Twente mass and heat transfer water tunnel: Temperature controlled turbulent multiphase channel flow with heat and mass transfer

A new vertical water tunnel with global temperature control and the possibility for bubble and local heat and mass injection has been designed and constructed. The new facility offers the possibility to accurately study heat and mass transfer in turbulent multiphase flow (gas volume fraction up to 8...

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Bibliographic Details
Published in:Review of scientific instruments 2019-07, Vol.90 (7), p.075117-075117
Main Authors: Gvozdić, Biljana, Dung, On-Yu, van Gils, Dennis P. M., Bruggert, Gert-Wim H., Alméras, Elise, Sun, Chao, Lohse, Detlef, Huisman, Sander G.
Format: Article
Language:English
Subjects:
Channel flow
Chemical engineering
Chemical Sciences
Engineering Sciences
Fluid dynamics
Fluids mechanics
Fluoroscopic imaging
Heat
Heat flux
Heat transfer
Instrumentation and Detectors
Laser doppler velocimeters
Mass transfer
Mechanics
Multiphase flow
Particle image velocimetry
Particle tracking velocimetry
Physics
Saline solutions
Scientific apparatus & instruments
Stainless steels
Temperature control
Thermics
Turbulent flow
Two phase flow
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Summary:A new vertical water tunnel with global temperature control and the possibility for bubble and local heat and mass injection has been designed and constructed. The new facility offers the possibility to accurately study heat and mass transfer in turbulent multiphase flow (gas volume fraction up to 8%) with a Reynolds-number range from 1.5 × 104 to 3 × 105 in the case of water at room temperature. The tunnel is made of high-grade stainless steel permitting the use of salt solutions in excess of 15% mass fraction. The tunnel has a volume of 300 l. The tunnel has three interchangeable measurement sections of 1 m height but with different cross sections (0.3 × 0.04 m2, 0.3 × 0.06 m2, and 0.3 × 0.08 m2). The glass vertical measurement sections allow for optical access to the flow, enabling techniques such as laser Doppler anemometry, particle image velocimetry, particle tracking velocimetry, and laser-induced fluorescent imaging. Local sensors can be introduced from the top and can be traversed using a built-in traverse system, allowing, for example, local temperature, hot-wire, or local phase measurements. Combined with simultaneous velocity measurements, the local heat flux in single phase and two phase turbulent flows can thus be studied quantitatively and precisely.
ISSN:0034-6748
1089-7623
DOI:10.1063/1.5092967