Potable water in Tunisia has well defined characteristics. Thus, the Water researches and Technologies Centre-Borj Cedria mainly processing Natural Waters Laboratory, has worked on the physic-chemical quality of the water. As the Higher Institute of Agronomy-chott mariem have studied the phenomena associated with flows. For this work shows that natural water flows that can be generated in a pipeline.
During operation of agricultural pumps (centrifugal pumps), the speed of the electric motor increases from zero to the permanent regime speed. This change in regime influences the flow of the hydraulic installation and forced it to follow the starting dynamic law of the motor. Under the effect of the friction force, due to the fluid viscosity, the transient regime is dumped until reaching the normal operating conditions. In this work, we study this phenomenon and see the influence of the pump startup on the hydraulic behaviour of one dimensional flow throw a cylindrical pipe of linear elastic behaviour. The pipe is connected to constant level reservoir at the downstream end. The problem is governed by a two coupled linear hyperbolic partial differential equations which are the equations of continuity and motion. The mathematical model is solved by the method of characteristics where at the upstream end, that is, at the pump station, the boundary condition is given by the differential equation for speed change of the pump motor. A theoretical relationship is introduced to express the motor torque in terms of the time. At the downstream end the discharging reservoir is assumed to be at a constant level. The computed head and discharge time curves, caused by the starting of the pump, are plotted at some cross sections of the pipe. The results show that the evolution of the hydraulic variables is well influenced by the applied motor torque.

Wylie, E.B., Streeter, V.L., 1993. Fluid transients in Systems. Prentice Hall, Englewood Cliffs, N.J.

Frelin, M., 2003. Coup de bélier. Les techniques de l’Ingénieur BM 4176, 1-27.

Wiggert, D.C., Tijsseling, A.S., 2001. Fluid transients and fluid-structure interaction in flexible liquid-filled piping. ASME, Applied Mechanics Reviews 54, 455-481.

Streeter, V.L., Wylie, E.B., 1983. Hydraulic transients. F.E.B. Press, Ann Arbor.

Fox, J.A., 1977 Hydraulic Analysis of Unsteady Flow in Pipe Networks. The Mac Millan Press LTD., London.

Hadj-Taïeb, E., Lili, T., 1999. The Numerical Solution of the Tansient Two-Phase Flow in Rigid Pipelines. International Journal For Numerical Methods in Fluids 29, 501-514.

Hadj-Taïeb, E., Lili, T., 2000. Validation of hyperbolic model for water-hammer in deformables pipes. ASME, Journal of fluids engineering 122, 57-64.

Roberson, J.A., Cassidy, J.J., Chandhry, M.H., 1995. Hydraulic engineering.

Samani, H.M.V., Khayatzadeh, A., 2002. Transient flow in pipe networks. Journal of Hydraulic Research 40, No 5, 637-644.

Schulhof, P., 1991. Les stations de pompage d’eau. Lavoisier-Tec & Doc, Paris.

El Badsi, B., Guermazi, A., Masmoudi, A., 2007. On the Comparaison Between Different Space Vector PWM Strategies Implemented in FSTPI-Fed Induction Motor Drives. Computation and Mathematics in Electrical and Electronic Engineering (COMPEL) 26.

Thomson, W.T., 1972. Theory of vibration with applications. Prentice-Hall, Inc. Englewood Cliffs, New Jersey.

Jlali, A., Hadj-Taib, E., Thirriot, C., 2005. Algorithme simplifié de calcul de phénomènes de propagation d’ondes dans les systèmes de conduites avec embranchement, la Houille Blanche. Revue Internationale de L’eau, N°1, 81-89.

Li, W.H., 1966. Differential equations of hyperbolic transients, dispersion, and groundwater flow, Mathematical methods in Water resources, Prentice-Hall, Inc.

Nehari, T., Tefiani, L., Nehari, D., Wall-models for LES of channel flows, (2012) International Review of Mechanical Engineering (IREME), 6 (5), pp. 1005-1010.