Advanced Iterative Procedures for Solving the Implicit Colebrook Equation for Fluid Flow Friction
Author(s): |
Pavel Praks
Dejan Brkić |
---|---|
Medium: | journal article |
Language(s): | English |
Published in: | Advances in Civil Engineering, 2018, v. 2018 |
Page(s): | 1-18 |
DOI: | 10.1155/2018/5451034 |
Abstract: |
The empirical Colebrook equation from 1939 is still accepted as an informal standard way to calculate the friction factor of turbulent flows (4000 < Re < 108) through pipes with roughness between negligible relative roughness (ε/D ⟶ 0) to very rough (up toε/D = 0.05). The Colebrook equation includes the flow friction factorλin an implicit logarithmic form,λbeing a function of the Reynolds number Re and the relative roughness of inner pipe surfaceε/D:λ = f(λ, Re,ε/D). To evaluate the error introduced by the many available explicit approximations to the Colebrook equation,λ ≈ f(Re,ε/D), it is necessary to determinate the value of the friction factorλfrom the Colebrook equation as accurately as possible. The most accurate way to achieve that is by using some kind of the iterative method. The most used iterative approach is the simple fixed-point method, which requires up to 10 iterations to achieve a good level of accuracy. The simple fixed-point method does not require derivatives of the Colebrook function, while the most of the other presented methods in this paper do require. The methods based on the accelerated Householder's approach (3rd order, 2nd order: Halley's and Schröder's method, and 1st order: Newton–Raphson) require few iterations less, while the three-point iterative methods require only 1 to 3 iterations to achieve the same level of accuracy. The paper also discusses strategies for finding the derivatives of the Colebrook function in symbolic form, for avoiding the use of the derivatives (secant method), and for choosing an optimal starting point for the iterative procedure. The Householder approach to the Colebrook' equations expressed through the Lambert W-function is also analyzed. Finally, it is presented one approximation to the Colebrook equation with an error of no more than 0.0617%. |
Copyright: | © 2018 Pavel Praks et al. |
License: | This creative work has been published under the Creative Commons Attribution 4.0 International (CC-BY 4.0) license which allows copying, and redistribution as well as adaptation of the original work provided appropriate credit is given to the original author and the conditions of the license are met. |
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10236480 - Published on:
11/12/2018 - Last updated on:
02/06/2021