seismic design of new r.c. structures design ec8... · 2015-03-18 · criteria for regularity in...
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Seismic Design of New R.C. Structures
Pisa, March 2015
Prof. Stephanos E. Dritsos
University of Patras, Greece.
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Seismic Design Philosophy
Main Concepts
Energy dissipation
Ductility
Capacity design
Learning from Earthquakes
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Energy Dissipation
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Ductility and Ductility Factors• Ductility is the ability of the system to undergo plastic deformation. The
structural system deforms before collapse without a substantial loss ofstrength but with a significant energy dissipation.
• The system can be designed with smaller restoring forces, exploitingits ability to undergo plastic deformation.
• Ductility factor (δu/δy): Ratio of theultimate deformation at failure δu to theyield deformation δy.
* δu is defined for design purposes as thedeformation for which the material orthe structural element loses apredefined percentage of its maximumstrength.
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Ductility Factorsu
yδ
δµδ
=• In terms of displacements:
• In terms of rotations:(for members)
• In terms of curvatures:(for members)
u
yθ
θµθ
=
u
yϕ
ϕµϕ
=
δu: ultimate deformation at failure δy: yield deformation
θu: ultimate rotation at failure θy: yield rotation
φu: ultimate curvature at failure φy: yield curvature
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The q factor corresponds to the reduction in the level of seismic forces due to nonlinear behaviour as compared with the expected elastic force levels.
Behaviour q Factor
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.= el
inel
VDefinition qV
Ductility and Behaviour Factor q
7δy2 δu2δ
Flexible Structures T ≥ Tc : Rule of equal dispacement
21max
2max 2
= = =u
y
VqV δ
δµ
δ
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1/ 21max
2max
(2 1)= = = −el
inel
V VqV V δµ
Ductility and Behaviour Factor q
Rule of equal dissipating energyδy δu2
Stiff Structures T≤Tc
1
μδ
Τc
q
1 ( 1)= + −c
TqTδµ (Eurocode 8)
for T=0 q=1for T=Tc q=μδ
Τδ
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Design spectrum for linear analysis
• The capacity of structural systems to resist seismic actionsin the non-linear range permits their design for resistanceto seismic forces smaller than those corresponding to alinear elastic response.
• The energy dissipation capacity of the structure is takeninto account mainly through the ductile behavior of itselements by performing a linear analysis based on a reducedresponse spectrum, called design spectrum. This reduction isaccomplished by introducing the behavior factor q.
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Design spectrum for linear analysis (Eurocode 8)• For the horizontal components of the seismic action the design spectrum, Sd(T),
shall be defined by the following expressions:
ag is the design ground acceleration on type A ground (ag = γI.agR); γI=importance factorTB is the lower limit of the period of the constant spectral acceleration branch;TC is the upper limit of the period of the constant spectral acceleration branch;TD is the value defining the beginning of the constant displacement response rangeof the spectrum;S is the soil factorSd(T) is the design spectrum;q is the behaviour factor;β is the lower bound factor for the horizontal design spectrum, recommended β=0,2
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Importance Classes (Eurocode 8)
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Behaviour Factor (Eurocode 8)• The upper limit value of the behavior factor q, introduced to account
for energy dissipation capacity, shall be derived for each designdirection as follows: q = qo∙kw ≥ 1,5
Where qo is the basic value of the behavior factor, dependent on the typeof the structural system and on its regularity in elevation;
kw is the factor reflecting the prevailing failure mode in structural systemswith walls:
• Low Ductility Class (DCL): Seismic design for low ductility , followingEC2 without any additional requirements other than those of § 5.3.2, isrecomended only for low seismicity cases (see §3.2.1(4)).
(1 ) / 3 1 0,5= + ≤ ≥u ok a and Pr /= =Σ Σo wi wia evailing wall aspect ratio h
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Behaviour Factor (Eurocode 8)A behaviour factor q of up to 1,5 may be used in deriving the seismic actions, regardless of the structural system and the regularity in elevation.
For buildings which are not regular in elevation, the value of qo should bereduced by 20%
• Medium (DCM) and High Ductility Class (DCH):
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au/a1 in behaviour factor of buildings designed for ductility:due to system redundancy & overstrenght
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Structural Regularity (Eurocode 8)
• For seismic design, building structures in all modern codes areseparated in two categories: a) regular buildings
b) non-regular buildings• This distinction has implications for the following aspects of the seismic
design:− the structural model, which can be either a simplified planar model or
a spatial model ;− the method of analysis, which can be either a simplified response
spectrum analysis (lateral force procedure) or a modal one;− the value of the behavior factor q, which shall be decreased for
buildings non-regular in elevation
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Structural Regularity (Eurocode 8)
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Criteria for Regularity in Elevation (Eurocode 8)
• All lateral load resisting systems, such as cores, structural walls, or
frames, shall run without interruption from their foundations to the top
of the building or, if setbacks at different heights are present, to the
top of the relevant zone of the building.
• Both the lateral stiffness and the mass of the individual storeys shall
remain constant or reduce gradually, without abrupt changes, from the
base to the top of a particular building.
• When setbacks are present, special additional provisions apply.
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STRUCTURE OF EN1998-1:2004
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How q is achieved?
• Specific requirements in detailing (e.g. confining actions bywell anchored stirrups)
• Avoid brittle failures• Avoid soft storey mechanism• Avoid short columns• Provide seismic joints to protect from earthquake induced
pounding from adjacent structures• …..
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Material limitations for primary seismic elements“
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Avoid weak column/strong beam framesCapacity Design
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Provide strong column/weak beam frames or wall equivalent dual frames, with beam sway mechanisms, trying to involve plastic hinging at all beam ends
Capacity Design
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Capacity Design (Eurocode 8)
column 1
column 2
beam 1 beam 2
Exceptions: see EC8 §5.2.3.3 (2)
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Shear Capacity Design (Eurocode 8)
Avoid Brittle failureM2
1
∆Μ=∆
Vx
2 1
12
−Μ=
MVColumn moment distribution
or
M1 2
+
-
1
2
M1,d+
-M2,d
1, 2,max,c 12
12
,+ −+Μ
= =
d dclear
MV
-
+
1
2
M1,d-
M2,d+
2, 1,max,c
12
+ −+Μ= −
d dMV
+E -E
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Shear Capacity Design of Columns (Eurocode 8)
M1,d+
γRd·MRc,1+ , when ΣΜRb > ΣΜRc , weak columns
γRd·MRc,1+ ·(ΣΜRd,b\ΣΜRd,c) , when ΣΜRb < ΣΜRc , weak beams:
(moment developed in the column when beams fail)
M1,d-
γRd·MRc,1- , when ΣΜRb < ΣΜRc
γRd·MRc,1- ·(ΣΜRd,b\ΣΜRd,c)
• In DC H γRd=1.3• In DC M γRd=1.1
Also similarly for M2,d+, M2,d
-
ΣΜRb , ΣΜRc for the corresponding direction of seismic action (+E or -E)
Similarly
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Shear Capacity Design of Beams (Eurocode 8)
or
2, 1,M max,b
12
+ −+Μ=
d dMV
+E
M21
M1 2
VMDetermination of VM
• In DC H γRd=1.2 • In DC M γRd=1.0
Vg+ψq
=1 2
VCD
+M2
1M1 2
-
-
+
1 2
M1,d M2,d+
+ [V]
[M]
1, 2,M max,b
12
+ −+Μ= −
d dMV
-E
[M]
+
-
1 2
M1,d+ -M2,d
- [V]
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Shear Capacity Design of Beams (Eurocode 8)
M1,d+
γRd·MRb,1+ , when ΣΜRb < ΣΜRc , weak beams
γRd·MRb,1+ ·(ΣΜRd,c\ ΣΜRd,b) , when ΣΜRb > ΣΜRc , weak columns:
(moment developed in the column when beams fail)
M1,d-
γRd·MRb,1- , when ΣΜRb < ΣΜRc
γRd·MRb,1- ·(ΣΜRd,c\ ΣΜRd,b)
• In DC H γRd=1.3• In DC M γRd=1.1
Also similarly for M2,d+, M2,d
-
ΣΜRb , ΣΜRc for the corresponding direction of seismic action (+E or -E)
Similarly
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Local Ductility Conditions
Relation between q and μδ1 ,= ≥ cq if T Tδµ 1 11 ( 1) / ;= + − <c cq T T if T Tδµ
Relation between μδ and μφ1 3( 1) / (1 0.5 / );= + − −pl s pl sL L L Lδ φµ µ where Lpl:plastic hinge length, Ls: shear span
Relation of Lpl & Ls for typical RC beams, columns & walls*( : 0.0035 0.1 )= +cu wconsidering aε ω
0.3 2 : 0.15 : 2 1≈ ≈ ≈ −pl s pl sL L and for safety factor L L Then φ δµ µFor T1≥Tc 2 1 2 1= − = −qφ δµ µ
For T1≤Tc1 1
2 1 2[1 ( 1) ] 1 1 2( 1)= − = + − − = + −c cT Tq qT Tφ δµ µ
In EC8 qo is used instead of q concervatively to include irregular buildings (q<qo)Therefore:
12 1= − ≥o cq if T Tφµ
11
1 2( 1)= + − <co c
Tq if T TTφµ
Note: For Steel class B μφ demand increases by 50%
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Ductility Estimation for Beams
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Ductility Estimation for Beams
Ductility increases when:
cuε cf confinement
2ρ 1ρ Compressive reinforcement neccessaryWhile for tension reinforcement: the less the best
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Ductility Estimation for Columns
2 1+ − =c s cF F F N
/= cv N bdf
1 2
0.61.2 [ 1]( )( / )
= = −+ −
u scu
y y y c
Ef v k f fφ
φµ εφ ρ ρ
Ductility is reduced when axial load increases
0.65 0.55> >d dv for DCM and v for DCHEC8 limits:
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περισφιγμένο με FRP
περισφιγμένο με χαλύβδινα στοιχεία
fc*
fc0,85fc
εc u*0 ε co ε co
*εc u
σ c
ε
Confined Concrete Model
According to EC2* * 2= =c c co cof fβ ε β ε
0.86
1 3,7
≈ + c
pf
β
min 1 5 , 1.125 2.5
≈ + + c c
p pf f
β
* 0.0035 0.2= +cuc
pf
ε
When hoops are used 0.5≈ wc
p af
ω
Thereforemin (1 2.5 , 1.125 1.25 )= + +w wa aβ ω ω
* 0.0035 0.1= +cu waε ω
ωw= Mechanical volumertic ratio of hoops
α=Confinement effectiveness factor, = s na a a
Adopting
(Newman K. & Newnan J.B. 1971)
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EN 1998-1:2004 (Ε) § 5.4.3.1.2Detailing of primary beams for local ductility
For Tension Reinforcement
For Comression Reinforcement
2 2 0.5= +reqρ ρ ρ
More detailing rules for DCH
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= cr wfor DCM h1.5= cr wfor DCH h
Within ℓcr transverse reinforcement in critical regions of beams:6≥bwd mm
≤s
/ 4wh24 bwd8 bLd225mm
Detailing of primary beams for local ductility
( ) 6 ( )bLDCM or d DCH( ) 175 ( )DCM or mm DCH
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Detailing of primary seismic columns for local ductility EN 1998-1:2004 (Ε) § 5.4.3.2.2
/ 3.0< → = cr c cr clFor h
Everywhere
≥bwd6mm
,max14 bLd
more restrictions for DCHcritical regions
In critical regionsfor DCM
≤s/ 2ob
,min8 bLd175mm
for DCH
≤s ,min6 bLd
125mm
/ 3ob
s
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Detailing of primary seismic columns for local ductility EN 1998-1:2004 (Ε) § 5.4.3.2.2
Normilised Axial Load0.65≤dv for DCM0.55≤dv for DCH
2( )2
= − + wo c
db b c200≤ib mm for DCM150≤ib mm for DCH
At least 3 bars in every slide
min 1%=totρmax 4%=totρ
= stottot
Abu
ρ
c d
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Detailing of primary seismic columns for local ductility for DCM & DCH incritical region at column base EN 1998-1:2004 (Ε) § 5.4.3.2.2
0.08≥w for DCMω 0.12≥w for DCHω
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Beam-Column Joints
DCM- Horizontal hoops as in critical region of columns
- At least one intermediate column bar at each joint slide
DCHSpecific rules in § 5.5.33
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Types of Dissipative Walls
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Ductile Walls
hw
hcr
ℓw
max=crhw
/ 6wh
≤crh2w
6≤sh for n storeys2 7≥sh for n storeys
=sh clear storey height
/′ =o o Ed Rdafter q q M Mφµ/Ed RdM M at the base
Normilised axial load 0.40 0.35> >d dfor DCM v and for DCH v
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No strong column/weak beam capacity design required in wall or wall-equivallent dual systems (<50% of seismic base shear in walls)
For ShearDesign in shear for V from analysis, times:
1.5 for DCM
,For DCH
=Ed EdV Vε 0.5≥ε
.
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Design and Detailing of Ductile Walls
, /=v v yd v cdwhere f fω ρ
Confined boundary element of free-edge wall end: Longitudinal reinforcement 0.5%≥totρ
Same restrictions as in columns e.g. 0.08 ( )≥wd DCMω 0.12 ( )≥wd DCHω
max ,S etc
strain distribution *= cuε
(0.15 , 1.5 )≥ c w calso b
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Detailing of Ductile WallsEN 1998-1:2004 (Ε) § 5.4.3.4.2
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EN 1998-1:2004 (Ε) § 5.4.3.4.2
Detailing of Ductile Walls
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Large Lightly Reinforced Walls
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Design and Detailing of Large Lightly Reinforced Walls
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Foundation Problem Large lw
Usual way of footing with tie-beams is insufficient
Impossible to form plastic hinge at the wall base. Wall will uplift & rock as a rigid body
Large moment at the base and very low normalized axial force
Design and Detailing of Large Lightly Reinforced Walls
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Large Lightly Reinforced Walls Boundary elements
c max≥ wb
3 w cm cdb / fσcmσ = mean value of concrete
compressive stress
Longitudinal Reinforcement of Boundary Elements
(a) Diameter of vertical bars (EC8- §5.4.3.5.3 (2))
lower storeys when
higher storeys:
12bLd mm≥10bLd mm≥
(b) Stirrups (EC8- §5.4.3.5.3 (1))In all storeys-closed stirrups
6 3bL
bwdd max( mm, )≥
100 8w bLs min( mm, d )≤No other particular regulations for LLRCW
3w storey /h :∆ ≤
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Secondary Seismic Members
A limited number of structural members may be designated as secondary seismic members. The strength and stiffness of these elements against seismic actions shall be neglected.
The total contribution to lateral stiffness of all secondary seismic members should not exceed 15% of that of all primary seismic members.
Such elements shall be designed and detailed to maintain their capacity to support the gravity loads present in the seismic design situation, when subjected to the maximum deformations under the seismic design situation. Maximum deformations shall account for P-Δ.
In more detail § 4.2.2., 5.2.3.6, 5.7
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Specific Provisions in EC8 for:
LOCAL EFFECTS to masonry infills see § 5.9
CONCRETE DIAPHRAGMS see § 5.10
PRECAST CONCRETE STRUCTURES see § 5.11
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Thank you for your attention
http://www.episkeves.civil.upatras.gr
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APPENDIX: Detailing & Dimensioning of seismic elements (Synopsis by M. Fardis)
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APPENDIX: Detailing & Dimensioning of seismic elements (Synopsis by M. Fardis)
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APPENDIX: Detailing & Dimensioning of seismic elements (Synopsis by M. Fardis)
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APPENDIX: Detailing & Dimensioning of seismic elements (Synopsis by M. Fardis)
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APPENDIX: Detailing & Dimensioning of seismic elements (Synopsis by M. Fardis)
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APPENDIX: Detailing & Dimensioning of seismic elements (Synopsis by M. Fardis)
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APPENDIX: Detailing & Dimensioning of seismic elements (Synopsis by M. Fardis)