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{live-template:Tutorial} There are various ways of modeling composite behavior of beam-and-slab assembly in SAP2000. For your reference and study, we have attached four SAP2000 models that show different ways for modeling composite action for girder-and-slab assembly. The model description used for the comparison is as follows: * The Slab width = 2 m * Slab thickness = .2 m * Girder total height = 1.2 m * Top and bottom flanges width = 1 m * Top and bottom flange thickness = .1 m * Web thickness = .1 m * The applied load at mid span is 100 kN * Modules of elasticity E= 33000000 kN/m2 * Span length = 20 m, fixed at both ends The deflection at mid-span is calculated for the naked girder and composite girder as 0.0018m and 0.00083m respectively. h1. Model Overview !problem statement.png|border=1! h1. Various Approaches to Modeling Composite Behavior !composite section sketches.png|border=1! h1. Fixed Beams Model The model contains contains 8 beams that are fixed at their both ends and the composite behavior is modeled using the 8 approaches outlined in the figure above. || Beam Designation || Behavior || Midspan Deflection \\ \[mm\] || Comments || | Theoretical Beam | composite \\ | 0.8181 | Theoretical deflection based on the {math}\frac{PL^3}{192EI}{math} formula. Please note that the SAP2000 calculated deflections are slightly higher because the program considers shear deformations. | | Beam 1 \\ (top beam) \\ \\ | nocomposite \\ | 1.7938 | The center line of deck slab coincides with the neutral axis of the section. Hence, the contribution of deck slab to the flexural stiffness of the section will be negligible and the deflection at mid-span for this model should be close to the deflection for naked girder (i.e. no composite action). | | | Beam 2 \\ | composite \\ | 0.8313 | In this model, the shell elements representing the slab are drawn at the CG of the girder and then offset above the girder to model the composite action. The shells are offset such that the soffit of the slab is at the top of the girder top flange. | | Beam 3 \\ | composite \\ | 0.8313 | In this model the girder and slab are drawn at their respective centerlines and then the corresponding joints of the girder and the slab are connected together through body constraints. This is another way to model the composite action. | | Beam 4 \\ | composite \\ | 0.8313 | In this model the concept of frame insertion points is used to model the composite action. | | Beam 5 \\ | noncompostite \\ | 1.7938 | Equal constrain is used to model noncomposite behavior. \\ | | Beam 6 \\ | noncomposite \\ | 1.7938 | Link is used to model noncomposite behavior. \\ | | Beam 7 \\ | partially composite \\ | 1.0302 | Link is used to model partially composite behavior \\ | | Beam 8 \\ (bottom beam) \\ | composite \\ | 0.8313 | Link is used to model composite behavior. \\ | In view of the foregoing, you can use either area offsets, body constraints, frame insertion points or links to model composite action of the beam-and-slab assembly. h1. Simply Supported Beams Model The model contains contains 8 beams that are simply supported at their both ends and the composite behavior is modeled using the 8 approaches outlined in the figure above. || Beam Designation || Behavior || Midspan Deflection \\ \[mm\] || Comments || | Theoretical Beam | composite \\ | 3.2725 | Theoretical deflection based on the {math}\frac{PL^3}{48EI}{math} formula. Please note that the SAP2000 calculated deflections are slightly higher because the program considers shear deformations. | | Beam 1 \\ (top beam) \\ \\ | nocomposite \\ | 7.1752 | The center line of deck slab coincides with the neutral axis of the section. Hence, the contribution of deck slab to the flexural stiffness of the section will be negligible and the deflection at mid-span for this model should be close to the deflection for naked girder (i.e. no composite action). | | | Beam 2 \\ | composite \\ | 3.2624\\ | In this model, the shell elements representing the slab are drawn at the CG of the girder and then offset above the girder to model the composite action. The shells are offset such that the soffit of the slab is at the top of the girder top flange. | | Beam 3 \\ | composite \\ | 3.2624\\ | In this model the girder and slab are drawn at their respective centerlines and then the corresponding joints of the girder and the slab are connected together through body constraints. This is another way to model the composite action. | | Beam 4 \\ | composite \\ | 3.2624\\ | In this model the concept of frame insertion points is used to model the composite action. | | Beam 5 \\ | noncompostite \\ | 7.1752\\ | Equal constrain is used to model noncomposite behavior. \\ | | Beam 6 \\ | noncomposite \\ | 7.1752\\ | Link is used to model noncomposite behavior. \\ | | Beam 7 \\ | partially composite \\ | 3.5036\\ | Link is used to model partially composite behavior \\ | | Beam 8 \\ (bottom beam) \\ | composite \\ | 3.2624\\ | Link is used to model composite behavior. \\ | h1. Attachments * [Modeling composite behavior in SAP2000.zip|^Modeling_composite_behavior_in_SAP2000.zip] - The zipped file contains the following files: ** SAP2000 V12.0.0 file for with 8 fixed beams for which the composite behavior is modeled using different approaches. ** SAP2000 V12.0.0 file for with 8 simply supported beams for which the composite behavior is modeled using different approaches. ** Sketches illustrating modeling composite, noncomposite and partially composite behavior in SAP2000 (PDF file). {hidden-content} The "Modeling composite behavior in SAP2000.zip" attachment file can be directly emailed to support questions. {hidden-content}
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This article is for SAP2000, but the same concepts apply also to CSiBridge.

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Table of Contents

SAP2000 provides various ways to model the composite behavior of a beam-slab assembly. Attached are four SAP2000 models which demonstrate various approaches. The geometric and material properties of the model used for comparison are listed as follows:

  • Slab width = 2.0m

  • Slab thickness = 0.2m

  • Total girder height = 1.2m

  • Top and bottom flange width = 1.0m

  • Top and bottom flange thickness = 0.1m

  • Web thickness = 0.1m

  • Applied load at midspan = 100kN

  • Modulus of elasticity, E = 33000000 kN/m2

  • Span length L = 20m

  • Boundary condition: fixed at both ends

Midspan deflections are calculated as follows:

  • Naked girder, Δ = 0.0018m

  • Composite girder, Δ = 0.00083m

Model overview

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Figure 1 - Model overview

Approaches to modeling composite behavior

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Figure 2 - Modeling composite behavior

Fixed-beam model

The eight approaches to modeling composite behavior, described above, are applied using eight different beam models which are fixed at either end. Results are summarized as follows:

Beam Designation

Behavior

Midspan Deflection
[mm]

Comments

Theoretical Beam

composite

0.8181

Theoretical deflection is based on the PL^3/192EI formulation. Please note that SAP2000 calculations produce slightly greater values because shear deformation is considered in deflection.

Beam 1
(top beam)

nocomposite

1.7938

The deck-slab center line coincides with the section neutral axis. Therefore, the deck-slab contribution to section flexural stiffness will be negligible. Further, because there is no composite action, midspan deflection should be close to that of a naked girder.

Beam 2

composite

0.8313

In this model, slab shell objects are drawn at the girder center of gravity (COG), and then offset vertically, above the girder, to model composite action. The shells are offset such that the slab soffit is located above the girder top flange.

Beam 3

composite

0.8313

In this model, the girder and the slab are drawn at their respective center-lines. The corresponding girder and slab joints are then connected through body constraints.

Beam 4

composite

0.8313

In this model, composite action is modeled using frame insertion points.

Beam 5

noncompostite

1.7938

Equal constraints are used to model noncomposite behavior.

Beam 6

noncomposite

1.7938

Links are used to model noncomposite behavior.

Beam 7

partially composite

1.0302

Links are used to model partially composite behavior.

Beam 8
(bottom beam)

composite

0.8313

Links are used to model composite behavior.

As implied by the list above, the composite action of a beam-slab assembly may be modeled using either area offsets, body constraints, frame insertion points, or links.

Simply supported beam model

The eight approaches to composite-behavior modeling, described above, are applied using eight different simply supported beam models. Results are summarized as follows:

Beam Designation

Behavior

Midspan Deflection
[mm]

Comments

Theoretical Beam

composite

3.2725

Theoretical deflection is based on the PL^3/48EI formulation. Please note that SAP2000 calculations produce slightly greater values because shear deformation is considered in deflection.

Beam 1
(top beam)

nocomposite

7.1752

The deck-slab center line coincides with the section neutral axis. Therefore, the deck-slab contribution to section flexural stiffness will be negligible. Further, because there is no composite action, midspan deflection should be close to that of a naked girder.

Beam 2

composite

3.2624

In this model, slab shell objects are drawn at the girder center of gravity (COG), and then offset vertically, above the girder, to model composite action. The shells are offset such that the slab soffit is located above the girder top flange.

Beam 3

composite

3.2624

In this model, the girder and the slab are drawn at their respective center-lines. The corresponding girder and slab joints are then connected through body constraints.

Beam 4

composite

3.2624

In this model, composite action is modeled using frame insertion points.

Beam 5

noncompostite

7.1752

Equal constraints are used to model noncomposite behavior.

Beam 6

noncomposite

7.1752

Links are used to model noncomposite behavior.

Beam 7

partially composite

3.5036

Links are used to model partially composite behavior.

Beam 8
(bottom beam)

composite

3.2624

Links are used to model composite behavior.

Attachments

  • Modeling composite behavior in SAP2000.zip (zipped SDB file), which contains:

    • SAP2000 V12.0.0 file which demonstrates the modeling of composite behavior for eight fixed beams.

    • SAP2000 V12.0.0 file which demonstrates the modeling of composite behavior for eight simply supported beams.

    • Sketches which illustrate the modeling of composite, noncomposite, and partially composite behavior.

Metadata

  • Name: Composite section

  • Description: Several approaches to the modeling of composite sections.

  • Program: SAP2000

  • Program Version: 12.0.0

  • Model ID: na

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NOTE: The attached file, Modeling composite behavior in SAP2000.zip, may be emailed directly to users to answer support questions.