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Hydrogeology Journal

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01-08-2016 | Paper

The use of salinity contrast for density difference compensation to improve the thermal recovery efficiency in high-temperature aquifer thermal energy storage systems

Authors: Jan H. van Lopik, Niels Hartog, Willem Jan Zaadnoordijk

Published in: Hydrogeology Journal | Issue 5/2016

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Abstract

The efficiency of heat recovery in high-temperature (>60 °C) aquifer thermal energy storage (HT-ATES) systems is limited due to the buoyancy of the injected hot water. This study investigates the potential to improve the efficiency through compensation of the density difference by increased salinity of the injected hot water for a single injection-recovery well scheme. The proposed method was tested through numerical modeling with SEAWATv4, considering seasonal HT-ATES with four consecutive injection-storage-recovery cycles. Recovery efficiencies for the consecutive cycles were investigated for six cases with three simulated scenarios: (a) regular HT-ATES, (b) HT-ATES with density difference compensation using saline water, and (c) theoretical regular HT-ATES without free thermal convection. For the reference case, in which 80 °C water was injected into a high-permeability aquifer, regular HT-ATES had an efficiency of 0.40 after four consecutive recovery cycles. The density difference compensation method resulted in an efficiency of 0.69, approximating the theoretical case (0.76). Sensitivity analysis showed that the net efficiency increase by using the density difference compensation method instead of regular HT-ATES is greater for higher aquifer hydraulic conductivity, larger temperature difference between injection water and ambient groundwater, smaller injection volume, and larger aquifer thickness. This means that density difference compensation allows the application of HT-ATES in thicker, more permeable aquifers and with larger temperatures than would be considered for regular HT-ATES systems.

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Bodvarsson GS (1982) Mathematical modeling of the behavior of geothermal systems under exploitation. PhD Thesis, University of California at Berkeley; and as Rep. LBL-13937, Lawrence Berkeley Lab, Berkeley, CA

Bonte M, van Breukelen BM, Stuyfzand PJ (2013) Temperature-induced impact on groundwater quality and arsenic mobility in anoxic aquifer sediments used for both drinking water and shallow geothermal energy production. Water Res 47(14):5088–5100. doi:10.1016/j.watres.2013.05.049 CrossRef

Brons HJ, Griffioen J, Appelo CAJ, Zehnder AJB (1991) (Bio)geochemical reactions in aquifer material from a thermal energy storage site. Water Res 25(6):729–736. doi:10.1016/0043-1354(91)90048-U CrossRef

Brown DL, Silvey WD (1977) Artificial recharge to a freshwater-sensitive brackish-water sand aquifer. US Geol Surv Prof Pap 939

Buscheck TA, Doughty C, Tsang CF (1983) Prediction and analysis of a field experiment on a multilayered aquifer thermal energy storage system with strong buoyancy flow. Water Resour Res 19(5):1307–1315. doi:10.1029/WR019i005p01307 CrossRef

Doughty C, Hellström G, Tsang CF, Claesson J (1982) A dimensionless parameter approach to the thermal behavior of an aquifer thermal energy storage system. Water Resour Res 18(3):571–587. doi:10.1029/WR018i003p00571 CrossRef

Griffioen J, Appelo CAJ (1993) Nature and extent of carbonate precipitation during aquifer thermal energy storage. Appl Geochem 8(2):161–176. doi:10.1016/0883-2927(93)90032-C CrossRef

Guo W, Langevin CD (2002) User’s guide to SEAWAT: a computer program for simulation of three-dimensional variable-density ground-water flow. US Geol Surv Tech Water-Resour Invest 6-A7

Harbaugh AW, Banta ER, Hill MC, McDonald MG (2000) MODFLOW-2000, the US Geological Survey modular ground-water models: user guide to modularization concepts and the ground-water flow process. US Geol Surv Open-File Rep 00-92

Hartog N, Drijver B, Dinkla I, Bonte M (2013) Field assessment on the impact of Aquifer Thermal Energy Storage (ATES) systems on chemical and microbial groundwater compositions. European Geothermal Conference, Pisa, Italy, 3–7 June 2013

Hellström G, Tsang CF, Claesson J (1979) Heat storage in aquifers: buoyancy flow and thermal stratification problems. Institute of Technology, Lund, Sweden; and as Rep. LBL-14246, Lawrence Berkeley Lab, Berkeley, CA

Isdale JD, Morris R (1972) Physical properties of sea water solutions: density. Desalination 10(4):329–339. doi:10.1016/S0011-9164(00)80003-X CrossRef

Kabus F, Seibt P (2000) Aquifer Thermal Energy Storage for the Berlin Reichstag building: new seat of the German Parliament. Proceedings of the World Geothermal Congress 2000, Kyushu, Tohoku, Japan, May 28–June 10 2000

Langevin CD (2008) Modeling axisymmetric flow and transport. Ground Water 46(4):579–590. doi:10.1111/j.1745-6584.2008.00445.x CrossRef

Langevin CD, Thorne DT Jr., Dausman AM, Sukop MC, Guo W (2008) SEAWAT Version 4: a computer program for simulation of multi-species solute and heat transport. US Geological Surv Tech Meth 6-A22

Mathey B (1977) Development and resorption of a thermal disturbance in a phreatic aquifer with natural convection. J Hydrol 34(3–4):315–333. doi:10.1016/0022-1694(77)90139-1 CrossRef

Meyer CF, Todd DK (1973) Conserving energy with heat storage wells. Environ Sci Technol 7(6):512–516. doi:10.1021/es60078a009 CrossRef

Millero FJ, Poisson A (1981) International one-atmosphere equation of state of seawater. Deep-Sea Res 28A(6):625–629. doi:10.1016/0198-0149(81)90122-9 CrossRef

Miotliński K, Dillon PJ (2015) Relative recovery of thermal energy and fresh water in aquifer storage and recovery systems. Ground Water 53(6):877–884. doi:10.1111/gwat.12286 CrossRef

Miotliński K, Dillon PJ, Pavelic P, Barry K, Kremer S (2014) Recovery of injected freshwater from a brackish aquifer with a multiwell system. Ground Water 52(4):495–502. doi:10.1111/gwat.12089 CrossRef

Molz FJ, Melville JG, Parr AD, King DA, Hopf MT (1983a) Aquifer thermal energy storage: a well doublet experiment at increased temperatures. Water Resour Res 19(1):149–160. doi:10.1029/WR019i001p00149 CrossRef

Molz FJ, Melville JG, Güven O, Parr AD (1983b) Aquifer thermal energy storage: an attempt to counter free thermal convection. Water Resour Res 19(4):922–930. doi:10.1029/WR019i004p00922 CrossRef

Molz FJ, Parr AD, Andersen PF, Lucido VD, Warman JC (1979) Thermal energy storage in a confined aquifer: experimental results. Water Resour Res 15(6):1509–1514. doi:10.1029/WR015i006p01509 CrossRef

Oldenburg CM, Preuss K (1999) Plume separation by transient thermohaline convection in porous media. Geophys Res Lett 26(19):2997–3000. doi:10.1029/1999GL002360 CrossRef

Olsthoorn TN (1982) The clogging of recharge wells, main subjects. KIWA Communications-72, The Netherlands Testing and Research Institute, Rijswijk, The Netherlands

Palmer CD, Blowes DW, Frind EO, Molson JW (1992) Thermal energy storage in an unconfined aquifer, 1: field injection experiment. Water Resour Res 28(10):2845–2856. doi:10.1029/92WR01471 CrossRef

Pérez-Gonzaléz A, Urtiaga AM, Ibáñez R, Ortiz I (2012) State of the art and review on the treatment technologies of water reverse osmosis concentrates. Water Res 46(2):267–283. doi:10.1016/j.watres.2011.10.046 CrossRef

Réveillère A, Hamm V, Lesueur H, Cordier E, Goblet P (2013) Geothermal contribution to the energy mix of a heating network when using Aquifer Thermal Energy Storage: modeling and application to the Paris basin. Geothermics 47:69–79. doi:10.1016/j.geothermics.2013.02.005 CrossRef

Sanner B, Karytsas C, Mendrinos D, Ryback L (2003) Current status of ground source heat pumps and underground thermal energy storage in Europe. Geothermics 32(4–6):579–588. doi:10.1016/S0375-6505(03)00060-9 CrossRef

Sanner B, Kabus F, Seibt P, Bartels J (2005) Underground thermal energy storage for the German Parliament in Berlin: system concept and operational experiences. Proceedings of the World Geothermal Congress, Antalya, Turkey, 24–29 April 2005

Sauty JP, Gringarten AC, Menjoz A, Landel PA (1982) Sensible energy storage in aquifers, 1: theoretical study. Water Resour Res 18(2):245–252. doi:10.1029/WR018i002p00245 CrossRef

Schout G, Drijver B, Gutierrez-Neri M, Schotting R (2014) Analysis of recovery efficiency in high-temperature aquifer thermal energy storage: a Rayleigh-based method. Hydrogeol J 22(1):281–291. doi:10.1007/s10040-013-1050-8 CrossRef

Seibert S, Prommer H, Siade A, Harris B, Trefry M, Martin M (2014) Heat and mass transport during a groundwater replenishment trial in a highly heterogeneous aquifer. Water Resour Res 50(12):9463–9483. doi:10.1002/2013WR015219 CrossRef

Sharqawy MH, Lienhard VJH, Zubair SM (2010) Thermophysical properties of seawater: a review of existing correlations and data. Desalination Water Treat 16(1–3):354–380. doi:10.5004/dwt.2010.1079 CrossRef

Vandenbohede A, Louwyck A, Vlamynck N (2014) SEAWAT-based simulation of axisymmetric heat transport. Ground Water 52(6):908–915. doi:10.1111/gwat.12137 CrossRef

Van Lopik JH, Hartog N, Zaadnoordijk WJ, Cirkel DG, Raoof A (2015) Salinization in a stratified aquifer induced by heat transfer from well casings. Adv Water Resour 86A:32–45. doi:10.1016/j.advwatres.2015.09.025 CrossRef

Voss CI (1984) A finite-element simulation model for saturated-unsaturated, fluid-density-dependent ground-water flow with energy transport or chemically-reactive single-species solute transport. US Geol Surv Water Resour Invest Rep 84-4369

Wallis I, Prommer H, Post V, Vandenbohede A, Simmons CT (2013) Simulating MODFLOW-based reactive transport under radially symmetric flow conditions. Ground Water 51(3):398–413. doi:10.1111/j.1745-6584.2012.00978.x

Ward JD, Simmons CT, Dillon PJ (2007) A theoretical analysis of mixed convection in aquifer storage and recovery: how important are density effects? J Hydrol 343(3–4):169–186. doi:10.1016/j.jhydrol.2007.06.011 CrossRef

Zeghici RM, Oude Essink GHP, Hartog N, Sommer W (2015) Integrated assessment of variable density-viscosity flow for a high temperature aquifer thermal energy storage (HT-ATES) system in a deep geothermal reservoir. Geothermics 55:58–68. doi:10.1016/j.geothermics.2014.12.006

Zheng C, Wang PP (1999) MT3DMS: a modular three-dimensional multispecies transport model for simulation of advection, dispersion and chemical reactions of contaminant in ground-water systems: documentation and user’s guide. US Army Corps of Engineer Research and Development Center, Contract Report SERDP-99-1, University of Alabama, Vicksburg, MI

Zuurbier KG, Zaadnoordijk WJ, Stuyfzand PJ (2014) How multiple partially penetrating wells improve freshwater recovery of coastal aquifer storage and recovery (ASR) systems: a field and modeling study. J Hydrol 509:430–441. doi:10.1016/j.jhydrol.2013.11.057 CrossRef

Title: The use of salinity contrast for density difference compensation to improve the thermal recovery efficiency in high-temperature aquifer thermal energy storage systems
Authors: Jan H. van Lopik
Niels Hartog
Willem Jan Zaadnoordijk
Publication date: 01-08-2016
Publisher: Springer Berlin Heidelberg
Published in: Hydrogeology Journal / Issue 5/2016
Print ISSN: 1431-2174
Electronic ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-016-1366-2

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