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    • 8. 发明授权
    • Fluid scrubber
    • 流体洗涤器
    • US08425665B2
    • 2013-04-23
    • US11625024
    • 2007-01-19
    • Bernard F. Duesel, Jr.Michael J. Rutsch
    • Bernard F. Duesel, Jr.Michael J. Rutsch
    • B01D47/02
    • B01D47/021B01D53/18B01D53/48B01D2258/05Y02E50/346
    • A fluid scrubber in the form of a submerged gas reactor includes a reaction vessel, a gas delivery lube partially disposed within the reaction vessel to deliver a gas into the reaction vessel and a scrubbing liquid inlet that provides a scrubbing liquid to the reaction vessel at a rate sufficient to maintain a controlled, constant level of fluid within the reaction vessel. A weir is disposed within the reaction vessel adjacent the gas delivery tube to form a first fluid circulation path between a first weir end and a wall of the reaction vessel and a second fluid circulation path between a second weir end and an upper end of the reaction vessel. During operation, gas introduced through the tube mixes with the scrubbing liquid and the combined gas and liquid flow at a high rate with a high degree of turbulence along the first and second, circulation paths defined around the weir, thereby promoting vigorous mixing and intimate contact between the gas and the scrubbing liquid. This turbulent flow develops a significant amount of interfacial surface area between the gas and the scrubbing liquid resulting in a reduction of the required residence time of the gas within the scrubbing liquid to achieve thermal equilibrium and/or to drive chemical reactions to completion, all of which leads to a more efficient and complete evaporation, chemical reaction, or combined evaporation and chemical reaction process.
    • 浸没式气体反应器形式的流体洗涤器包括反应容器,部分设置在反应容器内的气体输送润滑剂,以将气体输送到反应容器中;以及洗涤液体入口,其在一 速率足以在反应容器内保持受控的恒定水平的流体。 堰被布置在与气体输送管相邻的反应容器内,以在第一堰端和反应容器的壁之间形成第一流体循环路径,并且在第二堰端和反应的上端之间形成第二流体循环路径 船只。 在操作过程中,通过管道引入的气体沿着围绕堰的第一和第二循环路径,与洗涤液和组合的气体和液体流以高速率与高度的湍流混合,从而促进剧烈的混合和紧密接触 在气体和洗涤液之间。 这种湍流在气体和洗涤液之间产生显着量的界面表面积,导致气体在洗涤液中所需的停留时间减少,以实现热平衡和/或驱动化学反应完成, 这导致更有效和完全的蒸发,化学反应或组合的蒸发和化学反应过程。
    • 9. 发明授权
    • Air stripper
    • 脱气机
    • US08382075B2
    • 2013-02-26
    • US11625002
    • 2007-01-19
    • Bernard F. Duesel, Jr.Michael J. Rutsch
    • Bernard F. Duesel, Jr.Michael J. Rutsch
    • B01F3/04B01D21/24C02F3/28
    • C02F1/048B01D1/0058B01D1/14B01D1/305C02F1/10Y02E50/343
    • An air stripper in the form of an submerged gas evaporator or a submerged gas reactor that includes a vessel, a gas delivery tube partially disposed within the vessel to deliver a gas into the vessel and a contaminated liquid inlet that provides a contaminated liquid to the vessel at a rate sufficient to maintain a controlled constant level of process fluid within the vessel. A weir is disposed within the vessel adjacent the gas delivery tube to form a first fluid circulation path between a first weir end and a wall of the vessel and a second fluid circulation path between a second weir end and an upper end of the vessel. During operation, gas introduced through the tube mixes with the process fluid and the combined gas and fluid flow at a high rate with a high degree of turbulence along the first and second circulation paths defined around the weir, thereby promoting vigorous mixing and intimate contact between the gas and the process fluid. This turbulent flow develops a significant amount of interfacial surface area between the gas and the process fluid resulting in a reduction of the required residence time of the gas within the process fluid to achieve thermal equilibrium and/or to drive chemical reactions to completion, all of which leads to a more efficient and complete evaporation, chemical reaction, or combined evaporation and chemical reaction process.
    • 浸没式气体蒸发器或潜入式气体反应器形式的空气汽提器,其包括容器,部分地设置在容器内以将气体输送到容器中的气体输送管以及向容器提供污染液体的污染液体入口 以足以在容器内保持受控恒定水平的工艺流体的速率。 堰被设置在邻近气体输送管的容器内,以在第一堰端和容器的壁之间形成第一流体循环路径,以及在第二堰端和容器的上端之间的第二流体循环路径。 在操作过程中,通过管道引入的气体沿着沿堰周围限定的第一和第二循环路径以高速率高速湍流混合过程流体和组合的气体和流体流,从而促进了湍流之间的剧烈混合和紧密接触 气体和过程流体。 这种湍流在气体和过程流体之间产生显着量的界面表面积,导致气体在工艺流体中所需的停留时间减少,以实现热平衡和/或驱使化学反应完成, 这导致更有效和完全的蒸发,化学反应或组合的蒸发和化学反应过程。
    • 10. 发明授权
    • Desalination system
    • 海水淡化系统
    • US07832714B2
    • 2010-11-16
    • US11625159
    • 2007-01-19
    • Bernard F. Duesel, Jr.Michael J. Rutsch
    • Bernard F. Duesel, Jr.Michael J. Rutsch
    • B01F3/04
    • C02F1/10B01D1/0058B01D1/14B01D1/305B01D5/0006B01D5/006C02F1/14C02F2101/12C02F2103/08C02F2301/024Y02A20/128
    • A desalination system in the form of a submerged gas evaporator that includes a vessel, a gas delivery tube partially disposed within the vessel to deliver a gas into the vessel and a fluid inlet that provides a fluid to the vessel at a rate sufficient to maintain a controlled constant level of fluid within the vessel. A weir is disposed within the vessel adjacent the gas delivery tube to form a first fluid circulation path between a first weir end and a wall of the vessel and a second fluid circulation path between a second weir end and an upper end of the vessel. During operation, gas introduced through the tube mixes with the fluid and the combined gas and fluid flow at a high rate with a high degree of turbulence along the first and second circulation paths defined around the weir, thereby promoting vigorous mixing and intimate contact between the gas and the fluid. This turbulent flow develops a significant amount of inter facial surface area between the gas and the fluid resulting in a reduction of the required residence time of the gas within the fluid to achieve thermal equilibrium which leads to a more efficient and complete evaporation. Additionally, vapor exiting the submerged gas evaporator is condensed in a condensing unit thus precipitating vapor into a liquid for removal.
    • 浸没式气体蒸发器形式的脱盐系统,其包括容器,部分地设置在容器内以将气体输送到容器中的气体输送管,以及以足以维持流体的速率向容器提供流体的流体入口 在容器内控制恒定水平的流体。 堰被设置在邻近气体输送管的容器内,以在第一堰端和容器的壁之间形成第一流体循环路径,以及在第二堰端和容器的上端之间的第二流体循环路径。 在操作过程中,通过管道引入的气体与围绕堰的第一和第二循环通道以高速率高速混合流体和组合的气体和流体流动,从而促进了湍流之间的剧烈混合和紧密接触 气体和流体。 这种湍流在气体和流体之间产生大量的面间表面积,导致气体在流体内所需的停留时间的减少,以实现热平衡,这导致更有效和完全的蒸发。 此外,离开浸没式气体蒸发器的蒸汽在冷凝单元中冷凝,从而将蒸气沉淀成液体以便除去。