Numerical analysis of fluid hammer in helical pipes considering non-Newtonian fluids

Abstract

This study focuses on a 3D CFD analysis of the laminar fast transient flow of non-Newtonian fluids through helical pipes. Classical simulations of fluid hammer do not deal with the pipeline helicity and non-Newtonian characteristics of the fluid, while the present work addresses those features. To this end, ANSYS FLUENT is used for simulation of the 3D domain and the power-law model is employed to accommodate the non-Newtonian behavior of the fluid. Effects of the pipe wall elasticity and compressibility of the working fluid are taken into account through a modified bulk modulus elasticity of the fluid using a UDF code. The results of the three-dimensional numerical analysis followed herein demonstrate good agreement with the available experimental data, and they show that non-Newtonian properties of the fluid significantly influence the pressure head response, velocity and shear stress profiles, and also the strength of the formed secondary flows. At the first stage of the fluid hammer, where the maximum deviation arises, the magnitude of the wall shear stress at the pipe midpoint for the shear-thinning and shear thickening fluids are respectively 67.7% lower and 200% higher than the Newtonian fluid. Furthermore, the average magnitude of the axial vorticity over the upper half of the pipe cross-section area for the shear-thinning and shear-thickening fluids are respectively 65.5% lower and 111.7% upper than the Newtonian case.