Hydrochemical changes induced by underground pumped storage hydropower and their associated impacts

Pujades, Estanislao; Jurado, Anna; Orban, Philippe; Ayora, Carlos; Poulain, Angélique; Goderniaux, Pascal; Brouyère, Serge; Dassargues, Alain

doi:10.1016/j.jhydrol.2018.06.041

Cited by 31 publications

(25 citation statements)

References 41 publications

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“…Impacts of the water exchanges on the groundwater flow conditions and on the UPHS efficiency evolution have been also investigated (Poulain et al, 2016;Pujades et al, 2016;Bodeux et al, 2017;Pujades et al, 2017a). Finally, Pujades et al (2017bPujades et al ( , 2018 have investigated quantitatively potential hydrochemical impacts induced by UPHS when abandoned mines are used as underground reservoirs. They have simulated chemical changes associated to UPHS as water tends to evolve chemically to reach chemical equilibrium with the atmosphere (in the surface reservoir) and with the surrounding porous medium (in the underground reservoir).…”

Section: U N C O R R E C T E D P R O O Fmentioning

confidence: 99%

“…Hydrochemical changes vary depending on the chemical composition of the porous medium. Pujades et al (2018) studied them under three different scenarios that differed in the chemical composition of the porous medium. They consider the presence of only pyrite, pyrite and calcite or only calcite.…”

Section: U N C O R R E C T E D P R O O Fmentioning

confidence: 99%

“…The actual future frequency of pumping and discharge phases cannot be known in advance as it depends on numerous factors (Pujades et al, 2018). Therefore, day/night cycles are considered defining regular pumping and discharge phases allowing to obtain representative results for prediction.…”

Section: Pumping/discharge Frequenciesmentioning

confidence: 99%

“…This assumption is reasonable because water is not stagnant and is mostly moving in the surface reservoir. Anyway, if water pO 2 and pCO 2 do not reach completely chemical equilibrium with the atmosphere in the upper reservoir, chemical reactions are the same but their consequences are mitigated as shown in Pujades et al (2018).…”

Section: System Behaviormentioning

confidence: 99%

“…The chemistry of the discharged water depends on the previously pumped water that is aerated in the surface reservoir before to be discharged. Thus, successive iterations with increasing simulated periods are performed following the same procedure than Pujades et al (2018). The chemical characteristics of the discharged water are derived from the previous iteration results and are reintroduced in each iteration.…”

Section: Simulation Strategymentioning

confidence: 99%

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Parametric assessment of hydrochemical changes associated to underground pumped hydropower storage

Pujades

Jurado

Orban

et al. 2019

Science of The Total Environment

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Underground pumped hydropower storage (UPHS) using abandoned mines is an alternative to store and produce electricity in flat regions. Excess of electricity is stored in form of potential energy by pumping mine water to a surface reservoir. When the demand of electricity increases, water is discharged into the mine (i.e., underground reservoir) through turbines producing electricity. During the complete operational process of UPHS plants, hydrochemical characteristics of water evolve continuously to be in equilibrium successively with the atmosphere (in the surface reservoir) and the surrounding porous medium (in the underground reservoir). It may lead to precipitation and/or dissolution of minerals and their associated consequences, such as pH variations. Induced hydrochemical changes may have an impact on the environment and/or the efficiency (e.g., corrosions and incrustations affect facilities) of UPHS plants. The nature of the hydrochemical changes is controlled by the specific chemical characteristics of the surrounding porous medium. However, the magnitude of the changes also depends on other variables, such as hydraulic parameters. The role of these parameters is established to define screening criteria and improve the selection procedure of abandoned mines for constructing UPHS plants. This work evaluates the role of the main hydrogeological factors for three different chemical composition of the porous medium. Results are obtained by means of numerical reactive transport modeling. Potential impacts on the environment (mainly on groundwater and surface water bodies) and on the efficiency of the UPHS plants vary considerably from a hydraulic parameter to another showing the need for a detailed characterization before choosing locations of future UPHS plants.

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Section: U N C O R R E C T E D P R O O Fmentioning

confidence: 99%

Section: U N C O R R E C T E D P R O O Fmentioning

confidence: 99%

Section: Pumping/discharge Frequenciesmentioning

confidence: 99%

Section: System Behaviormentioning

confidence: 99%

Section: Simulation Strategymentioning

confidence: 99%

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Parametric assessment of hydrochemical changes associated to underground pumped hydropower storage

Pujades

Jurado

Orban

et al. 2019

Science of The Total Environment

Self Cite

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A meso‐damage‐based constitutive model for yellow sandstone under dry–wet cycles

Qin,

Zhang,

Mao

et al. 2024

Deep Underground Science and Engineering

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The mechanical properties of rocks weaken under dry–wet cycles. This weakening may significantly modify the safety reserve of underground caverns or reservoir bank slopes. However, meso‐damage has not been carefully studied based on micromechanical observations and analyses. Therefore, in this study, meso‐damage of a yellow sandstone is investigated and a meso‐damage‐based constitutive model for dry–wet cycles is proposed. First, computed tomography scanning and uniaxial compression tests were conducted on yellow sandstones under different dry–wet cycles. Second, the evolution of rock mesostructures and the damage mechanism subjected to dry–wet cycles were simulated using the discrete element method with Particle Flow Code in 2 Dimensions (PFC2D) software. Third, a constitutive model was proposed based on the meso‐statistical theory and damage mechanics. Finally, this constitutive model was verified with the experimental results to check its prediction capability. It is found that the radius and number of pore throats in the sandstone increase gradually with the number of dry–wet cycles, and the pore structure connectivity is also improved. The contact force of sandstone interparticle cementation decreases approximately linearly and the continuity of the particle contact network is continuously broken. The meso‐deformation and strength parameters show similar declining patterns to the modulus of elasticity and peak strength of the rock sample, respectively. This meso‐damage‐based constitutive model can describe well the rock deformation in the initial pressure density stage and the damage stage under the coupling effect of dry–wet cycles and loads.

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Life cycle sustainability assessment of pumped hydro energy storage

Guo

Yao

et al. 2019

Int J Energy Res

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Hydrochemical changes induced by underground pumped storage hydropower and their associated impacts

Cited by 31 publications

References 41 publications

Parametric assessment of hydrochemical changes associated to underground pumped hydropower storage

Parametric assessment of hydrochemical changes associated to underground pumped hydropower storage

A meso‐damage‐based constitutive model for yellow sandstone under dry–wet cycles

Life cycle sustainability assessment of pumped hydro energy storage

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