Northwest Trunk Presentation

NORTHWEST TRUNK TRENCHLESS SCUGOG RIVER
CROSSING – CONTRACT 1
BY: SEAMUS TYNAN P.ENG
WARD AND BURKE MICROTUNNELLING LTD
28th August 2014
PRESENTATION OUTLINE
1. Project Overview
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Location
Geology
Construction Approach
2. Microtunnelling - Methodology
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Overview of System
AVN Microtunnelling Machine
Slurry Separation Plant
Concrete Microtunnelling Pipe
Interjacking Stations (IJS)
Lubrication
TBM Guidance Systems
3. Shaft Construction Methodology
4. Installation of Concrete Pressure Pipe and Grouting
5.
Case Studies
6. Key Project Risks & Mitigation Measures
7. Questions
PROJECT GEOLOGY
SOIL DESCRIPTION
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Till: Silt to Silty
Clay,Clasts,
- - Cobbles &
Boulders
- Bedrock: Ottawa /
Shadow Lake
Formation
CONSTRUCTION SCOPE
Reception Shaft
6m Ø Caisson
14m Deep
Launch Shaft
9m Ø Caisson
13.2m Deep
2.0 MICROTUNNELLING - OVERVIEW
3D Schematic
What Characterizes Microtunnelling
• Trenchless construction
• Pipe Jacking
• Remotely controlled execution
• Minimized excavated material
• No requirement for dewatering
• Often the most efficient method of pipe
installation
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Applications & Benefits
• No Requirement for Dewatering – Environmentally Friendly and less surface
disruption
• Smaller shaft sizes – Smaller working footprint
• Ability to stabilize the cutting face with slurry pressure. Very low risk of surface
settlement as a result. Ideal for major highways and rail crossings
• Remote Operation – No Requirement for physical work in the tunnel providing
superior Health and Safety benefits
• Extremely accurate alignments with tolerances of +/- 25mm achievable
• Curved Alignments Possible in both horizontal and vertical plane
• Ability to break down cobbles and boulders due to advancements in cutting
head design and TBM torque increases
• Applicable to a large range of sizes, 600mm to 3000mm ID (typical)
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Applications & Benefits Continued
• Can be used as a conduit for water mains, gas & oil lines, jet fuel lines and as
a product tunnel for sewer and drainage lines . Direct Installation of product
pipe for Sanitary Sewers
• Minimizes surface disruption – two working locations
• Inherent strength of lining – concrete is the strongest lining available
• Minimal reinstatement required
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Typical Tunnel Drive Lengths
• Dependent on the TBM size & geology but a general guide:• AVN600 – max drive length – 170m – 30 inch outside diameter
• AVN900 – max drive length – 300m – 43 inch outside diameter
• AVN1200 – max drive length – 800m – 56 inch outside diameter
• AVN1500 – max drive length – 800m – 69 inch outside diameter
• AVN1800 – max drive length – 1200m – 81 inch outside diameter
• AVN2000 – max drive length – 2000m – 91 inch outside diameter
• AVN2400 – max drive length – 3000m – 107 inch outside diameter
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AVN1500 HERRENKNECHT MTBM
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Technical Considerations
• No dewatering of the existing ground water is required
• Drives of several hundred meters are readily achievable
• Accuracies of ~40mm are easily achieved
• Ground support provided immediately after excavation
• Can excavate through cohesive & non cohesive soil as well as rock
• Method most suitable to poor ground conditions
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3.0 MICROTUNNELLING – SLURRY SEPARATION PLANT
Separation Systems
• Primary solids removal >3mm
• Secondary solids removal >45μm
• Tertiary treatment - centrifuge
Slurry
• Main purposes are to act as transport medium for cuttings, & provide face stability
• Main slurry parameters that need to be checked regularly are:• Slurry density – mud balance
• Viscosity – marsh funnel
• Sand content – sand content kit
• SG of slurry < 1.3 – otherwise saturation is reached
• Separation System must be able to cope with accumulation of ultrafine solids
• Conventional screening & cyclone methods fail to remove clay fraction leading to a
successive densification of the slurry
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Jacking Pipes
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Jacking Pipes – Joint Detail
Example for 1500mm ID Pipe
• 1.800m OD concrete pipe (56 inch OD), 60MPa concrete
• Can withstand axial load of 11,000kN (1100 Tonnes) (different for each size
pipe)
• Ultimate line load of 180kN/m (unconfined, different for each size pipe)
• Waterproof joint – dry internal tunnel
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MICROTUNNELLING – 1800mm OD CONCRETE
MICROTUNNELLING PIPE
VIEW INSIDE CONVENTIONAL ROCK BORE TUNNEL
MICROTUNNELLING – VIEW INSIDE 1800mm OD MICROTUNNEL
Intermediate Interjack Stations
• Used to limit the stresses applied to pipes and thrust wall
• Used when jacking frame cannot provide enough thrust for tunnel length
• A number of interjacks can be used per tunnel to achieve the desired length
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Intermediate Interjack Stations
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Jacking Pipes – Lubrication Pipes
• Typically every 6th pipe
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MICROTUNNELLING - LUBRICATION
Jacking Pipes – Effect of Lubrication
• Case Studies
• Keswick – 340m compound curved tunnel
• 1.43m concrete pipe, silty sandy material
• Tunnel surface area = 1530m2, push through force = 640kN
• Tunnel interface friction = 0.42kN/m2 = 0.42kPa (NO INTERJACK REQUIRED)
• Elgin Mills – tunnel length 740m
• 1.800mm OD concrete pipe, sandy silty clayey material
• Tunnel surface area 4138m2, push through force = 1275kN
• Tunnel interface friction = 0.31kN/m2 = 0.31kPa (NO INTERJACK REQUIRED)
Bentonite Lubrication
• Viscosity measured using marsh funnel
• Measures time to pass 946ml through venturi
• Crude measure but good site test
• Base measurement is water at 26 seconds
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Tunnel Alignment
• Straight alignment – laser guidance good up to ~ 250m (820 ft)
• Operate on line of sight – laser placed in starting shaft
• Can keep line and grade within ~ 25mm
• Ideal for gravity storm and sewer lines – any straight tunnel
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Tunnel Alignment
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Curved Tunnel Alignments
• Robotic Total Station Guidance System Running Inside Tunnel
• Horizontally curved tunnel to eliminate additional shaft in difficult ground
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3.CONSTRUCTION OF SHAFTS
TUNNELLING SHAFT CONSTRUCTION – CAISSON SINKING
2 Shafts Required On Scugog Project
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Minimal Surface Set-Up Time
Monolithic Construction
NO – DEWATERING Required
QA/QC Approved Materials - Concrete
Efficient Design – Ward and Burke Microtunnelling Ltd
Meets Canadian Foundation Engineering Manual and CSA
Standards
Incorporates O.Reg Safety Requirements, Ladder Access Etc.
CONSTRUCTION OF SHAFTS
CONSTRUCTION OF SHAFTS
CONSTRUCTION SEQUENCE FOR CONCRETE LINED SHAFT
CONSTRUCTION SEQUENCE FOR CONCRETE CAISSON SHAFT
CONSTRUCTION SEQUENCE FOR CONCRETE CAISSON SHAFT
Installation of Safety Systems
5.0 INSTALLATION OF CONCRETE PRESSURE PIPE AND GROUTING
Use of Microtunnelling Pipe as Secondary Liner
• Concrete jacking pipe used as product pipe for storm & sewer applications
• Completed waterproof tunnel
• Also used as secondary liner for utilities – casing and carrier
• To date:- water, electrical, jet fuel lines, gas lines, telecommunications etc.
• Multiple services can be installed in the same tunnel to maximize use of space
• Annular area between utilities & concrete pipe can be grouted or remain open
• Utilities installed from one side and then pushed into tunnel on “spiders”
4.0 INSTALLATION OF CONCRETE PRESSURE PIPE AND GROUTING
Custom Pipe “Spiders”
4.0 INSTALLATION OF CONCRETE PRESSURE PIPE AND GROUTING
Lowering CPP into specially
designed hydraulic jacking frame
CPP watermain being installed complete
with grouting hose.
4.0 INSTALLATION OF CONCRETE PRESSURE PIPE AND GROUTING
Jacking frame with 200T/450T
Capacity
4.0 INSTALLATION OF CONCRETE PRESSURE PIPE AND GROUTING
ANNULUS GROUTING
5.0 CASE STUDIES
River Dargle Crossing - Bray
Project Brief
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Provide a system to
transport sewage from Bray
pump station to the newly
constructed treatment
works
600 and 800mm id pumped
rising mains were needed
to fulfil all hydraulic
requirements
Pipeline route crossing the
River Dargle.
Bray Pump
Station
River Dargle
Direction to new
treatment works
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Construction Constraints
Geotechnical
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Proximity of Structures
and services
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Soft medium plasticy clay
with low undrained shear
strengths (Su < 30 kPa for
over 15m deep)
Main East coast railway
10m from works area with
98 trains passing daily
Two deep retaining walls
each side of the River
Dargle
Existing pump station and
sea outfall.
Gas main and fibre optic
eircom cable in works area.
Working pressures of
rising main
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System needed to
withstand pressures > 7.5
bar
Bray Pump
Station
6m High Retaining wall
4m High Retaining wall
Main East Coast Rail
Line Bridge
Gas and Fibre Optic
Lines
Design Solution
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In situ caisson and microtunnel
construction
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In situ caissons sunk in the wet would prevent the possibility of basal heave, lateral
ground deformation, and surface settlements. The in situ caissons could provide the
tensile anchor block resistance for the rising main pipework where a segmental shaft
system would have failed.
The microtunnel construction would prevent damage to the existing retaining walls, rail
line, sea outfall, and existing pump station.
Construction of 7m id x 10 m deep launch caisson
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Site Clearance, cutting shoe positioning, and steel fixing
Construction of 7m id x 10 m deep launch caisson
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Fixing of guide/jacking collar
Construction of 7m id x 10 m deep launch caisson
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Sinking in the wet to prevent basal heave, lateral ground deformation, and surface
settlement
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Sinking of fifth lift, 8-10m deep.
A Kobelco 235 with clam shell used for excavation
4 no. 100T hollow jacks used to sink caisson with excavation process simultaenously
Construction of 7m id x 10 m deep launch caisson
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Plugging in the wet
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Concrete delivered to the formation via tremie pipe.
Construction of 5m id x 12.1 m deep reception caisson
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Site clearance, cutting shoe positioning, and shuttering
Construction of 5m id x 12.1 m deep reception caisson
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Construction of guide/jacking collar
Construction of 5m id x 12.1 m deep reception caisson
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Sinking caisson in the wet
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A CAT 328 with clam shell was used to excavate inside caisson
4 no. 100T hollow jacks were used to sink caisson as excavation progressed
1200 id Tunnel Construction with Tunnel Boring Machine
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Launch eye construction
1200 id Tunnel Construction with Tunnel Boring Machine
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Jacking frame installation
1200 id Tunnel Construction with Tunnel Boring Machine
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Jacking Pipe installation
1200 id Tunnel Construction with Tunnel Boring Machine
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Separation of clay using separation equipment
1200 id Tunnel Construction with Tunnel Boring Machine
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Reception of Tunnel Boring Machine
1200 id Tunnel Construction with Tunnel Boring Machine
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Launch of Tunnel Boring Machine for 2nd Tunnel
Installation of Ductile Iron Rising Main Pipework
5.0 KEY PROJECT RISKS AND MITIGATION MEASURES
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No Requirement for Dewatering – Environmentally Friendly and less surface disruption
Vibration – No Vibration Inducing Equipment Used During Construction
Settlement – Controlled Rate of Advance, Pressurised Face
Cobbles/Boulders – Mixed Face Cutterhead
Frac Out – Pre Engineered Drive Assessment, Filter Cake, Contingency Plans
Alignment – ELS or Gyro TBM Guidance Systems
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Lubrication Migration – Precise Control of Injection Rate
Shaft Construction Through Flowing Soils – Wet Caisson System
Risk Assessments – FLRA, Toolbox Talks
Application of Ward and Burke + OSHA on all Sites.
QUESTIONS?