Numerical Analyses of the Influence of Blast-Induced Damaged Rock Around Shallow Tunnels in Brittle Rock

Most of the railway tunnels in Sweden are shallow-seated (<20 m of rock cover) and are located in hard brittle rock masses. The majority of these tunnels are excavated by drilling and blasting, which, consequently, result in the development of a blast-induced damaged zone around the tunnel bounda...

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Published in	Rock mechanics and rock engineering Vol. 42; no. 3; pp. 421 - 448
Main Authors	Saiang, David, Nordlund, Erling
Format	Journal Article
Language	English
Published	Vienna Springer Vienna 01.06.2009 Springer Springer Nature B.V
Subjects	Applied sciences Blast-induced damaged zone Blasting Brittle rock Buildings. Public works Civil Engineering Computation methods. Tables. Charts Deformation Earth and Environmental Science Earth Sciences Exact sciences and technology Geophysics/Geodesy Geotechnics Gruv- och berganläggningsteknik Inherent rock properties Mining and Rock Engineering Numerical analyses Numerical analysis Original Paper Overbreak Rock mass strength and stiffness Rocks Shallow tunnels Soil mechanics. Rocks mechanics Structural analysis. Stresses Tunnels Tunnels, galleries Sweden Europe Inherent rock properties Brittle rock Blast-induced damaged zone Rock mass strength and stiffness Shallow tunnels Overbreak Numerical analyses Stress analysis Rock mechanics Brittle material Blasting operation Shallow tunnel Rock mass Railway tunnel Design Geometry Numerical analysis Failure analysis Tunnel driving
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ISSN	0723-2632 1434-453X 1434-453X
DOI	10.1007/s00603-008-0013-1

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Abstract	Most of the railway tunnels in Sweden are shallow-seated (<20 m of rock cover) and are located in hard brittle rock masses. The majority of these tunnels are excavated by drilling and blasting, which, consequently, result in the development of a blast-induced damaged zone around the tunnel boundary. Theoretically, the presence of this zone, with its reduced strength and stiffness, will affect the overall performance of the tunnel, as well as its construction and maintenance. The Swedish Railroad Administration, therefore, uses a set of guidelines based on peak particle velocity models and perimeter blasting to regulate the extent of damage due to blasting. However, the real effects of the damage caused by blasting around a shallow tunnel and their criticality to the overall performance of the tunnel are yet to be quantified and, therefore, remain the subject of research and investigation. This paper presents a numerical parametric study of blast-induced damage in rock. By varying the strength and stiffness of the blast-induced damaged zone and other relevant parameters, the near-field rock mass response was evaluated in terms of the effects on induced boundary stresses and ground deformation. The continuum method of numerical analysis was used. The input parameters, particularly those relating to strength and stiffness, were estimated using a systematic approach related to the fact that, at shallow depths, the stress and geologic conditions may be highly anisotropic. Due to the lack of data on the post-failure characteristics of the rock mass, the traditional Mohr–Coulomb yield criterion was assumed and used. The results clearly indicate that, as expected, the presence of the blast-induced damage zone does affect the behaviour of the boundary stresses and ground deformation. Potential failure types occurring around the tunnel boundary and their mechanisms have also been identified.
AbstractList	Most of the railway tunnels in Sweden are shallow-seated (<20 m of rock cover) and are located in hard brittle rock masses. The majority of these tunnels are excavated by drilling and blasting, which, consequently, result in the development of a blast-induced damaged zone around the tunnel boundary. Theoretically, the presence of this zone, with its reduced strength and stiffness, will affect the overall performance of the tunnel, as well as its construction and maintenance. The Swedish Railroad Administration, therefore, uses a set of guidelines based on peak particle velocity models and perimeter blasting to regulate the extent of damage due to blasting. However, the real effects of the damage caused by blasting around a shallow tunnel and their criticality to the overall performance of the tunnel are yet to be quantified and, therefore, remain the subject of research and investigation. This paper presents a numerical parametric study of blast-induced damage in rock. By varying the strength and stiffness of the blast-induced damaged zone and other relevant parameters, the near-field rock mass response was evaluated in terms of the effects on induced boundary stresses and ground deformation. The continuum method of numerical analysis was used. The input parameters, particularly those relating to strength and stiffness, were estimated using a systematic approach related to the fact that, at shallow depths, the stress and geologic conditions may be highly anisotropic. Due to the lack of data on the post-failure characteristics of the rock mass, the traditional Mohr-Coulomb yield criterion was assumed and used. The results clearly indicate that, as expected, the presence of the blast-induced damage zone does affect the behaviour of the boundary stresses and ground deformation. Potential failure types occurring around the tunnel boundary and their mechanisms have also been identified.[PUBLICATION ABSTRACT] Most of the railway tunnels in Sweden are shallow-seated (<20 m of rock cover) and are located in hard brittle rock masses. The majority of these tunnels are excavated by drilling and blasting, which, consequently, result in the development of a blast-induced damaged zone around the tunnel boundary. Theoretically, the presence of this zone, with its reduced strength and stiffness, will affect the overall performance of the tunnel, as well as its construction and maintenance. The Swedish Railroad Administration, therefore, uses a set of guidelines based on peak particle velocity models and perimeter blasting to regulate the extent of damage due to blasting. However, the real effects of the damage caused by blasting around a shallow tunnel and their criticality to the overall performance of the tunnel are yet to be quantified and, therefore, remain the subject of research and investigation. This paper presents a numerical parametric study of blast-induced damage in rock. By varying the strength and stiffness of the blast-induced damaged zone and other relevant parameters, the near-field rock mass response was evaluated in terms of the effects on induced boundary stresses and ground deformation. The continuum method of numerical analysis was used. The input parameters, particularly those relating to strength and stiffness, were estimated using a systematic approach related to the fact that, at shallow depths, the stress and geologic conditions may be highly anisotropic. Due to the lack of data on the post-failure characteristics of the rock mass, the traditional Mohr-Coulomb yield criterion was assumed and used. The results clearly indicate that, as expected, the presence of the blast-induced damage zone does affect the behaviour of the boundary stresses and ground deformation. Potential failure types occurring around the tunnel boundary and their mechanisms have also been identified. Most of the railway tunnels in Sweden are shallow-seated (<20 m of rock cover) and are located in hard brittle rock masses. The majority of these tunnels are excavated by drilling and blasting, which, consequently, result in the development of a blast-induced damaged zone around the tunnel boundary. Theoretically, the presence of this zone, with its reduced strength and stiffness, will affect the overall performance of the tunnel, as well as its construction and maintenance. The Swedish Railroad Administration, therefore, uses a set of guidelines based on peak particle velocity models and perimeter blasting to regulate the extent of damage due to blasting. However, the real effects of the damage caused by blasting around a shallow tunnel and their criticality to the overall performance of the tunnel are yet to be quantified and, therefore, remain the subject of research and investigation. This paper presents a numerical parametric study of blast-induced damage in rock. By varying the strength and stiffness of the blast-induced damaged zone and other relevant parameters, the near-field rock mass response was evaluated in terms of the effects on induced boundary stresses and ground deformation. The continuum method of numerical analysis was used. The input parameters, particularly those relating to strength and stiffness, were estimated using a systematic approach related to the fact that, at shallow depths, the stress and geologic conditions may be highly anisotropic. Due to the lack of data on the post-failure characteristics of the rock mass, the traditional Mohr–Coulomb yield criterion was assumed and used. The results clearly indicate that, as expected, the presence of the blast-induced damage zone does affect the behaviour of the boundary stresses and ground deformation. Potential failure types occurring around the tunnel boundary and their mechanisms have also been identified. Most of the railway tunnels in Sweden are shallow-seated ( < 20m of rock cover) and are located in hard brittle rock masses. The majority of these tunnels are excavated by drilling and blasting, which, consequently, result in the development of a blast-induced damaged zone around the tunnel boundary. Theoretically, the presence of this zone, with its reduced strength and stiffness, will affect the overall performance of the tunnel, as well as its construction and maintenance. The Swedish Railroad Administration, therefore, uses a set of guidelines based on peak particle velocity models and perimeter blasting to regulate the extent of damage due to blasting. However, the real effects of the damage caused by blasting around a shallow tunnel and their criticality to the overall performance of the tunnel are yet to be quantified and, therefore, remain the subject of research and investigation. This paper presents a numerical parametric study of blast-induced damage in rock. By varying the strength and stiffness of the blast-induced damaged zone and other relevant parameters, the near-field rock mass response was evaluated in terms of the effects on induced boundary stresses and ground deformation. The continuum method of numerical analysis was used. The input parameters, particularly those relating to strength and stiffness, were estimated using a systematic approach related to the fact that, at shallow depths, the stress and geologic conditions may be highly anisotropic. Due to the lack of data on the post-failure characteristics of the rock mass, the traditional Mohr-Coulomb yield criterion was assumed and used. The results clearly indicate that, as expected, the presence of the blast-induced damage zone does affect the behaviour of the boundary stresses and ground deformation. Potential failure types occurring around the tunnel boundary and their mechanisms have also been identified.
Author	Nordlund, Erling Saiang, David
Author_xml	– sequence: 1 givenname: David surname: Saiang fullname: Saiang, David email: david.saiang@ltu.se organization: Division of Rock Mechanics, Luleå University of Technology – sequence: 2 givenname: Erling surname: Nordlund fullname: Nordlund, Erling organization: Division of Rock Mechanics, Luleå University of Technology
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Keywords	Inherent rock properties Brittle rock Blast-induced damaged zone Rock mass strength and stiffness Shallow tunnels Overbreak Numerical analyses Stress analysis Rock mechanics Brittle material Blasting operation Shallow tunnel Rock mass Railway tunnel Design Geometry Numerical analysis Failure analysis Tunnel driving
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SveBeFo Report No. 3, Swedish Rock Engineering Research, Stockholm 13_CR28 13_CR29 13_CR26 MS Diederichs (13_CR10) 1999; 36 13_CR27 R Holmberg (13_CR50) 1982 AM Robertson (13_CR37) 1973; 254 13_CR4 13_CR5 X-T Feng (13_CR48) 2000; 37 13_CR6 13_CR7 13_CR9 13_CR20 13_CR21 13_CR1 13_CR2 13_CR22 13_CR3 13_CR17 AF MacKown (13_CR23) 1986; XXIII 13_CR15 13_CR16 13_CR19 RL Yang (13_CR57) 1993 F Pelli (13_CR33) 1991; 28 D Saiang (13_CR40) 2005; 38 R Holmberg (13_CR18) 1980; 89 13_CR52 SD Priest (13_CR34) 2005; 38 13_CR13 13_CR11 13_CR55 13_CR12 13_CR56 L Malmgren (13_CR24) 2007; 61 V Hajiabdolmajid (13_CR14) 2002; 39 CD Martin (13_CR25) 1997; 34 Q Sheng (13_CR42) 2002; 39 B Tang (13_CR45) 2001; 5 13_CR43 T Sato (13_CR41) 2000; 56 13_CR46 13_CR47 13_CR39 P-A Persson (13_CR54) 1996 13_CR38 R Pusch (13_CR35) 1992; 29 O Stephansson (13_CR44) 1993 E Hoek (13_CR49) 2006; 43 LL Oriad (13_CR53) 1982 MS Diederichs (13_CR8) 2003; 36 13_CR31 13_CR32 13_CR30 U Nyberg (13_CR51) 2002 AK Raina (13_CR36) 2000; 4
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Snippet	Most of the railway tunnels in Sweden are shallow-seated (<20 m of rock cover) and are located in hard brittle rock masses. The majority of these tunnels are... Most of the railway tunnels in Sweden are shallow-seated (<20 m of rock cover) and are located in hard brittle rock masses. The majority of these tunnels are... Most of the railway tunnels in Sweden are shallow-seated ( < 20m of rock cover) and are located in hard brittle rock masses. The majority of these tunnels are... Most of the railway tunnels in Sweden are shallow-seated (<20 m of rock cover) and are located in hard brittle rock masses. The majority of these tunnels...
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SubjectTerms	Applied sciences Blast-induced damaged zone Blasting Brittle rock Buildings. Public works Civil Engineering Computation methods. Tables. Charts Deformation Earth and Environmental Science Earth Sciences Exact sciences and technology Geophysics/Geodesy Geotechnics Gruv- och berganläggningsteknik Inherent rock properties Mining and Rock Engineering Numerical analyses Numerical analysis Original Paper Overbreak Rock mass strength and stiffness Rocks Shallow tunnels Soil mechanics. Rocks mechanics Structural analysis. Stresses Tunnels Tunnels, galleries
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Title	Numerical Analyses of the Influence of Blast-Induced Damaged Rock Around Shallow Tunnels in Brittle Rock
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