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Improved method for simulating transients of turbulent pipe flow

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EN
Abstrakty
EN
The paper presents the problem of modelling and simulation of transients during turbulent fluid flow in hydraulic pipes. The instantaneous wall shear stress on a pipe wall is presented in the form of integral convolution of a weighting function and local acceleration of the liquid. This weighting function depends on the dimensionless time and Reynolds number. Its original, very complicated mathematical structure is approximated to a simpler form which is useful for practical engineering calculations. The paper presents an efficient way to solve the integral convolution based on the method given by Trikha (1975) for laminar flow. An application of an improved method with the use of the Method of Characteristic for the case of unsteady flow (water hammer) is presented. This method is characterised by high efficiency compared to traditional numerical schemes.
PL
Artykuł przedstawia zagadnienie modelowania i symulacji przebiegów przejściowych podczas turbulentnego przepływu cieczy w przewodach ciśnieniowych. Chwilowe naprężenie styczne na ściance przewodu przedstawiono w postaci całki splotowej z funkcji wagi i przyspieszenia cieczy. Funkcja wagi dla naprężenia stycznego na ściance przewodu zależy od czasu bezwymiarowego i liczby Reynoldsa. Ma ona zawiłą postać matematyczną, dlatego aproksymowano ją do prostszej postaci, przydatnej do praktycznych obliczeń inżynierskich. Przedstawiono efektywny sposób rozwiązania całki splotowej, opierając się na metodzie podanej przez Trikha (1975) dla przepływu laminarnego. Podano zastosowanie ulepszonej metody symulacji naprężenia stycznego do metody charakterystyk podczas uderzenia hydraulicznego. Charakteryzuje się ona dużą efektywnością w stosunku do metody tradycyjnej.
Rocznik
Strony
135--158
Opis fizyczny
Bibliogr. 46 poz., rys.
Twórcy
autor
autor
Bibliografia
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  • 22. Rahl F.M., Barlamont J., 1996, Unsteady pipe flow simulations using unsteady friction flow formulae, 7th International Conference on Pressure Surges and Transients in Pipeline and Open Channels, BHR Group, Harrogate, UK, 313-322
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  • 24. Satlar A.M., Chaudhry M.H., Kassen A.A., 2008, Partial blockage detection in pipelines by frequency response method, Journal of Hydraulic Engineering, ASCE, 134, January, 76-89
  • 25. Satlar A.M., Dicherson J.R., Chaudhry M.H., 2009, Wavelet-Galerkin solution to the water hammer equations, Journal of Hydraulic Engineering, ASCE, 135, April, 283-295
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  • 28. Suzuki K., Taketomi T., Sato S., 1991, Improving Zielke’s method of simulating frequency-dependent friction in laminar liquid pipe flow, Journal of Fluids Engineering, Trans. ASME, 113, December, 569-573
  • 29. Trikha A.K., 1975, An efficient method for simulating frequency-dependent friction in transient liquid flow, Journ. of Fluids Eng., Trans. ASME, March, 97-105
  • 30. Vardy A.E., 1980, Unsteady flows: fact and friction, Proc. 3rd International Conference on Pressure Surges, Cantenbury, UK, 1-14
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  • 33. Vardy A.E., Brown J.M.B., 2003, Transient turbulent friction in smooth pipe flows, Journal of Sound and Vibration, 259, 5, 1011-1036
  • 34. Vardy A.E., Brown J.M.B., 2004, Transient turbulent friction in fully rough pipe flows, Journal of Sound and Vibration, 270, 233-257
  • 35. Vardy A.E., Brown J.M.B., 2007, Approximation of turbulent wall shear stress in highly transient pipe flows, Journal of Hydraulic Engineering, ASCE, November, 1219-1228
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  • 44. Zarzycki Z., Kudźma S., 2004, Simulations of transient turbulent flow in liquid lines using time-dependent frictional losses, The 9th International Conference on Pressure Surges, BHR Group, Chester, UK, 24-26 March, 439-455
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  • 46. Zielke W., 1968, Frequency-dependent friction in transient pipe flow, Journal of Basic Eng., Trans. ASME, March, 109-115
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BWM6-0005-0007
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