Interesting customer projects designed with the structural analysis programs by Dlubal Software.
RF-GLASS Add-on Module for RFEM
“The RFEM platform is the most efficient and friendly with which we have worked, the RF‑GLASS module is really unique in the market with which we can solve our projects in an integral way.
The technical support is incomparable, having immediate assistance from Germany to Costa Rica at the time required, despite the time difference, is a great proof of their professionalism and passion.”
Design of Single-Layer, Laminated, and Insulating Glass
The RF-GLASS program is integrated into the RFEM user interface as an optional add‑on module. RF‑GLASS analyzes deformations and stresses of arbitrary shaped and curved glass surfaces.
Two different calculation methods are available in RF‑GLASS:
- Local calculation of individual glass surfaces, without regard to the surrounding structure
- Global calculation of the entire structure, with regard to interactions among glass surfaces and the surrounding structure
It is possible to create all glazing types in the module; this means not only single layer glass, but also laminated and insulating glass.
RF‑GLASS provides an extensive material library including all common types of glass, foil, and gas. The calculation is performed according to the following standards:
- DIN 18008:2010-12
- Code independent (analysis only)
- Design of single‑layer or laminated glass as well as insulating glass with intermediate gas layer
- Design of curved glass
- Option to select either local calculation without regard to the influence of a surrounding structure, or global calculation with regard to the influence of an entire structure
- Limit stress analysis according to DIN 18008:2010-12 or TRLV:2006-08
- Assignment of loads to load duration classes
- Extensive material library including all common glass, foil, and gas types in compliance with the DIN 18008:2010-12, E DIN EN 13474 standards, and the TRLV:2006-08 regulation
- Optional consideration of shear coupling of layers
- Consideration of climatic loads
- Calculation according to the linear static analysis or nonlinear analysis according to the large deformation theory
- Stress analysis, the ultimate limit state design, the serviceability limit state design
- Graphical representation of all results in RFEM
- Possibility to filter results and color scales in result tables
- Direct data export to MS Excel
First of all, you have to select the surfaces for design (using the select function). The geometry of a glass pane and loads are imported from the RFEM model.
Then, it is necessary to decide whether the calculation should proceed without influence of the surrounding structure (local calculation) or considering this influence (global calculation). If you select the local calculation, each surface selected for the design is detached from the model and calculated separately.
The global calculation considers the entire structure including entered glass panes. All glass composition data and glass properties of individual layers are to be defined in RF-GLASS input windows. You can select the layers of type glass, foil, and gas. It is possible to transfer the respective material directly from the library covering a large number of materials.
All parameters of individual layers including their thicknesses are editable. In addition, you can create a number of various compositions in RF-GLASS, which allows you to design different types of glass together.
For insulating glass, you can consider external loads as well as loads due to temperature, atmospheric pressure, and altitude changes for the analysis. The module calculates these loads automatically on the basis of climatic load parameters. If you select the local calculation type, it is necessary to define line supports, nodal supports, and boundary members of the surfaces in RF-GLASS. These supports and members are considered in RF-GLASS only and have no influence on the model created in RFEM.
The global calculation assigns the stiffness determined by means of the selected composition and the glass geometry to each surface. Then, the calculation proceeds using the plate theory. It is possible to select whether the shear coupling of layers should be considered.
In the case of the local calculation, you can further specify 2D or 3D calculation. The 2D calculation means that single layer or laminated glass is modeled as a surface and the calculation of its thickness (using the plate theory) is based on the selected composition and glass geometry. Similarly to the global calculation, you can optionally consider shear coupling of layers.
The 3D calculation uses solids in the model to substitute each composition layer. In this way, results are more accurate but the calculation may take more time.
It is possible to model insulating glass only if local calculation is selected. The gas layer is always modeled as a solid element, so it is necessary to design individual insulation glasses separately from the surrounding structure. The calculation applies the ideal gas law (thermal equation of state of ideal gases) and the large deformation analysis.
After the calculation, results are displayed in clearly arranged result windows. Thus, you can easily find the maximum stress ratio. The stress diagram by composition is displayed as well.
Moreover, RF-GLASS shows the parts list and the gas pressure of insulating glass. It is possible to display the results graphically in the RFEM model.
Both input and result tables of RF-GLASS including graphics can be added to the RFEM printout report. In addition, it is also possible to export all tables to MS Excel.
Do you have any questions about our products or need advice on selecting the products needed for your projects?
Contact us via our free e-mail, chat, or forum support or find various suggested solutions and useful tips on our FAQ page.
Customers who bought this product also bought
Structural engineering software for finite element analysis (FEA) of planar and spatial structural systems consisting of plates, walls, shells, members (beams), solids and contact elements
Stress analysis of steel surfaces and members
Design of steel members according to Eurocode 3
Design of reinforced concrete members and surfaces (plates, walls, planar structures, shells)
Module Extension for RFEM
Extension of the modules for reinforced concrete design by the Eurocode 2 design
Stability analysis according to the eigenvalue method
Dynamic analysis of natural frequencies and mode shapes of member, surface, and solid models
Consideration of nonlinear material laws
Generation of equivalent geometric imperfections and pre-deformed initial structures for nonlinear calculations
Design of aluminum members according to Eurocode 9
Seismic and static load analysis using the multi-modal response spectrum analysis
Timber design according to Eurocode 5, SIA 265 and/or DIN 1052
Reinforced concrete design according to the model column method (method based on nominal curvature)
Physical and geometrical nonlinear calculation of beam and plate structures consisting of reinforced concrete
Module Extension for RF-STEEL EC3 and RF-STEEL AISC
Warping torsion analysis according to the second-order theory with 7 degrees of freedom
Punching shear design of foundations and slabs with nodal and line supports
Analytical deformation analysis of plate structures consisting of reinforced concrete
Design of single, bucket and block foundations
Soil-structure interaction analysis and determination of elastic foundation coefficients based on soil data
Dynamic and seismic analysis including time history analysis and multi-modal response spectrum analysis