After generating the effective lengths, the results are displayed in clearly arranged tables. You can modify the effective lengths manually there.
The Export function transfers the effective lengths to the RF-/TOWER Design add-on module for further calculation. The complete module data are part of the RFEM/RSTAB printout report. The report contents and the extent of the results can be selected specifically for the individual designs.
Finally, it is possible to export the generated model to RFEM/RSTAB with a single mouse click.
The complete module data are part of the RFEM/RSTAB printout report. The report contents and the extent of the results can be selected specifically for the individual designs.
The results are displayed in clearly arranged module windows. In addition to the design data, the results include all design-relevant parameters. A parts list is generated automatically during the calculation.
The complete module data are part of the RFEM/RSTAB printout report. The report contents and the extent of the results can be selected specifically for the individual designs.
When performing the design of tension, compression, bending, and shear loading, the module compares the design values of the maximum load capacity to the design values of the actions. If the components are subjected to both bending and compression, the program performs an interaction. You can determine the factors according to Method 1 (Annex A) or Method 2 (Annex B).
The flexural buckling design requires neither the slenderness nor the elastic critical buckling load of the governing buckling case. The module automatically calculates all required factors for the bending stress design value. RF-/TOWER Design determines the effective critical moment for lateral-torsional buckling for each member on every x-location of the cross-section.
Members of triangular and quadrilateral lattice towers are allocated automatically, provided that the lattice tower was generated in the RF-/TOWER Structure and RF-/TOWER Equipment add-on modules.
However, it is also possible to allocate the members manually. In RF-/TOWER Design, you can use the effective lengths of truss members generated in the RF-/TOWER Effective Lengths add-on module. Manual input is also possible.
According to the EN 1993-3-1 and EN 50341 standards, different bracing cases and support types can be specified for the leg members and bracing members.
In the Details dialog box, you can specify nodal restraints of the individual bracing types. For example, intersection points of horizontal and vertical bracings can be defined as being kept perpendicular to the bracing plane.
You can specify the tower type, the number of each type of installed equipment, and the allocated members in the individual categories under General Data. The members of lattice towers previously defined in the RF-/TOWER Structure and/or RF-/TOWER Equipment add-on modules are allocated automatically.
In order to check the overall model graphically, you can use the viewer function. Statically effective equipment can be generated with a single mouse click and exported to RFEM/RSTAB.
All module data are included in the global RFEM/RSTAB printout report.
After generating the lattice tower model, the generated data are displayed in clearly arranged tables. The output includes all specifications for member hinges and effective lengths.
In order to check the data graphically, the Viewer function provides a full-screen display, which is also available in the input windows.
First, it is necessary to select a tower type and the relevant materials and cross-sections. The tower geometry is defined by individual tower segments. Slopes can be defined via widths or relatively by geometry modification.
After entering the tower legs, you can specify various stiffening of the lattice tower. It is possible to enter detailed specifications of horizontal girts, inner bracing, and vertical bracing of a tower with unequal sides. An extensive library including parametrized bracing types facilitates the input.
In addition, there is an interactive graphic in all input windows.
The generated loads can be transferred easily to RFEM/RSTAB in order to superimpose other load cases. All module data is included in the RFEM/RSTAB printout report.
The report contents and the extent of the results can be selected specifically for the individual designs.
After generating the loads, you can check the results in clearly arranged tables. The output includes all information about the generated load cases and loads due to self-weight, wind load, and ice load. All loads are itemized in structural objects and equipment.
The RF-/TOWER Loading add-on module meets the requirements of EN 1991-1-4 / DIN EN 1993-3-1, DIN 1055-4, DIN 4131:1991-11, and DIN V 4131:2008-09. These standards include specifications of dead, wind, maintenance/technician and ice loads (ISO 12494 or DIN 1055-5), as well as variable loads. The standard specifications are preset or available in the libraries.
For the generation of wind loads according to Eurocode, the National Annexes (NA) of the following countries are available:
DIN EN 1991-1-4 (Germany)
CSN EN 1994-1-4 (Czech Republic)
NA to CYS EN 1991-1-4 (Cyprus)
DK EN 1991-1-4 (Denmark)
NBN EN 1991-1-4 (Belgium)
NEN EN 1991-1-4 (Netherlands)
NF EN 1991-1-4 (France)
SFS-EN 1991-1-4 (Finland)
SIST EN 1991-1-4 (Slovenia)
SR EN 1991-1-4 (Romania)
SS EN 1991-1-4 (Singapore)
SS-EN 1991-1-4 (Sweden)
STN EN 1991-1-4 (Slovakia)
UNI EN 1991-1-4 (Italy)
It is possible to generate individual load situations: You can set the wind pressure, wind direction, or ice loads manually, or import them from tables.
You can define platforms, tubular extensions, antenna brackets, antennas, inner ducts, cable ducts, and ladders in separate input windows. Extensive libraries including parameterized models facilitate the entry.
There is an interactive graphic available in all input windows. This way, you can immediately see the position of tower equipment.