided between the shaft portion and the processing vessel to disconnect the processing chamber from the rotary driving member.

Abstract: When the hatch of a substrate washing chamber 5 is opened to place a substrate therein, valves V1, V2, V3, V4 and V6 are closed, only a valve V5 being opened. Thus, gaseous CO2 is supplied into the substrate washing chamber 5 to perform a chamber purge for preventing surrounding air components from straying in. As the hatch of the substrate washing chamber 5 is closed, the valve V6 is further closed to form a vent line for the substrate washing chamber 5. Thus, the gas residing within the substrate washing chamber 5 and the conduits is expelled by CO2 gas, into the surrounding air, thereby performing a chamber purge to prevent any unwanted surrounding air components from being left. Thereafter, super critical CO2 is used to wash the substrate.

Abstract: A method and system for processing a substrate includes performing a wet process by supplying a working liquid to a substrate in a wet processing apparatus, transferring the substrate in a non-dry state from the wet processing apparatus to a drying apparatus, and subjecting the substrate to a supercritical drying by a supercritical fluid in the drying apparatus.

Abstract: A high-pressure processing apparatus for removing unnecessary matters on objects to be processed by bringing a high-pressure fluid and a chemical liquid other than the high-pressure fluid into contact with the objects to be processed in a pressurized state is provided with a plurality of high-pressure processing chambers, a common high-pressure fluid supply unit for supplying the high-pressure fluid to each one of the high-pressure processing chambers, a common chemical liquid supply unit for supplying the chemical liquid to the each high-pressure processing chambers, and a separating unit for separating gaseous components from a mixture of the high-pressure fluid and the chemical liquid discharged from the high-pressure processing chambers after the objects are processed.

Abstract: An atmospheric conditioning unit for supplying temperature- and humidity-controlled air to a chemical processing part (spin coater) is arranged immediately above a chemical processing part, between this chemical processing part and a heat treatment part (including a hot plate and a cool plate). Namely, the chemical processing part, the atmospheric conditioning unit and the heat treatment part are vertically arranged in a stacked manner. The atmospheric conditioning unit receives external air from an opening. A closed partition is provided to block air flow between the atmospheric conditioning unit and a transport area. The temperature- and humidity-controlled air supplied from the atmospheric conditioning unit to the spin coater forms a downflow in the spin coater, and thereafter rises through an opening and joins with the air flowing from the opening, to be introduced into the atmospheric conditioning unit again and reused.

Abstract: A substrate processing apparatus comprises a first substrate transfer unit having a first transfer path and a second substrate transfer unit having a second transfer path. A spin coating unit and a spin developing unit are arranged along the first transfer path, and a substrate cassette is arranged along the second transfer path. A substrate transport robot of the second substrate transfer unit selectively introduces a substrate received from a substrate transport robot of the first substrate transfer unit in one of external exposure apparatuses arranged on both end portions of the second transfer path, and discharges the substrate from the exposure apparatus for transfering the same to the substrate transport robot of the first substrate transfer unit. Thereby the substrate processing apparatus can avoid or relieve reduction of operational efficiency even if its throughput is different from that of an exposure apparatus.