On Dynamics of Acoustically Driven Bistable Fluidic Valves

Mair, Michael; Bacic, Marko; Ireland, Peter T.

doi:10.1115/1.4041890

Cited by 17 publications

(16 citation statements)

References 44 publications

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“…The bistability in flow is a phenomenon that the fluid can flow along one side and can be provoked to the other side and keep stable state, which occurs when the fluid flowing across tubes arranged in a characteristic pitch or through a slit. This flow behavior is highly lighted not only in academic researches but also in applications as the fluid amplifier, the fluid oscillator and the logic circuit [1] . This study adopts numerical simulation to study the bistable slit jet deflection under different temperature gradients in detail.…”

Section: Introductionmentioning

confidence: 99%

Temperature-driven Switching and Deflection of Bistable Flow Crossing Side- by-side Tubes

Shaobo¹,

Han²,

Du³

2022

Preprint

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Section: Introductionmentioning

confidence: 99%

Temperature-driven Switching and Deflection of Bistable Flow Crossing Side- by-side Tubes

Shaobo¹,

Han²,

Du³

2022

Preprint

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“…The regulating valve is an indispensable component in modern control systems, as it can control ow rate and stabilize pressure [1][2][3]. This valve is widely used in petrochemical, water conservancy, energy and other industrial sectors.…”

Section: Introductionmentioning

confidence: 99%

Comparative Analysis of Monitoring Methods for Vortex-induced Vibration of Multistage Pressure Reducing Valves

Chen

et al. 2021

Preprint

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In this paper, a multistage pressure reducing valve is presented. The main frequency of vortex-induced vibration is evaluated by monitoring the lift coefficient during vortex shedding and the pressure fluctuation formed after vortex shedding in the flow field. By comparative analysis of two different methods, the number of vortices is relatively small at small openings. Due to the limitations of the location and quantity of monitoring points, accurately locating the most active position where pressure fluctuation occurs is difficult. Monitoring the lift coefficient is more suitable to evaluate the main frequency of vortex-induced vibration. At medium and large openings, due to the increase in the number of vortices, the superposition effect of the pressure fluctuation and the influence of the flow channel shape is more obvious. Monitoring the pressure fluctuation is more appropriate to evaluate the main frequency of vortex-induced vibration the valve. Therefore, a combination of the two methods can more accurately evaluate the vortex-induced vibration characteristics of the valve. When monitoring pressure fluctuation, the position and number of monitoring points directly affect the evaluation accuracy. The pressure fluctuations around the outlet and the multilayer sleeve are more active. It is more meaningful to monitor the pressure fluctuation at these points. The main frequency of the pressure fluctuation at these points better reflects the vortex-induced vibration characteristics of the valve.

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“…However, unlike conventional flow control valves, neither of these approaches allows for controlled modulation of the output flow according to a desired reference trajectory. Piezo-fluidic amplifiers [14][15][16] rely on the fundamental physics of jet dynamics when subjected to sound injection in a transverse direction. The purpose of this paper is to demonstrate the effective closed-loop control of such dynamics thereby enabling continuous output flow modulation according to a desired output trajectory.…”

Section: Introductionmentioning

confidence: 99%

“…In this paper, we employ the same piezo actuation method as in [14] where a highly reliable piezo buzzer is used to deflect the jet inside a Coandă diverter causing the device to switch its state. However, the response of the device is limited in Mair et al [14][15][16] in applications that require strong synchronisation. In this paper we propose the use of closed-loop control to tackle both of these deficiencies by utilising pressure measurements from the total pressure tappings in the output channels as feedback signals (see Fig.…”

Section: Introductionmentioning

confidence: 99%

“…These have been utilised for a range of flow control applications from improving the effectiveness of a vertical tail [10,11] to noise control [12]. Another means to achieve both high bandwidth and high authority is by amplifying the effect of plasma or piezo actuators by switching fluidic diverters [13][14][15][16]. However, unlike conventional flow control valves, neither of these approaches allows for controlled modulation of the output flow according to a desired reference trajectory.…”

Section: Introductionmentioning

confidence: 99%

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Closed-loop control of a piezo-fluidic amplifier

Nicholls

Bacic

2018

2018 Flow Control Conference

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Fluidic valves based on the Coandă effect are increasingly being considered for use in aerodynamic flow control applications. A limiting factor is their variation in switching time, which often precludes their use. The purpose of this paper is to demonstrate the closed-loop control of a recently developed, novel piezo-fluidic valve that reduces response time uncertainty at the expense of operating bandwidth. Use is made of the fact that a fluidic jet responds to a piezo tone by deflecting away from its steady state position. A control signal used to vary this deflection is amplitude modulated onto the piezo tone. Using only a pressure measurement from one of the device output channels, an output-based LQG regulator was designed to follow a desired reference deflection, achieving control of a 90 ms −1 jet. Finally, the controller's performance in terms of disturbance rejection and response time predictability is demonstrated. Nomenclature Miscellaneous αFeed-forward gain (-) δx(t)State deviation from equilibrium (-) δx(t)State deviation estimate (-) δy(t)Output deviations from reference (-) δy ′ (t)Noisy measurement of δy (-) δy(t)Output deviation estimate (-) δu(t)Control input deviation from equilibrium (-) Φ yu (ω) Output-input cross-spectral density (dB/Hz)

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On Dynamics of Acoustically Driven Bistable Fluidic Valves

Cited by 17 publications

References 44 publications

Temperature-driven Switching and Deflection of Bistable Flow Crossing Side- by-side Tubes

Temperature-driven Switching and Deflection of Bistable Flow Crossing Side- by-side Tubes

Comparative Analysis of Monitoring Methods for Vortex-induced Vibration of Multistage Pressure Reducing Valves

Closed-loop control of a piezo-fluidic amplifier

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