Search Result
19 result(s) for " AEF"
CO2 Emissions
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003601
Converting Scripts into Blocks
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003595
Cost Optimization
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003600
Costs
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003599
Creating New Model and Activating Add-on
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003506
Creating Scripting
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003596
Defining Global Parameters
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003510
Defining Members
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003531
Defining Nodal Supports
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003532
Defining Optimization Settings
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003535
Defining Type of Global Parameter
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003534
Estimation of Costs and CO2 Emissions
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003591
Modeling Truss
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003503
Optimization of Parameters
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003505
Optimization Results
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003536
Parameterizing Model
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003504
Scripting in RFEM 6
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003577
Using Blocks Created with Scripting
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003597
Using Parameters in Formulas
/en/downloads-and-information/documents/online-manuals/rfem-6-model-optimization-using-artificial-intelligence-in-rfem-6/003533
Length: 00:31:17 min
Length: 01:08:12 min
Length: 00:02:14 min
Product Feature
Length: 00:00:34 min
Product Feature
Length: 00:00:41 min
Product Feature
Length: 00:00:49 min
Length: 00:58:00 min
Length: 00:24:11 min
Length: 01:04:39 min
In this article, you will learn how to model and design cable structures in RFEM 6 or RSTAB 9.
This article describes and explains the influence of bending stiffness of cables on their internal forces. Furthermore, the text provides information on how this influence can be reduced.
The ASCE 7-22 Standard [1], Sect. 12.9.1.6 specifies when P-delta effects should be considered when running a modal response spectrum analysis for seismic design. In the NBC 2020 [2], Sent. 4.1.8.3.8.c gives only a short requirement that sway effects due to the interaction of gravity loads with the deformed structure should be considered. Therefore, there may be situations where second-order effects, also known as P-delta, must be considered when carrying out a seismic analysis.
The data exchange between RFEM 6 and Allplan can be done using various file formats. This article describes the data exchange of a determined surface reinforcement using the ASF interface. This allows you to display the RFEM reinforcement values as level curves or colored reinforcement images in Allplan.
.png?mw=350&hash=1e465b4d2779430fcc688d549d871dda4c4b2f76)
The material library of RFEM and RSTAB includes the timber materials according to the American standard ANSI/AWC NDS‑2024.
In addition to JavaScript, the Python high-level functions are also available in the console. Using the Python option, the console also provides you with the Python HLF functions known from the WebService function catalog for further use in the object properties dialog box for in-app scripting.
Get a better understanding of the stress distribution within member cross-sections by using clipping planes.
In RFEM, the oriented strand board (OSB) material is available for the USA and Canada. The material parameters are taken from the "Panel Design Specification manual".
Does RFEM 5 have a surface contact?
How is the axial offset from the adjoining member modeled?
I would like to start my calculation in cloud. However, I get the error message "File upload has failed with the error SSL handshake failed." What is the problem?
How can I use an RSECTION cross-section when exporting a model from Revit to RFEM 6?
How can I reduce the calculation time for members with a nonlinear material model in RFEM 6 and RSTAB 9?
Why are the stresses of the structural analysis different from those calculated with the Stress-Strain Analysis add-on?
