Computational Fluid Dynamics

Simulate multiphase fluid flow and heat transfer problems to optimise system performance.

Heating, ventilation and air conditioning (HVAC)

Cost-effective, iterative design methodology

Test multiple scenarios to optimise the system design

Improve energy efficiency

Improve comfort/system quality

Data centre cooling

Vehicular environments

External aerodynamics

Drag reduction

Flow analysis over a aerofoil

Virtual wind tunnel testing

Influence of vortex and turbulent flow

Wind power industry


Thermal Analysis & Heat Transfer​

Conduction, convection and radiation through solid and fluid bodies

Natural, forced and mixed convection

Electronics cooling and heat dissipation

Analyse complex geometry and non-homogenous materials

Increase product efficiency

Heat exchangers

Rotating equipment/turbomachinery

Advanced turbulent models

Real gas properties and multiphase effects, such as cavitation

Improve design performance and reduce running costs

Pressure rise generated by centrifugal compressor

Visualise velocity and pressure profiles

Multiphase processing equipment

Predict separator performance

Cyclonic devices


Estimate gas bubble carry-under, liquid droplet carry-over and overall separation performance

Fluid-structures interaction

Mixing tanks

Wind loading

Steady state and transient

Aerodynamic effect on slender structures

Fluid-structures interactions

Fatigue analysis

Outdoor structures

Gas dispersion analysis

Flow assurance

Minimise loss of production

Optimise injection points

Analyse complex flow problems

Analyse slugging

Optimise flow parameters

Erosion analysis

Sand erosion

Liquid droplet erosion

Cavitation bubbles

Satisfy regulatory codes such as DNV RP 0501

Two stage coupling: flow equations and discrete phase model (DPM) to calculate sand particle trajectory

Learn how to assess fatigue lifetime using FEA

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