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Transcript
TUNNELS
TERMINOLOGY for UNDERGROUND
STRUCTURES
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Adit.....................................galeri
Tunnel................................tünel
Subway..............................metro
Shaft...................................baca
Chamber............................oda
Portal.................................ana giriş veya çıkış
Pilot adit.............................yan galeri, pilot galerisi
Centre................................merkez, eksen
Face...................................ayna
Wall ~ site..........................yan, kenar, duvar
Floor...................................taban
Roof...................................tavan
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Overbreak.............................aşırı sökülme
Excavated profile..................kazı profili
Natural archling....................doğal kemerlenme
Load......................................yük
Support.................................destek, iksa
Failure...................................yenilme, çökme
Gentle failure........................yavaş yenilme
Rock burst............................kaya patlaması
Squeezing ground................sıkışan zemin
Swelling ground....................şişen zemin
Clay-filled joint.......................kil dolgulu eklem
Long term stability.................uzun süreli duraylılık
Ground treatment..................zemin iyileştirmesi
Support before excavation....kazı öncesi destekleme
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Jet grouted roof cover..............jet grouting ile iyileştirilmiş
tavan örtüsü
Shotcrete initial lining..............püskürtme beton
başlangıç çizgisi
Jet grouted floor cover............jet grouting ile iyileştirilmiş
döşeme
Top heading............................kalot (Crown)
Invert.......................................stros (Bottom excavation)
Bench......................................üzengi çizgisi
Final concrete lining................sonuncu beton kaplama
(nihai beton kaplama çizgisi)
SHIELD tunnelling method..............KALKAN Yöntemi
CUT & COVER tunnelling method....AÇ-KAPA Yöntemi
TBM (Full face ~ Total Boring Machine).....TÜM KESİT
KAZI MAKİNASI
TERMINOLOGY for EXCAVATIONS of
ROCKS & SOILS
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DRILLING....................Sondalama
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AUGERING..................Burgulama
MACHINE BORING.....Mekanize tünel açma
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Hardness.........................Sertlik
Toughness.......................Dayanım – direnç
Abrasiveness...................Aşındırıcılık
Structure..........................Jeolojik yapı
Drilkling fluids..................Sondaj sıvısı
Total Boring Machine (TBM)
Full face excavation
BLASTING...................Patlatma
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SCRAPING...................Kazıma (makinayla)
RIPPING.......................Kırarak kazıma
DIGGING......................Kazma
GROUND WATER........yeraltısuyu
Control of groundwater
 Groundwater flow
 Rate of flow
 Volume of flow
 Boundaries
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TUNNEL DESCRIPTION
1.
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Made into natural material (rocks)
Empty inside
Carry the loads itself
Both ends are open to atmosphere
Generally horizontal
Thick walled structure looks like cylinder
1- Kilit (anahtar) taşı........................Key stone
2- Kemer...........................................Arch
3- Ayak (duvar)................................Wall
4- Taban...........................................Floor
5- Üzengi..........................................Bench
6- Üzengi çizgisi (düzeyi)...............Bench line or plane
7- Kalot............................................Top heading
8- Stros............................................Invert
9- Ano..............................................Ano (unit)
Tunnel Section for Swelling Ground
1- Digging section
2- Support
3- Swelling section
4- Pressurized area
5- Flow direction of water
SURFACE EXCAVATIONS
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Deformation & failure
UNDERGROUND EXCAVATIONS
In Rock
 In Sediment
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Stability & Arching
 Water
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Dry tunnel...............above water table
 Wet tunnel..............below water table
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Gases
Carbon dioxide (CO2)
 Carbon monoxide (CO)
 Methane (CH4)
 Hydrogen sulphide (H2S)
 Other gases
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Gas bursts......................gaz patlaması
 Rock falls........................kaya düşmesi
 Rock bursts....................kaya fırlaması
 Squeezing ground..........şişen – kabaran zemin
 Temperature
 Subsidence
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EXPLORATION & INVESTIGATIONS
RELATED of SLOPE STABILITY
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Geomorphologic maping and preparation of
longitudinal & cross sections
Geological maping & surveyings (aerial
photographs)
Geophysical surveyings
Underground explorations, boreholes
Ground water surveyings
Laboratory tests
Model studies
SURFACE EXCAVATIONS
Permanent
 Short term excavations
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SUBSURFACE EXCAVATIONS
1.
GEOLOGY
Soil profile or hard rock geology
2. Structure
3. Ground water (hydrogeology)
4. Stability
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2.
INVESTIGATIONS
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Mapping (Topographic, geologic, etc...)
Geophysical surveying (especially seismic
velocity of rocks)
Trial pits & boreholes
General and local stability analysis
Decide to excavation method
UNDERGROUND EXCAVATIONS
Adit, shaft, incline, large chamber
 Tunnel
 Subway ~ metro
 Underpass
 Shelter
 Power house
 Ware house, store, mining ...etc
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GASES
(can be lethal or burst)
Carbon monoxide (CO) 0.97 of air
 Carbon dioxide (CO2)
1.53 of air
 Methane (CH4)
0.55 of air
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(Highly explosive with air) marsh gas
Hydrogene sulphide (H2S) 1.19 of air
(Highly toxic and explosive)
 Sulphur dioxide (SO2)
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ROCK FALL
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SQUEEZING GROUND (sand, silt, shale, clay)
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ROCK BURST
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BULKING (Increase in volume, 10-40%)
FACTORS EFFECTING
EXCAVATION of ROCKS
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Mineralogical composition of rocks
Texture & fabric
Petrographic features
Structure
Rock mass
Strike & dip of beds in relation to face of
excavation
Intensity of tectonic disturbances
Degreee of weathering
RESISTANCE of ROCKS to
EXCAVATION
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Loose soils
Soil easy to spade (bel ile kazmak)
Soil easy to dig
Crumbling weak rocks (ufalamak)
Rocks easy to blast
Rocks difficult to blast
Rocks very difficult to blast
TUNNELLING METHODS
SHIELD TUNNELLING METHOD
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This method involves the use of shield machine to drive
the tunnels below the ground.
After completion of a work shaft, the shield machine is
lowered into the shaft and assembled there before
excavation and construction of the tunnels using precast
concrete lining segments of about 1.2 meter width.
This construction method causes minimal disruption to
traffic and the environment because all the work takes
place below ground and the ground level environment is
unaffected.
CUT and COVER TUNNELLING
METHOD
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This construction method, whereby the site is fully
excavated, the structure built and then covered over,
uses diaphragm walls as temporary retaining walls within
the site area.
Step one :Construction of diaphragm walls, pin piles, and
decking.
Step two :Excavation within the diaphragm walls,
installing struts as work progresses.
Step three :Construction of permanent floor slabs and
walls.
Step four : Fitting out the internal structures, backfilling,
and reinstating the surface structures.
TBM (Tunnel Boring Machine)
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5.
Mechanical-support TBM
Compressed-air TBM
Slurry shield TBM
Earth pressure balance machine
Mixed-face shield TBM
1- Mechanical Support TBM
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A mechanical-support TBM has a full-face
cutterhead which provides face support by
constantly pushing the excavated material
ahead of the cutterhead against the
surrounding ground.
2- Compressed-Air TBM
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A compressed-air TBM can have either a
full-face cutterhead or excavating arms.
Confinement is achieved by pressurizing
the air in the cutter chamber.
3- Slurry Shield TBM
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A slurry shield TBM has a full-face
cutterhead. Confinement is achieved by
pressurizing boring fluid inside the
cutterhead chamber.
4- Earth Pressure Balance Machine
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An earth pressure balance machine has a
full-face cutterhead. Confinement is
achieved by pressurizing the excavated
material in the cutterhead chamber.
5- Mix-Face Shield TBM
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Mix-face shield TBMs have full-face
cutterheads and can work inclosed or
open mode and with different confinement
techniques.
EFFECT of GEOLOGICAL STRUCTURES
to TUNNEL EXCAVATION
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Effect of soil layers: horizontal, vertical and
inclined layers have different kinds of loading
conditions for tunnels.
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Effect of faults: the relation between the fault
slope direction and the tunnel direction, width
of the fault zone, type and thickness of the fill
material and the hydrostatic pressures in both
sides of the fault are some problems in the
tunnelling.
Relation between the fault zone and the tunnel
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Tunnel excavations in the slopes: the
discontinuities (layers, fissures) inclined inside
or outside of the slope are very important
regarding the stress and strength of the tunnel.
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Effect of the folds: While tunnel is excavated in
an area that contains folded rocks, different
stresses and conditions may occur depending on
the fold type.
Fold axis and the tunnel direction is parallel
Fold axis and the tunnel direction is vertical
CLASSIFICATION of
ROCKS for TUNNELING
PURPOSES
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Classification of rocks for engineering purposes
is needed in analyzing the project costs and to
obtain an economic and reliable solution.
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The classification of the rocks, that the tunnel
will be constructed in, is first done by Terzaghi.
But, it is too general and gives qualitative
results.
TUNNEL ROCK CLASSIFICATION by TERZAGHI
Laufer classified tunnel rocks to 7 groups according to stand-up time
Rock classification and determination of unsupported span
URFA IRRIGATION
TUNNEL
ONE of the LONGEST IRRIGATION TUNNELS in
the WORLD
Consist of two concrete lined tunnels
each of which is 7.62 m in diameter and
26.4 km in length discharging water
from the reservoir of Atatürk Dam.