A combined-water-system approach for tackling water scarcity: application to the Permilovo groundwater basin, Russia

详细信息    查看全文

• 作者：Elena A. Filimonova ; Mikhail G. Baldenkov
• 关键词：Groundwater/surface ; water relations ; Aquifer storage ; Groundwater management ; Karst ; Russia
• 刊名：Hydrogeology Journal
• 出版年：2016
• 出版时间：March 2016
• 年：2016
• 卷：24
• 期：2
• 页码：489-502
• 全文大小：2,617 KB
• 参考文献：Bakker M, Anderson EI (2003) Steady flow to a well near a stream with a leaky bed. Ground Water 41(6):833–840. doi:10.​1111/​j.​1745-6584.​2003.​tb02424.​x CrossRef
  Bolgov MV, Ratkovich DY (1997) The problem of a hydrological feasibility study for projects of nuclear power stations (using the Kalinin nuclear power station as an example). Water Resour 24(3):338–346
  Bolgov MV, Shtengelov RS, Maslov AA, Filimonova EA (2012) Assessing the efficiency of combined use of surface water and groundwater for process water supply to Kalininskaya NPP. Water Resour 39(2):229–236. doi:10.​1134/​S009780781201003​4 CrossRef
  Bredehoeft J, Kendy E (2008) Strategies for offsetting seasonal impacts of pumping on a nearby stream. Ground Water 46(1):23–29. doi:10.​1111/​j.​1745-6584.​2007.​00367.​x
  Butler JJ Jr, Zlotnik VA, Tsou M-S (2001) Drawdown and stream depletion produced by pumping in the vicinity of a partially penetrating stream. Ground Water 39(5):651–659. doi:10.​1007/​s12665-009-0117-2 CrossRef
  Chen X, Shu L (2002) Stream–aquifer interactions: evaluation of depletion volume and residual effects from groundwater pumping. Ground Water 40(3):284–290. doi:10.​1111/​j.​1745-6584.​2002.​tb02656.​x CrossRef
  Chen X, Yin Y (2001) Streamflow depletion: modeling of baseflow reduction and stream infiltration from seasonally pumped wells. J Am Water Resour Assoc 37(1):185–195CrossRef
  Chen X, Yin Y (2004) Semianalytical solutions for stream depletion in partially penetrating streams. Ground Water 42(1):92–96. doi:10.​1111/​j.​1745-6584.​2004.​tb02454.​x CrossRef
  Conrad LP, Beljin MS (1996) Evaluation of an induced infiltration model as applied to glacial aquifer systems. Water Resour Bull 32(6):1209–1220CrossRef
  Darama Y (2001) An analytical solution for stream depletion by cyclic pumping of wells near streams with semipervious beds. Water Resour Res 36(1):79–86
  Downing RA (1993) Groundwater resources, their development and management in the UK: an historical perspective. Q J Eng Geol 26:335–358CrossRef
  Filimonova YA (2009) An analysis of the balance of operational water discharge using a combined water-intake system. Mosc Univ Geol Bull 64(4):265–268. doi:10.​3103/​S014587520904008​5 CrossRef
  Filimonova EA, Baldenkov MG (2014) The combined water system as approach for tackling water scarcity in Permilovo groundwater basin. Geophysical Research Abstracts, vol 16. EGU General Assembly Vienna, Vienna
  Filimonova EA, Baldenkov MG (2015) Numerical simulation of seasonal groundwater pumping. Geophysical Research Abstracts, vol 17. EGU General Assembly Vienna, Vienna
  Filimonova EA, Shtengelov RS (2013) The dependence of stream depletion by seasonal pumping on various hydraulic characteristics and engineering factors. Hydrogeol J 21(8):1821–1832. doi:10.​1007/​s10040-013-1053-5 CrossRef
  Glover RE, Balmer GG (1954) River depletion resulting from pumping a well near a river. Trans Am Geophys Union 35(3):468–470CrossRef
  Grinevsky SO (1991a) Obosnovanie geogidrologicheskih prognozov vodootbora na mestorogdeniah podzemnyh vod v dolinah malih rek [Assessing of geohydrological forecast of groundwater pumping in valleys of small rivers]. PhD Thesis, MSU, Russia
  Grinevsky SO (1991b) Formirovanie ekspluatacionnyh zapasov vodozabora podzemnyh vod v doline maloi reki [Operational reserve of fresh groundwater reserves in the valleys of small rivers]. Moscow Univ Geol Bull Ser 4 3:87–92
  Grinevsky SO, Shtengelov RS (1988) O prognozirovanii vliyaniya vodozaborov podzemnyh vod na stok malyh rek [Forecast of the influence of groundwater pumping on flow of small rivers]. Water Resour 4:24–32
  Hantush MS (1965) Wells near streams with semipervious beds. J Geophys Res 70(12):2829–2838CrossRef
  Harbaugh AW, Banta ER, Hill MC, McDonald MG (2000) MODFLOW-2000, the US Geological Survey modular ground-water model: user guide to modularization concepts and the ground-water flow process. Open File Rep 00–92. US Geol Surv, Denver
  Hunt B (1999) Unsteady stream depletion from ground water pumping. Ground Water 37(1):98–102CrossRef
  Jenkins CT (1968) Techniques for computing rate and volume of stream depletion by wells. Ground Water 6(2):37–46CrossRef
  Kendy E, Bredehoeft J (2006) Transient effects of groundwater pumping and surface water-irrigation returns on streamflow. Water Resour Res 42. doi:10.​1029/​2005WR004792
  Khublaryan MG, Kovalevskii VS, Bolgov MV (2005) Concept of water resources system management based on the combined use of surface and subsurface waters. Water Resour 32(5):565–571CrossRef
  Konsebovskiy SY, Minkin EA (1989) Gidrogeologicheskie raschety pri ispol’zovanii podzemnykh vod dlya orosheniya [The hydrogeological estimations for groundwater pumping for irrigation]. Nauka, Moscow
  Kovalevskii VS (2001) Kombinirovannoe ispol’zovanie resursov poverkhnostnykh i podzemnykh vod [Combined use of surface and groundwater resources]. Nauch. mir, Moscow
  Kumsiashvily GP (1980) Regulirovanie stoka i okhrana podzemnykh vod [Regulation of the flow and protection of natural waters]. MSU, Moscow
  Langhoff JH, Rasmussen KR, Christensen S (2006) Quantification and regionalization of groundwater–surface water interaction along an alluvial stream. J Hydrol 320:342–358. doi:10.​1016/​j.​jhydrol.​2005.​07.​040 CrossRef
  Law F (1965) Integrated use of diverse sources. J Inst Water Eng 19:413–457
  Maddock T III, Vionnet LB (1998) Groundwater capture processes under a seasonal variation in natural recharge and discharge. Hydrogeol J 6:24–32CrossRef
  Maknoon R, Burges SJ (1978) Conjunctive use of ground and surface water. Am Water Works Assoc 70(8):419–424
  Maslov AA, Filimonova EA, Shtengelov RS (2010) Pit’evaya voda – dragocennoe poleznoe iskopaemoe [Fresh water – valuable mineral deposits]. Nature 10:38–46
  Mirzaev et al. (1991) Opyt kompleksnogo ispol’zovanii podzemnykh vod v stranah mira s razvitym orowaemym zemledeliem [Experience of complex use of groundwater in countries with progressive irrigated agriculture]. FAN, Tashkent, Uzbekistan
  Owen M, Robinson VK (1978) Characteristics and yield in fissured Chalk. In: Thames groundwater scheme. Institution of Civil Engineers, London, pp 33–49
  Prudic DE (1989) Documentation of a computer program to simulate stream-aquifer relations using a modular, finite-difference, groundwater flow model. US Geol Surv Open-File Rep 88–729, 113 pp
  Rodriguez LB, Cello PA, Vionnet CA (2006) Modeling stream–aquifer interactions in a shallow aquifer, Choele Choel Island, Patagonia, Argentina. Hydrogeol J 14:591–602. doi:10.​1007/​s10040-005-0472-3 CrossRef
  Shestakov VM (1965) Teoreticheskie osnovy ocenki podpora, vodoponijeniya i drenaja [Theoretical base of estimation of an afflux, drawdowns and drainage]. MSU, Moscow
  Shtengelov RS, Filimonova EA (2011) Kombinirovannye vodozabornye sistemy kak metod optimal’nogo upravleniya vodnymi resursami [Combined water-intake systems: optimal method of water resources management] Amelioration Water Manage 6:21–24
  Sophocleous MA, Koussis JLM, Perkins SP (1995) Evaluation of simplified stream-aquifer depletion models for water rights administration. Ground Water 33(4):579–588CrossRef
  Theis CV (1940) The source of water derived from wells: essential factors controlling the response of an aquifer to development. Civ Eng 10:277–280
  Velikanov AL, Klyepov VI, Minkin EL (1994) Conjunctive use of surface and groundwater for Moscow agglomeration. Water Resour 21(6):711–714
  Vsevolghskij VA, Shtengelov RS, Dolgopolov VV et al (1986) Ocenka estestvennyh i ekspluatacionnyh zapasov podzemnyh vod Permilovskogo mestorogdeniya podzemnyh vod (dlya hozyaistvenno-pit’evogo vodosnabgeniya) [Estimation of groundwater resources of the Permilivo groundwater basin (for drinking water demand)], vols 1–2. Geology Faculty, MSU, Moscow
  Wallace RB, Darama Y, Annable MD (1990) Stream depletion by cyclic pumping of wells. Water Resour Res 26(6):1263–1270CrossRef
  Wang P, Pozdniakov SP, Shestakov VM (2015) Optimum experimental design of a monitoring network for parameter identification at riverbank well fields. J Hydrol 523:531–541. doi:10.​1016/​j.​jhydrol.​2015.​02.​004 CrossRef
  Woessner WW (2000) Stream and fluvial plain ground water interactions: rescaling hydrogeologic thought. Ground Water 38(3):423–429. doi:10.​1007/​s10040-006-0110-8 CrossRef
  Wu B, Zheng Y, Wu X, Tian Y, Han F, Liu J, Zheng C (2015) Optimizing water resources management in large river basins with integrated surface water-groundwater modeling: a surrogate-based approach. Water Resour Res 51:2153–2173. doi:10.​1002/​2014WR016653
  Young RA, Bregehoeft JD (1972) Digital computer simulation for solving management problems of conjunctive use of ground and surface water. Water Resour Res 8(3):533–556CrossRef
  Zektser IS, Dzhamalov RG, Plemenov VA (1996) The possibility of ground water use for water supply of nuclear power plants with special reference to the Kalinin plant. Water Resour 23(4):468–470
  Zlotnik VA (2004) A concept of maximum stream depletion rate for leaky aquifers in alluvial valleys. Water Resour Res 40:W06507. doi:10.​1029.​/​2003WR002932
  Zume J, Tarhule A (2008) Simulating the impacts of groundwater pumping on stream–aquifer dynamics in semiarid northwestern Oklahoma, USA. Hydrogeol J 16:797–810. doi:10.​1007/​s10040-007-0268-8 CrossRef
  
• 作者单位：Elena A. Filimonova (1)
  Mikhail G. Baldenkov (2)
  
  1. Novo-Mytishchinskiy Avenue, Building 47, block 1, Apt.17, Mytishchi, Russia, 141018
  2. Magnitogorskaya Street, Building 11, Apt. 172, Moscow, Russia, 105568
  
• 刊物类别：Earth and Environmental Science
• 刊物主题：Earth sciences
  Hydrogeology
  Geology
  Waste Water Technology, Water Pollution Control, Water Management and Aquatic Pollution
  
• 出版者：Springer Berlin / Heidelberg
• ISSN：1435-0157

文摘

The suitability of a combined water system (CWS) is assessed for meeting drinking-water demand for the city of Arkhangelsk (northwestern Russian Federation), instead of using the polluted surface water of the Northern Dvina River. An appropriate aquifer system (Permilovo groundwater basin) was found and explored in the 1980s, and there were plans then to operate an abstraction scheme using traditional pumping methods. However, the 1980s planned water system was abandoned due to projected impermissible stream depletion such that complete interception of the cone of depression with the riverbed would cause the riverbed to become dry. The design of a CWS is now offered as an approach to addressing this environmental problem. Several sets of major pumping wells associated with the CWS are located on the banks of Vaymuga River and induce infiltration from the stream. The deficiency of the stream flow in dry seasons is compensated for by pumping from aquifer storage. A numerical model was constructed using MODFLOW-2000. The results of the simulation showed the efficiency of the compensation pumping. The streamflow depletion caused by the CWS is equal to the minimum permissible stream flow and is lower than the depletion projected by the abandoned plan. Application of the CWS in the Permilovo groundwater basin makes it possible to meet water demands during water-limited periods and to avoid environmental problems.