Optimizing a Trapezoidal Open-channel for Least Velocity Fluctuation during Overflow Using Mathematical Efficiency Criterion

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Applied Mathematical Sciences, Vol. 8, 2014, no. 140, 6979-6987 HIKARI Ltd, www.m-hikari.com http://dx.doi.org/10.12988/ams.2014.4864 Optimizing a Trapezoidal Open-channel for Least Velocity Fluctuation during Overflow Using Mathematical Efficiency Criterion John Wahome 1, Bitok J.K. 2, Lonyangapuo J.K., Nyamai Benjamin 4 and Kweyu Cleophas 5 1 (Corresponding author) Department of Mathematics, Laikipia University P.O. Box 441, Nyahururu, Kenya 2, Department of Mathematics and Computer Science University of Eldoret, P.O. Box 1125, Eldoret, Kenya 4,5 Department of Mathematics, Moi University P.O. Box 900, Eldoret, Kenya Copyright c 2014 John Wahome et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Abstract In open channels, fluid velocity increases with depth of flow. Sewers are particularly susceptible to overwhelming storm water velocities during rains. When flow velocities exceed a certain threshold, damage of channel by scouring may result, or, conversely, siltation of suspended matter. Channel design must optimize dimensions and shapes which both minimize cost, maximizing discharge in normal seasons and regulate the discharge to minimize velocity fluctuations during overflow. Depending on the designer s objectives, channel design involves numerous parameters, including the characteristics of construction materials and earthwork. Traditional methods such as Langrage multipliers, Sequential Quadratic Programming (SQP), Differential Evolution Algorithm (DEA), genetic algorithms, ant-colony optimization, and lately, metaheuristic algorithms are often used to minimize a cost function subject to channel cross-section. In this paper, using only the mathematical hydraulic efficiency criterion (other factors assumed optimum), a direct integro-differential

6980 John Wahome et al. technique is applied to determine the optimum trapezoidal channel design that additionally minimizes velocity fluctuations during excessive discharge. Keywords: Discharge, depth, top width, bottom width, area, wetted perimeter, hydraulic radius, Froude number, Manning equation, Chézy equation, channel slope, open channel, optimization, slope stability 1 Introduction The main characteristic of open-channel flow (which includes flow in partially full conduit) is that one surface of the flow is exposed to the atmosphere. Flow in a closed, full pipe, however, differs in various aspects with the open-channel flow, mainly in that the cross-section of the flow for open channels is not determined entirely by the solid boundaries, but is free to change without restraint, depending on other parameters of the flow. The free surface is usually subjected to atmospheric pressure (which is constant) and therefore, the flow is caused by the component of the weight of the liquid. As expected therefore, uniform open channel flow is accompanied by drop in the piezometric pressure, p + ρgz, but not a drop in the pressure at the free surface. See Wahome [7] for a synoptic comparison of the two flows. The commonest examples of natural channel flow are rivers and streams, while irrigation canals, flumes and spillways are artificial open channels. In practical channel hydrodynamics where conservation of resources is of prime importance, it is crucial to interrogate the issue of the most hydraulically optimum shape. This means the channel shape which allows maximum discharge for a fixed area, surface roughness and bed slope. All the common open channel formulas, including those of Chézy and Manning predict that for uniform flow with a given bed gradient, roughness and cross-sectional area, the mean velocity and discharge, Q - parameters which influence channel efficiency - all depend on the hydraulic mean depth, m, Massey, et al[8]. m is defined as the ratio of the flow area, A, to the wetted perimeter, P. The implication here is that the hydraulic efficacy of a channel will be predicated on the channelshape. Maximizing m, which is equivalent to minizing the wetted perimeter, will therefore maximize the discharge. Cost of lining material will also be minimized. Among the common channel designs, the semicircular shape has been found to possess the maximum hydraulic mean depth, Douglas,et al[9]. However, the consideration of other factors, such as angle of repose for loose granular banking material, cost of excavation and relative ease of construction make the semicircular shapes applicable only to small channels, leaving the trapezoidal shape more preferable in practice, Massey,et al[8]. Notably, rectangular and triangular channels are special cases of the trapezoidal channel. Hameed [4]

Optimizing a trapezoidal open-channel 6981 has studied rectangular canals with round bottoms and found them superior to trapezoidal channels. Even when the channel cross-sectional is trapezoidal, it is still important to determine the most economical trapezium, that is, the one giving the maximum discharge for a given amount of excavation, based on dimensions characteristics and side slopes. In this paper, the dimensional characteristics of the most economical trapezoidal channel with minimum velocity fluctuations (to minimize scouring or siltation Stephenson [14], Chow [10]), are derived progressively. It is assumed that the free surface fluid flow is steady, inviscid, incompressible, irrotational and neglects surface tension and viscosity. It is further assumed that the mathematical hydraulic efficiency is the only consideration, and that the trapezoidal channel is symmetric. The condition for the turning points, and hence the optimal dimensions, are obtained by maximizing the hydraulic mean depth function using integro-differential calculus. 2 Mathematical Formulation 2.1 Most economical trapezoidal channel section From the continuity equation (we state its convective form below), it is clear that discharge in a channel maximizes with velocity. (ρ = density, V = velocity, t=time) Dρ Dt + ρ V = 0 (2.1) The Chézy formula for discharge in steady uniform flow, which is Discharge = Q = AC (mi) (2.2) with i being a gradient function, A the cross-sectional area, m the hydraulic mean depth, and C the Chézy constant shows that with slope and surface roughness held constant, flow velocity maximizes with the hydraulic mean depth, m. Other formulae, such as Manning s confirm this fact. The most economical (or efficient) section of a channel is defined as one which gives the maximum discharge for a given amount of excavation, Rajput [1].

6982 John Wahome et al. A free surface B C η H θ O ζ E bottom surface θ F G Figure 1: Physical setting of the open-channel problem In the figure 1 above, AOF C represents the symmetric trapezoidal cross section of the open channel. We use an integration approach to determine the area of the cross-section of the flow (this method is versatile for other non-regular shapes, when need arises). We take the origin to be at O, to have with Area A = η y cot θ+ζ 0 y cot(π θ) dxdy (2.) y cot(π θ) x y cot θ + ζ (2.4) between the opposite banks of the channel. Since cot(π θ) = cot θ, the area evaluates to The wetted perimeter in the channel is A = ζη + η 2 cot θ (2.5) P = ζ + 2η cscθ (2.6) The hydraulic mean depth, m, which we need to maximize is m = A P = ζη + η2 cot θ ζ + 2 cscθ From equations (2.6) and (2.5) we note that = A ζ + 2η cscθ (2.7) ζ = A η η cot θ (2.8) so that equation (2.7) becomes m = A A η cot θ + 2η cscθ (2.9) η

Optimizing a trapezoidal open-channel 698 2.1.1 Optimum hydraulic radius and area We expect m to be maximum when the denominator of equation (2.9) is minimized (w.r.t. η). That is, when the wetted perimeter is minimum. This happens when ( A η η cot θ + 2η cscθ) η = ( A ) cot θ + 2cscθ = 0 (2.10) η2 with the attached (and obviously true) condition that 2 ( A η η cot θ + 2η cscθ) η 2 = 2A η > 0 (2.11) to guarantee that we have a minimum and not a maximum condition here. Equation (2.10) holds when A optm = (2cscθ cot θ)η 2 (2.12) with A optm representing the optimum area (i.e. area when the mean hydraulic depth is maximum). We now replace A in the equation (2.9), with the A optm of equation (2.10) to have the maximum hydraulic mean depth, m max, as m max = (2cscθ cot θ)η 2 (2cscθ cot θ)η 2 η η cot θ + 2η cscθ = η 2 (2.1) The last equation establishes that maximum efficiency for the symmetric trapezoidal channel obtains when m is half the level of free surface of the fluid from the channel bed. 2.1.2 Optimum polygonal shape and slope We wish to establish the optimum angle, θ and hence the best shape for the trapezoidal channel. We find the value of θ which minimizes the denominator of equation (2.9). We seek, That is therefore ( A η η cot θ + 2η cscθ) θ = 0 (2.14) η( csc 2 θ) + 2η( csc θ cot θ) = 0 (2.15) 1 sin θ (1 2 cos θ) = 0 θ = π (2.16)

6984 John Wahome et al. Clearly, the derivative 2 ( A η cot θ + 2η cscθ) η 2 θ [ = η 2 csc 2 θ[ ] 1 sin θ (1 cosθ)] + 2 csc θ cot2 θ (2.17) is positive-definite in the interval 0 < θ < π which confirms that the angle π of equation (2.16) occurs at a maximum point. This result confirms that the most economical angle of slope for a trapezoidal channel is π. With θ = π in figure 1, we note that the slanting sides OA = CF = 2 η = 4 m (2.18) by (2.1). Comparing equation (2.12) with (2.5) we have, (2 csc θ cos θ)η 2 = ζη + η 2 cot θ 2η csc π = ζ cot π (2.19) And therefore ζ = 2 η = 4 m (2.20) similar to equation (2.18). The results of equations (2.20) and (2.18) show that at the optimal channel dimensions,the base of the canal should be equal to the slanting side. This, together with the fact that θ = π proves that the most economical cross-sectional of a trapezoidal channel is a half hexagon. The various values for the first 8 polygons are tabulated in table below. Table 1: Efficiency values for the first 8 polygons with A = 100 and η = 50 Polygon s sides n Slope θ(rad) Wetted Perimeter P Efficiency 1 P 2.09495 146.75981 0.0068514 4 1.5707965 102.0000087 0.00980921 5 1.256672 90.90024054 0.011001071 6 1.047197667 88.6025408 0.01128658 7 0.897598 90.01129 0.011107269 8 0.7859825 9.4215265 0.010704191 9 0.69811778 97.9846981 0.010205675 10 0.628186 10.110595 0.009679506 The graph below (figure 2) compares the relative efficiencies for polygonal channels of side n, n 50. We have computed canal efficiency in terms of the size of reciprocal 1, P being the wetted perimeter(see equation (2.9). We P have used the provisional values A = 100 and η = 50. Besides peaking at n = 6 and therefore vindicating that the hexagon is the

Optimizing a trapezoidal open-channel 6985 most efficient c-sectional design, the graph reveals interesting information, for instance that a 7-sided (heptagonal) cross-section at 0.011107269 is more efficient than a 5-sided (pentagonal) one at 0.011001071. relative efficiency 1 P polygon s sides, n Figure 2: Relative efficiencies for n-sided trapezoidal channels 2.2 Minimum velocity fluctuation design Having established the relative dimensions of the most economical trapezoidal channel, we now wish to construct the section above the free surface of the fluid in such a way that an overflow will not cause a change in velocity. See figure below. Least velocity fluctuation section x = 0 The optimized Trapezoidal Channel Section 2x + 2 dx 2x dy y = 0 ( 2 _ m, 0) Figure : Least velocity fluctuation section of channel Since the velocity is influenced only by the hydraulic mean depth m = A P, we can suppress velocity fluctuations by keeping m constant. thus, m = da dp = 2xdy 2 dx 2 + dy 2 [ dx 2 + dy 2] m 2 = x 2 dy 2 (2.21)

6986 John Wahome et al. Which simplifies to [dy ] 2 m 2 = dx x 2 m y = 2 m 2 x2 m dx = m [ x ] 2 cosh 1 + k (2.22) m In view of the equations (2.18), (2.1) and (2.20), BC in Figure 1 has length 2 m. Since this constant velocity section starts just above the optimized trapezium, we substitute the coordinates ( 2 m, 0) into the equation (2.22) to find the value of k as, k = m cosh 1 ( 2 ). Therefore, the channel walls of the minimum fluctuation section should bear the relationship Conclusion y = m cosh [ 1 x ] m cosh 1 ( 2 ) (2.2) m For a trapezoidal section open-channel flow with base width ζ, fluid depth η and hydraulic mean depth m, the optimum conditions for maximum discharge, and constant velocity during overflow are summarized below. Table 2: Summary of optimal values Polygon Slope θ(deg) η Slant Side ζ Hexagon 60 0 2m 4 m 4 m It was also found that a heptagonal channel-base design would give better performance than a pentagonal one, and that the equation of the constant velocity section is y = m cosh [ ] 1 x m m cosh 1 ( 2 ). References [1] R.K. Rajput, Fluid Mechanics and Hydraulic Machines, S. Chand and Company, New Delhi, (2006). [2] D. C.Froehlich, Width and Depth-Constrained Best Trapezoidal Section, Journal of Irrigation and Drainage Engineering, 4 (1994) 828-85 [] B. Aksoy, Optimal Channel Design, MSc. thesis, Middle East Technical University.(200) [4] A.T.Hameed, Optimal Design of Round Bottomed Triangle Channels, Tikrit Journal of Eng.Sciences (2010) 1-4.

Optimizing a trapezoidal open-channel 6987 [5] S. M. Easa, A. R. Vatankhah b and A. O. Abd El Halim, A simplified direct method for finding optimal stable trapezoidal channels, International Journal of River Basin Management 2 (2011), 85-29 [6] E.T. Mustafa,Yurdusev M.A., Optimization of Open Channels by Differential Evolution Algorithm, Mathematical and Computational Applications Journal 1 (2011), 77-86. [7] J.N. Wahome, An Investigation Of Free Surface Fluid Flow Topologies Using an Inverse Conformal Mapping Inferencing Technique, PhD thesis, University of Eldoret.(2014) [8] B. Massey, J.W. Smith, Mechanics of fluids, Stanley Thornes.. 182 (1998), 11-17. [9] Doughlas, J.F., Gasiorek, J.M., Swaffield, J.A., Fluid Mechanics, Prentice Hall.. 182 (2001), 514-558. [10] V.T. Chow, P. Open Channel Hydraulics, McGraw-Hill, New York, (1959) [11] R.H.French, Open Channel Hydraulics, McGraw-Hill, New York, (1985) [12] F.M. Henderson, Open Channel Flow, McGraw-Hill, New York,(1966) [1] F.M. Henderson, Open Channel Flow, Macmillan, New York,(1996) [14] D. Stephenson, Stormwater Hydrology and Drainage, Elsevier, Amsterdam,(1981) [15] J.A. Swaffield and L.S. Galowin, The Engineered Design of Building Drainage Systems Ashgate, Aldershot,(2011) [16] H. Rouse, Critical Analysis of Open Channel Roughness, J.Hydraul.Div. ASCE, 91 (1965), 1-15. Received: August 15, 2014

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