Overview of PraVaHa Software

Context:

The Indian Space Research Organisation (ISRO) recently developed Computational Fluid Dynamics (CFD) software named PraVaHa.

Relevance:

Facts for Prelims

Dimensions of the Article:

1. Overview of PraVaHa Software
2. CFD’s Role in Aerospace

Overview of PraVaHa Software

What is PraVaHa Software?

• Full Name: Parallel RANS Solver for Aerospace Vehicle Aero-thermo-dynamic Analysis (PraVaHa).
• Developed By: ISRO’s Vikram Sarabhai Space Centre (VSSC).
• Type: Computational Fluid Dynamics (CFD) software.
• Capabilities: Simulates external and internal flows on launch vehicles, including both winged and non-winged re-entry vehicles.

Key Features and Applications:

• Extensive Use: Utilized in the Gaganyaan program for aerodynamic analysis of human-rated launch vehicles, such as HLVM3, Crew Escape System (CES), and Crew Module (CM).
• Collaboration: Secure and flexible for collaborative development with academic institutions and government labs.
• Operational Status: Currently operational for simulating airflow under Perfect Gas and Real Gas conditions.
• Future Enhancements: Undergoing validations to simulate chemical reactions during air dissociation upon ‘earth re-entry’ and ‘combustion’ in scramjet vehicles.
• Replacement Potential: Expected to replace most CFD simulations for aero characterisation currently done using commercial software.
• Educational and Research Utility: Aids academia and other institutions in designing missiles, aircraft, and rockets to solve complex aerodynamic problems.

Importance of Computational Fluid Dynamics (CFD):

• Design Studies: Initial aerodynamic design studies for launch vehicles require evaluating numerous configurations.
• Aerodynamic and Aerothermal Loads: Aerospace vehicles during launch or re-entry face severe aerodynamic and aerothermal loads in terms of external pressure and heat flux.
• Airflow Understanding: Essential to understand airflow around aircraft, rocket bodies, or Crew Modules (CM) during earth re-entry to design the necessary shape, structure, and Thermal Protection System (TPS).
• Unsteady Aerodynamics: Contributes to significant flow issues around rocket bodies, generating substantial acoustic noise during missions.
• Predictive Tool: CFD predicts aerodynamic and aerothermal loads by numerically solving the equations of conservation of mass, momentum, and energy, along with the equation of state.

Importance and Benefits

PraVaHa’s Impact:

• Advanced Simulations: Enables advanced and accurate simulations crucial for the design and analysis of modern aerospace vehicles.
• Collaborative Development: Its secure and flexible nature supports collaborative projects between academic and governmental research institutions.
• Cost-Effective: Potentially reduces dependency on expensive commercial CFD software by providing an in-house alternative.

CFD’s Role in Aerospace:

• Design Optimization: Critical in optimizing the design and safety of aerospace vehicles.
• Performance Prediction: Helps in predicting vehicle performance under various atmospheric conditions, ensuring mission success.
• Research and Innovation: Facilitates research and innovation in aerodynamics, contributing to advancements in aerospace technology.

-Source: The Hindu