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Chakma, Sumedha
- Assessment of Sedimentation and Useful Life of Tehri Reservoir using Integrated Approaches of Hydrodynamic Modelling, Satellite Remote Sensing and Empirical Curves
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Authors
Affiliations
1 Department of Civil Engineering, Indian Institute of Technology Delhi, New Delhi 110 016, IN
1 Department of Civil Engineering, Indian Institute of Technology Delhi, New Delhi 110 016, IN
Source
Current Science, Vol 118, No 3 (2020), Pagination: 411-420Abstract
The higher rate of sedimentation in reservoirs is one of the main concerns in sustainable reservoir management, which impairs the functional capacity of reservoirs that may lead to various environmental risks. Estimation of sedimentation rate and useful life of a reservoir using appropriate methods is imperative for sustainable management. This paper deals with the computation of sedimentation rate and useful life of Tehri reservoir of Bhagirathi river, in India, using hydrographic survey analysis, Hydrologic Engineering Center’s River Analysis System (HEC-RAS) modelling, satellite remote sensing (SRS) technique, and trap efficiency based empirical curve methods. The rate of sedimentation was found as 5.33 million cubic metres (MCM)/year based on hydrographic survey analysis from the data obtained for the years 2005, 2008 and 2013. Likewise, the mean annual rate of sedimentation was estimated to be 5.07 MCM/year and 5.75 MCM/year based on the HEC-RAS model and SRS techniques respectively. Brune’s method and Churchill’s method of trap efficiency were found to be inconsistent with the hydrographic survey results. The reservoir can be classified as Type III reservoir with respect to the sediment vertical distribution analysis. Changes in bathymetry obtained in the simulation studies showed that the Bhagirathi river’s 28–30 km reach would be most vulnerable to sedimentation problems. The estimated useful life of Tehri reservoir was found to be in the range of 160–180 years. The SRS technique and hydrodynamic model provided a better fit with the observed data.Keywords
Empirical Curve, HEC-RAS Model, Reservoir, Sedimentation, Tehri Reservoir, Useful Life.References
- Sumi, T. and Hirose, T., Accumulation of sediment in reservoirs. In Water Storage, Transport, and Distribution – Encyclopedia of Life Support Systems (ed. Takahasi, Y.), EOLSS Publishers, Oxford, UK, 2009, pp. 224–252.
- Kondolf, G. M. et al., Sustainable sediment management in reservoirs and regulated rivers: experiences from five continents. Earth’s Future, 2014, 2(5), 256–280.
- Wang, H. W. and Kondolf, G. M., Upstream sediment‐control dams: five decades of experience in the rapidly eroding Dahan River Basin, Taiwan. J. Am. Water Resour. Assoc., 2014, 50(3), 735–747; doi:10.1111/jawr.12141.
- Luis, J., Sidek, L. M. and Jajarmizadeh, M., Impact of sedimentation hazard at Jor Reservoir, Batang Padang hydroelectric scheme in Malaysia. In IOP Conference Series: Earth and Environmental Science, IOP Publishing Ltd, UK, 2016, vol. 32, no. 1, p. 012030; doi:10.1088/1755-1315/32/1/012030.
- Graf, W. H., The hydraulics of reservoir sedimentation. International Water Power Dam Construction, 1983, 35(4), 45–52.
- Garcia, M. H., Sediment transport and morphodynamics. In Sedimentation Engineering: Processes, Measurements, Modelling, and Practice (ed. Garcia, M.), ASCE Manuals and Reports on Engineering Practice No. 110. American Society of Civil Engineers, Reston, VA, 2008, pp. 21–164.
- Morris, G. L. and Fan, J., Reservoir Sedimentation Handbook: Design and Management of Dams Reservoirs, and Watershed for Sustainable Use, McGraw-Hill Book Company, New York, USA; 2010; http://reservoirsedimentation.com.
- Fiock, L. R., Records of silt carried by the Rio Grande and its accumulation in Elephant Butte Reservoir. Eos Trans. Am. Geophys. Union, 1934, 15(2), 468–473.
- Annandale, G., Quenching the Thirst: Sustainable Water Supply and Climate Change, CreateSpace Independent Publishing Platform, North Charleston, SC, USA, 2013.
- UNESCO, Water in a Changing World. The United Nations World Water Development Report 3, World Water Assessment Programme, Routledge, 2012, p. 190.
- Central Water Commission (CWC), Compendium on silting of reservoirs in India. Ministry of Water Resources, Watershed and Reservoir Sedimentation Directorate, New Delhi, India. 2015.
- MoWR, Storage Status of 91 Major Reservoirs of the Country as on 5 November 2015. Press Information Bureau, Govt. of India, Ministry of Water Resources (MoWR), New Delhi, India, 2015; http://pib.nic.in/newsite/PrintRelease.aspx?relid=130237 (accessed on May 2016).
- Merina, N. R., Sashikkumar, M. C., Rizvana, N. and Adlin, R., Sedimentation study in a reservoir using remote sensing technique. Appl. Ecol. Environ. Res., 2016, 14(4), 296–304.
- Eakin, H. M., Instructions for reservoir sedimentation surveys, in silting of reservoirs. Technical Report, US Department of Agriculture, Technical Bulletin, 1939.
- Brown, C. B., Discussion of Sedimentation in reservoirs, by J. Witzig. In Proceedings of the American Society of Civil Engineers, 1943, 69(6), 1493–1500.
- Churchill, M. A., Discussion of analyses and use of reservoir sedimentation data by L.C. Gottschalk. In Proceedings of the Federal Inter-agency Sedimentation conference, Denver, USA, 1948, pp. 139–140.
- Brune, G. M., Trap efficiency of reservoirs. Eos Trans., Am. Geophys. Union, 1953, 34(3), 407–418; doi:10.1029/TR034i003p00407.
- Cristofano, E. A., Area increment method for distributing sediment in a reservoir. US Bureau of Reclamation, Albuquerque, New Mexico, 1953.
- Borland, W. M. and Miller, C. R., Distribution of sediment in large reservoir. J. Hydraul. Div., 1958, 84(2), 1–18.
- Solomonson, V. V., Remote sensing applications in water resources. In Third Earth Resources Technology Symposium, Washington DC, USA, 1973, pp. 10–14.
- Smith, S. E., Mancy, K. H. and Latif, A. F. A., The application of remote sensing techniques towards the management of the Aswan high dam reservoir. In 14th International Symposium on Remote Sensing of Environment, San Jose, Costa Rica, 1980, pp. 1297– 1307.
- Vemu, S. and Udayabhaskar, P., An integrated approach for prioritization of reservoir catchment using remote sensing and geographic information system techniques. Geocarto Int., 2010, 25(2), 149–168.
- Goel, M. K., Jain, S. K. and Agarwal, P. K., Assessment of sediment deposition rate in Bargi Reservoir using digital image processing. Hydrol. Sci. J., 2002, 47(S1), S81–S92.
- Keys, T. A. and Scott, D. T., Monitoring volumetric fluctuations in tropical lakes and reservoirs using satellite remote sensing. Lake Reserv. Manage., 2018, 34(2), 154–166.
- Jagalingam, P., Akshaya, B. J. and Hegde, A. V., Bathymetry Mapping Using Landsat 8 Satellite Imagery. Procedia Eng., 2015, 116, 560–566; doi:10.1016/j.proeng.2015.08.326.
- Jain, S. K., Singh, P. and Seth, S. M., Assessment of sedimentation in Bhakra reservoir in the western Himalayan region using remotely sensed data. Hydrolog. Sci. J., 2002, 47(2), 203–212; doi:10.1080/02626660209492924.
- Pandey, A., Chaube, U. C., Mishra, S. K. and Kumar, D., Assessment of reservoir sedimentation using remote sensing and recommendations for desilting Patratu Reservoir, India. Hydrol. Sci. J., 2016, 61(4), 711–718.
- Koomullil, D. S., Chaube, U. C. and Pandey, A., Revisiting the useful life computation of Gobindsagar (Bhakra) reservoir. ISH J. Hydraul. Eng., 2016, 22(2), 115–123; doi:10.1080/09715010.2015.1084600.
- Vishnoi, R. K. and Govil, R., Sedimentation and life of the reservoir. Water Energ. Int., 2007, 64(1), 99–107.
- Brunner, G. W., Hydraulic Reference Manual, US Army Corps of Engineers, Hydrologic Engineering Center, Davis, CA, 2010.
- USACE, HEC-RAS River Analysis System Hydraulic Reference Manual, Ver. 5.0, 2016.
- Chow, V. T., Open-Channel Hydraulics, McGraw-Hill, New York, 1959, vol. 1, p. 680.
- Ackers, P. and White, W. R., Sediment transport: new approach and analysis. J. Hydraulics Div., 1973, 99 (hy11).
- Barsi, J., Lee, K., Kvaran, G., Markham, B. and Pedelty, J., The spectral response of the Landsat-8 operational land imager. Remote Sens., 2014, 6(10), 10232–10251.
- IS Manual 13665, Sedimentation in Reservoirs – Method of Measurement, New Delhi, India, 1993.
- Verstraeten, G. and Poesen, J., Estimating trap efficiency of small reservoirs and ponds: methods and implications for the assessment of sediment yield. Prog. Phys. Geog., 2000, 24(2), 219–251.
- Garg, V. and Jothiprakash, V., Estimation of useful life of a reservoir using sediment trap efficiency. J. Spat. Hydrol., 2008, 8(2), 1–14.
- Issa, I. E., Al-Ansari, N., Sherwany, G. and Knutsson, S., Sedimentation processes and useful life of Mosul dam reservoir, Iraq. Engineering, 2013, 5(10), 779–784; https://doi.org/10.4236/eng.2013.510094.
- Effects of temperature and slope on the infiltration rate for a landfill surface
Abstract Views :109 |
PDF Views:69
Authors
Lohit Jain
1,
Sumedha Chakma
1
Affiliations
1 Department of Civil Engineering, Indian Institute of Technology, Delhi 110 016, India, IN
1 Department of Civil Engineering, Indian Institute of Technology, Delhi 110 016, India, IN
Source
Current Science, Vol 124, No 1 (2023), Pagination: 94-101Abstract
In this study, parameters of the Kostiakov, Horton, Modified Kostiakov, SCS, Philip and Smith models were estimated using the double-ring infiltrometer on two different slopes, viz. 4° and 23°; in morning and afternoon sessions to assess their usefulness in characterizing the infiltration process. Observations revealed that the average increment in temperature by 9°C increased the final and initial infiltration rates by 65% and 38% respectively. The combined effects of the 23° slope and higher temperature increased the infiltrated volume by 6.4 times. The comparative analysis showed Kostiakov as the most efficient model incorporating combined and individual effects of temperature and slopeReferences
- Singh, R. P., Tyagi, V. V., Allen, T., Ibrahim, M. H. and Kothari, R., An overview for exploring the possibilities of energy generation from municipal solid waste (MSW) in Indian scenario. Renew. Sus-tain. Energy Rev., 2011, 15, 4797–4808; https://doi.org/10.1016/ J.RSER.2011.07.071.
- Census of India 2011, Population projections for India and the states: 2011–2036, National Commission on Population, Ministry of Health & Family Welfare, New Delhi, 2020.
- Annual Report with respect to solid waste management rules, 2016 in respect of NCT of Delhi for the Year 2016, Delhi Pollution Con-trol Committee, Government of NCT of Delhi, New Delhi, 2019.
- Annual Report in respect of NCT of Delhi for the year 2021–2022 on the implementation of solid waste management rules, 2016, New Delhi, 2022.
- Delhi Pollution Control Council, Compliance report of Govt. of NCT of Delhi in OA No. 606/2018, New Delhi, 2020.
- Talyan, V., Dahiya, R. P. and Sreekrishnan, T. R., State of municipal solid waste management in Delhi, the capital of India. Waste Man-age., 2008, 28, 1276–1287.
- Chakma, S. and Mathur, S., Estimation of primary and mechanical compression in MSW landfills. J. Hazard., Toxic, Radioact. Waste, 2012, 16, 298–303.
- Mukherjee, S., Mukhopadhyay, S., Hashim, M. A. and Sen Gupta, B., Contemporary environmental issues of landfill leachate: assessment and remedies. Crit. Rev. Environ. Sci. Technol., 2014, 45, 472–590; https://doi.org/10.1080/10643389.2013.876524.
- Chakma, S. and Mathur, S., Postclosure long-term settlement for MSW landfills. J. Hazard., Toxic, Radioact. Waste, 2013, 17, 81–88.
- Hopmans, J., Clausnitzer, V. and Kosugi, K. I., Evaluation of various infiltration models. Sci. Agric., 1995, 140, 5–8.
- Haghighi, F., Gorji, M., Shorafa, M., Sarmadian, F. and Mohammadi, M. H., Evaluation of some infiltration models and hydraulic para-meters. Span. J. Agric. Res., 2010, 8, 210.
- Sihag, P., Tiwari, N. K. and Ranjan, S., Estimation and inter-com-parison of infiltration models. Water Sci., 2017, 31, 34–43.
- Helalia, A. M., The relation between soil infiltration and effective porosity in different soils. Agric. Water Manage., 1993, 24, 39–47.
- Mishra, S. K., Tyagi, J. V. and Singh, V. P., Comparison of infiltra-tion models. Hydrol. Process., 2003, 17, 2629–2652.
- Skaggs, R. W., Huggins, L., Monke, E. and Foster, G., Experimental evaluation of infiltration equations. Trans. ASAE, 1969, 12, 822–828.
- Levy, G. J., Smith, H. J. C. and Agassi, M., Water temperature effect on hydraulic conductivity and infiltration rate of soils. S. Afr. J. Plant Soil, 1989, 6, 240–244.
- Gavin, K. and Xue, J., A simple method to analyze infiltration into unsaturated soil slopes. Comput. Geotech., 2008, 35, 223–230.
- Langhans, C., Govers, G. and Diels, J., Development and parame-terization of an infiltration model accounting for water depth and rainfall intensity. Hydrol. Process., 2013, 27, 3777–3790.
- Avudainayagam, S., Sharma, K. K. and Rajamani, V., Rate of infil-tration – an in situ measurement. Curr. Sci., 1987, 13, 663–664.
- Fenn, D. G., Hanley, K. J. and Degeare, T. V., Use of the water-balance method for predicting leachate generation from solid-waste-disposal sites. Technical Report, Office of Scientific and Technical Infor-mation, US Department of Energy, Washington, DC, USA, 1975; https://www.osti.gov/biblio/6328350
- Kargas, G. and Kerkides, P., A contribution to the study of the phe-nomenon of horizontal infiltration. Water Resour. Manage., 2010, 25, 1131–1141.
- ICAR, Daily weather data, Indian Council of Agricultural Res-earch, New Delhi, 2020.
- Mohan, M. and Kandya, A., Impact of urbanization and land-use/ land-cover change on diurnal temperature range: a case study of tropical urban airshed of India using remote sensing data. Sci. Total Environ., 2015, 506–507, 453–465.
- Integrated Research and Action for Development, Report on assessment of landfill gas and pre feasibility study at the Okhla landfill gas uti-lization as domestic fuel, New Delhi, 2009.
- Gregory, J. H., Dukes, M. D., Miller, G. L. and Jones, P. H., Analysis of double-ring infiltration techniques and development of a simple automatic water delivery system. Appl. Turfgrass Sci., 2005, 2, 1–7.
- ASTM D3385-03, Standard test method for infiltration rate of soils in field using double-ring infiltrometer, ASTM International, 2009.
- Rocheta, V. L. S., Isidoro, J. M. G. P. and de Lima, J. L. M. P., Infiltra-tion of Portuguese cobblestone pavements – an exploratory assessment using a double-ring infiltrometer. Urban Water J., 2015, 14, 291– 297; http://dx.doi.org/10.1080/1573062X.2015.1111914.
- Shukla, M. K., Lal, R., Owens, L. B. and Unkefer, P., Land use and management impacts on structure and infiltration characteristics of soils in the North Appalachian region of Ohio. Soil Sci., 2003, 168, 167–177.
- Kirkham, M. B. (ed.), Infiltration. In Principals of Soil Plant Water Relations (Second Edition), 2014, pp. 201–227.
- Legates, D. R. and McCabe, G. J., Evaluating the use of ‘goodness-of-fit’ measures in hydrologic and hydroclimatic model validation. Water Resour. Res., 1999, 35, 233–241.
- Moriasi, D. N., Arnold, J. G., Van, L., Bingner, W., Harmel, R. D. and Veith, T. L., Model evaluation guidelines for systematic quantifica-tion of accuracy in watershed simulations. Trans. ASABE, 2007, 50, 885–900.
- Jaynes, D. B., Temperature variations effect on field-measured in-filtration. Soil Sci. Soc. Am. J., 1990, 54, 305–312.
- Sharma, K. D., Singh, H. P. and Pareek, O. P., Rainwater infiltration into a bare loamy sand. Hydrol. Sci. J., 2009, 28, 417–424; https:// doi.org/10.1080/02626668309491980.
- Mu, W. et al., Effects of rainfall intensity and slope gradient on run-off and soil moisture content on different growing stages of spring maize. Water, 2015, 7, 2990–3008.
- Khan, M. N. et al., Effect of slope, rainfall intensity and mulch on erosion and infiltration under simulated rain on purple soil of south-western Sichuan Province, China. Water, 2016, 8, 528.
- Klein, R., Baumann, T., Kahapka, E. and Niessner, R., Temperature development in a modern municipal solid waste incineration (MSWI) bottom ash landfill with regard to sustainable waste manage-ment. J. Hazard. Mater., 2001, 83, 265–280.
- Wright, P. G., The variation of viscosity with temperature. Phys. Educ., 1977, 12, 323–325.
- Petrucci, G., De Bondt, K. and Claeys, P., Toward better practices in infiltration regulations for urban stormwater management. Urban Water J., 2016, 14, 546–550.
- Lv, M., Hao, Z., Liu, Z. and Yu, Z., Conditions for lateral downslope unsaturated flow and effects of slope angle on soil moisture move-ment. J. Hydrol., 2013, 486, 321–333.
- Miyazaki, T., Water Flow in Soils, Boca Raton, CRC Press, 2005, pp. 163–217.
- Poesen, J., The influence of slope angle on infiltration rate and Hortonian overland flow volume. Z. Geomorphol. Suppl., 1984, 49, 117–131.
- Chen, L. and Young, M. H., Green–Ampt infiltration model for sloping surfaces. Water Resour. Res., 2006, 42, 1–9.
- Liu, C.-W., Chen, S.-K., Jou, S.-W. and Kuo, S.-F., Estimation of the infiltration rate of a paddy field in Yun-Lin, Taiwan. Agric. Syst., 2001, 1, 41–54.
- Chahinian, N., Moussa, R., Andrieux, P. and Voltz, M., Comparison of infiltration models to simulate flood events at the field scale. J. Hydrol., 2005, 306, 191–214.
- Zolfaghari, A. A., Mirzaee, S. and Gorji, M., Comparison of different models for estimating cumulative infiltration. Int. J. Soil Sci., 2012, 7, 108–115.
- Farid, H. U. et al., Estimation of infiltration model parameters and their comparison to simulate the onsite soil infiltration characteristics. Int. J. Agric. Biol. Eng., 2019, 12, 84–91.
- Ioannou, I., Charalambous, C. and Hall, C., The temperature variation of the water sorptivity of construction materials. Mater. Struct. Constr., 2017, 50, 1–12.