{Test Problem
name = Shrinkage bridge example. |
description = Demonstrates how shrinkage can be evaluated for 2-span bridge. |
keyword = shrinkage; bridge; bridge modeler |
program = SAP2000 |
version = V12.0.2 |
status = done |
id = ok/shrinkage - composite section bridge example}} |
Model Overview
The purpose of this model is to evaluate internal forces due to shrinkage of a deck for 1-span and 2-span continuous bridge structures. The
On this page:
Table of Contents |
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Model overview
Internal shrinkage forces are evaluated for one-span and continuous two-span bridge structures. These bridges have the following properties:
- span
Span length = 10m
- deck
Deck-section type:
teeT-beam
decksection with a 0.5m-deep
and, 3m-wide deck and two 0.5m-wide
and, 1.
55m-deep beams
View A 3D view of the bridge model:
Geometry of the deck section of the bridge model:
...
one and two-span bridge models is shown in Figure 1:
Figure 1 - Bridge model
The cross-sectional geometry of the bridge deck is shown in Figure 2:
Figure 2 - Bridge deck section
Key modeling steps
Define shrinkage characteristics for the default, 4000psi concrete material
"4000psi". First, create. Create a copy of
the default concretethis material and
name the material "label it '4000psi no shrinkage
". This material will be used for the concrete girders, for which the'. Concrete girders will use this new material, and shrinkage will not be considered.
SecondNext, add shrinkage properties to the
"4000psi
"concrete material as follows:
Use "
Define > Materials" menu command.Check "Show Advanced Properties" and clickComponents Tab > Properties > Materials > select 4000psi material > click the Modify button" to ope the "Material Property Data" form
Check the "Switch to Advanced Property Display" checkbox
Click the "Modify/Show Material Properties..." button
. Click "Modify/Show Material Properties..."Clickto open "Material Property Data" form
Click the "Time Dependent Properties
", which will open form..." button to open "Time Dependent Properties for Concrete"
. Check "Shrinkage" under the "form
Under "Time Dependence Considered For" heading
", check Shrinkage.
Define the two bridges using a single, straight layout line. The
2two-span bridge will have a beginning station at 0m and an end station 20m
, while the 1. The one-span bridge will have a beginning station at 30m and an end station
40at 40m.
Define the bridge deck section
"as Tee Beam
", with dimensions
aslisted above in the Model Overview section
above. Although both. Assign 4000psi concrete material to the deck
and the girders will be made of concrete, use different concrete property for the deck and for the, and the '4000psi no shrinkage' material to the girders. This will enable
to easily considershrinkage consideration for the deck
(material "4000psi"), butand not for the girders
(material "4000psi no shrinkage").
Define a pinned-bearing condition for the start abutment, and roller-bearing condition for the end abutment. For the
2two-span bridge, defined a fixed foundation spring at the bottom of the column, and pinned bearings at the top
of the column.
- Define
Directly within the bridge object definition (Bridge Tab > Bridge Object > Groups), define staged construction bridge groups for the deck and
thegirders
forof the
1one-span and
2two-span bridge objects
directly within the bridge object definition.
This can be done on the "Bridge Object Data" form, by selecting "Staged Construction Groups" and clicking "Modify/Show..." button.
Define a staged-construction load case named
"STAGED"Staged. Add the entire structure in the first stage and define several empty stages with nonzero durations in order to evaluate response due to shrinkage as
thetime progresses.
MakeBe sure to check
"Time Dependent Material Properties
"on the
"Nonlinear Parameters
" formmenu.
Run the analysis
and, then use the "Home Tab > Display > Show Bridge Superstructure Forces/Stresses" menu command to review the
results for thestaged-construction load-case results.
Results
The deformed shape for For both the 1one-span and the 2two-span bridge objects, the deformed shape indicates that the deck shrinkage causes shortening of the deck fibers, and it causes the entire bridge to bow downwards, which is expected:as expected. This behavior is shown in Figure 3:
Figure 3 - Shrinkage deflection
For the 1one-span bridge, there are no internal forces being generated, since the bridge structure is statically determinate, no internal forces are generated. However, the 2two-span bridge is statically indeterminate, and the redundant reactions do cause internal moments (with tension . At the interior pier, tension is generated in the top fibers at the interior pier) , as shown in the screenshot below:Figure 4:
Figure 4 - Shrinkage moment
Attachments
- File | filename = Shrinkage SAP2000 V12.0.2 model.zip | title = SAP2000 V12.0.2 file (Zipped SDB file)
...
(CSiBridge V18.1.1).zip (zipped BDB file)
Metadata
Name: Bridge shrinkage example
Description: Evaluate shrinkage for a one-span and a continuous two-span bridge system.
Program: CSiBridge
Program Version: 18.1.1
Model ID: 1402