The simultaneous effects of nanoparticles and ultrasonic vibration on inlet turbulent flow: An experimental study

The simultaneous effects of nanoparticles and ultrasonic vibration on inlet turbulent flow: An experimental study

•The pressure drop increase related to nanoparticle reduces in the ultrasonic field.•Increasing the Reynolds number leads to decrease of positive ultrasonic vibration effects.•The positive ultrasonic effects are bolder in higher nanoparticle volume fractions. In the current study, the effects of the...

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Bibliographic Details
Published in:Applied thermal engineering Vol. 146; pp. 268 - 277
Main Authors: Amiri Delouei, A., Sajjadi, H., Izadi, M., Mohebbi, R.
Format: Journal Article
Language:English
Published: Oxford Elsevier Ltd 05-01-2019
Elsevier BV
Subjects:
Design factors
Experimental study
Flow velocity
Fluid dynamics
Fluid flow
Heat exchangers
Heat transfer
Heat transfer enhancement
Measuring instruments
Nanofluid
Nanofluids
Nanoparticles
Pressure drop
Pressure effects
Reynolds number
Turbulent flow
Ultrasonic technology
Ultrasonic vibration
Vibration
Vibration measurement
Heat transfer enhancement
Turbulent flow
Experimental study
Nanofluid
Ultrasonic vibration
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Summary:•The pressure drop increase related to nanoparticle reduces in the ultrasonic field.•Increasing the Reynolds number leads to decrease of positive ultrasonic vibration effects.•The positive ultrasonic effects are bolder in higher nanoparticle volume fractions. In the current study, the effects of the ultrasonic vibration and nanoparticles on the pressure drop and heat transfer enhancement of inlet turbulent flow are experimentally investigated. Two important factors in the design of heat exchangers, namely, heat transfer improvement and pressure drop, have been considered at different nanoparticle volume fractions, ultrasonic power levels, and flow rates. Existing experiential correlations are utilized to ensure the accuracy of the measurement instruments. It is observed that the effects of ultrasound vibration are more pronounced on the lower Reynolds number as well as the higher nanoparticle volume fraction. The result indicates that the ultrasonic vibrations could reduce the negative effect of pressure drop and improve the positive effect of heat transfer enhancement caused by nanoparticles up to 15.27% and 11.37%, respectively. The effect of ultrasonic power level variation is also bolder in more concentrated nanofluids and lower flow rates. The results of this work will be useful for designing future-oriented vibrating heat exchangers that also have the ability to work with nanofluid.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2018.09.113