Presentation for lecture on underwater concrete - TU Delft: MSc Geotechnical Engineering
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Transcript of Presentation for lecture on underwater concrete - TU Delft: MSc Geotechnical Engineering
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Lecture CiTG
Underwater concrete floors
ir. Ruud Arkesteijn
29th of September 2015
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Content
1st hour:• Use and functions of UCF’s• Distribution of forces2nd hour:
• Design-rules (CUR77)• Case: guidelines for preliminary designExtra:
• Steel fibre reinforced UCF’s• Projects• Innovations
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Use of UCF’s
Conditions for application in building pits:1. sub-surface construction in ‘soft soils’…2. below the groundwater level…3. especially in permeable soils.
Typical Delta/Dutch conditions!
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Bouwput en fasering
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Bouwput en fasering
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Functions of UCF’s
1. Water retaining layer2. Horizontal force equilibrium (strut)3. Vertical force equilibrium (up burst / heave)
Often a combination of the above!
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Bouwput en fasering
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Distribution of forces
4 mechanisms:• Boundary-disturbance à “Randstoringseffect”
• Arching à “Boogwerking”
• Membrane-effect à “Membraanwerking”
• Re-distribution of forces à “Krachtenherverdeling”
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Boundary-disturbance à “Randstoringseffect”
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Arching à “Boogwerking”
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Membrane-effect à “Membraanwerking”
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Arching & membrane-effect
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Re-distribution of forces à “Krachtenherverdeling”
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Ultimate limit states
1) Bending moments (tension)2) Bending moments in arch (compression)3) Shear failure (near retaining wall)4) Failure or slipping at retaining wall5) Pull-out of retaining wall (geotechnical failure)6) Failure of connection with tension piles (punching shear)7) Pull-out of tension piles (structural or geotechnical failure)
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Design rules (CUR77)
CUR77 providesguidelines for designof unreinforced UCF’swith respect to:• Schematisation• Modelling• Dimensioning• Detailing
Revision in 2014!
Demand is to comply with Eurocodes (0, 2 & 7)!
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• Longitudinal (“lange richting”):à no boundary-disturbanceà no initial normal forcesà membrane-effect is big!
• Cross-sectional (“korte richting”):à boundary-disturbance is criticalà normal forces present (strut-function)à limited membrane-effect
Focus in CUR77 is on the cross-sectionaldirection. Longitudinal direction is notcritical under the assumption of:
Schematisation #1
“lange” richting
“korte” richting
onderwaterbetonvloer
damwand
palen
Ly
Lx
Ly≤ Lx
CUR77:2001+2014
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à hgem = average height (minimum 800mm?)
à tolerances on floor thicknessà calculate stresses with:
hmin = hgem - √(tolonder2+ tolboven
2)
Schematisation #2
Guidelines:tolonder à 250 mm for peat/clay
à 150 mm for sand/gravel
tolboven à 75 mm for hob-dobberà higher for slopes?
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Modellingà beam-model of cross-section
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Longitudinal:à
Serviceability Limit State (SLS)à dry building pità discrete cracking (minimal compression-zone)
2, ,
1 (without N')8 s rep y r repq L M£× ×
Cross-sectional:à uncracked
or with arching
or with arching + re-dristribution of forces
, ,mod , (with N')s rep el r repM M£
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Ultimate Limit State (ULS)à structural safetyà incl. material and load factors
Longitudinal:à no check because of membrane-effect!
Cross sectional:à uncracked
or with arching and infinite re-distribution of forces (local):
, ,mod , (with N' )s d el r d dM M£
2, ,
18s d s d xM q L= × ×
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New in revised CUR77 (v2014):1. Revised according to Eurocode 2 (NEN-EN1992)2. No design rules for SLS in cross sectional direction3. Optimization of arch-height (z) in ULS4. Check on shear forces near retaining wall5. Safety check considering slipping of UCF at retaining wall6. Adjustments for disc-shape-connections (micro piles):
- extra safety factor kr for punching shear- increased capacity of concrete compression strength under discs
7. Calculation of axial stiffness piles based on secant-valueà according to CUR236:Anchor-piles
8. Calculation method for optimization with membrane force9. Guidelines for use of 2D calculation models
Latest developments have been publishedin Cement 2013/3 and Cement 2015/5
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Not in CUR77…
Hydration of concrete produces heat à temp. in UCF to 30-45oCCooling after heating à shrinkageStrength of concrete at 50% à sensitive for cracking
Thermal shrinkage of concrete:
à In relatively big building pits the risk of water-conductingcracks to occur is high even before pumping out the water !
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Verificatie en toepasbaarheid
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Case
à Use CUR77:2001 (on Blackboard)à Consider an unreinforced UCF (no addition of steel fibres)
Make a preliminary design for a deep building pit:à Modelling a beam-model is not necessaryà Do not check SLS in cross-sectional direction!à Only check:
SLS longitudinal directionULS punching shearULS equilibrium in arch
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Case: guidelines for preliminary design of UCF
1. Choose concrete strength class B25 (nowadays C20/25):à tensional strength fb = 1,15 N/mm2
à compression strength f’b = 18,0 N/mm2
2. Determine Ly using SLS check in longitudinal direction (CUR77).Choose Lx ≤ Ly(for edge piles distance to retaining wall Lx,edge < Lx )
LxLx,edge
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Case: guidelines for preliminary design of UCF
3. Determine effective load on piles based on:Lx * Ly * Pwater pressure–weight of UCF (incl. load factors)
4. Check punching shear (CUR77).Adjust hgem or Lx if needed/possible.
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Case: guidelines for preliminary design of UCF
5. Determine normal forces in UCF (with D-Sheet Piling):
à suggested modelling:
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Case: guidelines for preliminary design of UCF
6. Check safety in arching-mechanism (ULS cross-sectional direction)
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Steel fibre reinforced UCF
First use:Potsdammer Platz Berlijn(1997)
In the Netherlands:• Heinoseweg Zwolle
(1998)• Betuweroute
(1999-2002)• multiple others…
2014:• Mauritshuis (The Hague)• Groninger Forum
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“After-crack-behaviour”
à Tensional strength ≈à Early tensional strengthà Tensional strength after crackà Re-distribution of forcesà Moment capacity
Effect on force distribution
tension:
bending:
à limits shrinkage-cracks-widths
à limited crack-depth
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Moment capacity for UCF with steelfibresà example for UCF with hmin = 700 mm and N’ = 200 kN/m’à 30 kg/m3 of steelfibres
0
100
200
300
400
0,0 2,0 4,0 6,0 8,0 10,0
mom
entc
apac
iteit
MRd
[kN
m/m
']
kromming κ [mrad] *10-6
M-N-κ diagramSVB (UGT)C25/30 (UGT)fctd,pl
εUGT = 0,1%:MRd = 380 [kNm/m']Egescheurd = 4.664 [MPa]
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Projects
Groninger Forum
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Projects
Groninger Forum
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Link to video (dutch) of the process ofpooring the UCF with steel fibres for
project Groninger Forum:https://vimeo.com/89189883
Lecture CiTG
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Projects
Mauritshuis (The Hague)
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Mauritshuis (The Hague)
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Mauritshuis
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Link to video (dutch) with animationsmade by diving company C.O.W.:https://vimeo.com/24826624
Lecture CiTG
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Innovations…“Traditional building method”:
- Unreinforced UCF withtemporary function
- Reinforced concrete floorhas permanent function
“Integrated floor”:
- Steelfibre reinforced UCF- For the permament
function the UCF iscollaborating with a(traditional) reinforcedconcrete floor
“Permanent UCF”:
- Steelfibre reinforced UCFhas a temporary and apermament function
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Lecture CiTG 29th of September 2015