Effect of Model Dimension in Numerical Simulation on Assessment of Water Inflow to Tunnel in Discontinues Rock
Groundwater inflow to the tunnels is one of the most
important problems in tunneling operation. The objective of this
study is the investigation of model dimension effects on tunnel inflow
assessment in discontinuous rock masses using numerical modeling.
In the numerical simulation, the model dimension has an important
role in prediction of water inflow rate. When the model dimension is
very small, due to low distance to the tunnel border, the model
boundary conditions affect the estimated amount of groundwater flow
into the tunnel and results show a very high inflow to tunnel. Hence,
in this study, the two-dimensional universal distinct element code
(UDEC) used and the impact of different model parameters, such as
tunnel radius, joint spacing, horizontal and vertical model domain
extent has been evaluated. Results show that the model domain extent
is a function of the most significant parameters, which are tunnel
radius and joint spacing.
[1] H. Farhadian, A. Aalianvari, H. Katibeh, “Optimization of Analytical
Equations of Groundwater Seepage into Tunnels: A Case Study of
Amirkabir Tunnel,” Journal geological society of India, 80 (1): 96-100,
2012. doi: 0016-7622/2012-80-1-96/$
[2] H. Farhadian, H. Katibeh, A.R. Sayadi, “Prediction of Site Groundwater
Rating (SGR) for Amirkabir Tunnel Using Artificial Neural Networks,”
International Journal of Mining, Metallurgy & Mechanical Engineering
(IJMMME) 1(1), 2013.
[3] M. El Tani, “Circular tunnel in a semi-infinite aquifer,” Tunn Undergr
Space Technol 18(1):49–55, 2003. doi:10.1016/S0886-7798(02)00102-5
[4] P. Perrochet, “Confined flow into a tunnel during progressive drilling:
An analytical solution,” Ground Water 43(6):943–946, 2005. doi:
10.1111/j.1745-6584.2005.00108.x
[5] D. Kolymbas and P. Wagner, “Groundwater ingress to tunnels – the
exact analytical solution,” Tunn Undergr Space Technol 22(1):23–27,
2007. doi:10.1016/j.tust.2006.02.001
[6] P. Gattinoni, L. Scesi and S. Terrana, “Hydrogeological risk analysis for
tunneling in anisotropic rock masses,” In: Proceedings of the ITAAITES
World Tunnel Congress “Underground Facilities for Better
Environment & Safety”, Arga, India, pp. 1736–174, 2008.
[7] J. Molinero, J. Samper and R. Juanes, “Numerical modeling of the
transient hydrogeological response produced by tunnel construction in
fractured bedrocks,” Eng Geol 64(4):369–386, 2002.
doi:10.1016/S0013-7952(01)00099-0
[8] J.H. Hwang, and C.C. Lu, “A semi-analytical method for analyzing the
tunnel water inflow,” Tunn Undergr Space Technol 22(1):39– 46, 2007.
doi:10.1016/j.tust.2006.03.003
[9] C. Zangerl, E. Eberhardt, K.F. Evans and S. Loew, “Consolidation
settlements above deep tunnels in fractured crystalline rock: part 2,
numerical analysis of the Gotthard highway tunnel case study,” Int J
Rock Mech Min Sci 45(8):1211–1225, 2008.
[10] P. Gattinoni and L. Scesi, “An empirical equation for tunnel inflow
assessment: application to sedimentary rock masses,” Hydrogeology J
18(8):1797–1810, 2010. doi: 10.1007/s10040-010-0674-1
[11] K. Esmaieli, J. Hadjigeorgiou and M. Grenon, “Estimating geometrical
and mechanical REV based on synthetic rock mass models at Brunswick
Mine,” Int J Rock Mech Min Sci 47(6):915–926, 2010.
doi:10.1016/j.ijrmms.2010.05.010
[12] B. Indraratna and P. Ranjith, “Effects of boundary conditions and
boundary block size on inflow to an underground excavation – sensivity
analysis,” IMWA Proceedings, 1998.
[13] D. Cesano, A.C. Bagtzoglou and B. Olofsson, “Quantifying fractured
rock hydraulic heterogeneity and groundwater inflow prediction in
underground excavations: the heterogeneity index,” Tunn Undergr Space
Technol 18(1):19 –34, 2003.
[14] J. Moon and G. Fernandez, “Effect of Excavation-Induced Groundwater
Level Drawdown on Tunnel Inflow in a Jointed Rock Mass,” Eng Geol
110(3-4):33–42, 2010. doi:10.1016/j.enggeo.2009.09.002
[15] J. Moon and S. Jeong, “Effect of highly pervious geological features on
ground water flow into a tunnel,” Eng Geol 117(3-4):207–216, 2011.
doi:10.1016/j.enggeo.2010.10.019
[16] C. Butscher, “Steady-state groundwater inflow into a circular tunnel,”
Tunn Undergr Space Technol 32:158–167, 2012.
doi:10.1016/j.tust.2012.06.007
[17] H. Farhadian, H. Katibeh, “Groundwater Seepage Estimation into
Amirkabir Tunnel Using Analytical Methods and DEM and SGR
Method,” World Academy of Science, Engineering and Technology,
International Journal of Civil, Structural, Construction and Architectural
Engineering 9(3), 2015.
[1] H. Farhadian, A. Aalianvari, H. Katibeh, “Optimization of Analytical
Equations of Groundwater Seepage into Tunnels: A Case Study of
Amirkabir Tunnel,” Journal geological society of India, 80 (1): 96-100,
2012. doi: 0016-7622/2012-80-1-96/$
[2] H. Farhadian, H. Katibeh, A.R. Sayadi, “Prediction of Site Groundwater
Rating (SGR) for Amirkabir Tunnel Using Artificial Neural Networks,”
International Journal of Mining, Metallurgy & Mechanical Engineering
(IJMMME) 1(1), 2013.
[3] M. El Tani, “Circular tunnel in a semi-infinite aquifer,” Tunn Undergr
Space Technol 18(1):49–55, 2003. doi:10.1016/S0886-7798(02)00102-5
[4] P. Perrochet, “Confined flow into a tunnel during progressive drilling:
An analytical solution,” Ground Water 43(6):943–946, 2005. doi:
10.1111/j.1745-6584.2005.00108.x
[5] D. Kolymbas and P. Wagner, “Groundwater ingress to tunnels – the
exact analytical solution,” Tunn Undergr Space Technol 22(1):23–27,
2007. doi:10.1016/j.tust.2006.02.001
[6] P. Gattinoni, L. Scesi and S. Terrana, “Hydrogeological risk analysis for
tunneling in anisotropic rock masses,” In: Proceedings of the ITAAITES
World Tunnel Congress “Underground Facilities for Better
Environment & Safety”, Arga, India, pp. 1736–174, 2008.
[7] J. Molinero, J. Samper and R. Juanes, “Numerical modeling of the
transient hydrogeological response produced by tunnel construction in
fractured bedrocks,” Eng Geol 64(4):369–386, 2002.
doi:10.1016/S0013-7952(01)00099-0
[8] J.H. Hwang, and C.C. Lu, “A semi-analytical method for analyzing the
tunnel water inflow,” Tunn Undergr Space Technol 22(1):39– 46, 2007.
doi:10.1016/j.tust.2006.03.003
[9] C. Zangerl, E. Eberhardt, K.F. Evans and S. Loew, “Consolidation
settlements above deep tunnels in fractured crystalline rock: part 2,
numerical analysis of the Gotthard highway tunnel case study,” Int J
Rock Mech Min Sci 45(8):1211–1225, 2008.
[10] P. Gattinoni and L. Scesi, “An empirical equation for tunnel inflow
assessment: application to sedimentary rock masses,” Hydrogeology J
18(8):1797–1810, 2010. doi: 10.1007/s10040-010-0674-1
[11] K. Esmaieli, J. Hadjigeorgiou and M. Grenon, “Estimating geometrical
and mechanical REV based on synthetic rock mass models at Brunswick
Mine,” Int J Rock Mech Min Sci 47(6):915–926, 2010.
doi:10.1016/j.ijrmms.2010.05.010
[12] B. Indraratna and P. Ranjith, “Effects of boundary conditions and
boundary block size on inflow to an underground excavation – sensivity
analysis,” IMWA Proceedings, 1998.
[13] D. Cesano, A.C. Bagtzoglou and B. Olofsson, “Quantifying fractured
rock hydraulic heterogeneity and groundwater inflow prediction in
underground excavations: the heterogeneity index,” Tunn Undergr Space
Technol 18(1):19 –34, 2003.
[14] J. Moon and G. Fernandez, “Effect of Excavation-Induced Groundwater
Level Drawdown on Tunnel Inflow in a Jointed Rock Mass,” Eng Geol
110(3-4):33–42, 2010. doi:10.1016/j.enggeo.2009.09.002
[15] J. Moon and S. Jeong, “Effect of highly pervious geological features on
ground water flow into a tunnel,” Eng Geol 117(3-4):207–216, 2011.
doi:10.1016/j.enggeo.2010.10.019
[16] C. Butscher, “Steady-state groundwater inflow into a circular tunnel,”
Tunn Undergr Space Technol 32:158–167, 2012.
doi:10.1016/j.tust.2012.06.007
[17] H. Farhadian, H. Katibeh, “Groundwater Seepage Estimation into
Amirkabir Tunnel Using Analytical Methods and DEM and SGR
Method,” World Academy of Science, Engineering and Technology,
International Journal of Civil, Structural, Construction and Architectural
Engineering 9(3), 2015.
@article{"International Journal of Earth, Energy and Environmental Sciences:69636", author = "Hadi Farhadian and Homayoon Katibeh", title = "Effect of Model Dimension in Numerical Simulation on Assessment of Water Inflow to Tunnel in Discontinues Rock", abstract = "Groundwater inflow to the tunnels is one of the most
important problems in tunneling operation. The objective of this
study is the investigation of model dimension effects on tunnel inflow
assessment in discontinuous rock masses using numerical modeling.
In the numerical simulation, the model dimension has an important
role in prediction of water inflow rate. When the model dimension is
very small, due to low distance to the tunnel border, the model
boundary conditions affect the estimated amount of groundwater flow
into the tunnel and results show a very high inflow to tunnel. Hence,
in this study, the two-dimensional universal distinct element code
(UDEC) used and the impact of different model parameters, such as
tunnel radius, joint spacing, horizontal and vertical model domain
extent has been evaluated. Results show that the model domain extent
is a function of the most significant parameters, which are tunnel
radius and joint spacing.
", keywords = "Water inflow, Tunnel, Discontinues rock, Numerical
simulation.", volume = "9", number = "4", pages = "350-4", }
