At Intrigon LLC, we harness the power of multi-physics modeling to tackle intricate engineering challenges. Our approach integrates various physical phenomena to provide accurate simulations that inform your design decisions. By predicting interactions between mechanical, thermal, and fluid dynamics, we enable you to visualize outcomes and optimize your product development process.
Car Wind-Tunnel Model
Problem statement: Optimize a vehicle design to reduce aerodynamic drag and weight, while ensuring safety features and design constraints are met.
Solution outline: Use Computational Fluid Dynamics (CFD) to simulate airflow and evaluate drag across design iterations. Combine with structural modeling to assess weight and safety compliance. Apply multi-objective optimization algorithms to balance drag reduction, weight minimization, and safety/design requirements.
Thermal Vaporization Model
Problem statement: Identify cold spots in a thermal evaporator and optimize heater placement to achieve uniform temperature distribution.
Solution outline: Use thermal modeling to identify cold spots and evaluate heater performance. Optimize heater placement and power levels to ensure uniform temperature distribution, meeting specifications.
Flow in Transitional Vacuum Systems Using Coupled Flow and Radiation Analysis
​​Problem statement: Estimate pressure drop and flow velocities of a vapor plume transitioning from molecular to viscous flow in a vacuum, incorporating a coupled photon model to capture vapor dynamics. This behavior is key in processes like evaporation, deposition, and exhaust plumes in low-pressure systems.
Solution outline: Simulate the vapor plume transition using a multi-phase flow model to capture pressure drop and flow velocities. Integrate a photon model for the molecular flow regime, and validate with experimental or computational data to ensure accuracy in low-pressure systems.