Vuoi provare il metodo BIM applicato alla progettazione delle strutture in cemeto armato con Allplan Engineering?
Questo corso di formazione online ti offre la possibilità di farlo con l'assistenza 'step by step' dei nostri esperti. Grazie a questo corso base di formazione, puoi creare tu stesso un progetto con le carpenterie e le armature di una platea e di un vano scala e potrai verificare la semplicità di utilizzo di Allplan Engineering.

Welcome to the SCIA section, where you will be introduced to SCIA Engineer and guided to key sources of important information.

This webinar illustrates the Moving Loads functionality in SCIA Engineer.

When structures must withstand moving or shifting loads—such as traffic on bridges, cranes in industrial facilities or crowds on slabs—structural engineers face the daunting challenge of managing an overwhelming number of load combinations. Evaluating all these scenarios is not only extremely time‑consuming, it also increases the risk of overlooking critical worst‑case situations, which can result in over‑designed or unsafe structures. The Moving Loads functionality in SCIA Engineer 2026 is designed to cut through this complexity. Using the proven principles of influence lines and surfaces, it automatically identifies the most critical positions of moving load systems before calculations even start. This lets you focus your analysis and post‑processing on the truly governing cases, instead of sifting through countless non‑critical combinations. With the new Moving Loads in SCIA Engineer 2026, you can be confident that your structure is checked against its most demanding real‑world scenarios—quickly, efficiently and with precision.

This webinar illustrates the Footfall Analysis functionality in SCIA Engineer.

Many engineers face significant challenges when designing buildings with large open spaces, lightweight floors, or areas housing sensitive equipment. Vibrations caused by everyday human activities—like walking, running, or crowd movement—can lead to occupant discomfort, dissatisfied clients, or even operational problems for sensitive equipment. Footfall analysis allows engineers to evaluate how the structure responds to these human-induced vibrations. With the insights gained from this analysis, engineers can adjust the structural design early in the project to keep vibrations within acceptable limits, ensuring occupants’ comfort and protecting sensitive equipment. This proactive approach helps avoid costly modifications after construction that might otherwise be required to address unsatisfactory structural performance.

This webinar illustrates the finite beam element that can account for an additional degree of freedom (warping) in SCIA Engineer.

Designing slender, thin-walled, or open-section beams presents structural engineers with tough challenges. Traditional beam theories often fall short when confronted with complex torsional loads, non-uniform cross-sectional deformations, or warping effects. As projects become more ambitious, the consequences of overlooking these complex behaviors can be significant: inaccurate stress predictions, unexpected failures, and costly design revisions late in the process. SCIA Engineer 2026 introduces a new type of finite beam element that can account for an additional degree of freedom (warping). It allows for accurate modelling of slender or thin-walled beams, open-section beams, and structures subjected to significant torsion or complex loading. This approach is important especially for bridges, steel girders, or structures with non-standard cross-sections, where warping and distortional effects play a significant role in the structural response. As a result, engineers get more accurate predictions of stresses and deformations in cases where traditional beam elements are inadequate.

Welcome to the FRILO course. This program introduces you to FRILO’s structural analysis and design solutions, which support engineers in calculating, checking, and documenting safe and economical structures in everyday practice.

The training is designed to guide you through the modeling process for an parametrical 3D Prestressed concrete bridge model using Allplan Bridge and using Allplan Engineering for further detailing of the bridge. The used example is a hollow box concrete girder bridge with three spans. The length of the bridge is 80 meters, and the span lengths are 25, 30 and 25 meters. The bridge has two piers with variable dimensions along the height of 10 meters. The bridge axis is curved in plan and in elevation.

This tutorial describes the basic functions of SCIA Engineer for the input, analysis and design of a 3D concrete structure with 1D and 2D elements. 

Before you start, you must be familiar with your operating system: for instance working with dialogues, menu bars, toolbars, status bars, handling the mouse, etc. 

First, we will explain how to create a new project and how to setup your structure. 

After the geometry and load input, the structure will be calculated and the results can be viewed. 

Next, we will discuss the concrete settings and we will perform the concrete design for 1D and 2D elements. 

The tutorial ends with a brief introduction to the engineering report.

This tutorial describes the basic functions of SCIA Engineer for the input, analysis and design of a 3D steel hall structure. 

Before you start, you must be familiar with your operating system: for instance working with dialogues, menu bars, toolbars, status bars, handling the mouse, etc. 

First, we will explain how to create a new project and how to setup your structure. 

After the geometry and load input, the structure will be calculated and the results can be viewed. 

Next, we will discuss the steel code check according AISC 360-22 and we will create a simple steel connection. 

The tutorial ends with a brief introduction to the engineering report.

Dive into ALLPLAN's dynamic structural engineering course! Learn key skills, from crafting 3D models to seamless modifications. Discover creating sections, views, and automatic 3D reinforcement - all while ensuring BIM compliance. Elevate designs with real-time updates through linked documents like steel and bending lists.

Course modules:

It's that simple!
Creating the 3D building model
Modification made easy ...
Completion of the 3D building model
Evaluation
Compile and output the plan
Reinforcement
Project backup

ALLPLAN Excavation Pit is a powerful module for foundation engineering. Its intuitive functions allow users to quickly learn the basic functions. Users can easily create precise excavations by designing excavation elements according to individual requirements. The excavation offers the flexibility to easily define slope angles to achieve optimal results. With its user-friendly interface, ALLPLAN Excavation supports efficient working and thus contributes significantly to the successful realisation of construction projects.

V rámci tohoto e-learning kurzu, si můžete bezplatně projít všechny záznamy našich webinářů. Přesvědčte se sami o tom, co Vám přinesou...