Our Analytic Solutions for a Better Results
Structural Analysis
Structural Analysis
Structural Analysis
- Linear Static Analysis
Calculates stresses, strains, and displacements under constant and small loads, assuming linear material behavior.
- Nonlinear Static Analysis
Includes material nonlinearity (plasticity, hyperelasticity), large deformations, and contact conditions.
- Buckling Analysis
Predicts the critical load at which a structure becomes unstable and deforms suddenly (e.g., columns under compression).
- Dynamic Analysis
Modal Analysis
Harmonic Response Analysis
Transient Dynamic Analysis
Response Spectrum Analysis
Thermal Analysis
Structural Analysis
Structural Analysis
- Steady-State Thermal Analysis
Calculates temperature distribution under constant thermal conditions.
- Transient Thermal Analysis
Evaluates how temperature changes over time due to time-dependent heat sources.
- Thermal Stress Analysis
Combines temperature results with structural analysis to predict thermal-induced stresses and deformations.
Moldflow Analysis
Structural Analysis
Moldflow Analysis
- Filling Analysis
Predict how molten plastic flows through the mold cavity. Identify short shots, air traps, weld lines, and potential hesitation areas.
- Packing & Holding Analysis
Optimize packing pressure and time to reduce sink marks and ensure uniform density.
- Cooling Analysis
Simulate cooling channel design and temperature distribution to minimize cycle time and warpage.
- Warp Analysis
Predict part deformation due to residual stress, shrinkage, or asymmetric cooling — critical for tight-tolerance applications.
- Fiber Orientation Analysis (for fiber-reinforced plastics)
Evaluate the directional behavior of fibers to predict anisotropic mechanical performance and improve part strength.
Fatigue Analysis
Time-Dependent Analysis
Moldflow Analysis
Predicts the life expectancy of components under cyclic loading.
- High-Cycle Fatigue: For loads with low stress but high number of cycles.
- Low-Cycle Fatigue: For high-stress levels over fewer cycles.
Time-Dependent Analysis
Time-Dependent Analysis
Time-Dependent Analysis
- Creep Analysis: Simulates time-dependent plastic deformation under sustained load at elevated temperatures.
- Viscoelastic Analysis: Used for polymers or rubbers that exhibit both elastic and viscous behavior over time.
Others
Time-Dependent Analysis
Time-Dependent Analysis
- Thermal Shock
- Electro-thermal
- Electromechanical
- Contact Analysis
- Fluid-Structure Interaction (FSI)