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    • 1. 发明公开
    • 플라즈마 처리 장치
    • 等离子体处理装置
    • KR20180025832A
    • 2018-03-09
    • KR20170112052
    • 2017-09-01
    • TOKYO ELECTRON LTD
    • MATSUURA SHINHIROSE JUN
    • H01J37/32
    • H01J37/32807H01J37/18H01J37/32009H01J37/32513H01J37/32743H01L21/67126H01L21/6719
    • 본발명은플라즈마처리장치를소형화하는것을과제로한다. 플라즈마처리장치(10)는, 챔버(1)와, 셔터(20)와, 접촉부를구비한다. 챔버(1)는, 측벽에웨이퍼(W)를반입하기위한개구부(74)를가지며, 내부에공급된처리가스의플라즈마에의해웨이퍼(W)에미리정해진처리를실시한다. 셔터(20)는, 챔버(1)의측벽을따라이동함으로써, 개구부(74)를개폐한다. 접촉부는, 도전성의재료로구성되어있으며, 셔터(20)가이동중인경우에셔터와접촉하지않고, 셔터(20)가개구부(74)를폐쇄하는위치에있는경우에, 셔터(20)의이동방향과는상이한방향으로변위하여셔터(20)와접촉한다.
    • 本公开的等离子体处理设备包括腔室,快门和接触部分。 腔室在其侧壁上具有开口以便通过开口将晶片W运送到腔室中,并且通过供应到其中的处理气体的等离子体对晶片W进行预定的处理。 快门通过沿着腔室的侧壁移动来打开或关闭开口。 接触部分由导电材料形成,并且在快门移动时不与快门接触。 当开闭器处于关闭开口的位置时,接触部分沿不同于开闭器的移动方向的方向移动以与开闭器接触。
    • 4. 发明专利
    • DE69938368T2
    • 2009-03-05
    • DE69938368
    • 1999-08-09
    • FUJIKIN KKTOKYO ELECTRON LTDOHMI TADAHIRO
    • OHMI TADAHIROKAGATSUME SATOSHIHIROSE JUNNISHINO KOUJI
    • F16K7/14G05D7/06C01B5/00F15D1/04F16K31/06G05B11/36
    • A fluid-switchable flow rate control system that permits free changing of the full scale flow rate and which can control a plurality of kinds of fluids with high precision. The fluid-switchable flow rate control system controls the flow rate of fluid with the pressure P1 on the upstream side of the orifice member held about twice or more higher than the downstream pressure P2, the fluid-switchable flow rate control system comprising an orifice member 8 replaceable with another to provide a suitable orifice diameter according to the kind of fluid and the flow rate range, a control valve 2 provided on the upstream side thereof, a pressure detector 6 provided between the control valve 2 and the orifice member 8, and a flow rate calculation circuit 14 where, from the pressure P1 detected by the pressure detector, the flow rate Qc is calculated by the equation Qc = KP1 (K: constant), a flow rate-setting circuit 16 for outputting flow rate setting signal Qe, a flow rate conversion circuit 18 for multiplying the calculated flow rate signal Qc by the flow rate conversion rate k into switch-over calculated flow rate signal Qf (Qf = kQc) to change the full scale flow rate, and a calculation control circuit 20 to output the difference between the switch-over calculation flow rate signal Qf and the flow rate setting signal Qe as control signal Qy to the drive 4 of the control valve 2, thereby opening or closing the control valve to bring the control signal Qy to zero, thus controlling the flow rate on the downstream side of the orifice member.
    • 7. 发明专利
    • DE69927932D1
    • 2005-12-01
    • DE69927932
    • 1999-08-09
    • FUJIKIN KKTOKYO ELECTRON LTDOHMI TADAHIRO
    • OHMI TADAHIROKAGATSUME SATOSHIHIROSE JUNNISHINO KOUJI
    • F16K7/14C01B5/00F15D1/04F16K31/06G05B11/36G05D7/06
    • A fluid-switchable flow rate control system that permits free changing of the full scale flow rate and which can control a plurality of kinds of fluids with high precision. The fluid-switchable flow rate control system controls the flow rate of fluid with the pressure P1 on the upstream side of the orifice member held about twice or more higher than the downstream pressure P2, the fluid-switchable flow rate control system comprising an orifice member 8 replaceable with another to provide a suitable orifice diameter according to the kind of fluid and the flow rate range, a control valve 2 provided on the upstream side thereof, a pressure detector 6 provided between the control valve 2 and the orifice member 8, and a flow rate calculation circuit 14 where, from the pressure P1 detected by the pressure detector, the flow rate Qc is calculated by the equation Qc = KP1 (K: constant), a flow rate-setting circuit 16 for outputting flow rate setting signal Qe, a flow rate conversion circuit 18 for multiplying the calculated flow rate signal Qc by the flow rate conversion rate k into switch-over calculated flow rate signal Qf (Qf = kQc) to change the full scale flow rate, and a calculation control circuit 20 to output the difference between the switch-over calculation flow rate signal Qf and the flow rate setting signal Qe as control signal Qy to the drive 4 of the control valve 2, thereby opening or closing the control valve to bring the control signal Qy to zero, thus controlling the flow rate on the downstream side of the orifice member.
    • 9. 发明专利
    • AT308074T
    • 2005-11-15
    • AT99935121
    • 1999-08-09
    • FUJIKIN KKTOKYO ELECTRON LTDOHMI TADAHIRO
    • OHMI TADAHIROKAGATSUME SATOSHIKITASHIMOJO FUJIICHOHIROSE JUNNISHINO KOUJI
    • F16K7/14C01B5/00F15D1/04F16K31/06G05B11/36G05D7/06
    • A fluid-switchable flow rate control system that permits free changing of the full scale flow rate and which can control a plurality of kinds of fluids with high precision. The fluid-switchable flow rate control system controls the flow rate of fluid with the pressure P1 on the upstream side of the orifice member held about twice or more higher than the downstream pressure P2, the fluid-switchable flow rate control system comprising an orifice member 8 replaceable with another to provide a suitable orifice diameter according to the kind of fluid and the flow rate range, a control valve 2 provided on the upstream side thereof, a pressure detector 6 provided between the control valve 2 and the orifice member 8, and a flow rate calculation circuit 14 where, from the pressure P1 detected by the pressure detector, the flow rate Qc is calculated by the equation Qc = KP1 (K: constant), a flow rate-setting circuit 16 for outputting flow rate setting signal Qe, a flow rate conversion circuit 18 for multiplying the calculated flow rate signal Qc by the flow rate conversion rate k into switch-over calculated flow rate signal Qf (Qf = kQc) to change the full scale flow rate, and a calculation control circuit 20 to output the difference between the switch-over calculation flow rate signal Qf and the flow rate setting signal Qe as control signal Qy to the drive 4 of the control valve 2, thereby opening or closing the control valve to bring the control signal Qy to zero, thus controlling the flow rate on the downstream side of the orifice member.