masonry code of practice amp
TRANSCRIPT
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Dr. A. Meher PrasadDr. A. Meher Prasad
Department of Civil EngineeringDepartment of Civil EngineeringIndian Institute of Technology MadrasIndian Institute of Technology Madras
email: [email protected]
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ACI 530-02 / ASCE 5-02 / TMS 402-02
Minimum requirements for structural design and Construction of masonry unit.
Allowable Stress Design (ASD)
Limit State Design (LSD)
IBC 2000
NZS 4230: Part 1: 1990
Eurocode 6: Design of Masonry Structures
IS: 1905 - 1987
Masonry Codes of PracticeMasonry Codes of Practice
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Design PhilosophiesDesign Philosophies
Working Stress Method (WSM)Working Stress Method (WSM)
Ultimate Load Method (ULM)Ultimate Load Method (ULM)
Limit States Method (LSM)Limit States Method (LSM)
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“Limit states design” is supposed to be the most rational design
philosophy. Why?
Design PhilosophiesDesign Philosophies……
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Design PhilosophiesDesign Philosophies• Working stress method (WSM)
- Behaviour under ‘service loads’ - All uncertainties accommodated in ‘factors of safety’ applied to material strengths
• Ultimate load method (ULM)
- Behaviour under ‘ultimate loads’ - All uncertainties accommodated in ‘load factors’
WSM attempts to ensure adequate safety under service loads, while ULM attempts to ensure adequate safety under extreme loads.
WSM does not investigate behaviour beyond service loads, ULM does not guarantee serviceability under service loads.
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WSM and ULMWSM and ULM
WSM attempts to ensure adequate safety under service loads, while ULM attempts to ensure adequate safety under extreme loads.
WSM does not investigate behaviour beyond service loads, ULM does not guarantee serviceability under service loads.
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A limit state is a state of impending failure, beyond which a structure ceases to perform its intended function satisfactorily, in terms of either strength or serviceability; i.e., it either collapses or becomes unserviceable.
Unlike WSM, which bases calculations on service load conditions alone, and unlike ULM, which bases calculations on ultimate load conditions alone, LSM aims for a comprehensive and rational solution to the design problem, by considering safety at ultimate loads and serviceability at working loads.
LSM is described as a ‘semi-probabilistic’ method or a ‘Level I reliability’ method
Limit States Method (LSM)Limit States Method (LSM)
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Strength Design ModelStrength Design Model
Sn Rn
LOAD EFFECT S
RESISTANCE R
Load and Resistance variables 0
R and S are independent random variablesR S Structure will survive!
R < S Structure will fail!
Probabilistic approach:
nominal / characteristic values (deterministic)
Moral:
There is always a risk of failure. No structure is 100% safe!
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Fs = Rn / Sn
Pf = Prob [R < S]
Reliability = Probability of survival
= 1 - Probability of failure
Sn Rn
LOAD EFFECT S
RESISTANCE R
Load and Resistance variables 0
Deterministic measure of safety:
Probabilistic measure of safety:
fS (s)
fR (r)
dsdrrfsfPS
RSf
00)()(
0 0)()(1 drdssfrfP
S
SRf
SSR 0= Prob
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Rk
Sk
Load and Resistance Design (LRFD) Format
Design Resistance Design Load Effect
Sn Rn
LOAD EFFECT S
RESISTANCE R
Load and Resistance variables 0
Sn = Rn
Load factor > 1
(‘overloading’)
Resistance factor < 1
(‘understrength’)
SR
nn
(WSM format)
R Sn n
(ULM format)
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Partial load and material safety factorsPartial load and material safety factors
Ultimate limit states – partial load factors:UL = 1.5 (DL + LL)UL = 1.5 (DL + QL) or (0.9DL + 1.5 QL)UL = 1.2 (DL + LL + QL)
c
Note: It is not correct to apply 33.3% increase in allowable stress in WSM when only DL and QL are involved!
Ultimate limit states – material safety factors:Concrete: = 1.5 Steel: = 1.15
c
s
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Design PhilosophiesDesign Philosophies
Empirical Design
• Formulae for the design developed by experience
• Not a design analysis for sizing and proportioning masonry elements
• For simple structures still being continued in ACI 530 – 02 and to some extent in IBC 2000
• Imposes severe limitation on building height proportions
• IS 1905 – mixes empirical with allowable stress design
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Design Philosophies ...
Allowable Stress Design
• All uncertainties are accommodated in Factor of safety applied to material strength
• Under working loads, the stress developed in a member must be less than the permissible stress
• For URM, tensile stress in masonry is less than allowable limits and for RM, tensile stress neglected
• ACI follows this for URM and RM
• In IS code applies only to URM
• Does not find place in Eurocode, NZS 4230
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Design Philosophies . . .
Limit State Design
Adopted by ACI, IBC 2000 and New Zealand codes
Proportion masonry members such that
Design strength ≥ Required strength
where, Design strength = Nominal strength φ
φ is the strength reduction factor
Required strength is computed from design load combinations of building code
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Eurocode - 6
Limit state design for Collapse and Serviceability
Partial safety factors for loads and materials are specified
separately instead of strength reduction factor
Partial safety factor for loads depends on the load combinations
Partial safety factor for materials depends on the type of masonry unit and the failure mode
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Assumptions in LSD and LRFD
Strain continuity between reinforcement, grout and masonry
Max Compressive strain εmu ≈ 0.0035 for clay material
≈ 0.0025 for concrete (CMU)
≈ 0.008 confined masonry ( NZ)
Stress in steel, fs = Esε ≤ fy
= fy for ε ≥ εy ( = fy/ Es)
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Flexural strength is assessed by neglecting tensile strength of masonry
But deflections assessed by including tensile strength
Masonry stress uniform over hatched block
0.8 fm (ACI) 0.85fm (IBC)
Assumptions in LSD and LRFD
Equivalent rectangular masonry stress distribution Equivalent rectangular masonry stress distribution for confined masonry according to NZS
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ACI
(fa / Fa) 1
fa = Calculated compressive stress
Fa = Allowable compressive strength
= 0.25 fm R Capacity reduction factor for slenderness
Accounts for material uncertainties
Axial Compression - ASDAxial Compression - ASD
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R = 1 – (h/40t)2 for h/t ≤ 29
R = (20t/h)2 for h/t > 29
P ≤ ¼ Pe where
32
2
I 21m n
e
E eP
h t
Slenderness can affect capacity either as a result of inelastic buckling or because of additional bending moment
Axial Compression - ASDAxial Compression - ASD
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IS 1905 :1987: a stress reduction factor ks which depends on slenderness ratio and eccentricity of load (Table 9 of Code)
Slenderness effects on axial compression
Axial Compression - ASDAxial Compression - ASD
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Image is Image is not clearnot clear
The The previous previous fig is the fig is the same….same….
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Slenderness ratio for different EccentricitiesSlenderness ratio for different Eccentricities
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Reinforced MasonryReinforced Masonry
Axial Compression - ASDAxial Compression - ASD
ACI 530-02
IBC 2000, NZS:4230: Part 1, , Eurocode 6, IS: 1905-1987
No Provisions have been givenNo Provisions have been given
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Maximum h/t RatioMaximum h/t Ratio
There is no directly specified limit to the h/t ratio. It is There is no directly specified limit to the h/t ratio. It is indirectly specified through the check against Euler’s indirectly specified through the check against Euler’s buckling formulabuckling formula
ACI 530-02
IS: 1905-1987
Maximum h/t ratio depends on the storey height and Maximum h/t ratio depends on the storey height and type of mortar used.type of mortar used.
IBC 2000, NZS:4230: Part 1, , Eurocode 6
No Provisions have been givenNo Provisions have been given
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Flexural stress due to
eccentricity of axial loading
application of horizontal loads such as wind and earthquake loads
ACI: A member subjected to pure flexure only
Allowable bending compressive stress, Fb = 0.33 fm
Calculated fb Fb
Axial compression with flexure: ASD
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Interaction formula
1a b
a b
f f
F F Very conservative
Axial compression with flexure: ASD
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Axial compression with flexure: ASD
Significance of M/Vdv factor
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IS 1905:1987
Bending compressive and tensile stresses
Permissible value for bending compressive stress is increased by 25% and then reducing it for eccentric loading causing flexure.
Permissible loads for 3 eccentric values
(a) e < t/24
(b) t/24 < e < t/6
(c) e > t/6
Applied moment converted into equivalent eccentricity
Axial compression with flexure: ASD
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e < t/24
t/24 < e < t/6
e > t/6
Axial compression with flexure: ASD
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Axial compression with flexure
Flexure and Axial Wall Loading Interaction Diagram
Reinforced MasonryReinforced Masonry
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Design for Shear – ASDDesign for Shear – ASD
ACI 530-02
Shear stress shall not exceed either of Shear stress shall not exceed either of
0.125 , 0.83MPa or v+0.45N0.125 , 0.83MPa or v+0.45Nvv/A/Ann
IBC 2000, NZS:4230: Part 1, , Eurocode 6
No Provisions have been givenNo Provisions have been given
IS: 1905-1987
Permissible shear stress is given by:Permissible shear stress is given by:FFvv = 0.1 + /6 < 0.5MPa = 0.1 + /6 < 0.5MPa
Un Reinforced MasonryUn Reinforced Masonry
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If shear reinforcement is not providedIf shear reinforcement is not provided
ACI 530-02
For flexural members,For flexural members,
For shear walls,For shear walls,
a. M/Vda. M/Vdvv < 1, < 1,
FFvv = 0.028[4-M/Vd = 0.028[4-M/Vdvv] < (0.55-0.31M/Vd] < (0.55-0.31M/Vdvv)MPa)MPa
b. M/Vdb. M/Vdvv > 1, > 1,
FFvv =0.083 < 0.24MPa =0.083 < 0.24MPa
FFvv = 0.083 < 0.35MPa, = 0.083 < 0.35MPa,
IBC 2000, NZS:4230: Part 1, , Eurocode 6, IS: 1905-1987
No Provisions have been givenNo Provisions have been given
Design for Shear – ASDDesign for Shear – ASD
Reinforced MasonryReinforced Masonry
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ACI 530-02
For flexural members,For flexural members,
Fv = 0.25 < 1.03MPaFv = 0.25 < 1.03MPaFor shear walls,For shear walls,
a. M/Vda. M/Vdvv < 1, < 1,
Fv = 0.042[4-M/Vdv] < (0.82-0.031M/Vdv)MPaFv = 0.042[4-M/Vdv] < (0.82-0.031M/Vdv)MPa
b. M/Vdb. M/Vdvv > 1, > 1,
Fv = 0.125 < 0.52MPaFv = 0.125 < 0.52MPa
If shear reinforcement is providedIf shear reinforcement is provided
Design for Shear – ASDDesign for Shear – ASD
Reinforced MasonryReinforced Masonry
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IS: 1905-1987
Permissible shear stress is given by:Permissible shear stress is given by:Fv = 0.1 + /6 < 0.5MPaFv = 0.1 + /6 < 0.5MPa
IBC 2000, NZS:4230: Part 1, , Eurocode 6
No Provisions have been given ASD formatNo Provisions have been given ASD format
If shear reinforcement is providedIf shear reinforcement is provided
Design for Shear – ASDDesign for Shear – ASDReinforced MasonryReinforced Masonry
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IS 1905:1987: Shear
Masonry load bearing walls also act as shear walls to resist in plane lateral loads.
Shear failure in URM are: (3 modes)
Diagonal tension cracks from through mortar and masonry units
Design for Shear – ASDDesign for Shear – ASD
vF 0.125 mf
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Design for Shear – ASDDesign for Shear – ASD
Sliding occurs along a straight crack of horizontal bed joints
While specifying Mohr coulomb type failure criterion
Stepped cracks form, alternating from head joint to bed joint depends on bond pattern of masonry
tandc
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IS 1905:1987: takes care of sliding failure by specifying permissible shear stress URM
0.16d
vF
0.5MPa
d Average axial stress not more than 2.4 MPa
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Allowable shear for reinforced walls
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Capacity Design for strength of flanged wallCapacity Design for strength of flanged wall
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Effective Shear AreasEffective Shear Areas
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LSDLSD
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AXIAL COMPRESSION - LSDAXIAL COMPRESSION - LSD
Un Reinforced Masonry:Un Reinforced Masonry:
ACI 530-02
IS: 1905-1987, NZS:4230: Part 1
IBC 2000
Eurocode 6
Charactersistic Compressive strength of Masonry isCharactersistic Compressive strength of Masonry is
Maximum compressive strain is limited to 0.002Maximum compressive strain is limited to 0.002
No Provisions are givenNo Provisions are given
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Reinforced Masonry:Reinforced Masonry:
ACI 530-02
Eurocode 6, IS: 1905-1987
No Provisions are givenNo Provisions are given
AXIAL COMPRESSION - LSDAXIAL COMPRESSION - LSD
IBC 2000
NZS:4230: Part 1
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AXIAL COMPRESSION WITH FLEXURE - LSDAXIAL COMPRESSION WITH FLEXURE - LSD
Un Reinforced Masonry:Un Reinforced Masonry:
ACI 530-02, IBC 2000, NZS:4230: Part 1, IS 1905- 1987 ACI 530-02, IBC 2000, NZS:4230: Part 1, IS 1905- 1987
No Provisions are givenNo Provisions are given
Eurocode 6
1. Design Md equals1. Design Md equals
2. In case of vertical load,2. In case of vertical load, increases toincreases to
3. Lateral resistance3. Lateral resistance
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AXIAL COMPRESSION WITH FLEXURE - LSDAXIAL COMPRESSION WITH FLEXURE - LSD
Reinforced Masonry:Reinforced Masonry:
ACI 530-02
2. For walls with factored axial stress < 0.2f2. For walls with factored axial stress < 0.2fmm,,
1. For walls with factored axial stress < 0.05f1. For walls with factored axial stress < 0.05fmm,,
and SR > 30 shall be designed as above with walls having tand SR > 30 shall be designed as above with walls having tminmin=150mm.=150mm.
3. at extreme fiber is 0.0035 for clay masonry and 3. at extreme fiber is 0.0035 for clay masonry and
0.002 for concrete masonry.0.002 for concrete masonry.
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AXIAL COMPRESSION WITH FLEXURE - LSDAXIAL COMPRESSION WITH FLEXURE - LSD
Reinforced Masonry:Reinforced Masonry:
IBC 2000
1. For wall design against out-of-plane loads, all values are 1. For wall design against out-of-plane loads, all values are same as of the ACI code, exceptsame as of the ACI code, except
2. is the same as in the ACI code.2. is the same as in the ACI code.
NZS:4230: Part 1NZS:4230: Part 1
1. is 0.0025 for unconfined concrete masonry and1. is 0.0025 for unconfined concrete masonry and0.008 for confined concrete masonry0.008 for confined concrete masonry
Eurocode 6Eurocode 6
For singly reinforced rectangular c/s subjected toFor singly reinforced rectangular c/s subjected tobending onlybending only
IS 1905- 1987IS 1905- 1987
No provisionsNo provisions
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DESIGN FOR SHEAR - LSDDESIGN FOR SHEAR - LSD
Un Reinforced Masonry:Un Reinforced Masonry:
ACI 530-02ACI 530-02
Nominal shear strength can be obtained from code section 3.3.4Nominal shear strength can be obtained from code section 3.3.4
IBC 2000
Nominal shear strength can be obtained from code section 2108.10.4.1Nominal shear strength can be obtained from code section 2108.10.4.1
Eurocode 6Eurocode 6
1. F1. Fvv = 0.1 +0.4 = 0.1 +0.4
2. V2. Vnn = F = Fvvtltlcc/ /
IS: 1905-1987, NZS:4230: Part 1
No ProvisionsNo Provisions
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DESIGN FOR SHEAR - LSDDESIGN FOR SHEAR - LSDReinforced Masonry:Reinforced Masonry:
ACI 530-02
1. V1. Vnn = V = Vmm + V + Vss
2. When M/Vd2. When M/Vdvv < 0.25, < 0.25, VVnn < (0.083) 6A < (0.083) 6Ann
When M/VdWhen M/Vdvv > 1.00, > 1.00, VVnn < (0.083) 4A < (0.083) 4Ann
For M/VdFor M/Vdvv value between 0.25 and 1.00, V value between 0.25 and 1.00, Vnn may be interpolated may be interpolated
IBC 2000
1.1. Nominal shear strength is same as in the ACI code.Nominal shear strength is same as in the ACI code.
2. If shear wall failure mode is in flexure, M2. If shear wall failure mode is in flexure, Mnn shall be at least 1.5M shall be at least 1.5Mcrcr
for fully grouted wall or 3Mfor fully grouted wall or 3Mcrcr for partially grouted wall. for partially grouted wall.
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DESIGN FOR SHEAR - LSDDESIGN FOR SHEAR - LSDReinforced Masonry:Reinforced Masonry:
NZS:4230: Part 1
1. Shear strength is given in section 7.3.2.11. Shear strength is given in section 7.3.2.1
2. Minimum value of A2. Minimum value of Avv = 0.15 b = 0.15 bwws/fs/fyy
3. 3.
4. Required area of shear friction reinforcement is4. Required area of shear friction reinforcement is
Eurocode 6
1. Ignoring shear reinforcement:1. Ignoring shear reinforcement:
2. Taking shear reinforcement into account:2. Taking shear reinforcement into account:
IS: 1905-1987No ProvisionsNo Provisions