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Bentley RM Bridge Seismic Design and Analysis

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Title: Bentley RM Bridge Seismic Design and Analysis

1
Bentley RM Bridge Seismic Design and Analysis

Alexander Mabrich, PE, Msc

2
(No Transcript)
3
AGENDA
Kobe, Japan (1995)
4
AGENDA
Loma Prieta, California (1989)
5
RM Bridge Seismic Design and Analysis

Critical infrastructures require
Sophisticated design methods
Withstand collapse in earthquake occurrences

6
RM Bridge Seismic Design and Analysis

The Bentley BrIM vision
RM Bridge Seismic Design Methods
Earthquake simulations in Bentley RM Bridge

7
RM Bridge Seismic Design and Analysis

AASTHO, Simple Seismic Load
Basic concepts for Dynamic Analysis
- Eigenvalues
- Eigenshapes
Two non-linear dynamic options
- Response Spectrum
- Time-History

8
AASHTO Bridge Design Specifications

7 probability of exceedence in 75years
Seismic Design Categories
Soil
Site / location
Importance
Earthquake Resistant System
Demand/Capacity

9
AASHTO Bridge Design Specifications

Site Location

10
AASHTO Bridge Design Specifications

Type of Seismic Analysis Required

11
Static Seismic Load
12
Equivalent Static Analysis

Uniform Load Analysis
Orthogonal Displacements
Simultaneously
Fundamental mode

13
Equivalent Static Analysis

Direction, Factor

14
Fundamental Mode
15
Results
16
Basic Concepts used in Dynamic Analysis
17
Basic Concepts

Vibration of Systems with one or more DOF
Eigen values and Eigen modes
Forced Vibration
Harmonic and Stochastic Simulation
Linear and Non-linear behavior of the structure

18
Dynamic Vibration
19
Damped Vibration
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Rayleigh Damping

21
Single Mass Oscillator
EQUILIBRIUM
EQUATION OF MOTION
22
Damping Ratio
c?0

23
Free Vibration
no dampingand dividing by m
But..

Solution

24
Multi Degree of Freedom System

25
Numerical Methods for Dynamic Analysis

Calculation of Eigen frequency
Modal Analysis
Direct Time integration, linear and non-linear

26
Modal Analysis

System of dynamic equations

Free vibration motion

Non trivial solution

27
Eigen Calculation

Eigen values
Eigen shapes
Unique nature
Differential equations

28
Eigen Shapes
29
MASS PARTICIPATION FACTORS

MODE phiMphi X Y Z
SUM-X SUM-Y SUM-Z HERTZ
----------------------------------------
---------------------------------
1 0.3768E04 88.33 0.00 3.14
88.33 0.00 3.14 0.905
2 0.1653E04 2.35 0.00 71.45
90.68 0.00 74.59 1.704
3 0.8292E03 0.00 5.03 0.04
90.68 5.03 74.63 3.111
4 0.1770E04 1.14 0.01 0.05
91.82 5.04 74.68 3.809
5 0.1055E04 0.28 0.01 0.01
92.10 5.05 74.69 5.425
6 0.1101E04 0.00 57.35 0.01
92.10 62.40 74.69 6.300
7 0.1675E04 0.43 0.01 7.31
92.54 62.41 82.00 7.145
8 0.9072E03 0.17 0.00 0.05
92.70 62.41 82.05 9.656
9 0.5307E04 0.13 0.04 3.98
92.83 62.45 86.03 10.042
10 0.1038E04 0.06 0.01 0.04
92.90 62.46 86.08 11.795
11 0.1405E04 0.13 0.01 0.00
93.02 62.47 86.08 11.830
12 0.1671E04 0.74 0.01 0.03
93.77 62.48 86.10 13.265
13 0.4010E03 1.74 0.00 0.04
95.51 62.49 86.14 13.321
14 0.8892E03 0.00 0.43 0.05
95.51 62.92 86.20 13.890
15 0.5452E04 0.01 0.03 0.25
95.52 62.95 86.45 14.077
16 0.1986E04 0.08 0.03 0.87
95.59 62.97 87.32 16.719
17 0.6586E03 0.03 5.91 0.03
95.63 68.88 87.35 16.936

30
Response Spectrum

Modal Decomposition

31
Response Spectrum

Combination of natural modes
One mass oscillator
Oscillating loads
Intensity factor
Single contribution
Synchronization by Stochastic Calculation Rules
ABS,SRSS,CQC, etc

32
Spectral Response Acceleration
AASHTO Definition
33
Solution in Frequency Domain

Solution by combining the contributions of the
eigenvectors
Superposition of eigenvectors
Loading has lost information about correlation
during conversion
Solution has no information on phase differences
between the contributions of different
eigenvectorsUse Stochastic methodology
Use Stochastic methodology

34
Combination Rules

Max/Min results with different rules available
ABS Rule (Sum of absolute values)
SRSS Rule (Square root of sum of sqaures)
DSC Rule (Newmark/Rosenblueth)
CQC Rule (Complete quadratic combination)
GENERAL a lot of other rules exist

35
CQC-RULE

More complex theory, modelling the correlation
between different eigenfrequencies

Good results if the duration of the event is 5
times higher than the longest considered period
of vibration
AASHTO preferred by art. 4.7.4.3.3

36
ABS-RULE

Total response computed by adding the absolute
values of all individual contributions

Full correlation between the different
eigenfrequencies
All maxima are reached at the same time

ABS-rule is suitable for structures where
relevant eigenvalues are situated close to each
other

37
SRSS-RULE

Individual eigenfrequencies are completely
uncorrelated

Eigenfrequencies are added in Pythagorean manner

Good results if considered eigenfrequencies are
over a wide range
They are not situated too close one to each other

38
DSC-RULE

Correlation between the contributions of
individual eigenfrequencies must exist

Different damping for different eigenfrequencies
can be taken into account
Additional information specifiying the frequency
dependency of damping must be available

39
Earthquake Load

40
Response Spectrum in RM Bridge
41
Time-History

Time Integration

42
Time History

Direct Time Integration
Linear and Non-Linear analysis
Standard event is defined time-histories of
ground acceleration are site specific
Probability of bearable damage
Most accurate method to evaluate structure
response under earthquake event.

43
What Can Be Non-Linear in RM Bridge?