Effect of geometrical parameters on flow-switching frequencies in 3D printed fluidic oscillators containing different liquids

Effect of geometrical parameters on flow-switching frequencies in 3D printed fluidic oscillators containing different liquids

•Liquid-based single feedback loop fluidic oscillators have been characterised.•Switching frequencies of 2–22Hz were produced in the range of Re=600–12,000.•The frequency was mainly dependent on flow rate for viscosities of 1.00–4.37mm2/s.•No oscillations occurred using liquid viscosities of 29.8 an...

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Veröffentlicht in:Chemical engineering research & design 2017-01, Vol.117, p.228-239
Hauptverfasser: McDonough, J.R., Law, R., Kraemer, J., Harvey, A.P.
Format: Artikel
Sprache:eng
Schlagworte:
3-D printers
3D printing
Angles (geometry)
Convergence
Feedback loops
Flow switching
Flow velocity
Fluidic oscillator
Frequencies
Glycerol-Water
Horizontal orientation
Nozzles
OBR
Oscillation
Oscillators
Parameters
Plug flow
Studies
Switching
Three dimensional flow
Three dimensional printing
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container_title Chemical engineering research & design
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creator McDonough, J.R.
Law, R.
Kraemer, J.
Harvey, A.P.
description •Liquid-based single feedback loop fluidic oscillators have been characterised.•Switching frequencies of 2–22Hz were produced in the range of Re=600–12,000.•The frequency was mainly dependent on flow rate for viscosities of 1.00–4.37mm2/s.•No oscillations occurred using liquid viscosities of 29.8 and 75.9mm2/s.•The splitter distance had the greatest effect on the frequencies. There is limited information available regarding fluidic oscillator design for liquid phase applications. In this paper, the results of a simple parametric study investigating the effects of seven geometrical parameters on the flow-switching frequencies produced in 3D printed single feedback loop bistable oscillators are reported for a variety of glycerol–water mixtures. The most consequential parameter was the splitter distance (distance between the power nozzle and two outlet streams). Reducing the splitter distance from 10mm to 5mm produced higher frequencies at the same flow rate. The angle between the outlet channels was also important, with wider angles (18–24°) producing slightly higher frequencies. Feedback loop widths of 4mm and greater did not produce flow switching. Other factors that inhibited oscillations were reducing the inlet zone length from 32mm to 22mm and changing the feedback channel orientation from horizontal to vertical. Increasing the convergence length of the power nozzle (from 5 to 25mm) and changing the feedback loop length (from 101 to 113mm) did not greatly affect the frequencies obtained. Overall, frequencies of 2–22Hz were produced for kinematic viscosities of 1.00–4.37mm2/s, in the range of Re=600–12,000.
doi_str_mv 10.1016/j.cherd.2016.10.034
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Increasing the convergence length of the power nozzle (from 5 to 25mm) and changing the feedback loop length (from 101 to 113mm) did not greatly affect the frequencies obtained. 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There is limited information available regarding fluidic oscillator design for liquid phase applications. In this paper, the results of a simple parametric study investigating the effects of seven geometrical parameters on the flow-switching frequencies produced in 3D printed single feedback loop bistable oscillators are reported for a variety of glycerol–water mixtures. The most consequential parameter was the splitter distance (distance between the power nozzle and two outlet streams). Reducing the splitter distance from 10mm to 5mm produced higher frequencies at the same flow rate. The angle between the outlet channels was also important, with wider angles (18–24°) producing slightly higher frequencies. Feedback loop widths of 4mm and greater did not produce flow switching. Other factors that inhibited oscillations were reducing the inlet zone length from 32mm to 22mm and changing the feedback channel orientation from horizontal to vertical. Increasing the convergence length of the power nozzle (from 5 to 25mm) and changing the feedback loop length (from 101 to 113mm) did not greatly affect the frequencies obtained. 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source ScienceDirect Journals (5 years ago - present)
subjects 3-D printers
3D printing
Angles (geometry)
Convergence
Feedback loops
Flow switching
Flow velocity
Fluidic oscillator
Frequencies
Glycerol-Water
Horizontal orientation
Nozzles
OBR
Oscillation
Oscillators
Parameters
Plug flow
Studies
Switching
Three dimensional flow
Three dimensional printing
title Effect of geometrical parameters on flow-switching frequencies in 3D printed fluidic oscillators containing different liquids
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