Water Flow Visualization And Velocity Measurement Using Hydrogen Bubble Generation Technique In Low Speed Open Channel
محتوى المقالة الرئيسي
الملخص
Visualization of water flow around different bluff bodies at different Reynolds number ranging (1505 - 2492) was realized by designing and building a test rig which contains an open channel capable to ensure water velocity range (4-8cm/s) in this channel. Hydrogen bubbles generated from the ionized water using DC power supply are visualized by a light source and photographed by a digital camera. Flow pattern around a circular disk of (3.6cm) diameter and (3mm) thickness, a sphere of (3.8cm) diameter and a cylinder of
(3.2cm) diameter and (10cm) length are studied qualitatively. Parameters of the vortex ring generated in the wake region of the disk and the separation angle of water stream lines from the surface of the sphere are plotted versus Reynolds number. Proper empirical formulas are investigated to describe the behavior of vortex ring parameters and separation angle versus Reynolds number. Vortex growth history in the wake region of the cylinder is identified by analyzing the photographs extracted from the digital camera used for
photography purposes. Water velocity measurement in the upstream region and near the edge of the disk is conducted at different Reynolds number by measuring the length of Hydrogen bubble pulse streaks generated in the upstream region of the disk using electronic pulse generator circuit. Special electronic circuit is designed and fabricated to cut off the applied DC voltage. The calibration of the designed pulse generator is conducted using the proper oscilloscope device. The pictures extracted from the digital camera are used for analyzing the generated Hydrogen pulses.
تفاصيل المقالة
كيفية الاقتباس
تواريخ المنشور
المراجع
Burley, R., and Grigg, P.J., "A Solid State Pulser for the Hydrogen Bubble Flow Visualization Technique". J.Phys.E:Sci.Instrum, Vol.3, 1970, PP.1018-1020.
Clutter, D.W. and Smith, A.M.O., "Flow Visualization by Electrolysis of Water", Aerospace Eng, Vol. 20, 1961, pp. 24-27.
Davis, W., and Fox, R.W., "An Evaluation of the Hydrogen Bubble Technique for the Quantitative Determination of Fluid Velocities within Clear Tubes", Journal of Basic Engineering, Vol. 89, 1967, PP. 771-781.
Ellis, C.R. and Stefan, H.G., "Development of Hydrogen Bubble Velocity Meter ", Journal of Hydraulic Engineering, Vol.112, 1986, pp. 59-64.
Garcia, A. Solano, J.P., Vicente, P.G., and Viedma, A., "Flow Pattern Assessment in Tubes with Wire Coil Inserts in Laminar and Transition regimes ", International Journal of Heat and Fluid Flow, Vol. 28, 2007, PP. 516-525.
Hiramoto R. and Higuchi H., "Vortex Shedding behind a Non Parallel pair of Circular Cylinders "Journal of Fluids and Structures, Vol. 18, 2003, PP. 131-143.
Kline, S. J., Reynolds W.C., Shraub F.A. and Runstadler P.W., "The Structure of Turbulent Boundary Layer", Journal of Fluid Mechanics, Vol. 30, 1967, pp. 741.
Mahir, N., and Rokwell, D. ,"Vortex Formation from a Forced System of Two Tandem Arrangement Cylinders ", Journal of Fluids and Structures, Vol.10, 1996, PP.473-489.
Pipe, C.J. and Monkewtiz, P.A., "Vortex Shedding in Flows of Dilute polymer solutions", Journal of Non-Newtonian Fluid Mechanics, Vol. 139, 2006, pp. 54-67.
Shraub, F.A., Kline, S.J., Henry, J., Runstadler, P.W., and Littell , JR. A. "Use of Hydrogen Bubbles for Quantitative Determination of Time-Dependent Velocity Fields in LowSpeed Water Flows", Journal of Basic Engineering, Vol. 87, 1965, PP. 429-444.
Strykowski, P.J., and Sreenivasan, K.R., "on the Formation and Suppression of Vortex Shedding at Low Reynolds Numbers ", Journal of Mechanics, Vol. 218, 1990, PP.71-107.