Search engine for discovering works of Art, research articles, and books related to Art and Culture
ShareThis
Javascript must be enabled to continue!

Effects of Roughness on Turbulent Flow in Microchannels and Minichannels

View through CrossRef
The effect of roughness ranging from smooth to 24% relative roughness on laminar flow has been examined in previous works by the authors. It was shown that using a constricted parameter, εFP, the laminar results were predicted well in the roughened channels ([1],[2],[3]). For the turbulent regime, Kandlikar et al. [1] proposed a modified Moody diagram by using the same set of constricted parameters, and using the modification of the Colebrook equation. A new roughness parameter εFP was shown to accurately portray the roughness effects encountered in laminar flow. In addition, a thorough look at defining surface roughness was given in Young et al. [4]. In this paper, the experimental study has been extended to cover the effects of different roughness features on pressure drop in turbulent flow and to verify the validity of the new parameter set in representing the resulting roughness effects. The range of relative roughness covered is from smooth to 10.38% relative roughness, with Reynolds numbers up to 15,000. It was found that using the same constricted parameters some unique characteristics were noted for turbulent flow over sawtooth roughness elements.
Title: Effects of Roughness on Turbulent Flow in Microchannels and Minichannels
Description:
The effect of roughness ranging from smooth to 24% relative roughness on laminar flow has been examined in previous works by the authors.
It was shown that using a constricted parameter, εFP, the laminar results were predicted well in the roughened channels ([1],[2],[3]).
For the turbulent regime, Kandlikar et al.
[1] proposed a modified Moody diagram by using the same set of constricted parameters, and using the modification of the Colebrook equation.
A new roughness parameter εFP was shown to accurately portray the roughness effects encountered in laminar flow.
In addition, a thorough look at defining surface roughness was given in Young et al.
[4].
In this paper, the experimental study has been extended to cover the effects of different roughness features on pressure drop in turbulent flow and to verify the validity of the new parameter set in representing the resulting roughness effects.
The range of relative roughness covered is from smooth to 10.
38% relative roughness, with Reynolds numbers up to 15,000.
It was found that using the same constricted parameters some unique characteristics were noted for turbulent flow over sawtooth roughness elements.

Related Results

Two-Phase Flow Modeling in Microchannels and Minichannels
Two-Phase Flow Modeling in Microchannels and Minichannels
In the present paper, three different methods for two-phase flow modeling in microchannels and minichannels are presented. They are effective property models for homogeneous two-ph...
Microchannels and Minichannels: History, Terminology, Classification and Current Research Needs
Microchannels and Minichannels: History, Terminology, Classification and Current Research Needs
Microchannels and Minichannels are found in many biological systems providing very high heat and mass transfer rates in organs such as the brain, lung, liver and kidney. Many high ...
Experimental Study on the Influence of Surface Roughness on Laminar to Turbulent Flow Transition
Experimental Study on the Influence of Surface Roughness on Laminar to Turbulent Flow Transition
Models for how surface roughness influences laminar to turbulent flow have not been proven with experimental results in the moderate roughness zone which makes these models less us...
Effect of Surface Roughness on Gaseous Flow Through Microchannels
Effect of Surface Roughness on Gaseous Flow Through Microchannels
Abstract This paper presents an experimental investigation on nitrogen and helium flow through microchannels etched in silicon with hydraulic diameters between 10 an...
Numerical Investigation of Flow Boiling in Interconnected Microchannels at Varying Mass Fluxes
Numerical Investigation of Flow Boiling in Interconnected Microchannels at Varying Mass Fluxes
Interconnected microchannels (IMCs) in flow boiling have the advantages of optimized heat transfer performance, energy savings and high efficiency, compact size, and strong customi...
Shear and Pressure Driven Flow and Thermal Transport in Microchannels
Shear and Pressure Driven Flow and Thermal Transport in Microchannels
In many practical circumstances, the flow in microchannels is driven by moving surfaces that impart shear to the fluid. The shear may generate a pressure differential or the pressu...
Milling Microchannels in Monel 400 Alloy by Wire EDM: An Experimental Analysis
Milling Microchannels in Monel 400 Alloy by Wire EDM: An Experimental Analysis
This paper presents the results of an investigation on the capacity of wire electrical discharge machining (WEDM) to produce microchannels in the Nickel-based alloy, Monel 400. The...
Active Flow Control of Separated Turbulent Flow Over a Hump Using RANS, DES, and LES
Active Flow Control of Separated Turbulent Flow Over a Hump Using RANS, DES, and LES
Most practical flows in engineering applications are turbulent, and exhibit separation. Losses due to separation are undesirable because they generally have adverse effects on perf...

Back to Top