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RF-/FE-LTB Add-on Module for RFEM/RSTAB
Lateral-Torsional Buckling Analysis of Members According to Second-Order Analysis (FEA)
The RF-/FE-LTB add‑on module is used to detach planar substructures from spatial RFEM/RSTAB models to calculate them according to the second‑order analysis for torsional buckling considering warping. Geometry, support and load data are imported to RF‑/FE‑LTB automatically. Subsequent to the calculation, the module displays deformations, internal and support forces as well as stresses. Since the warping torsion is taken into account as well, the program displays also the results of bimoment distribution and the diagrams of primary and secondary torsion.
No other technical literature is necessary because the required tables, buckling curves, and properties of corrugated sheets are already included in the program. For example, the entire methodical approach for determining rotational restraints according to DIN 18800 is implemented in the RF‑/FE‑LTB add‑on module.
- Full integration in RFEM/RSTAB including import of all relevant loads
- General stress analysis with warping torsion according to elastic/elastic method
- Stability analysis of planar continuous members for buckling and lateral torsional buckling
- Determination of critical load factor and thus of Mcr or Ncr (the factor can be used in RF-/LTB for the el/pl design)
- Lateral torsional buckling analysis of any cross-section (also the SHAPE-THIN cross-sections)
- Design of members and sets of members with applied torsion (e.g. crane girder)
- Optional determination of the limit load factor (critical load factor)
- Display of eigenmodes and torsional modes on the rendered cross-section
- Wide range of tools for determining shear panels and rotational restraints (such as corrugated sheets, purlins, bracings)
- Easy determination of discrete springs such as warp springs from end plates or rotational springs from columns
- Graphical selection of load application points on a cross-section (upper chord, centroid, lower chord or any other point)
- Free arrangement of eccentric nodal and line supports on a cross-section
- Determination of value for inclination or precamber by means of eigenvalue analysis
- Special warping releases applicable for definition of warping conditions on transitions
After entering the model in RFEM/RSTAB, it is possible to open RF-/FE-LTB the add-on module where you can define sets of members and load cases or combination to be designed in a design case.
The sets of members can be selected graphically as well. The materials and cross-sections used in RFEM/RSTAB are already preset but can always be modified, if necessary. For this, there are an extensive libraries available.
Comprehensive and easy options in the individual input windows facilitate the representation of the structural system:
- Support type of each node is editable.
- It is possible to define a warp stiffening on each node. The resulting warp spring is determined automatically using the input parameters.
Elastic Member Foundations
- In the case of elastic member foundations, you can manually enter spring constants.
- Alternatively, you can use various setting options to define the rotational and translational spring from shear panel.
Member End Springs
- RF-/FE-LTB calculates the individual spring constants automatically. You can use the dialog boxes and detailed pictures to represent a translational spring by connecting components, a rotational spring by a connecting column, or a warping restraint (available types: end plate, channel section, angle, connecting column, cantilevered portion).
- If there are no member hinges defined in RFEM/RSTAB for the set of members, you can define them directly in the RF-/FE-LTB add-on module.
- The nodal and member loads of the selected load cases and combinations are displayed in separate windows where you can edit, delete or complete them individually.
- RF-/FE-LTB automatically applies the imperfections by scaling the lowest eigenvector.
In accordance with DIN 18800, Part 2, the designs are carried out separately for flexural buckling and lateral torsional buckling to simplify the calculation. Generally, the flexural buckling design is performed in the framework plane by using the stress analysis of the planar structure according to the second-order analysis, considering design loads and pre-deformations.
The lateral torsional buckling design is performed on an individual member detached from the entire structure by using defined boundary conditions and loads in accordance with the elastic-elastic method.
RF-/FE-LTB searches for the governing failure mode by means of the critical load factor which describes flexural, torsional, and lateral-torsional buckling, or the combination of all failure modes, depending on the model and load applied. Then, the module performs recalculation to obtain the required operands.
Detail settings control whether the critical load factor is calculated due to loss of stability (providing the material is defined by infinitely elastic properties), or with stress limitation.
If necessary, you can modify the lengths of finite elements. You can also adjust the partial safety factor γM. In RF-/FE-LTB, iteration parameters are preset appropriately to calculate all common models but can be adjusted individually.
After the calculation, the deformations, internal forces, support forces, and stresses are displayed. Since the module considers warping torsion, the diagrams of the warping bimoment as well as of the primary and the secondary torsional moment are also available. Stability analysis uses the imperfections during the calculation and determines the critical load factors which can be used to determine Mcr and Ncr.
In addition to the result values in tables, the corresponding cross-section graphic is shown. In RFEM/RSTAB, various results are highlighted in different colors on the member model. You can modify the colors and values assigned.
Result diagrams of a set of members provide targeted evaluation. It is also possible to represent all intermediate values. You can export all tables to OpenOffice.org Calc, MS Excel, or in a CSV file. A dialog box includes the necessary export data.
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PRICE for RFEM (VAT excluded)
PRICE for RSTAB (VAT excluded)
1.1 General Data
1.4 Nodal Supports
1.4 Edit Warp Spring
1.5 Elastic Member Foundations
1.6 Member End Springs
1.7 Member Hinges
2.1 Nodal Loads
2.2 Member Loads
2.3 Imperfection - Calculate Value
3.1 Stresses by Cross-Section
3.5 Internal Forces
3.7 Support Reaction Forces
3.8 Critical Load Factors
Result Diagram on Member
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