Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Catalogue of Notable
Tunnel Failure Case Histories
(up to December 2008)
Prepared by Mainland East DivisionGeotechnical Engineering Office
Civil Engineering and Development Department
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Foreword
This catalogue of notable tunnel failures is primar ily based on published information. Both overseas and local cases involving collapse or excessive deformation of the ground are included. For contractual and other reasons, there are relatively few cases reported in technical publications, and t hose reportedare usually of such scale or seriousness that they have receivedpublic attention. Even for the cases reported, usu ally only limited information is available. Apart from the c ases included, readers can find other information on tunnel failur e in the list of General References given at the end of this catalog ue.
This catalogue is a live document that will be upda ted from time to time as further information becomes av ailable.
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
The main purpose of the catalogue is to disseminate information and promote awareness on tunnel failure s which could pose a danger to life and property. The poss ible causes of the failures, the geotechnical problems and the lessons learnt, where these are known, are outlined in the catalogu e. Readers should refer to the source reference documents quot ed for details. Clients and works agents are advised to i mplement effective geotechnical risk management measures in the planning, investigation, design and construction of their tunnelprojects.
Foreword
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
The first edition of the catalogue was issued in Fe bruary 2007 and was put together by Mr W Lee, supervised by Mr K J Roberts. This second edition was prepared by Ms L Y Pau, supervised by Mr L P Ho. GEO staff, members of the Hong Kong Institution of Engineers Geotechnical Division Working Group on Cavern and Tunnel Engineering and other in dividuals have contributed to this Catalogue. All contribut ions are gratefully acknowledged.
Foreword
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
If any information in this catalogue is found to be inaccurate or out-of-date, please contact the Chief Geotechnical Engineer/Mainland East of the Geotechnical Engineer ing Office, Civil Engineering and Development Department, 101 P rincess Margaret Road, Ho Man Tin, Kowloon, Hong Kong.
P. L. R. PangChief Geotechnical Engineer/Mainland East
Geotechnical Engineering OfficeCivil Engineering and Development Department
March 2009
Foreword
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
1. Green Park, London, UK, 1964
2. Victoria Line Underground, London, UK, 1965
3. Southend-on-sea Sewage Tunnel, UK, 1966
4. Orange-fish Tunnel, South Africa, 1970
5. Munich Underground, Germany, 1980
6. Gibei Railway Tunnel, Romania, 1985
7. Moda Collector Tunnel, Istanbul Sewerage Scheme, Turkey, 1989
8. Seoul Metro Line 5 - Phase 2, Korea, 17 Nov. 1991
9. Seoul Metro Line 5 - Phase 2, Korea, 27 Nov. 1991
10. Seoul Metro Line 5 - Phase 2, Korea, 11 Feb. 1992
11. Seoul Metro Line 5 - Phase 2, Korea, 7 Jan. 1993
Tunnel Failures – List of Overseas Cases
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
12. Seoul Metro Line 5 - Phase 2, Korea, 1 Feb. 1993
13. Motorway Tunnels, Austria, 1993-1995
14. Heathrow Express, UK, 21 Oct. 1994
15. Munich Underground, Germany, 27 Sept. 1994
16. Los Angeles Metro, USA, 22 June 1995
17. Docklands Light Rail, UK, 23 Feb. 1998
18. Athens Metro, Greece, 1991-1998
19. Sewage Tunnel, Hull, UK, 1999
20. Taegu Metro, South Korea, 1 Jan. 2000
21. Channel Tunnel Rail Link, UK, Feb. 2003
22. Météor Metro Tunnel, France, 14 Feb. 2003
Tunnel Failures – List of Overseas Cases
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
23. Shanghai Metro, China, 2003
24. Hsuehshan Tunnel, Taiwan, 1991-2004
25. Stormwater Management and Road Tunnel (SMART), Malaysia, 2003 - 2006
26. Guangzhou Metro Line 3, China, 1 April 2004
27. Singapore MRT, 20 April 2004
28. Kaoshiung Rapid Transit, Taiwan, 10 Aug. 2004
29. Barcelona Metro, Spain, 27 Jan. 2005
30. Lausanne M2 Metro, Switzerland, 22 Feb. 2005
31. Lane Cove Tunnel, Australia, 2 Nov. 2005
Tunnel Failures – List of Overseas Cases
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
32. Kaoshiung Rapid Transit, Taiwan, 4 Dec. 2005
33. Sao Paulo Metro Station, Brazil, 15 Jan. 2007
34. Guangzhou Metro Line 5, China, 17 Jan. 2008
35. Circle Line 4 Tunnel, Singapore, 23 May 2008
36. Hangzhou Metro Tunnel, China, 15 Nov. 2008
Tunnel Failures – List of Overseas Cases
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
1. MTR Modified Initial System, Prince Edward Station, Nathan Road,12 Sept. 1977
2. MTR Island Line, 22 Hennessy Road, 1 Jan. 1983
3. MTR Island Line, Shing On Street, Shau Kei Wan, 23 July 1983
4. MTR Island Line, 140-168 Shau Kei Wan Road, 16 Dec. 1983
5. Kowloon Southern Link Contract KDB 200, Canton Road, 21 Oct. 2006
6. Kowloon Southern Link Contract KDB 200, Salisbury Road, 3 June 2007
Tunnel Failures – List of Hong Kong Cases
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Overseas Cases
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Tunnel (Green Park to Victoria) driven through London Clay
using drum-digger shield
• The failure• Inflow of sand and gravel, burying most of the shield
Green Park, London, UK, 1964
Clay & Takacs (1997)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• The crown of the shield penetrated through the London Clay
layer into sand and gravel
• Source• Clay & Takacs (1997)
Green Park, London, UK, 1964
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background • Tunnel (300m long and 3.7m internal diameter) driven through
London Clay using hand-shield and lined with cast-iron segments under a disused railway marshalling yard
• The failure• Inflow of sand and gravel
Victoria Line Underground, London, UK, 1965
Clay & Takacs (1997)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• The shield was ineffective in supporting the overlying ground
• Source• Clay & Takacs (1997)
Victoria Line Underground, London, UK, 1965
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background • Tunnel driven through London Clay (40m long and 1.35m in
diameter)
• The failure• Water inflow into the tunnel
Southend-on-Sea Sewage Tunnel, UK, 1966
Clay & Takacs (1997)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• The tunnel intersected the bottom of an abandoned 600mm
diameter well
• Source• Clay & Takacs (1997)
Southend-on-Sea Sewage Tunnel, UK, 1966
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Tunnel designed to carry irrigation water from the Orange River
(80km long and 5.3m in diameter, 1,200m above sea level)• Tunnelling using the rail-mounted drill and blast method and lined
with insitu concrete
• First failure – Heavy water inflow• Water inflow of about 55,000 litres/min into the tunnel at 14 bars• Entire 1.6km tunnel section flooded within 24 hours
• Possible cause of failure• The tunnel passed through a shallow anticline and intersected a
fissure, about 75mm wide, almost perpendicularly
Orange-fish Tunnel, South Africa, 1970
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Second failure – Fire• Methane gas ignited by a blast• No explosion occurred as the gas did not reach the explosive
concentration• The fire burnt for about 6 month
• Possible cause of failure• Methane gas from a methane bearing fissure entered the tunnel
during excavation
• Source• Clay & Takacs (1997)
Orange-fish Tunnel, South Africa, 1970
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Munich Underground, Germany, 1980
Construction Today (1994b)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• New Austrian Tunnelling Method (NATM) construction of twin 6m
diameter tunnels
• The failure• 10m wide, 14m deep sinkhole
• Possible causes of failure• Local variation in geology with reduction in marl cover to 1-1.5m
and led to overstressing of the sprayed concrete temporary lining
Munich Underground, Germany, 1980
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Delay to works
• Remedial Measures• Void was backfilled with crushed rock and cement and pressure
grouted
Source • Construction Today (1994b)
Munich Underground, Germany, 1980
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Railway tunnel 2.21km long and 9m in diameter
• The failure• “Compact” fissured clay layer failed suddenly, allowing water
inflow >600 litres/min into the tunnel
Gibei Railway Tunnel, Romania, 1985
Clay & Takacs (1997)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• The tunnel penetrated a lens of waterlogged fine-grained sand
just above the crown
• Source• Clay & Takacs (1997)
Gibei Railway Tunnel, Romania, 1985
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Tunnel constructed by Tunnel Boring Machine (TBM)
• The failure• Fine soil flowed into the tunnel forming a hole in the road as the
TBM went through the rock into the soft ground
Moda Collector Tunnel,
Istanbul Sewerage Scheme, Turkey, 1989
Clay & Takacs (1997)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• The tunnel intersected a hidden area of soft clay
• Source• Clay & Takacs (1997)
Moda Collector Tunnel,
Istanbul Sewerage Scheme, Turkey, 1989
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Seoul Metro Line 5 - Phase 2, Korea,
17 Nov. 1991
Lee & Cho (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of Seoul Metro tunnel near Majang by drill and blast
method
• The failure• After blasting : daylight collapse up to ground surface, involving
the embankment of a river• 20m x 15m and 4m deep crater at the ground surface• Water from river flowed into the tunnel
• Possible cause of failure• Thin weathered rock cover• Inflow of soil and groundwater
Seoul Metro Line 5 - Phase 2, Korea,
17 Nov. 1991
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Roads collapse and gas mains
fractured
• Remedial measures• Backfilling the crater with soil
followed by cement grouting and chemical grouting
• Lessons learnt• Insufficient ground investigation• Unexpected groundwater inflow• No tunnel face stability analysis• No consideration of blasting effects
closed to weathered zone with shallow cover
Seoul Metro Line 5 - Phase 2, Korea,
17 Nov. 1991
Majang Bridge
Alluvium
Soft rock
Hard rock
Cheonggye-choeon
4. grouting (JSP)
2. sand mat
3. face shotcrete
Fill (SM)Silty sand
Decomposedgranite soil
Weatheredrock
1. backfilling
-3.5m
-24.0m
-29.5m
-3.2m
18.0m
1.4m
-26.5m
1000m3
Sink hole
-12.8m-13.3m
-18.0m
Lee & Cho (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Source• Lee & Cho (2008) • Madrid (1996)• Shin et al (2006)
Seoul Metro Line 5 - Phase 2, Korea,
17 Nov. 1991
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Seoul Metro Line 5 - Phase 2, Korea,
27 Nov. 1991
Lee & Cho (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of Seoul Metro tunnel near Dangsan by drill and
blast method
• The failure• 27 November 1991
10:40am : blasting4:00pm : rock falls at the tunnel face
10:00pm : soil and groundwater inflow into the tunnel
• 28 November 19913:20am : substantial daylight collapse up to ground surface forming a 25m diameter crater
Seoul Metro Line 5 - Phase 2, Korea,
27 Nov. 1991
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• Weathered granite at the face
and high permeability soil
• Consequences• Three buildings collapsed• Several water mains, gas
pipes and sewerage were broken
• Remedial measures• Backfilling the crater with soil
followed by cement grouting and chemical grouting
Seoul Metro Line 5 - Phase 2, Korea,
27 Nov. 1991
25.0m
20.0m
D=20.0m-1.2m
-4.8m-6.0m
-28.5m
-37.5m
-22.2m
-25.1m
-29.2m
Fill sand
Silt
Sand
Weatheredrock
Soft rock
Hard rock
Ⅱ Ⅰ Ⅱ
Ⅲ
Ⅰ: Cement mortarⅡ: Cement milkⅢ: Chemical grout
15.0m5.0m10.0m5.0m
backfilling
Lee & Cho (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Lessons learnt• Insufficient ground investigation• Unexpected groundwater inflow• No tunnel face stability analysis• No consideration of blasting effects closed to weathered
zone with shallow cover
• Source• Lee & Cho (2008) • Madrid (1996)• Shin et al (2006)
Seoul Metro Line 5 - Phase 2, Korea,
27 Nov. 1991
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Seoul Metro Line 5 - Phase 2, Korea,
11 Feb. 1992
Lee & Cho (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of Seoul Metro tunnel near Youido by road header
• The failure• Significant inflow of groundwater• About 4.5 tonnes of soil flowed into tunnel• 38m wide x 6m deep crater at the ground surface
Seoul Metro Line 5 - Phase 2, Korea,
11 Feb. 1992
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• Weathered granite at the tunnel
face and high permeability soil
• Remedial measures• Backfilling the crater with soil
followed by cement grouting and chemical grouting
• Lessons learnt• Insufficient ground investigation• Unexpected groundwater inflow• No tunnel face stability analysis
Seoul Metro Line 5 - Phase 2, Korea,
11 Feb. 1992
-5.6m
-7.8m-9.9m
-13.2m
-21.7m
-25.9m-26.4m
-11.8m
Fill
Alluvium(SC)
Alluvium(SP)
Alluvium(ML)
Hard Rock
Weathered rock
Soft rock
Sewer box
MBC
Sewer Box
38.0m
3. urethan grouting
2. cement mortal grouting
1. back filling
-23.5m
-33.0m
3m
Decomposed rock
Lee & Cho (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Source• Lee & Cho (2008) • Madrid (1996)• Shin et al (2006)
Seoul Metro Line 5 - Phase 2, Korea,
11 Feb. 1992
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Seoul Metro Line 5 - Phase 2, Korea,
7 Jan. 1993
Lee & Cho (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of Seoul Metro tunnel near Yongdungpo by drill and
blast method
• The failure• Tunnel collapsed after removing spoil• Tunnel collapsed starting from the left side of the crown• 900m3 of loose material flowed into the tunnel and water inflow of
up to 300 litres/min recorded
Seoul Metro Line 5 - Phase 2, Korea,
7 Jan. 1993
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• Weathered granite at the tunnel
face • High groundwater pressure
• Remedial measures• Backfilling the crater with soil
followed by cement grouting and chemical grouting
Seoul Metro Line 5 - Phase 2, Korea,
7 Jan. 1993
Fill
Alluvium(ML)
Alluvium(SP)
Weathered rock
Soft rock
-1.1m
-7.1m
-16.5m
-21.5m
-4.9m
-20.14m
-28.34m
Sewer box
900m3
2. cement mortar
3. cement mortar
4. chemical grouting
1. back filling
Lee & Cho (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Lessons learnt• Insufficient ground investigation• Unexpected groundwater inflow• No tunnel face stability analysis• No consideration of blasting effects closed to weathered zone
with shallow cover
• Source• Lee & Cho (2008) • Madrid (1996)• Shin et al (2006)
Seoul Metro Line 5 - Phase 2, Korea,
7 Jan. 1993
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Seoul Metro Line 5 - Phase 2, Korea,
1 Feb. 1993
Lee & Cho (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of Seoul Metro tunnel near Anyangcheon by road
header
• The failure• Daylight collapse when weathered granite found at the tunnel
face• Groundwater flowed into the tunnel• 60m wide oval shaped area subsided
Seoul Metro Line 5 - Phase 2, Korea,
1 Feb. 1993
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• Weathered granite and alluvium
at the tunnel face • High groundwater pressure
• Consequences• Six heavy plants buried
• Remedial measures• Backfilling the crater with soil
followed by cement grouting and chemical grouting
Seoul Metro Line 5 - Phase 2, Korea,
1 Feb. 1993
8.3m
24.0m
59.3m
cement milkgrouting
59.3mjet grouting
5.0m-21.0m
-24.0m
-29.0mWeathered rock
Soft rock
Anyang cheon
Alluvium2. cement milk
grouting
Sewer box
-24.0m
-32.0m
3. jet grouting
1. backfilling
Decomposed granite soil
Sewer Box
Lee & Cho (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Lessons learnt• Insufficient ground investigation• Unexpected groundwater inflow• No tunnel face stability analysis
• Source• Lee & Cho (2008) • Madrid (1996)• Shin et al (2006)
Seoul Metro Line 5 - Phase 2, Korea,
1 Feb. 1993
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Tunnel constructed in sandstone and shale with fault zones
by the drill & blast method• Tunnel divided into 4 sections, namely T1 – T4• T1 - 376m long; T2 - 562m; T3 – 2,760m and T4 – 1,230m
• Failures at T4 in 1993• About 130 overbreak incidents with total volume of 1,461m3,
maximum deformation of 120mm measured in the tunnel• 200m3 of loose material collapsed after a blast, resulting in
water inflow of up to 450 litres/min
Motorway Tunnels, Austria, 1993-95
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Two failures at T3 in 1995• 650m3 of loose material flowed into the tunnel, water inflow of up
to 1,500 litres/min recorded• Radial movement of rib of about 300mm occurred and water
inflow of up to 1,500 litres/min recorded
• Source• Clay & Takacs (1997)
Motorway Tunnels, Austria, 1993-95
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Heathrow Express Tunnel, UK, 21 Oct. 1994
Ground Engineering (2008) ICE (1998b)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• NATM in London Clay
• The failure• 10m diameter crater formed
Heathrow Express Tunnel, UK, 21 Oct. 1994
ICE (1998b)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• A series of design and management errors combined with
poor workmanship and quality control
• Consequences • Differential settlement induced at adjacent buildings• Services Terminal 4 halted for one month• Remedial measures caused chaos at Heathrow Airport• Recovery cost £150M (3 times original contract sum)
Heathrow Express Tunnel, UK, 21 Oct. 1994
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
0 to +0.5m
0 to -1m
-1 to -2m
-2 to -3m
> -3m
GROUND SURFACE CONTOURSLEGENDS
Central Terminal Area Settlement Contours
Heathrow Express Tunnel, UK, 21 Oct. 1994
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Remedial measures• Backfilled with 13,000m3 concrete
Heathrow Express Tunnel, UK, 21 Oct. 1994
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Lessons learnt• Measures to ensure safety must be planned• Do not lose sight of critical technical issues in the pursuit of time
and cost reduction• Whilst a number of factors contributed to the collapse, half of them
were matters of management• However much engineers are pressured to build quickly and
cheaply, the industry will be judged by its own failures
• Sources• Ground Engineering (2000)• HSE (1996, 2000)• ICE (1998b, 1999)
Heathrow Express Tunnel, UK, 21 Oct. 1994
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
1996 report 2000 report
Heathrow Express Tunnel, UK, 21 Oct. 1994
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Munich Underground, Germany, 27 Sept. 1994
• Background• 7m diameter tunnel supported by
sprayed concrete lining• The tunnel was assumed to be
beneath a clay layer overlying water-bearing gravel and groundwater would not be drawn down
• The failure• Quick inflow of water and ground
materials• Large subsidence crater quickly
filled with groundwater• 20m wide, 18.5m deep craterConstruction Today (1994a)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible causes of failure• Layer of marl separating groundwater bearing layers was
much thinner than originally assumed• Sand-infilled cracks in the marl layer acted as preferential
pathways for water
• Consequences • Bus fell into the crater• Three passengers killed• 30 people injured
Munich Underground, Germany, 27 Sept. 1994
Construction Today (1994a)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Remedial measures• Bored-pile wall to form a shaft• Excavation inside the shaft for rescue• Tunnel driven again using compressed air
• Sources• Boos et al (2004)• Construction Today (1994a)• Ground Engineering (1994)
Munich Underground, Germany, 27 Sept. 1994
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Re-mining/remedial works to
realign an existing TBM tunnel (6.7m diameter, 25m deep), which had been bored off line
• Hard siltstone overlain by alluvium with groundwater level 10-12m below surface
• The failure• 25m deep sinkhole caused by
collapse of south bore• Serious cracking observed in
temporary lining of north bore
Los Angeles Metro, USA, 22 June 1995
Civil Engineer International (1995)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible causes of failure• Failure occurred during removal of segmental lining in tunnel
roof and relining of tunnel to correct the horizontal alignment• Unexpected ground conditions in the alluvium• Fractured water mains (unconfirmed)
• Consequences• 30m length of a four lane road (Hollywood Boulevard) affected
leading to road closure• Collapsed 250mm water main possibly contributing to failure• Broken gas pipe• Evacuation of local residents
Los Angeles Metro, USA, 22 June 1995
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Remedial measures• Steel rings installed in tunnel either side of the collapse• 3,300m3 of grout to fill void and stabilise area• Road resurfacing
• Source • Civil Engineer International (1995)
Los Angeles Metro, USA, 22 June 1995
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Docklands Light Rail, UK, 23 Feb. 1998
ICE (2004)ICE (1998a)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Tunnel constructed for Docklands Light Rail (diameter 5.2m) by
earth pressure balance TBM
• The failure• 22m wide and 7m deep crater formed in the grounds of George
Green School
Docklands Light Rail, UK, 23 Feb. 1998
ICE (1998a)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible causes of failure• Insufficient overburden above the tunnel• High pressure within tunnel causing blow out failure
• Consequence• Windows up to 100m away broken by the shower of mud and
stones released
Docklands Light Rail, UK, 23 Feb. 1998
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Lesson learnt• To require specific assessments / calculations to demonstrate
the adequacy of factor of safety against blow out failure
• Sources• ICE (1998a)• ICE (2004)
Docklands Light Rail, UK, 23 Feb. 1998
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Athens Metro, Greece, 1991-1998
IMS IMIA
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of the Olympic Metro under a turnkey contract
(estimated cost about 2 billion ECUs)• Construction started in November 1991 and operation in 1998• TBM (by Mitsubishi) used for construction of 11.7km long, 9.5m
diameter tunnels located at a depth of 15-20m (with penetration rate ranging from 1.6m to 18m per day based on 18-hour-per-day shift, depending on the ground conditions)
• Cut and cover, supported by soldier piles, struts and prestressedanchor tiebacks for 6.3km long tunnels and stations
• NATM for other short auxiliary tunnels and oval-shaped stations where existence of buried antiquities precluded open excavation
Athens Metro, Greece, 1991-1998
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• The failures• Roof collapses of appreciable size often occurred• Large and occasionally uncontrollable overbreaks for TBM
• Possible causes of failure• Ravelling of the ground seems to be due to insufficient strength in
the intensely weathered and highly tectonised zones of Athenian schist (which is a flysch-type sediment consisting of thinly bedded clayey and calcareous sandstones with alterations and subjected to intense folding, thrusting, faulting and fracturing)
• Large muck openings of the TBM cutterhead which cannot adequately control muck-flow (the cutterhead operates in the open air, i.e. under atmospheric pressure)
Athens Metro, Greece, 1991-1998
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequence• Major delay in TBM tunnelling
• Remedial measures• Cavities caused by the TBM overbreaks was backfilled by grout
(which sometimes reached the ground surface)
• Source• IMIA• IMS• Kavvadas et al (1996)• Mihalis & Kavvadas (1999)
Athens Metro, Greece, 1991-1998
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Sewage Tunnel, Hull, UK, 1999
Boos et al (2004)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of a 10.5km long underground sewer by earth
pressure balance TBM (diameter 3.85m) supported by reinforced concrete segmental lining
• The failure• Water and sand ingress• Tunnel subsided by 1.2m causing serious subsidence at surface
• Possible cause of failure• Fluctuation of groundwater level caused by tidal effects resulting in
vertical movement of the tunnel tube causing opening of joints
Sewage Tunnel, Hull, UK, 1999
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences • Damage to buildings, roads and utility lines• TBM had to be abandoned
• Emergency and remedial measures• Ground freezing• Reconstruction of tunnel using sprayed concrete
• Source • Boos et al (2004)
Sewage Tunnel, Hull, UK, 1999
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Taegu Metro, South Korea, 1 Jan. 2000
Boos et al (2004)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background • Construction of underground Taegu Metro
• The failure• Failure of diaphragm wall• Excavation pit caved in
• Possible causes of failure • Rapid fluctuation of groundwater level caused movement of
unidentified gravel and sand strata• Additional loading on diaphragm wall was not considered in design
Taegu Metro, South Korea, 1 Jan. 2000
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Bus buried and bus driver seriously injured• Three passengers killed• Neighbouring buildings suffered considerable damage
• Remedial measures • Excavation pit backfilled• Subsoil grouted and diaphragm wall strengthened
• Source • Boos et al (2004)
Taegu Metro, South Korea, 1 Jan. 2000
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Channel Tunnel Rail Link, UK, Feb. 2003
ICE (2003)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Tunnelling using TBM (diameter 8.2m)• Boring at a depth of 21m
• The failure• 10m diameter and 20m deep void
formed in the ground behind a row of houses
• Possible cause of failure• The vibration from the TBM may have
caused the nearby wells (30m deep and 1.8m diameter) to collapse
Channel Tunnel Rail Link, UK, Feb. 2003
ICE (2003)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequence• Three uncharted wells collapsed
• Remedial measures• The voids were backfilled with grout
• Source• ICE (2003)
Channel Tunnel Rail Link, UK, Feb. 2003
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Météor Metro Tunnel, France, 14 Feb. 2003
Dubois & Rat (2003)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of Météor
Metro Tunnel in Paris
• The failure• About 3,000m3 of
sedimentary deposits collapsed underneath a school, occupying an area of 400m2 on plan
Météor Metro Tunnel, France, 14 Feb. 2003
Dubois & Rat (2003)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• Not known
• Consequences• No casualty• The school had to be closed for a year affecting 900 students
• Source• Dubois & Rat (2003)
Météor Metro Tunnel, France, 14 Feb. 2003
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Shanghai Metro, China, 2003
Boos et al (2004)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Expansion of the Shanghai Metro (上海地鉄) Line 4 crossing
beneath the Huangpu River (黃埔江)• Two parallel tunnel tubes constructed by earth pressure balance
TBM
• The failure• Failure occurred during construction of a cross passage• Massive ingress of water and material at the face at a depth of 35m• Several metres ground subsidence
Shanghai Metro, China, 2003
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure • Failure of ground freezing unit
• Consequences• High rise office buildings seriously damaged• Flood protection dyke on the river badly damaged
• Source • Boos et al (2004)
Shanghai Metro, China, 2003
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Hsuehshan Tunnel, Taiwan, 1991-2004
TANEEB (2005)
TANEEB (2005)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of 12.9km long and 4.8m diameter Hsuehshan
Tunnel in Taiwan (雪山隧道) • Works commenced in 1991 and completed in 2004• Comprised 2 main tunnels (East & Westbound) and a pilot tunnel• Eastbound by TBM method (July 1993 to Sept. 2004)• Westbound by TBM method (July 1993 to April 2004)• Pilot tunnel by drill & blast method (July 1991 to Oct. 2003)
Westbound Eastbound
Pilot Tunnel
Hsuehshan Tunnel, Taiwan, 1991-2004
TANEEB (2005)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• The failures• Eastbound
• 28 collapses occurred• Westbound
• TBM badly damaged due to tunnel collapse and groundwater inflow of 45,000 litres/min into the tunnel
• Pilot Tunnel• 8 collapses occurred
• Possible causes of failure• Unexpected difficult geology with fractured rock and massive
inflows of water• 6 major faults found along the tunnel alignment
Hsuehshan Tunnel, Taiwan, 1991-2004
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Eastbound
• Failure in May 1993 affected 56 buildings and 73 families• Westbound
• 11 men died• Pilot Tunnel
• 13 stoppages
• Source• TANEEB (2005)
Hsuehshan Tunnel, Taiwan, 1991-2004
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Stormwater Management and Road Tunnel
(SMART), Malaysia, 2003 - 2006
SMART
Limestone
Siow, M. T. (2006)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• 9.7km long and 13.26m diameter tunnel driven through karst
formation by slurry shield TBM
• The failure• 37 incidents within 8 km of tunnel excavation
• Possible cause of failure• Adverse geology and karst conditions
Stormwater Management and Road Tunnel
(SMART), Malaysia, 2003 - 2006
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Stormwater Management and Road Tunnel
(SMART), Malaysia, 2003 - 2006
Siow, M. T. (2006)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Stormwater Management and Road Tunnel
(SMART), Malaysia, 2003 - 2006
McFeat-Smith (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Source• Siow, M. T. (2006)• McFeat-Smith (2008)
Stormwater Management and Road Tunnel
(SMART), Malaysia, 2003 - 2006
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Guangzhou Metro Line 3, China, 1 April 2004
ChinaDaily (2004)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of a 58.5km long underground metro in which
45.6km is a single-tube shield TBM
• The failure• Failure of a diaphragm wall
• Possible cause of failure• Rapid fluctuation of groundwater level due to the heavy rainfall• Complicated geology including a layer of swelling soil
Guangzhou Metro Line 3, China, 1 April 2004
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• A three-storey building collapsed and sunk into the ground• Collapse of nearby underground water mains
• Remedial measures• Backfilled with crushed rock and cement
• Source• ChinaDaily (2004)• Soufun (2004) • Longhoo (2004)
Guangzhou Metro Line 3, China, 1 April 2004
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Singapore MRT, 20 April 2004
Government of Singapore (2005)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• An open cut tunnel excavated for Singapore MRT’s new Circle Line • Design and build• Excavated trench of 15m wide and 33m deep mainly in marine clay
with some fluvial clay supported by 0.8-1.0m thick diaphragm wall which is 35-45m deep without rock socket
• Steel struts: 4-5m horizontal and 3m vertical spacing• Bottom-up construction • Jet grouted base slabs
• Layer 1-1.5m thick at 28.5m below ground• Layer 2-3m thick at 33.5m below ground (Layer 2 not yet
constructed when collapse occurred)
Singapore MRT, 20 April 2004
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• The failure• 9th level of struts being installed when
collapse took place• Unusual cracking and groaning noises heard
early in the morning (6 hours)• Loud cracking noise heard in the afternoon, 15
minutes before collapse• Collapse plan area was 100m by 130m• Settlement up to 15m• Diaphragm walls displaced• Steel struts mangled
Singapore MRT, 20 April 2004
Government of Singapore (2005)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible causes of failure• Under-design of the strut-waler connection in the strutting system• Incorrect use of Finite Element Method• No proper design reviews• Disregard of different warnings, for example, excessive wall
deflections and surging inclinometer readings• Poor construction quality• Ineffective instrumentation and monitoring system• Failure to implement risk management
Singapore MRT, 20 April 2004
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences • Part of Nicoll Highway, Singapore’s major east-west harbour-front
road, destroyed• Four workers killed• Several others injured • 15,000 people and 700 businesses affected• Three offices and retail towers at risk from further ground movement• Damage of a gas service line, resulting in an explosion and fire• A storm drain damaged
Singapore MRT, 20 April 2004
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Remedial measures• Rescue and backfilling• Structurally disconnected the Merdeka Bridge• All contracts of the Circle Line put on hold• All contracts to carry out checks and review of design and
construction of temporary works• All Professional Engineers to confirm in writing the adequacy of
their designs• All designs to be independently checked by the Building &
Construction Authority
Singapore MRT, 20 April 2004
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Lessons learnt• This is a need for robust design, risk management, design review
and independent checking, purposeful back analysis, an effectiveinstrumentation, monitoring and interpretation regime, an effective system of management of uncertainties and quality during construction, corporate competencies and safety management
• The safety of temporary works is as important as that of permanent works and should be designed according to established codes and checked by competent persons
• Main Source• Government of Singapore (2005)
Singapore MRT, 20 April 2004
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of the Kaohsiung Rapid
Transit Blue & Orange Lines in Kaohsiung City
• The failures• First collapse on 29 May 2004
underneath a street• Second collapse in mid June 2004• Third collapse on 13 July 2004 with
formation of a large sinkhole• Fourth collapse on 10 Aug 2004
Kaohsiung Rapid Transit, Taiwan, 10 Aug. 2004
Taiwan Info (2004)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• Possible adverse ground and groundwater conditions
• Consequences• First collapse - Several buildings affected and 100 people
evacuated • Third collapse - Three residential buildings evacuated and
significant disruption to water/electricity supply• Fourth collapse - No casualty, one building affected and part of
the works suspended
• Source• Taiwan Info (2004)
Kaohsiung Rapid Transit, Taiwan, 10 Aug. 2004
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Barcelona Metro, Spain, 27 Jan. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Tunnel for Barcelona Line Five Metro Extension• Tunnelling using NATM
• The failure• 30m wide and 32m deep crater formed
• Possible cause of failure• A “hidden” vertical fault located 1m behind the sprayed concrete
lining
Barcelona Metro, Spain, 27 Jan. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• 2 five-storey buildings and a smaller one demolished• More than 50 families made homeless
• Remedial measures• The void was backfilled with grout of about 2,000m3
• Source• European Foundations (2005)
Barcelona Metro, Spain, 27 Jan. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Lausanne M2 Metro, Switzerland, 22 Feb. 2005
Tunnels & Tunnelling (2005)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Tunnel (6km long, approximately 10m wide x 7m high) for
Lausanne Metro M2 Project (cost US$472M) in Switzerland• Tunnelling using an Eickhoff ET 380-L roadheader
• The failure• Collapse in area of soft ground (lake deposits)• 50m3 of material displaced into the tunnel at a depth of 12m,
leading to a crater at the surface
• Possible cause of failure• Tunnel driven through a pocket in the glacial moraine, causing
sudden inflow of groundwater
Lausanne M2 Metro, Switzerland, 22 Feb. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• People in two buildings, a supermarket and a food outlet in
commercial district evacuated when their cellars collapsed• No injuries reported
• Remedial measures• A curtain of 11 piles constructed ahead of the collapsed face with
grouting to strengthen the ground and limit further flow of material into the tunnel
• The void was backfilled with 800m3 of glass-sand (recycled glass)
• Source• Tunnels & Tunnelling (2005)
Lausanne M2 Metro, Switzerland, 22 Feb. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Lane Cove Tunnel, Australia, 2 Nov. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Twin NATM tunnels (7m high, 8.1 wide and 3.6km long)
constructed under Lane Cove Tunnel Project in Sydney
• The failure• Collapse occurred during breakout for a ventilation tunnel from
the running tunnel• A 10m by 10m, 25m deep crater formed in the ground between a
3-storey high residential building and a highway exit ramp
Lane Cove Tunnel, Australia, 2 Nov. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible causes of failure• Possible “rock slippage”• Ground investigation did not identify dyke at the tunnel
intersection• Under designed rock bolts due to increased effective span at
intersection of adit and tunnel
• Consequences• A 3-storey building partially collapsed and 47 residents
evacuated• A water main burst• Citybound road closed
Lane Cove Tunnel, Australia, 2 Nov. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Remedial measures• The void was backfilled with
1,400m3 of concrete• Continual monitoring
• Sources• Golder (2005)• Ground Engineering (2005)• Ground Engineering (2006a)• Ground Engineering (2006b)• ICE (2006)• NNN (2005)• SMH (2005)
Lane Cove Tunnel, Australia, 2 Nov. 2005
ICE (2006)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Kaohsiung Rapid Transit, Taiwan, 4 Dec. 2005
TT (2005)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of Kaohsiung Rapid Transit (KRT) Orange Line at
the junction of Chungcheng Road and Tashun Road in Kaohsiung City
• The failure• Failure occurred during excavation of an underground sump pit at
a cross passage (33m below ground) underneath an existing reservoir
• A 30m by 20m, 4m deep trench initially formed on 4 Dec. 2005 and was collapsed to form a 50m by 30m, 10m deep crater at the road surface
• This was the 10th reported failure of the KRT project• Another crater (10m diameter, 7m deep) formed at another
location on 10 Dec. 2005
Kaohsiung Rapid Transit, Taiwan, 4 Dec. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• Massive water seepage from a reservoir
Kaohsiung Rapid Transit, Taiwan, 4 Dec. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Chungcheng Road (a major trunk road) closed for a week• The nearby Linkang railway line temporarily suspended• A 100m long section of tunnels and utilities damaged• Cracks found at 20 nearby residential buildings
• Remedial measures• The crater was backfilled with about 2,800m3 of soil/rock and
concrete 20 hours after the accident• The damaged sections of the KRT tunnels needed to be re-
constructed• Cost of the remedial measures estimated to be up to NT$500M
(US$15M) excluding reconstruction of the damaged sections of the KRT tunnels
Kaohsiung Rapid Transit, Taiwan, 4 Dec. 2005
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Sources• TVB News (2005)• TT (2005)• SP (2005)• ST (2005)• Sun (2005)• WWP (2005)• OD (2005)• TKP (2005)• MP (2005)
Kaohsiung Rapid Transit, Taiwan, 4 Dec. 2005
TVB News (2005)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Sao Paulo Metro Station, Brazil,
15 Jan. 2007
Gulp (2007)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• New Austrian Tunnelling Method (NATM) was used to excavate a
18.5m diameter 45m long section station tunnel• The tunnel failure occurred close to a junction with a 40m
diameter, 40m deep access shaft
• The failure• Collapse of the station tunnel and partial damage to the access
shaft• The rate of settlement at the tunnel crown increased rapidly and
reached 15mm to 20mm two to three days before the failure
Sao Paulo Metro Station, Brazil,
15 Jan. 2007
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• Failed to account for the geology of the site; fractured rock
located over the excavation • The lack of sufficient supports in the roof and side walls of the
excavation
• Consequences• Several vehicles dropped into the 30m-deep hole• Seven persons killed
• Remedial measures• Stabilized the section of tunnel with extensive reinforcement• A system of anchors extending 32m into the soil was put in place
and the excavation through the section was performed after pre-grouting
Sao Paulo Metro Station, Brazil,
15 Jan. 2007
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Source• ICE (2008)• Gulp (2007)
Sao Paulo Metro Station, Brazil,
15 Jan. 2007
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Guangzhou Metro Line 5, China,
17 Jan. 2008
Sina (2008a)
AD (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of a cross passage between two tunnel boring
machine tunnels
• The failure• Collapse of the cross passage tunnel
• Possible cause of failure• Groundwater flowed into the tunnel
• Consequences• Cave-in at the road, about 100m2 on plan• No injury
Guangzhou Metro Line 5, China,
17 Jan. 2008
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Remedial measures• Crater backfilled with concrete
• Source• AD (2008a)• Sina (2008a, 2008b)
Guangzhou Metro Line 5, China,
17 Jan. 2008
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Circle Line 4 Tunnel, Singapore, 23 May 2008
Property Highlights of Singapore (2008)
Property Highlights of Singapore (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of Circle Line 4
tunnel by 6m diameter slurry mixshield TBM
• The failure• Cave-in at Holland Road
approximately 8m diameter x 3m deep
• Possible cause of failure• Loose ground
Circle Line 4 Tunnel, Singapore, 23 May 2008
Property Highlights of Singapore (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Temporary suspension of water supply
• Remedial measures• Crater backfilled with concrete
• Source• Property Highlights of Singapore (2008)
Circle Line 4 Tunnel, Singapore, 23 May 2008
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Hangzhou Metro Tunnel, China, 15 Nov. 2008
AD (2008b)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Construction of Hangzhou Metro
• The Failure• Failure of a series of continuous walls of 800mm thick
constructed by cut-and-cover method forming a 21m wide x 16m deep excavated area
• Consequences• A 75m long section of road collapsed and 11 vehicles fell into the
16m deep excavation• A 600mm diameter water main was broken • Water from the nearby river flowed into the collapsed area
Hangzhou Metro Tunnel, China, 15 Nov. 2008
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Three 3-storey buildings seriously damaged and needed to be
demolished• Two 110kV cables were damaged • 8 persons died, 13 persons missing (as of 19 Nov. 2008) and 11
persons injured
Hangzhou Metro Tunnel, China, 15 Nov. 2008
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Hangzhou Metro Tunnel, China, 15 Nov. 2008
CNS (2008)
CNS (2008)
CNS (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Hangzhou Metro Tunnel, China, 15 Nov. 2008
XINHUANET (2008)
XINHUANET (2008)
XINHUANET (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Hangzhou Metro Tunnel, China, 15 Nov. 2008
XINHUANET (2008)
XINHUANET (2008)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Source• AD (2008b)• Beijing Review (2008) • CNS (2008)• NCE (2008) • XINHUANET (2008)
Hangzhou Metro Tunnel, China, 15 Nov. 2008
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Hong Kong Cases
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• A running tunnel (5m in diameter) being constructed from Prince
Edward Station by the drill and blast method• Ground above the tunnel strengthened
• The failure• A wall section of the running tunnel under Nathan Road
collapsed• The subsidence did not affect the road surface
MTR Modified Initial System, Prince Edward
Station, Nathan Road, 12 Sept. 1977
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible causes of failure• Gap existed between the ground treatment above the station
tunnel and that above the running tunnel allowing the soil to flow into the tunnel
MTR Modified Initial System, Prince Edward
Station, Nathan Road, 12 Sept. 1977
Station Tunnel RunningTunnel
Nathan Road
Annular GroundTreatment
Annular GroundTreatment
after Clay & Takas (1997)
Water table
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Nathan Road between Argyle Street and Arran Street closed as
a safety measure• Three buildings (Nos. 745, 745A and 745B Nathan Road)
involving 100 people evacuated• Closure Order issued for nearby shops and a petrol station
• Source• Clay & Takacs (1997)• SCMP (1977)
MTR Modified Initial System, Prince Edward
Station, Nathan Road, 12 Sept. 1977
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
MTR Island Line, 22 Hennessy Road, 1 Jan. 1983
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background • Tunnelling from Admiralty to Causeway Bay for MTR Island Line
using the drill and blast method• Tunnel formed by the drill and blast method
• The failure• Water-bearing fill flowed into the tunnel, opening a hole at the
road above• 1,500m3 of material flowed into the tunnel creating a void of an
area of 100m2 and 30m deep beneath the road surface
MTR Island Line, 22 Hennessy Road, 1 Jan. 1983
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Possible cause of failure• Misinterpretation of the geology by the Contractor• Blasting went too far, resulting in the tunnel penetrating the
rock into soft ground
MTR Island Line, 22 Hennessy Road, 1 Jan. 1983
Soft Ground
Hennessy Road
after Clay & Takas (1997)
Shield Chamber
Rock
Water table
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Cracks found in the granite masonry of the outside wall of a
building at 22 Hennessy Road• At least 21 timber piles beneath an adjacent building of 22
Hennessy Road exposed• More than 150 people in 18-22 Hennessy Road evacuated• The building at 18-20 Hennessy Road reopened 3 hours after
the incident and the building at 22 Hennessy Road 6 days later
MTR Island Line, 22 Hennessy Road, 1 Jan. 1983
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Remedial measures• The void was backfilled by grout• The floor slab of the building at 22
Hennessy Road pushed up by the grouting works by 50-75mm
• Sources• Clay & Takacs (1997)• SCMP (1983)
MTR Island Line, 22 Hennessy Road, 1 Jan. 1983
SCMP (1983)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
MTR Island Line, Shing On Street,
Shau Kei Wan, 23 July 1983
MP (1983a)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background • Tunnelling from Tai Koo Station to Sai Wan Ho Station for
MTR Island Line
• The failure• 13m x 1m void formed
MTR Island Line, Shing On Street,
Shau Kei Wan, 23 July 1983
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Section of Shau Kei Wan Road closed• Building at 122-124 Shau Kei Wan Road settled more than
100mm and tilting observed• More than 80 families (400 people) evacuated & a woman injured• Water main damaged due to the settlement• Water and gas supplies stopped
• Source• MP (1983a)
MTR Island Line, Shing On Street,
Shau Kei Wan, 23 July 1983
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
MTR Island Line, 140-168 Shau Kei Wan Road
16 Dec. 1983
MP (1983a)
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
MTR Island Line, 140-168 Shau Kei Wan Road
16 Dec. 1983
• Background• Construction of Sai Wan Ho Station for MTR Island Line
• The failure• More than 40mm of ground settlement• About 150m3 of soil flowed into the tunnel leaving a void
between Shau Kei Wan Road and the tunnel
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Section of Shau Kei Wan Road closed• Water supply stopped
• Source• MP (1983b)
MTR Island Line, 140-168 Shau Kei Wan Road
16 Dec. 1983
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Kowloon Southern Link Contract KDB 200,
Canton Road, 21 Oct. 2006
GEO File Information
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Twin railway tunnels between Jordan Road and East Tsim Sha
Tsui Station constructed by a slurry TBM• Incident of ground loss occurred at TBM launch area
• The failure• 3m(W) x 3.5m(L) x 3m(D) sinkhole formed reaching the ground
surface
• Possible cause of failure• Slurry leakage and loss of slurry support pressure
Kowloon Southern Link Contract KDB 200,
Canton Road, 21 Oct. 2006
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences • Crater formed at the ground surface closed to a busy road and a gas main
• Remedial measures• Backfilling of the sinkhole with stockpile materials and sub-base materials
• Source• GEO File Information
Kowloon Southern Link Contract KDB 200,
Canton Road, 21 Oct. 2006
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Kowloon Southern Link Contract KDB 200,
Salisbury Road, 3 June 2007
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Background• Twin railway tunnels between Jordan Road and East Tsim Sha
Tsui Station constructed by a slurry TBM
• The failure• 2m x 3m sinkhole reaching the ground surface
• Possible cause of failure• Sudden air pressure loss through the interface between
CDG/HDG and overlying marine sand during a compressed air intervention, resulting in loss of face support and subsequent formation of sinkhole
Kowloon Southern Link Contract KDB 200,
Salisbury Road, 3 June 2007
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
• Consequences• Crater formed at the ground surface, with associated settlement• Temporary closure of a busy road lane• A low pressure gas main and a 1200 mm stormwater drain were
affected
• Remedial measures• Backfilling of sinkhole with granular fill
• Source• GEO File Information
Kowloon Southern Link Contract KDB 200,
Salisbury Road, 3 June 2007
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
AD (2008a). 珠江橋口塌半邊馬路. Apple Daily Newspaper. 19 January 2008, Hong Kong, pp A22.
AD (2008b). 杭州地鐵地盤塌陷增至2死19傷<http://www.appleactionews.com/site/art_main.php?&iss_id=20081116&sec_id=10793096&art_id=11853290&dis_type=ss&media_id=1>.
Beijing Review website (2008). Death Toll Could Reach 21 in Tunnel Collapse. <http://www.bjreview.com.cn/headline/txt/2008-11/19/content_165283.htm> (19 Nov 2008).
Boos, R., Braun, M., Hangen, P., Hoch, C., Popp, R., Reiner, H., Schmid, G., & Wannick, H. (2004). Underground Transportation Systems, Chances and Risks from the Re-insurer’s Point of View.Munich Re Group, Germany, pp 58-62. <http://www.munichre.com/> (31 Jan. 2007).
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
China Daily (2004). 100 homeless after metro site collapse. <http://www.chinadaily.com.cn/english/doc/2004-04/02/content_320246.htm> (2 April 2004).
Civil Engineer International (1995). Tunnel lining removal prompts LA Metro cave in. Institution of Civil Engineers, July Issue, p10.
CNS (2008). <http://www.chinanews.com/>.
Clay, R.B. & Takacs, A.P. (1997). Anticipating the unexpected – Flood, fire overbreak, inrush, collapse. Proceedings of the International Conference on Tunnelling Under Difficult Ground and Rock Mass Conditions, Basel, Switzerland, pp 223-242.
Construction Today (1994a). Police probe repeat Munich tunnel breach. Construction Today, October Issue, pp 4-5.
Construction Today (1994b). Unstable ground triggers Munich tunnel collapse. Construction Today, October Issue, p 5.
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Dubois, P. & Rat, M. (2003). Effondrement sur le chantier "Météor“. Conseil Général des Ponts et Chaussées, France, 22p. <http://www2.equipement.gouv.fr/actualites/Rapports/Meteor.pdf> (31 Jan. 2007).
European Foundations (2005). Tighter NATM rules follow Barcelona failure. European Foundations, Spring Issue, No. 26, p 3.
GEO File Information. GEO File Reference: GCME 3/5/7989/05, KSL Southern Link – C/No. KDB200, West Kln Station & Ancillary Bldg & Tunnel.
Golder (2005). Causes of Subsidence, 2 November 2005, Lane Cove Tunnel Project. Sydney NSW, 52p.
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Government of Singapore (2005). Report of the Committee of Inquiry into the Incident at the MRT Circle Line Worksite That Led to the Collapse of Nicoll Highway on 20 April 2004. Government of Singapore, Land Transport Authority. <http://www.lta.gov.sg/home/index_home_nicoll.htm> (31 Jan. 2007).
Ground Engineering (1994). London NATM controversy. Ground Engineering, November Issue, p 6.
Ground Engineering (2000). Catalogue of disaster. Ground Engineering, August Issue, pp 10-11.
Ground Engineering (2005). Australian tunnel collapse raises doubts over NATM. Ground Engineering, December Issue, p 6.
Ground Engineering (2006a). Sydney tunnel collapse triggered byunder-designed rock bolts. Ground Engineering, February Issue, p 4.
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Ground Engineering (2006b). Rock bolts used instead of steel girders may have contributed to Lane Cove collapse. Ground Engineering, May Issue, p 4.
Gulp (2007). Desenvolvimento e diversão. <http://gulp.com.br/imagem/acidente-no-metro-de-sao-paulo> (17 January 2007).
HSE (1996). Safety of New Austrian Tunnelling Method (NATM) Tunnels. Health & Safety Executive, UK, 86p.
HSE (2000). The Collapse of NATM Tunnels at Heathrow Airport. Health & Safety Executive, UK, 116p.
ICE (1998a). Bulkhead location blamed for DLR blast. New Civil Engineer, Institution of Civil Engineers, February Issue, pp 3-4.
ICE (1998b). HSE signs up QC Carlisle for HEX prosecution. New Civil Engineer, Institution of Civil Engineers, March Issue, pp 4-5.
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
ICE (1999). Heathrow Express court cases kicks off. New Civil Engineer, Institution of Civil Engineers, January Issue, p 6.
ICE (2003). Ground failure linked to well collapses. New Civil Engineer, Institution of Civil Engineers, February Issue, pp 6-7.
ICE (2004). Docklands tunnel blowout down to “elementary error”, says judge. New Civil Engineer, Institution of Civil Engineers, January Issue, pp 8-9.
ICE (2006). Australian tunnel collapse raises new NATM doubts. New Civil Engineer, Institution of Civil Engineers, January Issue, pp 6-7.
ICE (2008). Heart of darkness, New Civil Engineer, Institution of Civil Engineers, September Issue, pp 14-15.
IMIA. <http://www.imia.com>.
IMS. <http://www.imstunnel.com/index2.htm>
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Kavvadas, M., Hewison, L.R., Laskaratos, P.G., Seferoglou, C. & Michalis, I. (1996). Experiences from the construction of the Athens Metro. Proceedings of International Symposium on the Geotechnical Aspects of Underground Construction in Soft Ground, City University, London, April.
Lee, I. M. & Cho, G. C. (2008). Underground construction in decomposed residual soils (presentation slides). The 6th
International Symposium on Geotechnical Aspects of Underground Construction in Soft Ground (IS-Shanghai 2008), Tongji University, Shanghai, April.
Longhoo (2004). 廣州地鐵3號線工地塌方﹐附近居民樓傾斜.<http://www.longhoo.net/big5/longhoo/news/civil/node107/userobject1ai172577.html> (2 April 2004).
Madrid (1996). Informe sobre el NATM del Health & Safety Executive, de Inglaterra, 1996. <http://www.madrid.org/metro/infonatm.html> (1996).
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
McFeat-Smith, I. M. (2008). Personal communications. GEO File Reference: GCME 6/8/6-1, Newspaper Articles for Tunnels/Media Reports.
Mihalis, I. & Kavvadas, M. (1999). Ground movements caused by TBM tunnelling in the Athens Metro Project. Proceedings of International Symposium on the Geotechnical Aspects of Underground Construction in Soft Ground, Japan, July, pp 229-234.
MP (1983a). 筲箕灣路陷傳真. Ming Pao Newspaper. 24 July 1983, Hong Kong.
MP (1983b). 西灣河站塌泥墜道情況已穩定. Ming Pao Newspaper. 17 Dec. 1983, Hong Kong.
NNN (2005). National Nine News. 2 Nov. 2005, Australia.
OD (2005). 高捷洞陷. Oriental Daily. 7 Dec. 2005, Hong Kong.
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Property Highlights of Singapore (2008). <http://propertyhighlights.blogspot.com/2008/05/circle-line-work-causes-cave-in-off.html> (25 May 2008).
SCMP (1977). MTR tunnel collapses. South China Morning Post. 13 Sept. 1977, Hong Kong.
SCMP (1983). MTR tunnelling may be to blame. South China Morning Post. 2 Jan. 1983, Hong Kong.
Shin, J.H., Lee, I.K., Lee, Y.H. & Shin, H.S. (2006). Lessons from serial tunnel collapses during construction of the Seoul subway Line 5.Tunnel and Underground Space Techonology, Issue no. 21, pp 296-297.
Sina (2008a). <http://news.sina.com/ch/phoenixtv/102-101-101-102/2008-01-17/15232606535.html> (17 Jan 2008).
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Sina (2008b). <http://news.sina.com.hk/cgi-bin/nw/show.cgi/9/1/1/613096/> (18 Jan 2008).
Siow, M. T. (2006). Geotechnical aspects of the SMART tunnel. International Conference and Exhibition on Trenchless Technology and Tunnelling, 7-9 March 2006, Malaysia.
SMH (2005). The Sydney Morning Herald. 2 Nov. 2005, Australia.
Soufun (2004).追踪报道::::广州地铁3333号线工地塌方险情受控. <http://news.gz.soufun.com/2004-04-04/259585.htm> (4 April 2004).
SP (2005). Sing Pao Newspaper. 6 Dec. 2005, Hong Kong.
ST (2005). Sing Tao Newspaper. 6 Dec. 2005, Hong Kong.
Sun (2005). Sun Newspaper. 6 Dec. 2005, Hong Kong.
TANEEB (2005). Hsuehshan Tunnel. Taiwan Area National Expressway Engineering Bureau (台灣國工局), Taiwan. <http://egip.taneeb.gov.tw> (31 Jan. 2007).
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
Taiwan Info (2004). Nouvel incident sur le chantier du métro de Kaohsiung. Taiwan. <http://taiwaninfo.nat.gov.tw/Societe/1092119498.html> (31 Jan. 2007).
TT (2005). Cave-in at KRTC site snarls up Kaohsiung traffic. Taipei Times. 5 Dec. 2005, Taiwan.
TKP (2005). Ta Kung Pao Newspaper. 7 Dec. 2005, Hong Kong.
TVB News (2005). TVB News. 4 Dec. 2005, Taiwan.
Tunnels & Tunnelling (2005). Lausanne Metro Tunnel collapse. Tunnels & Tunnelling International, April Issue, p 6.
WWP (2005). Wen Wei Po Newspaper. 6 Dec. 2005, Hong Kong.
XINHUANET. <http://www.xinhuanet.com/>
References
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
General References
Brand, E.W. (1996c). Bibliography on Settlements Caused by Tunnelling to March 1996 (GEO Report No. 51). Geotechnical Engineering Office, Hong Kong, 70 p.
Health and Safety Executive (HSE) 1996. Safety of New Austrian Tunnelling Method (NATM) Tunnels, A review of sprayed concrete tunnels with particular reference to London Clay, (HSE) Books, Sudbury, 80 p.
Jacobs J. D. (1975). Some tunnel failures and what they have taught. Hazards in Tunnelling and on Falsework, Institution of Civil Engineers, London, pp 37-46.
Moh, Z.C. & Hwang, R.N. (2007). Lessons learned from recent MRT construction failures in Asia Pacific. Journal of the Southeast Asian Geotechnical Society, December 2009, pp 121-137.
cases already included in the catalogue?
Civil Engineering and Development Department
Hong Kong Special Administration Region Government
General References
Seidenfub, T. (2006). Masters Degree in Foundation Engineering and Tunnelling: Collapse in Tunnelling. Stuttgart University of Applied Sciences, Germany, 194 p. (Note: 109 numbers of failures of all types of tunnels). <http://www.ita-aites.org/cms/fileadmin/filemounts/general/pdf/ItaAssociation/ProductAndPublication/Thesis/ThesisSeidenfuss.pdf>some the failure cases already included in the catalogue?
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