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Lecture 35 Beam Deflection

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The material properties are fc = 4 ksi and fy= 60 ksi. ... which may be damaged by large deflections, are to be erected at this level. ... – PowerPoint PPT presentation

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Title: Lecture 35 Beam Deflection


1
Lecture 35 - Beam Deflection
  • November 22, 2002
  • CVEN 444

2
Lecture Goals
  • Example on moment of inertia
  • Serviceability
  • Deflection calculation
  • Deflection example

3
Reinforced Concrete Sections - Example
Given a doubly reinforced beam with h 24 in, b
12 in., d 2.5 in. and d 21.5 in. with 2 7
bars in compression steel and 4 7 bars in
tension steel. The material properties are fc
4 ksi and fy 60 ksi. Determine Igt, Icr ,
Mcr(), Mcr(-), and compare to the NA of the
beam.
4
Reinforced Concrete Sections - Example
The components of the beam
5
Reinforced Concrete Sections - Example
The compute the n value and the centroid, I
uncracked
6
Reinforced Concrete Sections - Example
The compute the centroid and I uncracked
7
Reinforced Concrete Sections - Example
The compute the centroid and I for a cracked
doubly reinforced beam.
8
Reinforced Concrete Sections - Example
The compute the centroid for a cracked doubly
reinforced beam.
9
Reinforced Concrete Sections - Example
The compute the moment of inertia for a cracked
doubly reinforced beam.
10
Reinforced Concrete Sections - Example
The critical ratio of moment of inertia
11
Reinforced Concrete Sections - Example
Find the components of the beam
12
Reinforced Concrete Sections - Example
Find the components of the beam
The neutral axis
13
Reinforced Concrete Sections - Example
The strain of the steel
Note At service loads, beams are assumed to act
elastically.
14
Reinforced Concrete Sections - Example
Using a linearly varying e and s Ee along the
NA is the centroid of the area for an elastic
center
The maximum tension stress in tension is
15
Reinforced Concrete Sections - Example
The uncracked moments for the beam
16
Calculate the Deflections
(1) Instantaneous (immediate) deflections (2)
Sustained load deflection
Instantaneous Deflections due to dead loads(
unfactored) , live, etc.
17
Calculate the Deflections
Instantaneous Deflections
Equations for calculating Dinst for common cases
18
Calculate the Deflections
Instantaneous Deflections
Equations for calculating Dinst for common cases
19
Calculate the Deflections
Instantaneous Deflections
Equations for calculating Dinst for common cases
20
Calculate the Deflections
Instantaneous Deflections
Equations for calculating Dinst for common cases
21
Sustained Load Deflections
Creep causes an increase in concrete strain
Curvature increases
Increase in compressive strains cause increase in
stress in compression reinforcement (reduces
creep strain in concrete)
Compression steel present
Helps limit this effect.
22
Sustained Load Deflections
Sustain load deflection l Di
Instantaneous deflection
ACI 9.5.2.5
at midspan for simple and continuous beams at
support for cantilever beams
23
Sustained Load Deflections
x time dependent factor for sustained load
Also see Figure 9.5.2.5 from ACI code
24
Sustained Load Deflections
For dead and live loads
DL and LL may have different x factors for LT (
long term ) D calculations
25
Sustained Load Deflections
The appropriate value of Ic must be used to
calculate D at each load stage.
26
Serviceability Load Deflections - Example
Show in the attached figure is a typical interior
span of a floor beam spanning between the girders
at locations A and C. Partition walls, which may
be damaged by large deflections, are to be
erected at this level. The interior beam shown
in the attached figure will support one of these
partition walls. The weight of the wall is
included in the uniform dead load provided in the
figure. Assume that 15 of the distributed
dead load is due to a superimposed dead load,
which is applied to the beam after the partition
wall is in place. Also assume that 40 of the
live load will be sustained for at least 6 months.
27
Serviceability Load Deflections - Example
fc 5 ksi fy 60 ksi
28
Serviceability Load Deflections - Example
Part I Determine whether the floor beam meets the
ACI Code maximum permissible deflection criteria.
(Note it will be assumed that it is acceptable
to consider the effective moments of inertia at
location A and B when computing the average
effective moment of inertia for the span in this
example.) Part II Check the ACI Code crack width
provisions at midspan of the beam.
29
Serviceability Load Deflections - Example
Deflection before glass partition is installed
(85 of DL)
30
Serviceability Load Deflections - Example
Compute the centroid and gross moment of inertia,
Ig.
31
Serviceability Load Deflections - Example
The moment of inertia
32
Serviceability Load Deflections - Example
The moment capacity
33
Serviceability Load Deflections - Example
Determine bending moments due to initial load
(0.85 DL) The ACI moment coefficients will be
used to calculate the bending moments Since the
loading is not patterned in this case, This is
slightly conservative
34
Serviceability Load Deflections - Example
The moments at the two locations
35
Serviceability Load Deflections - Example
Moment at C will be set equal to Ma for
simplicity, as given in the problem statement.
36
Serviceability Load Deflections - Example
Assume Rectangular Section Behavior and calculate
the areas of steel and ratio of Modulus of
Elasticity
37
Serviceability Load Deflections - Example
Calculate the center of the T-beam
38
Serviceability Load Deflections - Example
The centroid is located at the As lt 4.5 in. tf
Use rectangular section behavior
39
Serviceability Load Deflections - Example
The moment of inertia at midspan
40
Serviceability Load Deflections - Example
Calculate average effective moment of inertia,
Ie(avg) for interior span (for 0.85 DL) For beam
with two ends continuous and use Ig for the two
ends.
41
Serviceability Load Deflections - Example
Calculate instantaneous deflection due to 0.85
DL Use the deflection equation for a fixed-fixed
beam but use the span length from the centerline
support to centerline support to reasonably
approximate the actual deflection.
42
Serviceability Load Deflections - Example
Calculate additional short-term Deflections (full
DL LL)
43
Serviceability Load Deflections - Example
Calculate additional short-term Deflections (full
DL LL) Let Mc Ma - 2000 k-in for
simplicity see problem statement
44
Serviceability Load Deflections - Example
Assume beam is fully cracked under full DL LL,
therefore I Icr (do not calculate Ie for now).
Icr for supports
45
Serviceability Load Deflections - Example
Class formula using doubly reinforced rectangular
section behavior.
46
Serviceability Load Deflections - Example
Class formula using doubly reinforced rectangular
section behavior.
47
Serviceability Load Deflections - Example
Calculate moment of inertia.
48
Serviceability Load Deflections - Example
Weighted Icr
49
Serviceability Load Deflections - Example
Instantaneous Dead and Live Load Deflection.
50
Serviceability Load Deflections - Example
Long term Deflection at the midspan
Dead Load (Duration gt 5 years)
51
Serviceability Load Deflections - Example
Long term Deflection use the midspan information
Live Load (40 sustained 6 months)
52
Serviceability Load Deflections - Example
Total Deflection after Installation of Glass
Partition Wall.
53
Serviceability Load Deflections - Example
Check whether modifying Icr to Ie will give an
acceptable deflection
54
Serviceability Load Deflections - Example
Check whether modifying Icr to Ie will give an
acceptable deflection
55
Serviceability Load Deflections - Example
Floor Beam meets the ACI Code Maximum permissible
Deflection Criteria. Adjust deflections
56
Serviceability Load Deflections - Example
Adjust deflections
57
Serviceability Load Deflections - Example
Part II Check crack width _at_ midspan
58
Serviceability Load Deflections - Example
Assume
For interior exposure, the crack width _at_ midspan
is acceptable.
59
Homework-12/2/02
Problem 8.7
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