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    • 26. 发明授权
    • Cross-flow fluidic oscillators for use with a subterranean well
    • 用于地下井的交叉流动振荡器
    • US08646483B2
    • 2014-02-11
    • US12983144
    • 2010-12-31
    • Roger L. SchultzRobert Pipkin
    • Roger L. SchultzRobert Pipkin
    • F15C1/02
    • E21B28/00E21B47/187Y10T137/2185Y10T137/2234Y10T137/224Y10T137/2251Y10T137/2262Y10T137/2267
    • A fluidic oscillator can include an input, first and second outputs on opposite sides of a longitudinal axis of the oscillator, whereby a majority of fluid which flows through the oscillator exits the oscillator alternately via the first and second outputs, first and second paths from the input to the respective first and second outputs, and wherein the first and second paths cross each other between the input and the respective first and second outputs. Another oscillator can include an input, first and second outputs, whereby a majority of fluid flowing through the fluidic oscillator exits the oscillator alternately via the first and second outputs, first and second paths from the input to the respective first and second outputs, and a feedback path which intersects the first path, whereby reduced pressure in the feedback path influences the majority of fluid to flow via the second path.
    • 流体振荡器可以包括在振荡器的纵向轴线的相对侧上的输入,第一和第二输出,由此流过振荡器的大部分流体经由第一和第二输出交替地离开振荡器,第一和第二路径从 输入到相应的第一和第二输出,并且其中第一和第二路径在输入与相应的第一和第二输出之间彼此交叉。 另一个振荡器可以包括输入,第一和第二输出,由此流过流体振荡器的大部分流体经由第一和第二输出交替地离开振荡器,从输入到相应的第一和第二输出的第一和第二路径,以及 与第一路径相交的反馈路径,由此反馈路径中的减压影响大部分流体经由第二路径流动。
    • 27. 发明申请
    • CROSS-FLOW FLUIDIC OSCILLATORS FOR USE WITH A SUBTERRANEAN WELL
    • 横流式液体振荡器,用于使用一个地下室
    • US20120168014A1
    • 2012-07-05
    • US12983144
    • 2010-12-31
    • Roger L. SCHULTZRobert PIPKIN
    • Roger L. SCHULTZRobert PIPKIN
    • F15C1/22
    • E21B28/00E21B47/187Y10T137/2185Y10T137/2234Y10T137/224Y10T137/2251Y10T137/2262Y10T137/2267
    • A fluidic oscillator can include an input, first and second outputs on opposite sides of a longitudinal axis of the oscillator, whereby a majority of fluid which flows through the oscillator exits the oscillator alternately via the first and second outputs, first and second paths from the input to the respective first and second outputs, and wherein the first and second paths cross each other between the input and the respective first and second outputs. Another oscillator can include an input, first and second outputs, whereby a majority of fluid flowing through the fluidic oscillator exits the oscillator alternately via the first and second outputs, first and second paths from the input to the respective first and second outputs, and a feedback path which intersects the first path, whereby reduced pressure in the feedback path influences the majority of fluid to flow via the second path.
    • 流体振荡器可以包括在振荡器的纵向轴线的相对侧上的输入,第一和第二输出,由此流过振荡器的大部分流体经由第一和第二输出交替地离开振荡器,第一和第二路径从 输入到相应的第一和第二输出,并且其中第一和第二路径在输入与相应的第一和第二输出之间彼此交叉。 另一个振荡器可以包括输入,第一和第二输出,由此流过流体振荡器的大部分流体经由第一和第二输出交替地离开振荡器,从输入到相应的第一和第二输出的第一和第二路径,以及 与第一路径相交的反馈路径,由此反馈路径中的减压影响大部分流体经由第二路径流动。
    • 29. 发明授权
    • Fluidic oscillator
    • 流体振荡器
    • US06860157B1
    • 2005-03-01
    • US10769627
    • 2004-01-30
    • Jing-Tang YangWei-Chih LinKuen-Jyh TsaiKer-Jer Huang
    • Jing-Tang YangWei-Chih LinKuen-Jyh TsaiKer-Jer Huang
    • G01F1/19
    • G01F1/3227Y10T137/224
    • A fluidic oscillator includes an oscillator body having two attachment walls defining an oscillating chamber therebetween, an inlet duct communicatively extended from the oscillating chamber for guiding a flow of fluid entering into the oscillating chamber, an outlet duct communicatively extended from the oscillating chamber for guiding the flow of fluid exiting from the oscillating chamber, a flow splitter provided at the outlet duct to communicate with the oscillating chamber, and two feedback channels communicating with the oscillating chamber. Each of the attachment walls has an upstream portion and a downstream portion integrally extended therefrom as a step shouldering manner to form a modulating shoulder for modulating an oscillation of the flow within the oscillation chamber so as to stabilize the flow of the fluid to pass through the oscillator body.
    • 流体振荡器包括:振荡器体,其具有在其间限定振荡室的两个连接壁,从振荡室通信地延伸的入口管,用于引导进入振荡室的流体流;从振荡室通信地延伸的出口管,用于引导 从振荡室流出的流体流,设置在出口管道处以与振荡室连通的分流器,以及与振荡室连通的两个反馈通道。 每个附接壁具有作为台阶承载方式一体地延伸的上游部分和下游部分,以形成用于调节振荡室内的流动的振荡的调制肩部,以便稳定流体流过 振荡器体。
    • 30. 再颁专利
    • Fluidic oscillator with resonary inertance and dynamic compliance circuit
    • 具有谐振惯性和动态兼容电路的流体振荡器
    • USRE31683E
    • 1984-09-25
    • US489674
    • 1983-04-28
    • Peter Bauer
    • Peter Bauer
    • B05B1/08F15C1/22
    • F15C1/22B05B1/08Y10T137/2104Y10T137/2185Y10T137/224
    • The fluidic oscillator consists of a resonant fluid circuit having a fluid inertance and a dynamic fluid compliance. The inertance is a conduit interconnecting two locations of a chamber on each side of a working fluid jet issuing into one end of the chamber, the inertance conduit serving to transfer working fluid between the two locations. Through one or more output orifices located approximately at the opposite end of the chamber, the fluid exits from a chamber exit region which is shaped to facilitate formation of a vortex (the dynamic compliance) from the entering fluid. The flow pattern in the chamber and particularly the vortex in the chamber exit region provide flow aspiration on one side and surplus of flow on the opposite side of the chamber, which effects accelerate and respectively decelerate the fluid in the inertance conduit such as to cause reversal of the vortex after a time delay given by the inertance. The vortex in the chamber exit region will thus cyclically alternate in velocity and direction of rotation to direct outflow through the output orifice such as to produce a cyclically repetitive side-to-side sweeping stream our spray pattern whose direction is determined, at any instant in time, as a function of the vectorial sum, at the output orifice, of the tangential vortex flow spin velocity vector and the static pressure vector as well as the dynamic pressure component, both directed radially from the vortex. By changing these parameters by suitable design measures and operating conditions and by appropriately configuring the oscillator, sweep angle, oscillation frequency, distribution, outflow velocity, break up into droplets, etc. can be readily controlled over large ranges.