Seismic Soil-Tunnel-Structure Interaction Analysis And Retrofit Of The Posey-Webster Street Tunnels

Anoosh SHAMSABADI, Hassan SEDARAT, Alexander KOZAK, Seismic Soil-Tunnel-Structure Interaction Analysis And Retrofit Of The Posey-Webster Street Tunnels, presented at The 2nd UJNR (United States and Japan Cooperative Program in Natural Resources) Workshop on Soil-Structure Interaction, March 6 to 8, 2001, Tsukuba, Japan.

The purpose of this paper is to present the Soil-Tunnel-Structure Interaction analysis performed for the “innovative” seismic retrofit of the Posey and Webster Street Tunnels located in the San Francisco Bay area.
The tunnels are situated between two major faults, the Hayward Fault and the San Andreas Fault (Figure 1).
Due to its close proximity to the site, the Hayward Fault is the controlling fault for the Safety Evaluation
Earthquake (SEE) event. The Hayward Fault is capable of generating a peak horizontal rock acceleration of
0.76g, and horizontal ground accelerations in excess of 0.5g. The duration of the seismic event may exceed
45 seconds. The high peak rock acceleration of the design earthquake, and the long duration of the event, will
allow the build-up of pore pressures. This could lead to extensive liquefaction with the consequent flotation
of the tunnels resulting in a structural failure. The 1989 Loma Prieta earthquake (estimated horizontal ground
acceleration of about 0.2g at the site) was the most recent major seismic event that occurred near the Posy and
Webster Street Tunnels. The Post Earthquake Investigation report indicated evidence of liquefaction on the
Island of Alameda and in the vicinity of the tunnels. Consequently, in 1997 ground improvement and retrofit
of a number of structural components of tunnel segments became part of the retrofit plan for the tunnels. The
ground improvement will prevent flotation of the tunnels, and the retrofit of structural components will
prevent major damage to the tunnels themselves. Located at each end of the tunnel is a portal structure. It
was necessary to design an opening between the portal structures and tunnels to reduce the tunnel-portal
interaction. The retrofit strategy for the structural components is to provide flexibility and significantly
reduce the forces in the tunnel segments. Response-spectrum-compatible rock motion time histories were
developed along the tunnel alignment. The rock motions were propagated towards the surface to obtain the
ground motion at the centerline of the tunnels for the Soil-Tunnel-Structure Interaction analysis. The
objectives of the analysis were to estimate the responses of the as-built and retrofit configurations of the
tunnels due to seismic excitations. In addition the global model racking analyses complements the global
model.

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