Experimental and numerical analysis of hydraulic transients in PVC pipes

BHR Group - Surge Analysis - System Design, Simulation, Monitoring and Control, 10th International Conference on Pressure Surges

Volumn , Issue , 2008, Pages 317-332

  Soares, A K ^a   Covas, D I C ^a   Reis, L F R ^b  

^a INSTITUTO SUPERIOR TÉCNICO   (Portugal)

^b UNIVERSITY OF SÃO PAULO   (Brazil)

Author keywords

Damping effects; Experimental data; Polyvinyl chloride pipes; Water hammer

Indexed keywords

ABS RESINS; BOUNDARY CONDITIONS; BOUNDARY VALUE PROBLEMS; ELASTIC MODULI; ENERGY DISSIPATION; EXPERIMENTS; FRICTION; HYDRAULICS; MECHANICAL ENGINEERING; MECHATRONICS; NUMERICAL ANALYSIS; PIPE; PIPE FLOW; PLASTIC PIPE; PLASTIC PRODUCTS; RHEOLOGY; TRANSIENTS; TWO PHASE FLOW; UNSTEADY FLOW; WATER PIPELINES;

DAMPING EFFECTS; DYNAMIC EFFECTS; EXPERIMENTAL AND NUMERICAL ANALYSIS; EXPERIMENTAL DATA; EXPERIMENTAL FACILITIES; HYDRAULIC TRANSIENT MODELS; HYDRAULIC TRANSIENT SOLVERS; HYDRAULIC TRANSIENTS; MECHANICAL BEHAVIOURS; NUMERICAL RESULTS; OBSERVED DATUMS; POLYVINYL CHLORIDE PIPES; PVC PIPES; RESEARCH WORKS; RHEOLOGICAL BEHAVIOURS; TRANSIENT PRESSURE WAVES; TRANSIENT PRESSURES; UNSTEADY FRICTIONS;

POLYVINYL CHLORIDES;

EID: 56149109328     PISSN: None     EISSN: None     Source Type: Conference Proceeding    
DOI: None     Document Type: Conference Paper

References (33)

1. Meissner, E. and Franke, G. (1977). "Influence of Pipe Material on the Dampening of Waterhammer." Proceedings of the 17th Congress of the International Association for Hydraulic Research, IAHR, Baden-Baden, F.R. Germany.
2. Gaily, M., Güney, M., and Rieutord, E. (1979). "An Investigation of Pressure Transients in Viscoelastic Pipes." Journal of Fluids Engineering, Trans. ASME, 101, 495-499.
3. Rieutord, E. (1982). "Transients Response of Fluid Viscoelastic Lines." Journal of Fluids Engineering, Trans. ASME, 104, 335-341.
4. Covas, D., Stoianov, I., Mano, J., Ramos, H., Graham, N., and Maksimovic, C. (2004). "The Dynamic Effect of Pipe-Wall Viscoelasticity in Hydraulic Transients. Part I - Experimental Analysis and Creep Characterization." Journal of Hydraulic Research, 42(5), 516-530.
5. Covas, D., Stoianov, I., Mano, J., Ramos, H., Graham, N., and Maksimovic, C. (2005). "The Dynamic Effect of Pipe-Wall Viscoelasticity in Hydraulic Transients. Part II - Model Development, Calibration and Verification." Journal of Hydraulic Research, 43(1), 56-70.
6. Brunone, B., Golia, U. M., and Greco, M. (1991). "Modelling of Fast Transients by Numerical Methods." Proc. Int. Conf. on Hydraulic Transients with Water Column Separation (9th and last round Table of IAHR Group), Valencia, Spain, 273-281.
7. Vitkovsky, J. P., Lambert, M. F., and Simpson, A. R. (2000). "Advances in unsteady friction modelling in transient pipe flow." 8th International Conference on Pressure Surges - Safe Design and Operation of Industrial Pipe Systems, BHR Group Ltd., Publication No. 39, Suffolk, UK, 471-498.
8. Rossman, L. A. (2000). "EPANET 2 - Users Manual." United States Environmental Protection Agency (US-EPA), Water Supply and Water Resources Division, National Risk Management Research Laboratory, Cincinnati, USA.
9. Franke, G. and Seyler, F. (1983). "Computation of Unsteady Pipe Flow with Respect to Viscoelastic Material Properties." Journal of Hydraulic Research, 21(5), 345-353.
10. Suo, L. and Wylie, E. B. (1990). "Complex Wave Speed and Hydraulic Transients in Viscoelastic Pipes." Journal of Fluids Engineering, Trans. ASME, 112, 496-500.
11. Güney, M. (1983). "Waterhammer in Viscoelastic Pipes where Cross-section Parameters are Time-Dependent." Proceedings of the 4th International Conference on Pressure Surges, BHRGroup, Bath, England, 189-204.
12. Rachid, F. B. F. and Sruckenbruck, S. (1990). "Transients in Liquid and Structure in Viscoelastic Pipes." Proc. 6th Int. Conf. on Pressure Surges, BHRGroup Ltd, Cranfield, UK, 69-84.
13. Pezzinga, G. (2002). "Unsteady Flow in Hydraulic Networks with Polymeric Additional Pipe." Journal of Hydraulic Engineering, ASCE, 128(2), 238-244.
14. Daily, J. W., Hankey, Jr. W. L., Olive, R. W., and Jordan, Jr. J. M. (1956). "Resistance Coefficients for Accelerated and Decelerated Flows through Smooth Tubes and Orifices." Journal of Basic Engineering, Trans. ASME, Series D, 78(7), 1071-1077.
15. Zielke, W. (1968). "Frequency-dependent friction in transient pipe flow." Journal of Basic Engineering, Trans. ASME, Series D, 90(1), 109-115.
16. Trikha, A. K. (1975). "An efficient method for simulating frequency-dependent friction in transient liquid flow." Journal of Fluids Engineering, Trans. ASME, 97(1), 97-105.
17. Vardy, A. E., Hwang, K. L., and Brown, J. (1993). "A weighting function model of transient turbulent pipe friction." Journal of Hydraulic Research, 31(4), 533-548.
18. Vardy, A. E. and Brown, J. (2004). "Efficient Approximation of Unsteady Friction Weighting Functions." Journal of Hydraulic Engineering, ASCE, 130(11), 1097-1107.
19. Ramos, H., Borga, A., Covas, D., and Loureiro, D. (2004). "Surge damping analysis in pipe systems: modelling and experiments." Journal of Hydraulic Research, 42(4), 413-425.
20. Vardy, A. E. and Hwang, K. L. (1991). "A characteristic model of transient friction in pipes." Journal of Hydraulic Research, 29(5), 669-684.
21. Eichinger, P. and Lein, G. (1992). "The influence of friction on unsteady pipe flow." Proceedings of the International Conference on Unsteady Flow and Fluid Transients, Balkema, Rotterdam, 41-50.
22. Brunone, B., Golia, U. M., and Greco, M. (1995). "Effects of Two-Dimensionality on Pipe Transients Modelling." Journal of Hydraulic Engineering, ASCE, 121(12), 906-912.
23. Pezzinga, G. (2000). "Evaluation of Unsteady Flow Resistances by Quasi-2D and ID Models." Journal of Hydraulic Engineering, ASCE, 126(10), 778-785.
24. Zhao, M. and Ghidaoui, M. S. (2003). "Efficient Quasi-Two- Dimensional Model for Water Hammer Problems." Journal of Hydraulic Engineering, ASCE, 129(12), 1007-1013.
25. Chaudhry, M. H. (1987). Applied Hydraulic Transients, Litton Educational Publishing Inc., Van Nostrand Reinhold Co, New York, USA.
26. Almeida, A. B. and Koelle, E. (1992). Fluid Transients in Pipe Networks, Computational Mechanics Publications, Elsevier Applied Science, Southampton, UK.
27. Wylie, E. B. and Streeter, V. L. (1993). Fluid Transients in Systems, Prentice Hall, Englewood Cliffs, N.J..
28. Bughazem, M. B. and Anderson, A. (1996). "Problems with Simple Models for Damping in Unsteady Flow." Proc. 7th Int. Conf. on Pressure Surges and Fluid Transients in Pipelines and Open Channels, BHR Group Ltd, Harrogate, England, 537-549.
29. Aklonis, J. J. and MacKnight, W. J. (1983). Introduction to Polymer Viscoelasticity, John Wiley & Sons, New York, USA.
30. Soares, A. K., Covas, D. I. C., and Reis, L. F. R. (2008). "Analysis of PVC Pipe-Wall Viscoelasticity during Water Hammer." Journal of Hydraulic Engineering, ASCE. (Accepted for publication)
31. Soares, A. K. (2007). "Leak Detection and Calibration of Transient Hydraulic System Models." PhD, São Carlos School of Engineering, University of São Paulo, Brazil. (In Portuguese)
32. Ghidaoui, M. S., Axworthy, D. H., Zhao, M., and McInnis, D. A. (2001). "Closure to 'Extended thermodynamics derivation of energy dissipation in unsteady pipe flow'." Journal of Hydraulic Engineering, ASCE, 127(10), 888-890.
33. Vitkovsky, J. P., Bergant, A., Simpson, A. R., and Lambert, M. F. (2006). "Systematic Evaluation of One-Dimensional Unsteady Friction Models in Simple Pipelines." Journal of Hydraulic Engineering, ASCE, 132(7), 696-708.