tunnel support design - tunneling short course · tunnel support design summary summary •...
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Tunnel Support DesignEric Wang, PE
University of Denver
Tunneling Short Course September 11, 2018
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Agenda
1.0 Introduction
2.0 Tunnel Support Design Principles
3.0 Input for Design
4.0 Tunnel Support Systems
5.0 Hard Rock Tunnel Support Design Example
6.0 Soft Ground Tunnel Support Design
7.0 Summary
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1.0 Introduction
Design Flowchart sample:
(THE Tunnel project)
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Rock Support Interaction:
• Optimize support installation - acceptable displacement.
2.0 Tunnel Support Design Principles
Ground vs Support Reaction Curves Ground Reaction Curves based on Overburden Depth
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3.0 Geologic Input for Rock Tunnel Design
• Rock Mass Classifications:
– Rock Mass Rating (RMR) System (Bieniawski, 1989)
– Modified RMR (Laubscher and Page, 1990)
– NGI’s (Q) System (Barton et al., 1974, 2015)
• Rock Mass Discontinuity Orientation and Properties
• Rock Hardness, Strength and Abrasiveness for Excavation
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• Rock Bolts / Dowels– Type
– Length
– Pattern
– Anchorage
Initial Ground Support
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• Shotcrete– Thickness
– Type, Dry vs Wet
• Lattice Girders
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Rock Mass Classification – Q system
After NGI 2015
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RMR Classification
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Tunnel Support Design
Support Estimate:
• Empirical Approach
• Analytical Approach
– Kinematic (Block stability)
– Rock Reinforcement (Bischoff and Smart)
• Numerical Modeling
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Empirical Methods
• Terzaghi’s Rock Load (conceptual)
– More conservative
– Modified by Deere et al., 1970
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Empirical Methods
Graphical – Ubiquitous Joint Method (No. 7 Subway Line Extension)11
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Kinematic Approach
Jointed Rock Mass
• DIPS and UNWEDGE software (Rocscience)
Stereonet of structural discontinuity planes (No. 7 Subway Line Extension)
Cavern cross-section – wedge formation and initial support pattern (No. 7 Subway Line Extension)
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Numerical Modeling Example – THE Tunnel 34th Street Station Cavern
Station Cross section (THE Partnership)
Station Longitudinal section (THE Partnership) 13
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Numerical Modeling Example – THE Tunnel 34th Street Station Cavern
Station Cavern Excavation (THE Partnership)
TBM1
TBM3
TBM2
TBM4
Excavation Sequence:Stage 1: Excavation of four TBM tunnels (TBM1, 2, 3, and 4) through the station cavern
Installing initial ground supports behind TBM shield as required.
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Numerical Modeling Example – THE Tunnel 34th Street Station Cavern
Full excavation sequence
TBM1 TBM2
TBM3 TBM4
Excavation Sequence:Stage 2: Excavation of Top-heading ( Side-drift 1, Side-drift 2, and Center-drift 3) Stage 3: Excavation of Benches and Inverts (4, 5, 6, 7, 8 and 9)
Installing initial ground support after excavation of each blast round including rock bolting and shotcreting.
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Numerical Modeling Example – THE Tunnel 34th Street Station Cavern
• Partially release of stress at the face of excavation at each excavation round before installing initial support.
• Evaluate stress release considering forces on ground and lining:
– Size of Excavation Face
– Ground Stiffness (Elastic Modulus, Poisson’s ratio)
– Initial Support Stiffness
– Length of Unsupported Excavation Round
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(after Hoek)
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Numerical Modeling Example – THE Tunnel 34th Street Station Cavern
Stress release for each excavation step before installing initial support in the model:
TBM1 = 10%, TBM2 = 10%, TBM3 = 10%, TBM4 = 10%
Side-Drift1 = 30%, Side-Drift2 = 30%Center-Drift3 = 40%
Bench4 = 50%, Bench5 = 50%Bench6 = 50%, Bench7 = 50%
Invert8 = 50%, Invert9 = 50%
Final Lining = 100% relaxation At the final stage: Eliminating the initial supports
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Numerical Modeling Example – THE Tunnel 34th Street Station Cavern
• Simulate excavation sequence– Consider ground strain due to excavation at each
Stage (Estimate stress release at each stage)
Eground = Stress / Strain
Installing initial support for each stage after simulating
the strains in the numerical model
(THE Partnership - ILF)
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Numerical Modeling Example – THE Tunnel 34th Street Station Cavern
Top heading / bench / invert excavation at Final Stage(prior to removing the initial support)
(THE Partnership - ILF)
General Station Cavern Excavation combining TBM and SEM Enlargement Top heading / Bench / Invert
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Numerical Modeling Example – THE Tunnel 34th Street Station Cavern
Total displacement contours with deformation vectors and deformed boundaries
Contours of yielded elements
(THE Partnership - ILF)
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Numerical Modeling Example – THE Tunnel 34th Street Station Cavern
Contours of yielded elements
Axial Forces Bending Moments
After Elimination of Initial Support
(THE Partnership - ILF)
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Ground Support
• Ground support classes
• Pre-support
• Ground Treatment / Ground improvement
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TUNNEL AXIS
6' TOE BOLT
W6X25 STEEL RIB
120°
6'-00"
ROCKBOLT
TUNNEL CENTER
4'-00"
ROCKBOLT
TUNNEL CENTER
160°
TUNNEL CENTER
Ground Support Classes
Contract - Typically 2 to 3 initial support classes • Hard rock TBM example:
Support Class III: Steel rib supportSupport Class II: Additional mine-straps and/or shotcrete support
Support Class I: Pattern rock dowels
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Tunnel Support Systems
• Hard Rock – Available Tunnel Support Systems• Rock bolts• Rock Anchors• Rock Dowels• Mine straps • Shotcrete – plain and reinforced (either steel fibers or WWF)
• Soft Ground – Available Tunnel Support Systems• Soil Nails• Rebar / Pipe Spiling• Lattice Girders• Shotcrete• Cast-In-Place
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Tunnel Support Systems
• Open (Gripper) TBM – Available Tunnel Support Systems• Rock bolts / Rock dowels• Steel Ribs with channel lagging or minestraps• Shotcrete (limited to extremely poor ground) • CIP Lining
• Double shield EPB / Slurry Face – Available Tunnel Support Systems• Segmental lining• Annular and Secondary Grouting
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Ground Support through Shear Zone
Steel mat lagging
Spiling and shotcrete
WWF and minestraps
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Pre-support Systems
Spiling (Fore-poling) Pre-grouting ahead of face Double-roof pipe canopy arch
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Canopy spiling at Portal
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Ground Treatment
Ground freezingPre-Grouting
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Groundwater Control
Tunneling – infiltration control and waterproofing systems
Pre-excavation grouting of open fracture (South River Tunnel, Atlanta, GA., 2011)
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Tunnel Grouting
CEMENTITIOUS vs. POLYURETHANE GROUTS
CEMENTITIOUS:
• Dry, open joints
• Long-term strength
POLYURETHANE:
• Wet conditions or relatively narrow fissures
• Time dependent properties
• Flow behavior (unreacted & reacting)
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Tunnel Grouting
Pre-excavation Combined Cement + Water-reactive Polyurethane Grout:
Steps
1. Polyurethane (TACSS – single component pre-polymerized polyurethane) reaches permeable rock mass – forms barrier upon reacting with water
2. Subsequent Cement grout able to begin filling crackand curing with dilution from leaky crack.
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5.0 Example - Pillar Stability Evaluation
• Phase 2D -Pre-support considered
• Staged Excavation
Results
• No significant yielding & deformations at 60% gripper pressure
• Localized spalling of Starter Tunnel shotcrete lining at 30%gripper
• No impact on Global Stability
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Pillar Stability Evaluation
Proposed
T302
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Pillar Stabilization Measures
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Starter Tunnel Rock Reinforcement
Cradle for TBM launch
Brow and gripper wall support
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Starter Tunnel Rock Reinforcement
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Starter Tunnel Rock Reinforcement
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Shotcrete Support Design
In Blocky ground• Prevent rock mass raveling and
loosening between bolts• Typical failure modes:
– Adhesive– Direct Shear– Flexural– Punching Shear
Applied Load Model -Shotcrete Support (after Barrett and McCreath, 1993)
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Shotcrete Support Design
Failure modes (blocky ground):
• Adhesive failure
Adhesive failure model
Failure mode (after Barrett and McCreath, 1993)
(after Barrett and McCreath, 1993)
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Shotcrete Support Design
Failure modes (blocky ground):• Direct Shear Failure
Direct Shear failure model (after Barrett and McCreath, 1993)
Failure mode (after Barrett and McCreath, 1993)
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Shotcrete Support Design
Failure modes (blocky ground):
• Flexural failure
Flexural failure model (after Barrett and McCreath, 1993)
Failure mode (after Barrett and McCreath, 1993)
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Shotcrete Support Design
Failure modes (blocky ground):
• Punching Shear failure
Punching Shear failure model (after Barrett and McCreath, 1993)
Failure mode (after Barrett and McCreath, 1993)
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Shotcrete Support Design
Good bond between rock and shotcrete
• Direct Shear Failure unlikely
• Adhesion Failure > 4m spacing
Adhesive failure model
44(after Barrett and McCreath, 1993)
Type equation here.
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Shotcrete Support Design
Poor bond between rock and shotcrete• Direct Shear Failure unlikely• Adhesion Failure > 2.25 m spacing
45(after Barrett and McCreath, 1993)
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Soft-ground Tunneling
• Continuous support of face and periphery (invert)
• Timely groundwater control
Horizontal vacuum system (after Taiwan HS Rail, 2001-2003)
Flowing Ground
Vacuum Drain
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Soft-ground Tunneling
• 3D tunnel convergence monitoring – vertical and transverse
• Reference THSR:
– 40-ft diam SEM tunnelVertical
LateralBackfilled Invert
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Soft-ground Tunneling
• Continuous tunnel convergence monitoring - longitudinal
Reference THSR: 40-ft diam SEM tunnel
Longitudinal
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Face bolting and Ring Cut in Sandy Ground
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Face bolting and Ring Cut in Sandy Ground
1. Face Bolting 2. Partial Excavation
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Face bolting and Ring Cut in Sandy Ground
Running Ground
• Periodic sealing (accelerator)
• Contact Grouting of Arch
3. Temp. Sealing
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Protection of Adjacent Structures
• Identify reinforcement/ underpinning needs
• Instrumentation & Monitoring Program
• Control Ground movement /Subsidence
• Rigid Water-tight Excavation Support under construction as well as permanent conditions
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1. Initial screening
2. Develop settlement profile
3. Evaluate settlement profile per project criteria (max surface settlement, impact to structures, etc.)
4. Identify sensitive structures within influence zone - more comprehensive analysis
5. Mitigation measures – construction restrictions
Building Impact Assessment - Procedure
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Settlement Contour Map at East Portal
0.8
0.8
1.1
0.81.1
0.8
TransPakProtection of Existing Structures – Potential Impacts1. TransPak (Shipping depot - single-story
warehouse bldg.) – settlement shallow (35-ft) cover
2. Bayshore Freeway (Route 101) – adjacent highway slight embankment shallow (30-ft) cover
3. Lower Silver Creek – shallow cover settlement cracking of liner leaking shallow (30-ft) cover
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1.4
1.4
0.9
Settlement Contour Map at West Portal
Protection of Existing Structure1. I-880 Nimitz Freeway Overpass, Shallow cover (+/-
40 FT) embankment footing and adjacent pile foundation.
2. Shallow cover (+/- 40 FT) overlying single-story building i.e., All-World Furniture and DekaBatteries settlement potential.
DEKA BATTERIES ALL WORLD FURNITURE
0.9
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Building Impact Evaluation
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Potential Mitigation Options
Further evaluation of specific existing structures based upon ground conditions and as-built foundation data, potential mitigation options could feature:
• Structural Underpinning,• Grouted Canopy spiling and lattice girder• Rigid Support of Excavation Systems (Secant pile walls, etc.)• Ground treatment
“A critical issue in design of mitigation measures is avoiding the creation of hard points in the building that can focus and amplify building response or damage.” (Boscardin and Walker, 1998)
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Tunnel Support Design Summary
Summary• Project-specific ground characterization• Compatible excavation methodology
– Hard rock tunnel: rock mass discontinuities, strength and abrasion– Soft-ground tunnel: continuous face and periphery support/ GW control /
monitoring
• Contingency – Risk Mitigation measures: pre-support / ground treatment/ temporary invert support
• Optimize support design evaluate results from several analytical approaches
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Questions?
Mile-high thank you for your attention!
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