Numerical investigation of temperature distribution and thermal performance while charging-discharging thermal energy in aquifer

A three-dimensional (3D) coupled thermo-hydrogeological numerical model for a confined aquifer thermal energy storage (ATES) system underlain and overlain by rock media has been presented in this paper. The ATES system operates in cyclic mode. The model takes into account heat transport processes of advection, conduction and heat loss to confining rock media. The model also includes regional groundwater flow in the aquifer in the longitudinal and lateral directions, geothermal gradient and anisotropy in the aquifer. Results show that thermal injection into the aquifer results in the generation of a thermal-front which grows in size with time. The thermal interference caused by the premature thermal-breakthrough when the thermal-front reaches the production well results in the fall of system performance and hence should be avoided. This study models the transient temperature distribution in the aquifer for different flow and geological conditions which may be effectively used in designing an efficient ATES project by ensuring safety from thermal-breakthrough while catering to the energy demand. Parameter studies are also performed which reveals that permeability of the confining rocks; well spacing and injection temperature are important parameters which influence transient heat transport in the subsurface porous media. Based on the simulations here a safe well spacing is proposed. The thermal energy produced by the system in two seasons is estimated for four different cases and strategy to avoid the premature thermal-breakthrough in critical cases is also discussed. The present numerical model results are validated using an analytical model and also compared with results from an experimental field study performed at an ATES test site at Auburn University. The present model results agree with the analytical model very well and have been found to approximate the field results quite well.

[1]  Kevin Rafferty Ground water issues in geothermal heat pump systems. , 2003, Ground water.

[2]  Wenxing Shi,et al.  A potential solution for thermal imbalance of ground source heat pump systems in cold regions: Ground source absorption heat pump , 2013 .

[3]  Diana M. Allen,et al.  Influence of geologic layering on heat transport and storage in an aquifer thermal energy storage system , 2014, Hydrogeology Journal.

[4]  Thomas A. Buscheck,et al.  Prediction and analysis of a field experiment on a multilayered aquifer thermal energy storage system with strong buoyancy flow , 1983 .

[5]  Fred J. Molz,et al.  Aquifer thermal energy storage : A well doublet experiment at increased temperatures , 1983 .

[6]  J. Bear Hydraulics of Groundwater , 1979 .

[7]  Youngseuk Keehm,et al.  Numerical modeling of aquifer thermal energy storage system , 2010 .

[8]  Steffen Müthing,et al.  DuMux: DUNE for multi-{phase,component,scale,physics,…} flow and transport in porous media , 2011 .

[9]  Sang Jin Jeong,et al.  Numerical Modeling on the Performance of Aquifer Thermal Energy Storage System under Cyclic Flow Regime , 2008 .

[10]  Thomas Driesner,et al.  Realistic simulation of an aquifer thermal energy storage: Effects of injection temperature, well placement and groundwater flow , 2014 .

[11]  Burkhard Sanner,et al.  Underground Thermal Energy Storage for the German Parliament in Berlin, System Concept and Operational Experiences , 2005 .

[12]  Johan Claesson,et al.  Buoyancy flow at a two-fluid interface in a porous medium: Analytical studies , 1988 .

[13]  J. Lienhard A heat transfer textbook , 1981 .

[14]  V. A. Jambhekar,et al.  Free-Flow–Porous-Media Coupling for Evaporation-Driven Transport and Precipitation of Salt in Soil , 2015, Transport in Porous Media.

[15]  N. W. Lanfredi,et al.  HP 67/97 calculator waves application programs , 1987 .

[16]  M. O'Sullivan,et al.  Modelling of chemical and thermal changes in well pn-26 palinpinon geothermal field, Philippines , 1991 .

[17]  Mahmoud Bakr,et al.  Efficiency of and interference among multiple Aquifer Thermal Energy Storage systems; A Dutch case study , 2013 .

[18]  B. Sanner SHALLOW GEOTHERMAL ENERGY , 2001 .

[20]  Allan D. Woodbury,et al.  Thermal sustainability of groundwater-source cooling in Winnipeg, Manitoba , 2005 .

[21]  H. Class,et al.  Numerical Investigation on the Benefits of Preheating for an Increased Thermal Radius of Influence During Steam Injection in Saturated Soil , 2016, Transport in Porous Media.

[22]  Laurent Trenty,et al.  A benchmark study on problems related to CO2 storage in geologic formations , 2009 .

[23]  Cycles in finite samples and cumulative processes of higher orders , 1988 .

[24]  M. M. Mohan Kumar,et al.  Analytical solutions for transient temperature distribution in a geothermal reservoir due to cold water injection , 2014, Hydrogeology Journal.

[25]  Johan R. Valstar,et al.  The impact of aquifer heterogeneity on the performance of aquifer thermal energy storage , 2013 .

[26]  V. Stefánsson,et al.  Geothermal reinjection experience , 1997 .

[27]  A. Gringarten,et al.  Sensible energy storage in aquifers: 1. Theoretical study , 1982 .

[28]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[29]  K. Lee Effects of regional groundwater flow on the performance of an aquifer thermal energy storage system under continuous operation , 2014, Hydrogeology Journal.

[30]  Olaf Kolditz,et al.  A Dynamic Flow Simulation Code Intercomparison based on the Revised Static Model of the Ketzin Pilot Site , 2013 .

[31]  Stefan Kranz,et al.  Simulation and Data Based Optimisation of an Operating Seasonal Aquifer Thermal Energy Storage , 2010 .

[32]  M. Kumar,et al.  A numerical model for transient temperature distribution in an aquifer thermal energy storage system with multiple wells , 2015 .

[33]  Olivier Banton,et al.  Modelling of heat transfer with the random walk method. Part 2. Application to thermal energy storage in fractured aquifers , 1999 .

[34]  Diana M. Allen,et al.  Heat transport simulations in a heterogeneous aquifer used for aquifer thermal energy storage (ATES) , 2010 .

[35]  Antonio Galgaro,et al.  Thermal short circuit on groundwater heat pump , 2013 .

[36]  C F Meyer,et al.  Conserving energy with heat storage wells. , 1973, Environmental science & technology.

[37]  Hans Hoes,et al.  An aquifer thermal storage system in a Belgian hospital: Long-term experimental evaluation of energy , 2011 .

[38]  W. H. Somerton Thermal Properties and Temperature-Related Behavior of Rock/Fluid Systems , 1992 .

[39]  P. V. Gaans,et al.  Thermal performance and heat transport in aquifer thermal energy storage , 2014, Hydrogeology Journal.

[40]  R. Schotting,et al.  Analysis of recovery efficiency in high-temperature aquifer thermal energy storage: a Rayleigh-based method , 2014, Hydrogeology Journal.

[41]  K. Lee,et al.  Numerical Simulation on the Continuous Operation of an Aquifer Thermal Energy Storage System Under Regional Groundwater Flow , 2011 .

[42]  Mohammad Hassan Saidi,et al.  Performance analysis and parametric study of thermal energy storage in an aquifer coupled with a heat pump and solar collectors, for a residential complex in Tehran, Iran , 2014 .

[43]  C. Doughty,et al.  A Dimensionless Parameter Approach to the Thermal Behavior of an Aquifer Thermal Energy Storage System , 1982 .