Engineering Analysis and Simulation

We support customers to verify and optimize products through advanced analysis techniques such as FEA and CFD.

FINITE ELEMENT ANALYSIS (FEA):

Following are the analysis types our team can support:

• Linear Stress Analysis, Stress and Deformation prediction
• Design optimization for weight and structural integrity
• Non-linear Stress Analysis – Contact, Material non-linearity (Plasticity, Hyper-elasticity), Geometric non-linearity
• Gasket Analysis, Sealing, analysis of bolted joints
• Steady state and Transient Thermal Analysis
• Thermal-structural analysis
• High Cycle and Low Cycle Fatigue (durability) Calculations
• Natural Frequency Prediction through modal analysis
• Forced Response Analysis - Harmonic, random excitation (PSD)
• Transient Dynamic Analysis (Shock load analysis)
• Seismic Analysis
• Coupled field analysis
• Piping Stress Analysis

COMPUTATIONAL FLUID DYNAMICS (CFD) ANALYSIS:

Following are the analysis types our team can support:

• Analysis of pressure drop, flow velocities and velocity vectors for complex systems
• Flow optimization to reduce restriction, recirculation and dead zones
• Conjugate heat transfer analysis for simultaneous prediction of temperature in fluid and structures for components such as heat exchangers
• Performance map prediction and optimization of rotating machines such as fans, blowers, pumps, compressors and turbines
• Transient simulations for rotating and sliding geometries
• Modeling of sprays, Multi-phase analysis (cavitation, mixing etc)
• Simulation of sloshing using free surface modeling
• Simulation of mixing of multiple fluid streams
• Cooling simulations for electronic circuits, simulation of battery cooling
• Flow and heat transfer simulation of electrical machines such as motors and alternators
• Room ventilation studies
• External Aero-dynamic simulations for vehicles
• Drag load prediction on telecommunication towers

DYNAMICS ANALYSES:

• Creation of complex power train and drive train models for engine, steam turbine and gas turbines for rotor dynamic / torsional vibration analysis (TVA)
• Idealization of gear box, hydrodynamic bearings and flexible couplings
• Estimation of torsional and lateral bending natural frequencies
• Identification of critical 4DI using Campbell diagram
• Backward and Forward whirl prediction
• Coupling selection assessment
• Forced Response Analysis of turbine and alternator rotors under the action of harmonic excitations such as rotor unbalance and unbalanced magnetic pull
• Prediction of dynamic response at bearings
• Transient Response Analysis for the power train under steady state torque condition (such as at start-up) and fault torque condition (electric short-circuit torque) to assess torque and torsional shear stress at various sections
• Bolted joint assessment for torque capability