TY - JOUR
T1 - Seismic response of tunnel near fault fracture zone under incident SV waves
AU - Liu, Zhongxian
AU - Liu, Jiaqiao
AU - Pei, Qiang
AU - Yu, Haitao
AU - Li, Chengcheng
AU - Wu, Chengqing
N1 - Publisher Copyright:
© 2021
PY - 2021/12
Y1 - 2021/12
N2 - This study investigated the impact of a non-causative fault on the dynamic response of a nearby lined tunnel under the incidence of plane SV waves using the indirect boundary element method. The effects of several critical parameters, such as the incident frequency, the inclination degree of the fault, the distance between the fault and the tunnel on the hoop stress of the lined inner and outer walls, were explored intensively. The numerical results indicated that the non-causative fault could significantly change the hoop stress distribution of inner and outer surfaces of the tunnels. In general, for the vertically incident seismic waves, when the tunnel was located in the foot wall (under the fault), the hoop stress within the tunnel was significantly greater than that of the tunnels in the non-fault half space, with an amplification factor of up to 117%. The amplification effect became more pronounced as the fault dip angle increased. However, when the tunnel was located in the hanging wall (above the fault), the non-causative fault could produce a significant shielding effect on the dynamic response of the tunnel under high frequency wave incidence, with the reduction of hoop stress being up to 81%. For low-frequency waves, though, the fault could lead to an increase of the hoop stress of the tunnel of up to 152%. The research results will provide a reference for the seismic design and safety protection of underground structures in non-causative fault sites.
AB - This study investigated the impact of a non-causative fault on the dynamic response of a nearby lined tunnel under the incidence of plane SV waves using the indirect boundary element method. The effects of several critical parameters, such as the incident frequency, the inclination degree of the fault, the distance between the fault and the tunnel on the hoop stress of the lined inner and outer walls, were explored intensively. The numerical results indicated that the non-causative fault could significantly change the hoop stress distribution of inner and outer surfaces of the tunnels. In general, for the vertically incident seismic waves, when the tunnel was located in the foot wall (under the fault), the hoop stress within the tunnel was significantly greater than that of the tunnels in the non-fault half space, with an amplification factor of up to 117%. The amplification effect became more pronounced as the fault dip angle increased. However, when the tunnel was located in the hanging wall (above the fault), the non-causative fault could produce a significant shielding effect on the dynamic response of the tunnel under high frequency wave incidence, with the reduction of hoop stress being up to 81%. For low-frequency waves, though, the fault could lead to an increase of the hoop stress of the tunnel of up to 152%. The research results will provide a reference for the seismic design and safety protection of underground structures in non-causative fault sites.
KW - Fault fracture zone
KW - Indirect boundary element method
KW - Lined tunnel
KW - Non-causative fault
UR - http://www.scopus.com/inward/record.url?scp=85120612892&partnerID=8YFLogxK
U2 - 10.1016/j.undsp.2021.03.007
DO - 10.1016/j.undsp.2021.03.007
M3 - Article
AN - SCOPUS:85120612892
SN - 2096-2754
VL - 6
SP - 695
EP - 708
JO - Underground Space (China)
JF - Underground Space (China)
IS - 6
ER -