Solution for Bridges Design & Analysis

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Solution for Bridges Design & Analysis The stateoftheart technology for the civil engineering world Dr. Dimitrios Sofialidis Technical Manager SimTec

Transcript of Solution for Bridges Design & Analysis

Page 1: Solution for Bridges Design & Analysis

Solution for Bridges

Design & AnalysisThe state–of–the–art technology

for the civil engineering world

Dr. Dimitrios Sofialidis

Technical Manager

SimTec

Page 2: Solution for Bridges Design & Analysis

Main Features

• Concrete Creep and Shrinkage

• Bridge layout modeling (in plan and elevation view)• Utilities for generating common bridge sections and

layout design• Geometric and finite element model generation with

both Beams (1D) and Solid elements (3D)• Loads Generation

• Overloads• Moving loads (vehicle’s editor)• Utility for Prestressing forces input• User loads

• Automatic Loads combination

• Simulation of the construction process

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Concrete Creep and Shrinkage• Effects of Creep and Shrinkage relative to concrete maturity can be easily

considered• Allows to obtain the deformed

shape as well as the forces,moments and stresses in the model

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Bridge Layout Modeling

• This utility allows to generate the geometry and the finite element model of the bridge from common engineering blueprints. It works as a "layout program", allowing to define the layout design in both plan and elevation views

• The procedure used for the bridge layout definition is the following:• Definition of the mileage points (MP’s) that represent the

structure axis• Definition of plan and elevation layout

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Bridges Layout in Plan View• In plan view, the mileage points line is a succession of user-

defined stretches:• straight segments • circular arcs• clothoid arcs

Caso R = R : Definition of the section elementsi f

/

(x ,y )i i

(x ,y )f f

R

i

f

s = s + Long

R

ii

s x

y Clothoid axis

cl

cl

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Bridge Layout in Elevation View• In elevation view, the mileage points line is a succession of user-

defined stretches:• straight segments • parabolic arcs

Vertical fillet

si

sf

i

ff

L

T

zf

zi

sStraight section

Straight section

Parabolic fillet

s

si f

i i

z

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Bridge Cross Sections

Bridge Section Types

Rectangular section

Trapezoidal section

Trapezoidal section with flanges

Polygonal section with two bends

Polygonal Asymmetric with two bends Note: The upper line (deck) is alwayshorizontal. The slope must be laterdefined with the section’s bank.

B

DEPTH

RS

BTOP

BBOT

DEPTH

TTOPTS

DEPTH

BTOP

BM

BBOT

TTOP

TBOTTF

TBOT BBOT

BM2

BM1

BTOP

DEPTH

TTOP

TMPS

BBOTR

BM2R

BM1R

BTOPRBTOPL

BM1LBM2L

BBOTL

DEPTHL

TBOTL

TML

TBOTR

TTOPR

TMR DEPTHR

axis

PATri-cell box section definition

a1

p11

b1

a2

t 22 t 21

t 11

p21p22

s31

1

1

p121

11

t 31

hL

vL

y

z

vCL

hCL

hCU

vCU

t 41

vU vUr

hU hUr

a /20

vCUr

hCUr

hCLr

vCLr

• This module includes a library of typical bridge cross sections, which are defined by the outline of the section:• Slab cross sections• Box cross sections

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Slab Concrete Sections• It’s possible to define holes

• The sections can be symmetric or asymmetric

• Sections and the hole diameters might vary along the bridge

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Box Sections with Variable Depth• Any generic box section can be easily defined• All the necessary input parameters can be introduced either by

menu or using the corresponding command (allows performing a parametric design of cross sections, creating macros, etc).

Tri-cell box section definition

a1

p11

b1

a2

t 22 t 21

t 11

p21p22

s31

1

1

p121

11

t 31

hL

vL

y

z

vCL

hCL

hCU

vCU

t 41

vU vUr

hU hUr

a /20

vCUr

hCUr

hCLr

vCLr

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Assigning Attributes

• The cross sections may have the following attributes:• Offsets• Banks• Skew• Hollow or solid sections

z

y

Zoffs

Yoffs

MP,s line

Bank (Rotation's center P) P

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Model Generation• Once the layout and cross sections are defined the geometrical and FEM

model generation can be automatically performed by the program

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Model Generation• Once the layout and cross sections are defined the geometrical and FEM

model generation can be automatically performed by the program

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Model Generation

Beam element model (shape option)

Solid element model

Just by specifying an element type, a Solid finite element model or a Beam finite element model can be generated

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A. Suspension Bridges WizardSuspension Bridge Generator windows can generate 3D

models for:

• Concrete Suspension Bridges(with a CivilFEM bridge section)

• Steel Suspension Bridges(with a CivilFEM 3D steel truss pattern)

• Generic Suspension Bridges(with a CivilFEM generic cross section)

• Mixed section, two types of section:

- Concrete slab over I-section steel beams

- Concrete slab over a steel box section

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A. Suspension Bridges Wizard• By using this Wizard it is possible to easily introduce the

number of segments and the corresponding data to generate

the entire bridge model for both 3D beams and solid elements.

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A. Suspension Bridges WizardConcrete

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A. Suspension Bridges Wizard• Both concrete and steel truss suspension bridge models are

automatically generated for any generic configuration by just inputting a

few parameters.

Steel

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A. Suspension Bridges Wizard

Steel

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A. Suspension Bridges Wizard• Any generic cross section from library and/or any 2D defined using

CivilFEM with ANSYS meshed drawing (capture utility) can be used as a

bridge cross section

• Optimization of the geometry

and initial tensions of cables

Generic

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A. Suspension Bridges Wizard

Bridge section is composed of a concrete slab over

I-section steel beams:

• Mixed Section (type 1)

nB bB

hBea

m

tFL

tWeb

yz

bSlab/2bSlab

tSla

bfSRfSL

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A. Suspension Bridges Wizard• Mixed Section (type 1)

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A. Suspension Bridges Wizard• Mixed Section (type 1) Example

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A. Suspension Bridges Wizard

Bridge section is composed of a concrete slab over a steel box section:

• Mixed Section (type 2)

bSlabfSL fSR

hBox

tSla

b

tboxLtboxR

tboxB

alphaL

alphaR

yz

bSlab/2

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A. Suspension Bridges Wizard• Mixed Section (type 2)

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A. Suspension Bridges Wizard• Mixed Section (type 2) Example

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A. Suspension Bridges Wizard• Supported Bridge Examples

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B. Cable Stayed Bridge Wizard

• Generation window

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B. Cable Stayed Bridge Wizard

• Model generation

• Cable arrangements:

HARP TYPE FAN TYPE

z

x

XL1XL2XL...

XR1 XR2 XR...

ZB1

ZB2

ZT1

ZT2

ZT...

ZB...

ZT3

(XB, ZB)

(XT, ZT)

z

x

XL1XL2XL...

XR1 XR2 XR...

ZB1

ZB2

ZT1

ZT2

ZT...

ZB...

ZT3

(XB, ZB)

(XT, ZT)

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B. Cable Stayed Bridge Wizard• Model generation

• Towers: Unlimited in number, variable cross sections,

vertical or inclined with multiple cable arrangements

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B. Cable Stayed Bridge Wizard

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M N

M X

XY

Z

B. Cable Stayed Bridge Wizard• Nonlinear Construction Process Analysis:

XY

ZX

Y

ZX

Y

Z

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B. Cable Stayed Bridge Wizard• Nonlinear Construction Process Analysis:

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B. Cable Stayed Bridge Wizard• Nonlinear Construction Process Analysis:

• Cable force optimization: Deflection

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B. Cable Stayed Bridge Wizard• Nonlinear Construction Process Analysis:

• Cable force optimization: Bending Moment

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C. Arch Bridge Wizard

• Arch Bridge Generator (Beam Model)

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C. Arch Bridge Wizard• Depending on the position of the bridge deck

compared to the arch, there are different cases:

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C. Arch Bridge Wizard

• Beam Model

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C. Arch Bridge Wizard

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C. Arch Bridge Wizard

• Shell Model

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Bridge Components• CivilFEM with ANSYS allows a detailed analysis of

piers, cross bracings, diaphragms, etc.

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Special Features

• Any of the bridge parameters (layout, sections, dimensions, etc.) can be easily parameterized by the user, allowing very fast sensitivity analysis, making use of some advanced features:• Log files

the program stores in a file all the orders executed by the program during a job. This file can be edited by the user at any time and the model can be executed again by just reading it

• Macros (APDL)

• Customization: users are able to create their own windows, commands, etc, customizing the program as much as possible to their own needs

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Loads Generation

• CivilFEM automatically generates the loads corresponding to the various load hypotheses over a 2D or 3D structure, such as:• Moving loads (traffic loads)• Surface loads (Overloads)• Prestressing tendons

• Any kind of "user defined" loads• "Smart" load combination of all

the load steps generated during the analysis

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Loads Generation (Traffic Loads)

Vehicle library: just choose the vehicle and the corresponding properties are automatically

defined

Property window

• With the vehicle editor it is possible to create, import from library, modify, copy, delete and list vehicles

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Loads Generation (Traffic Loads)• Two different types of vehicles: Rigid (truck) or flexible (train,

adaptable to the path)• User friendly path definition: road surface and road axis are

automatically detected by the program

Trajectory definition (Rigid vehicle)

MP,s

line components

Vehicle trajectory

Assembly the bridges nodes and elements, where the loads are applied

Dist

The tangency occurs in the point (xLoc, yLoc) of the vehicle

Trayectory definition ( )adaptable to the trajectory

KP,s

Lines component

Vehicle trayectoryAssembly the bridges nodes and elements, where the loads are applied

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Loads Generation (Surface Loads)

Definition of surface loads

KP,s

Lines

component

Overload

grid

s1

d1

d2

dm

Assembly with the bridges nodes and elements over which the

surface load will be applied

• Definition of an overload grid over the deck• Automatic load generation and combinations of all possible load

case scenarios

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Loads Generation (Prestressing Cables)

• Definition of points along the cable’s path (automatic adjustment of the points using splines)

• Introduce the tensile force at specific locations in the tendon’s path• Automatic transfer of the cable action to the structure:

• the program calculates an equivalent system of forces at each node of the element that equilibrate the system

3D spline generation

P

P

P P

P 1

2

k+2 k+1

N

P' 1 P' N

P k

Transmision of the cable actions to the model

OP

xR

R

MRy

z

MRz

xMR

c.d.g.R

y

Kfx

Kfy

Kfz

T1

T2

1

2

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Load Combination• In the bridge analysis process, a great number of load

steps are generated, which later on have to be combined looking for the worst case scenario. CivilFEM includes functionalities that can automatically handle all possible load cases

• Obtains the envelop that considers the worst case scenario for each structural point by specifying a target

• Concomitance at both global and element levels• Variable load coefficients can be defined • Combining the moving loads (traffic loads)

• The program automatically combines them as an "incompatible" load (which is the same as saying that a vehicle can only be located at one position at the same time)

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Load Combination

• Combining the surface loads (overloads)• CivilFEM will automatically combine them as a

"compatible" load (these loads will then be allowed to be located at any possible position over the surface)

To obtain the envelop of maximum vertical displacements at all nodes

OBJECTIVE:

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Load Combination

• Combining the prestressing cable loads• The program automatically combine them as an

"addition" load (adds all the loads and apply them at the same time)

• Combining "user-defined" loads• The same procedure is applied simply by defining the

combination rule to be used (compatible, incompatible, addition, selection, etc) to find the combined results

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Checking & Design• Serviceability Limit State

• Cracking checking according to codes

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Checking & Design

• Ultimate Limit State

• Check and design of the bridge reinforcement according to codes, taking into account all the loads applied to the structure.

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Simulation of Construction Process

Normal Procedure

• The bridges module allows to simulate multiple types of construction process

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Simulation of Construction Process

Cantilever construction

Y

X

Puente construido mediante dovelas yuxtapuestas: Situación después del step #3

Y

Z

Pile Section: AreaU, I , I , AreaB, I ,I , HyyU

z

Bridge plant

Not builded zone

10 11 12 13

Sections

12

Steps

Live cable

7 8 9 14 15 161 2 3 4 5 6

23

11

2

3

H

Live pile support

Not live support

zzU yyB zzB

Pile section axis

Bridge section axis

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Simulation of Construction Process

12345

Proceso constructivo de un puente empujado

123

En la etapa inicial nacen cuatro seccionesy solo una de ellas está "empujada" (la una)

4

1234

En la segunda etapa se empuja una nueva sección (la 2), la sección 1 ha llegadoa un apoyo intermedio que al final de la construcción ocupará la 4

1234

En la tercera etapa nace la sección 5, perono se empuja ninguna nueva

5

En la última etapa el puente está completo. Las secciones 4 y 1 alcanzan sus apoyos definitivos.

12345 12345 12345 12345

En la cuarta etapa el puente está completo, pero tan solo se empujandos secciones..

6

6

Push launching

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Bridge Postprocessing• CivilFEM with ANSYS performs a wide range of postprocessing

calculations: load combinations, results displays, check and

design processes, etc.

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For more information, you may contact:

Dr. Dimitris Sofialidis

SimTec Ltd.

Technical Manager

[email protected]

www.simtec.gr