Pre-investigations for TBM projects

Transcription

Geological and geotechnical
investigations for TBM projects
Pål Drevland Jakobsen
[email protected]
Norwegian University of Science and Technology
Contents
• Why and when execute ground investigations
• Examples of executed ground investigations and cost
• Comparison (TBM versus D&B / Hard rock versus soft
ground)
• Conclusive remarks and further research
• References and sources of information
2
Introduction – why and when execute
• Validate feasibility
ground investigations
(ITA WG 2 report no 15)
• Verification of rock/soil
• Indication of stability
/ excavation
challenges
• Find existing
geo-data.
Feasibility
Concept
study/design
Execution /
excavation
Detailed
design
• Documentation
• Handling of claims
• Probe drilling
• TBM data analyses
• Back-mapping
• Drilling (probe or
core)
• Find tunnel
alignments and
geometry
• Prepare geoprofiles
• Excavation
method
• Validate concept
study/design
• Laboratory tests
• Detailed profiles
• Excavation
method
3
Level of GI are dependent on
• Available knowledge/documentation of the geology
• Contract (e.g. unit price contracts versus design/build
contracts)
• Complexity of project (e.g. tunnel size, depth, neighbors)
4
DWA 125E
5
Case 1: Wistula river crossing
• Sub-river project in Gdansk,
Poland
• 2 x 1 100 m long TBM bored
tunnels (13.3 m diameter)
• Mainly clay and sandy soil
conditions
• Extensive pre-investigation
scheme
6
Wistula pre-investigation scheme
+ Standard
Penetration
Test (SPT)
General
geotechnical
tests
Mechanical
tests
Environmental
tests
Abrasivity
tests
7
Case 2: The Follo line
Photos courtesy
of AGJV
8
Follo line field tests
Colour
Number of tests
Comments
420
Probe-drilling for Follo line project
712
Probe drilling from other projects
14
Well-drillings (pore pressure measurements) + Lugeon
20
Core drilling holes. 2 000 m cores
59
Seismic profiles (velocity in the ground) 7 210 m
19
9
Resistivity profiles (identify planes of weaknes) 12 400 m.
Follo line rock mechanical tests (lab)
10
Follo line additional tests (AGJV)
• Additional resistivity testing and seismic refraction
• Core drilling + various laboratory tests
• Measure While Drilling Analyses / probe-drilling
• Optical televiewer measurements
11
Case 3: Røssåga
• Tender and design process as a conventional D&B
project
– Desk studies of geological maps
– Two core holes, mainly to assess the rock mass properties
around the underground power-house
– Evaluation of experiences from the hydropower project in the
50’s
12
Case 4: Ulriken
•
•
•
•
Existing parallel tunnel that has been mapped as GI
About 1 DRI/CLI sample per km tunnel
Probe-drilling
Refraction seismic
13
Lessons learned from Ulriken GI
• Possible need for rock stress measurements
• UCS values in the tender documentation are based on
measured values from Fløyfjell tunnelen
– Representability?
• Increase rock mass mapping of the existing Ulriken
tunnel
14
Comparision between apples and pears
From www.freegreatpictures.com
15
Cost for GI
(After ITA WG2 and own data)
Urban short tunnels in
soft ground
Long tunnels in rock
16
D&B and TBM
(SVV publication 101)
17
D&B and TBM
(SVV publication 101 and new data)
18
Hard rock tunnel investigations
Factor
TBM versus D&B
Examples of investigations
Boreability
Substantially more for
TBM
Intact rock strength
Rock mass quantification
Abrasivity and rock hardness
Water
Equal
Water head and estimated amounts
Settlement sensitivity
Stability
Equal to less (potentially
higher rock
Rock mechanical tests
Rock mass quantification
Environmental
impact
Equal to less (reduced
blast vibrations).
Use of excavated material
Trial blasting/rock mass sonic velocity
19
Soft ground tunnel investigations
• Use existing data/knowledge in feasibility – add pin
pointed tests to reduce risk in design phase.
• Use or discharge of excavated muck
• Soil types
– Organic content
– Boulders
– Sieve curves etc
• Mechanical tests
• Abrasivity
• Water head
– Relative constant or varying?
20
Recommendations for investigation
density
• Provide values for all the representative zones
– Mechanical rock/soil properties
– Boreability properties including abrasivity
– Water head and amounts
• Mixed face?
– The easy solution for the project owner is to describe the share
of materials
– How to assess this?
21
Conclusive remarks
• The pre-investigation scheme is highly dependent on:
– Anticipated ground conditions from the feasibility study
– The anticipated complexity of the project
– The selection of contract type (“Who is paying for the risk” –
“who is paying to reduce the geological risk?”)
• Further details and experiences is planned to be
published at WTC2017 in Bergen
22
Acknowledgements and references
Aknowlegdements to Bjørnar Gammelsæter (JBV), Leon Eide (JBV), Marek Multan (MartiNorge AS) for sharing experiences on GI.
Norsk Bergmekanikk gruppe Veileder for bruk av Eurokode 7 til Bergteknisk prosjektering.
November 2011 (In Norwegian)
Gammelsæter, B., Ground investigations for the Follo line. Personal communication April 2016.
Eide, L., Ground investigations for the Ulriken tunnel. Personal communication April 2016
ITA WG 2. Strategy for site investigation of tunnelling projects. May 2015.
DWA-A 125E Pipe Jacking and Related Techniques, German Association for Water,
Wasterwater and Waste. December 2008
Statens vegvesen Publication 101. Riktig omfang av undersøkelser for berganlegg. 2003 (In
Norwegian).
23

Pre-investigations for TBM projects

Transcription

Similar documents

A tribute to Norwegian Composer Halfdan Kjerulf Friday, February

Celebrating Norwegian Music

How Women ROCKED THE VOTE in Little Rock

free upgrades - Cruise Holidays of Burlington

«Jul» means

case as PDF

Annual report

blackBOOK - Roger Norum. Writer.

Del Sol Now Open at Channelside Bay Plaza Mayor Iorio Welcomes

Porsgrund - Norway House