Hydrogeological assessment of non-linear underground enclosures

[en] Excavations below the water table are usually undertaken by combining the protection of retaining walls with dewatering by pumping wells. Severe difficulties may arise if the retaining walls have defects. Therefore, their state must be determined and, if needed, the defects repaired or the dewatering system redesigned. The state of underground retaining walls can be evaluated using hydrogeological methods, but these methods are well-established only for linear excavations. The objective of this work is to propose a procedure to evaluate the state of non-linear underground enclosures by analyzing the groundwater response to pumping inside the enclosure. The proposed method, which is based on diagnostic plots (derivative of drawdown with respect to the logarithm of time), allows (1) determining if an underground non-linear enclosure has isolated openings or numerous defects and (2) computing its effective conductance or effective hydraulic conductivity. The methodology is tested with data collected during the excavation of a shaft required for the construction of the high speed train (HST) tunnel in Barcelona, Spain. The procedure can be applied using the wells drilled for dewatering. Although a test before the excavation is recommended to evaluate the underground retaining walls (Watertightness Assessment Test), the method can be applied using data collected at the beginning of the dewatering stage.

Research Center/Unit :

Hydrogeology & Environmental Geology

Disciplines :

Geological, petroleum & mining engineering

Author, co-author :

Pujades, Estanislao ; Université de Liège > Département ArGEnCo > Hydrogéologie & Géologie de l'environnement

Jurado Elices, Anna ; Université de Liège > Département ArGEnCo > Hydrogéologie & Géologie de l'environnement

Carrera, Jesus

Vázquez-Sunè, Enric

Dassargues, Alain ; Université de Liège > Département ArGEnCo > Hydrogéologie & Géologie de l'environnement

Language :

English

Title :

Hydrogeological assessment of non-linear underground enclosures

Publication date :

03 June 2016

Journal title :

Engineering Geology

ISSN :

0013-7952

Publisher :

Elsevier Science, Amsterdam, Netherlands

Volume :

207

Pages :

91-102

Peer reviewed :

Peer Reviewed verified by ORBi

European Projects :

FP7 - 600405 - BEIPD - Be International Post-Doc - Euregio and Greater Region

Funders :

University of Liège and the EU through the Marie Curie BeIPD-COFUND postdoctoral fellowship programme (2014–2016)
CE - Commission Européenne

Available on ORBi :

since 10 May 2016

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Bibliography

Bear, J., 1972. Dynamics of Fluids in Porous Media. Elsevier, New York
Bruce, D., De Paoli, B., Mascardi, C., Mongilardi, E., 1989.Monitoring and quality control of a 100 meter deep diaphragm wall. In: Burland, J., Mitchell, J. (Eds.), Pilling and Deep Foundations. A.A Balkema, Rotterdam, pp. 23-32
Cooper, H.H., Jacob, C.E., 1946.A generalized graphical method for evaluating formation constants and summarizing well-field history. Eos Trans. AGU 27 (4), 526-534
Croce, P., Modoni, G., 2007.Design of jet-grouting cut-off. Ground Improv. 11 (1), 11-19
Culí, L., Pujades, E., Vázquez-Suñé, E., Jurado, A., 2016.Modelling of the EPB TBM shield tunnelling advance as a tool for geological characterization. Tunn. Undergr. Space Technol. 56, 12-21
Davis, G.M., Horswill, P., 2002.Groundwater control and stability in an excavation in Magnesian Limestone near Sunderland, NE England. Eng. Geol. 66, 1-18
El-Nahhas, F.M., 1999.Soft ground tunnelling in Egypt: geotechnical challenges and expectations. Tunn. Undergr. Space Technol. 14 (3), 245-256
Flora, A., Modoni, G., Lirer, S., Croce, P., 2013.The diameter of single, double and triple fluid jet grouting columns: prediction method andfield trial results. Geotechnique 63 (11), 934-945
Forth, R.A., 2004.Groundwater and geotechnical aspects of deep excavations in Hong Kong. Eng. Geol. 72, 253-260
Gulhati, S., Datta, M., 2005.Geotechnical Engineering. Tata McGraw Hill, Delhi
Hantush, M.S., 1956.Analysis of data from pumping tests in leaky aquifer. EOS Trans. Am. Geophys. Union 37 (6), 702-714
Jurado, A., Bolster, D., Pujades, E., Vázquez-Suñè, E., Carrera, J., 2009.A methodology for analysing the drainage system in excavations between sheet pile walls. Proceedings of the 9th International Conference on Tunnel Construction and Underground Structures. Ljubljana, Slovenia, pp. 93-98
Jurado, A., De Gaspari, F., Vilarrasa, V., Bolster, D., Sánchez-Vila, X., Frenàndez-Garcia, D., Tartakovsky, D.M., 2011.Probabilistic analysis of groundwater-related risks at subsurface excavation sites. Eng. Geol. 125, 35-44
Knight, D.J., Smith, G.L., Sutton, J.S., 1996.Sizewell B foundation dewatering-system design, construction and performance monitoring. Geotechnique 46 (3), 473-490
Medina, A., Carrera, J., 1996.Coupled estimation offlow and solute transports parameters. Water Resour. Res. 32 (10), 3063-3076
Medina, A., Carrera, J., 2003.Computational different type of data. Geostatistical inversion of coupled problems: dealing with computational burden and different types of data. J. Hydrol. 281 (4), 251-264
Medina, A., Alcolea, A., Carrera, J., Castro, L.F., 2000.Modelos deflujo y transporte en la geosfera: Código TRANSIN IV. [Flow and transport modelling in the geosphere: The code TRANSIN IV]. IV Jornadas de Investigación y Desarrollo Tecnológico de Gestión de Residuos Radioactivos de ENRESA. Technical publication, pp. 195-200 (9/2000) Modoni, G., Croce, P., Mongiovì, L., 2006.Theoretical modeling of jet grouting. Geotechnique 56 (5), 335-347
Modoni, G., Croce, P., Mongiovì, L., 2006. Theoretical modeling of jet grouting. Geotechnique 56 (5), 335-347
Nikbakhtan, B., Ahangari, K., Rahmani, N., 2010.Estimation of jet grouting parameters in Shahriar dam, Iran. Int. Sci. Technol. 20, 472-477
Paikowsky, S., Chernauskas, L., 2003.Review of deep foundations integrity testing methods and case histories. BSCES-Geo-Institute Deep Foundations Seminar
Papadopulos, I.S., 1967.Drawdown distribution around a large diameter well. Symp. on Groundwater Hydrology, San Fransisco. Proc. Amer. Water Resources Assoc. Vol. 4, pp. 157-168
Papadopulos, I.S., Cooper, H.H., 1967.Drawdown in a well of large diameter. Water Resour. Res. 3 (1), 241-244
Pujades, P., Vázquez-Suñe, E., Carrera, J., 2008.Optimización de las lecturas de caudal durante el drenaje de obras y ensayos de bombeo. In: Carmen, M., Vallejos, A., Valverde, M., Lambán, L. (Eds.), El agua y las infraestructuras en el medio subterráneo. Instituto geológico y minero de España, Madrid, pp. 417-422
Pujades, P., Mascuñano, E., Jurado, A., Vázquez-Suñe, E., Carrera, J., 2009. Detection faulty joints during the construction of tunnels excavated by the cut and cover method. Proceedings of the 9th International Conference on Tunnel Construction and Underground Structures. University of Ljubljana, Faculty of Natural Sciences and Engineering, Ljubljana, Slovenia. ISBN: 978-961-6047-64-7, pp. 138-147
Pujades, E., Carrera, J., Vàzquez-Suñé, E., Jurado, A., Vilarrasa, V., Mascuñano-Salvador, E., 2012a. Hydraulic characterization of diaphragm walls for cut and cover tunnelling. Eng. Geol. 125, 1-10
Pujades, E., López, A., Carrera, J., Vàzquez-Suñé, E., Jurado, A., 2012b. Barrier effect of underground structures on aquifers. Eng. Geol. 145-146, 41-49
Pujades, E., Vàzquez-Suñé, E., Carrera, J., Jurado, A., 2014a. Dewatering of a deep excavation undertaken in a layered soil. Eng. Geol. 178, 15-27
Pujades, E., Vàzquez-Suñé, E., Carrera, J., Vilarrasa, V., De Simone, S., Jurado, A., Ledesma, A., Ramos, G., Lloret, A., 2014b. Deep enclosures versus pumping to reduce settlements during shaft excavations. Eng. Geol. 169, 100-111
Pujades, E., Vázquez-Suñè, E., Culí, L., Carrera, J., Ledesma, J., Jurado, A., 2015. Hydrogeological impact assessment by tunnelling at sites of high sensitivity. Eng. Geol. 193, 421-434
Rausche, F., 2004.Non destructive evaluation of deep foundations. Proceedings of the Fifth International Conference on Case Histories in Geotechnical Engineering, New York
Renard, P., Glenz, D., Mejias, M., 2008.Understanding diagnostic plots for well-test interpretation. Hydrogeol. J. 17, 589-600
Rienzo, F., Oreste, P., Pelizza, S., 2008.Subsurface geological-geotechnical modelling to sustain underground civil planning. Eng. Geol. 96, 187-204
Ross, R.R., Beljin, M.S., 1998.Evaluation of containment systems using hydraulic head data. J. Environ. Eng. 124 (6), 575-578
Shen, S.L., Wang, Z.F., Sun, W.J., Wang, L.B., Horpibulsuk, S., 2013a. Afield trial of horizontal jet grouting using the composite-pipe method in the soft deposits of Shanghai. Tunn. Undergr. Space Technol. 35, 142-151
Shen, S.L., Wang, Z.F., Yang, J., Ho, C.E., 2013b. Generalized approach for prediction of jet grout column diameter. J. Geotech. Geoenviron. Eng. 139, 2060-2069
Thierry, P., Prunier-Leparmentier, A.-M., Lembezat, C., Vanoudheusden, E., Vernoux, J.-F., 2009.3D geological modelling at urban scale and mapping of ground movement susceptibility from gypsum dissolution: the Paris example (France). Eng. Geol. 105, 51-64
Trinchero, P., Sanchez-Vila, X., Copty, N., Findikakis, A., 2008.A new method for the interpretation of pumping tests in leaky aquifers. Ground Water 46 (1), 133-143
UPC, 2003.Code Visual Transin 1.1 R65. Developed in the Department of Geotechnical Engineering and Geosciences (ETCG). UPC
Vilarrasa, V., Jurado-Elices, A., Vázquez-Suñé, E., Carrera, J., Pujades-Garnés, E., 2009.La modelación: un elemento clave en el seguimiento hidrogeológico de las obras de la LAV-tramo La Torrassa-Sants. Proceedings: Jornadas sobre el Agua y las Infraestructuras en el Medio Subterráneo. AIH-GE, Barcelona, pp. 235-242
Vilarrasa, V., Carrera, J., Jurado, A., Pujades, E., Vazquez-Sune, E., 2011.A methodology for characterizing the hydraulic effectiveness of an annular low-permeability barrier. Eng. Geol. 120, 68-80
Wang, Z.F., Shen, S.L., Ho, C.E., Kim, Y.Y., 2013.Investigation offield-installation effects of horizontal twin-jet grouting in Shanghai soft soil deposits. Can. Geotech. J. 50, 288-297
Wen, D., 2005.Chapter 13 use of jet grouting in deep excavations. In: Buddhima, Indraratna, Chu, Jian (Eds.), Ground Improvement-Case HistoriesElsevier Geo-Engineering Book Series Vol. 3. Elsevier, Oxford, pp. 357-370
White, B., Nagy, M., Allin, R., 2008.Comparing cross-hole sonic logging and low-strain integrity testing results. In: Santos, J.A. (Ed.), The 8th International Application of Stress Wave Theory to Piles. IOS Press BV, Amsterdam
Wong, I.H., Poh, T.Y., 2005.Chapter 14 a case history of jet grouting in marine clays. In: Buddhima, Indraratna, Chu, Jian (Eds.), Ground Improvement-Case HistoriesElsevier Geo-Engineering Book Series. Elsevier, Oxford, pp. 371-408
Wu, Y.X., Shen, S.L., Xu, Y.S., Yin, Z.Y., 2015a. Characteristics of groundwater seepage with cut-offwall in gravel aquifer. I:field observations. Can. Geotech. J. 52, 1526-1538
Wu, Y.X., Shen, S.L., Xu, Y.S., Yin, Z.Y., 2015b. Characteristics of groundwater seepage with cut-offwall in gravel aquifer. I:field observations. Can. Geotech. J. 52, 1539-1549
Xanthakos, P., Abramson, L., Bruce, D., 1994.Ground Control and Improvement. John Wiley and Sons, United States of America
Xu, Y.S., Shen, S.L., Du, Y.J., 2009.Geological and hydrogeological environment in Shangai with geohazards to construction and maintenance of infrastructures. Eng. Geol. 109, 241-254