STRUCTURAL ANALYSIS

We provide advanced structural analysis services that help maintain resilient, efficient and safe structural systems — from industrial facilities and process plants to civil and infrastructure projects. Our engineers apply structural simulation and analytical tools to enhance structural performance, optimize structural integrity

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Our Structural Analysis Capabilities

Linear & Non-Linear Analysis. Assessment of structural behaviour under different load conditions, including plasticity and geometric non-linearity.

Static & Transient Load Simulation. Evaluation of performance under steady and time-dependent forces, vibrations and impacts.

Stress, Modal & Frequency Response. Identification of stress concentrations, modal frequencies and vibration characteristics to ensure operational safety.

Dynamic Response & Fatigue. Prediction of long-term durability and resistance to cyclic or dynamic loads.

Turbomachinery & Equipment Analysis. Analysis of rotating machinery, foundations and support systems to minimise vibration and resonance risks.

About Structural Analysis

Static and Dynamic Analysis

Structural analysis allows us to understand how a structure behaves under various operational and extreme conditions. Using Finite Element Analysis (FEA) and Digital Twin technologies, our engineers simulate real-world performance based on detailed 3D models that include geometry, material properties and boundary conditions.

At this stage, stresses and deformations in structural elements are calculated under different load conditions. Key analytical methods include:

  • Mechanics of materials – for the design of beams, slabs, and columns
  • Structural mechanics – for assessing global stability and load paths
  • Software modelling and finite element analysis (FEA) using programs such as SAP2000, ANSYS, SCAD

Methods of Building Calculation


Several analytical approaches are used in engineering practice:

  • Analytical methods – based on mathematical models and theoretical formulations.
  • Numerical methods – such as the Finite Element Method (FEM), suitable for analysing complex geometries and load combinations.
  • Experimental methods – physical testing of scaled models or full-scale structural components.


Benefits for Your Project

Main Stages of Building Calculation

Determining Loads
Before beginning the design process, all potential loads acting on the building must be identified and assessed:

  • Permanent loads – the self-weight of structural components such as foundations, walls, floors, and roofs.
  • Variable loads – furniture, occupants, equipment, snow, and live loads from vehicles or machinery.
  • Dynamic loads – wind pressure, seismic activity, vibration, and other transient forces.

Building Calculation Software


Modern engineering software allows accurate modelling of structures, load simulation, and optimisation of design parameters:

  • AutoCAD, Tekla Structures, Revit – for 2D/3D modelling and drawing production.
  • SCAD, STAAD – for static and dynamic structural analysis.
  • ANSYS, Abaqus, Dlubal RFEM – for advanced finite element and nonlinear analysis.

Building design and calculation is a complex engineering process that requires careful consideration of multiple factors including loads, materials, environmental conditions, and regulatory standards. Accurate structural calculations are essential to ensure the safety, durability, and cost-effectiveness of any construction project

Selecting Building Materials
Material selection must balance strength, durability, and economic efficiency. Common structural materials include:

  • Concrete and reinforced concrete – for primary load-bearing elements.
  • Brickwork – for walls, partitions, and façades.
  • Steel – for framing, floor systems, and industrial structures.
  • Timber – for low-rise buildings and sustainable residential construction

Foundation Design and Calculation
The foundation is the structural base of the building. It’s design includes:

  • Soil investigation and determination of bearing capacity.
  • Selection of foundation type (strip, pile, raft/slab).
  • Calculation of depth, settlement, and load-transfer capacity.

Stability and Safety Verification
A crucial stage is verifying the overall stability, safety, and serviceability of the structure:

  • Deflection and deformation control to prevent cracking or structural failure.
  • Seismic resistance assessment in earthquake-prone regions.
  • Fire resistance analysis for compliance with fire safety standards.