Hydromorphodynamics Simulation for Selected Stretch of Euphrates River within Al-Anbar Governorate
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Abstract
In this study, the hydromorphodynamic simulation of a stretch of the Euphrates River was conducted. The stretch of the Euphrates River extended from Haditha dam to the city of Heet in Al-Anbar Governorate and it is estimated to be 124.4 km. Samples were taken from 3 sites along the banks of the river stretch using sampling equipment. The samples were taken to the laboratory for grain size analysis where the median size (D50) and sediment load were determined. The hydromorphodynamic simulation was conducted using the NACY 2DH solver of the iRIC model. The model was calibration using the Manning roughness, sediment load, and median particle size and the validation process showed that the error between the simulation and the recorded data was minimum. After calibration, three different scenarios were considered and the scenarios were based on different river discharges (low, average, and flood discharge). Four statistical indices were used to check the predicted values of the velocities and water depth in various sections of the Euphrates River section at the city of Heet and these indices were Mean Absolute Deviation (MAD), Mean Square Error (MSE), Root MSE (RMSE), and the Mean Absolute Percentage Error (MAPE). For velocity, values of the above indices for the first scenario were found to be 0.19, 0.046, 0.21, and 0.17 respectively. However, for water depth, values for the above statistical indices were found to be 0.07, 0.01, 0.01, and 0.13 respectively. The values confirmed the accuracy of the prediction of model iRIC Nacy2DH.
Article received: 08/08/2022
Article accepted: 20/08/2022
Article published: 01/03/2023
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References
Attard, M. E., 2012. Evaluation of ADCPs for suspended sediment transport monitoring, Fraser River, British Columbia Environment: Department of Geography.
Church, M., 2006. Bed material transport and the morphology of alluvial river channels. Annu. Rev. Earth Planet. Sci., 34, pp. 325-354. doi:10.1146/annurev.earth.33.092203.122721
Engelund, F., 1974. Flow and bed topography in channel bends. Journal of the Hydraulics Division, 100(11), pp. 1631-1648. doi: 10.1061/JYCEAJ.0004109
Gharbi, M., Soualmia, A., Dartus, D., Masbernat, L., 2014a. A comparative analysis of Lajeunesse model with other used bed load models - effects on river morphological changes, Journal of Water Resources and Ocean Science, 3(5), pp. 61–68. doi: 10.11648/j.wros.20140305.12
Goniva, G., Gruber, K., Koss, C., 2012. Sediment erosion a numerical and experimental study. Taylor and Francis, London, UK.
Hasegawa, A., 1985. Self-organization processes in continuous media. Advances in physics, 34(1), pp. 1-42. doi:10.1080/00018738500101721
Hiroshi, T., Hajime, N., Kenji, K., Yasuyuki, B., Hao, Z., 2011. Effects of hydraulic structures on river morphological processes. International Journal of Sediment Research, 26 (3), pp. 283-303. doi:10.1016/S1001-6279(11)60094-2
Hubbert, M. K., Rubey, W. W., 1959. Role of fluid pressure in mechanics of overthrust faultingi. mechanics of fluid-filled porous solids and its application to overthrust faulting. GSA Bulletin, 70(2), pp. 115-166. doi:10.1130/0016-7606(1959)70[115:ROFPIM]2.0.CO;2
Hydar, L. A., Badronnisa, Y., Thamer, A. M., Yasuyuki, S., Mohd Shahrizal A., Balqis, M., 2019. Improving the hydro-morpho dynamics of a river confluence by using vanes, Resources, 8(9), pp. 1-22.
Itakura, T., Kishi, T., 1980. Open channel flow with suspended sediments. Journal of the Hydraulics Division, 106(8), pp. 1325-1343. doi:10.1061/JYCEAJ.0005483
Iwagaki, Y., 1956. (I) Hydrodynamical study on critical tractive force. Transactions of the Japan Society of Civil Engineers, 41(1956), pp. 1-21. doi:10.2208/jscej1949.1956.41_1
Kamel, A., 2008. Application of a hydrodynamic MIKE 11 model for the Euphrates River in Iraq. Slovak Journal of Civil Engineering, 2(1), pp. 1-7.
Khudair, B.H., 2019. Influent flow rate effect on sewage pump station performance based on organic and sediment loading. Journal of Engineering, 25(9), pp. 1-11. doi: 10.31026/j.eng.2019.09.1.
Kishi, T.; Kuroki, M., 1973. Bed Forms and resistance to flow in erodible-bed channels. Bull. Fac. Eng. Hokkaido Univ., 67, pp. 1–23.
Meyer-Peter, E.; Müller, R., 1948. Formulas for bed-load transport. In Proceedings of the 2nd Meeting of the International Association for Hydraulic Structures Research, Delft, The Netherlands, 2, pp. 39–64.
Mingfu, G., Qiuhua, L., 2017. A two-dimensional hydro-morphological model for river hydraulics and morphology with vegetation. Environmental Modelling & Software, 88(2), pp. 10-21. doi:10.1016/j.envsoft.2016.11.008
Mustafa, A.S., Sulaiman, S.O., and Hussein, O.M., 2016. Application of swat model for sediment loads from valleys transmitted to Haditha reservoir. Journal of Engineering, 22(1), pp. 184-197.
Nakajima, A., Hashimoto, K., Watanabe, T., 2001. Recent studies on super-hydrophobic films. Molecular Materials and Functional Polymers, pp. 31-41. doi:10.1007/s007060170142
Nezu, I., Tominaga, A., and Nakagawa, H., 1993. Field measurements of secondary currents in straight rivers. Journal of Hydraulic Engineering, 119(5), pp. 598-614.
doi:10.1061/(ASCE)0733-9429(1993)119:5(598)
Von Rergen, H., Howland, W., Lenz, A. T., Stevens, J., Mavis, F., Rouse, H., and White, M. P., 1937. Discussion on Open Channels of adverse slope. Transactions of the American Society of Civil Engineers, 102(1), pp. 661-676. doi:10.1061/TACEAT.0004888