ARCHITECTURAL STRUCTURES FORM, B DESIGN ARCH...
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1 F2009abn twenty two concrete construction: flat spanning systems, columns & frames ARCHITECTURAL STRUCTURES: FORM, BEHAVIOR, AND DESIGN ARCH 331 DR. ANNE NICHOLS SUMMER 2014 Concrete Spans 1 Lecture 22 Architectural Structures ARCH 331 lecture http:// nisee.berkeley.edu/godden Concrete Spans 2 Lecture 25 Foundations Structures ARCH 331 F2008abn Reinforced Concrete Design • economical & common • resist lateral loads Concrete Spans 3 Lecture 25 Foundations Structures ARCH 331 F2008abn Reinforced Concrete Design • flat plate – 5”-10” thick – simple formwork – lower story heights • flat slab – same as plate – 2 ¼”–8” drop panels Concrete Spans 4 Lecture 25 Foundations Structures ARCH 331 F2008abn Reinforced Concrete Design • beam supported – slab depth ~ L/20 – 8”–60” deep • one-way joists – 3”–5” slab – 8”–20” stems – 5”-7” webs The Architect’s Studio Companion
Transcript of ARCHITECTURAL STRUCTURES FORM, B DESIGN ARCH...
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F2009abn
twenty two
concrete construction:
flat spanning systems, columns & frames
ARCHITECTURAL STRUCTURES:
FORM, BEHAVIOR, AND DESIGN ARCH 331
DR. ANNE NICHOLSSUMMER 2014
Concrete Spans 1Lecture 22
Architectural StructuresARCH 331
lecture
http:// nisee.berkeley.edu/godden
Concrete Spans 2
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Reinforced Concrete Design
• economical & common
• resist lateral loads
Concrete Spans 3
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Reinforced Concrete Design
• flat plate
– 5”-10” thick
– simple formwork
– lower story heights
• flat slab
– same as plate
– 2 ¼”–8” drop panels
Concrete Spans 4
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Reinforced Concrete Design
• beam supported
– slab depth ~ L/20
– 8”–60” deep
• one-way joists
– 3”–5” slab
– 8”–20” stems
– 5”-7” webs
The Architect’s Studio Companion
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Concrete Spans 5
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Reinforced Concrete Design
• two-way joist
– “waffle slab”
– 3”-5” slab
– 8”-24” stems
– 6”-8” webs
• beam supported slab
– 5”-10” slabs
– taller story heights
F2008abnConcrete Spans 6Lecture 25
Foundations Structures ARCH 331
Reinforced Concrete Design
• simplified frame analysis
– strips, like
continuous beams
• moments require flexural reinforcement
– top & bottom
– both directions of slab
– continuous, bent or
discontinuous
Concrete Spans 7
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Reinforced Concrete Design
• one-way slabs (wide beam design)
– approximate analysis for moment & shear
coefficients
– two or more spans
– ~ same lengths
– wu from combos
– uniform loads with L/D ≤ 3
– � n is clear span (+M) or average of
adjacent clear spans (-M)
Concrete Spans 8
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Reinforced Concrete Design
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Concrete Spans 9
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Reinforced Concrete Design
• two-way slabs - Direct Design Method
– 3 or more spans each way
– uniform loads with L/D ≤ 3
– rectangular panels with
long/short span ≤ 2
– successive spans
can’t differ > longer/3
– column offset no more
than 10% span
Concrete Spans 10
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Reinforced Concrete Design
F2008abnConcrete Spans 11Lecture 25
Foundations Structures ARCH 331
Shear in Concrete
• at columns
• want to avoid stirrups
• can use shear studs or heads
Concrete Spans 12
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Shear in Concrete
• critical section at d/2 from
– column face, column capital or drop panel
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F2008abnConcrete Spans 13
Lecture 25
Foundations Structures
ARCH 331
Shear in Concrete
• at columns with waffle slabs
http:// nisee.berkeley.edu/godden
Concrete Spans 14
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Openings in Slabs
• careful placement of holes
• shear strength reduced
• bending & deflection canincrease
Concrete Spans 15
Lecture 25
Foundations Structures
ARCH 331
F2008abn
General Beam Design
• f’c & fy needed
• usually size just b & h
– even inches typical (forms)
– similar joist to beam depth
– b:h of 1:1.5-1:2.5
– bw & bf for T
– to fit reinforcement + stirrups
• slab design, t
– deflection control & shear6
2bhS =
Concrete Spans 16
Lecture 25
Foundations Structures
ARCH 331
F2008abn
General Beam Design (cont’d)
• custom design:
– longitudinal steel
– shear reinforcement
– detailing
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Concrete Spans 17
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Space “Frame” Behavior
• handle uniformly distributed loads well
• bending moment
– tension &
compression
“couple” with
depth
– member sizes
can vary,
but difficult
Concrete Spans 18
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Space “Frame” Behavior
• shear at columns
• support conditions still important
– point supports not optimal
• fabrication/construction can dominate design
Concrete Spans 19
Lecture 25
Foundations Structures
ARCH 331
F2008abn
Folded Plates
• increased bending stiffness with folding
• lateral buckling avoided
F2008abnConcrete Spans 20Lecture 25
Foundations Structures ARCH 331
Folded Plates
• common for roofs
• edges needstiffening
http:// nisee.berkeley.edu/godden
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F2008abnConcrete Spans 21Lecture 25
Architectural Structures ARCH 331
Folded Plates
– State Farm Center(Assembly Hall), University of Illinois
– Harrison & Abramovitz 1963
– Edge-supported dome spanning 400 feet wound with 614 miles of one-fifth inch steel wire
www.library.illinois.edu
F2008abnConcrete Columns 2
Lecture 26
Foundations Structures
ARCH 331
Concrete in Compression
• crushing
• vertical cracking
– tension
• diagonal cracking
– shear
•cf ′
http://www.bam.de
Concrete Columns 3
Lecture 26
Foundations Structures
ARCH 331
F2008abn
Columns Reinforcement
• columns require
– ties or spiral reinforcement
to “confine” concrete
(#3 bars minimum)
– minimum amount of longitudinal steel
(#5 bars minimum: 4 with ties, 5 with spiral)
Concrete Columns 4Lecture 26
Foundations Structures ARCH 331
F2008abn
Slenderness
• effective length in monolithic with
respect to stiffness of joint: Ψ & k
• not slender when
22<r
kLu
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Concrete Columns 5Lecture 26
Foundations Structures ARCH 331
F2008abn
Effective Length (revisited)
• relative rotation
b
c
lEI
lEI
Σ
Σ=Ψ
Concrete Columns 6
Lecture 26
Foundations Structures
ARCH 331
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Column Behavior
F2008abnConcrete Columns 7Lecture 26
Foundations Structures ARCH 331
Column Design
• φc = 0.65 for ties, φc = 0.75 for spirals
• Po – no bending
• Pu ≤ φcPn– ties: Pn = 0.8Po– spiral: Pn = 0.85Po
• nominal axial capacity:
– presumes steel yields
– concrete at ultimate stress
stystgco AfAAfP +−′= )(85.0
Concrete Columns 8Lecture 26
Foundations Structures ARCH 331
F2008abn
Columns with Bending
• eccentric loads can cause moments
• moments can change shape and induce more deflection
(P-∆)P
∆
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Concrete Columns 9Lecture 26
Foundations Structures ARCH 331
F2008abn
Columns with Bending
• for ultimate strength behavior, ultimate strains can’t be exceeded
– concrete 0.003
– steel
• P reduces with M
s
y
E
f
F2009abn
Columns with Bending
• need to consider combined stresses
• linear strain
• steel stress at or below fy
• plot interactiondiagram
Concrete Columns 10
Lecture 26
Foundations Structures
ARCH 331
Concrete Columns 11
Lecture 26
Foundations Structures
ARCH 331
F2008abn
Design Methods
• calculation intensive
– handbook charts
– computer programs
Concrete Columns 12
Lecture 26
Foundations Structures
ARCH 331
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Design Considerations
• bending at both ends
– P- ∆ maximum
• biaxial bending
• walls
– unit wide columns
– “deep” beam shear
• detailing
– shorter development lengths
– dowels to footings
