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CFD Simulation Sample for Generator Set

Summary

This Computational Fluid Dynamics (CFD) study simulates how heat from a generator set (genset) spreads to a nearby building, looking at temperatures on each floor. The goal is to see if the genset design works well and to check for hot spots that could cause problems.

The study uses real-world conditions like high temperatures and wind direction. By simulating airflow, temperature, and sunlight, the study provides a detailed picture of how the genset’s heat affects the building.

Introduction

This CFD analysis and simulation focuses on evaluating the temperature distribution from the generator genset to the nearest building and across each floor surface. The objective is to assess the performance of the proposed design and study the temperature variations and potential short circuits within the genset. The maximum ambient temperature is set to 38.2°C, and the wind flow direction is determined based on the direction of maximum wind velocity at a height of 10 metres. Additional input conditions, as provided by the client, are detailed in later sections of the study.

With CFD, our professionals analysed airflow patterns, temperature profiles, solar radiation, and the impact of radiation on the building. Each piece of equipment is modelled with its operational conditions accurately represented in the simulation software, allowing for a detailed examination of flow parameters and their behaviour.

Objectives

The objectives of this analysis are to:

  • Determine the temperature distribution from the generator set exhaust.
  • Analyse potential short circuits (if any) within the layout of the generator set row.

Scope of Work

The scope of this evaluation includes:

  • Developing a 3D CAD model based on the proposed layout and site measurements.
  • Creating a mesh and setting up simulation conditions, including flow rates and temperature.
  • Reporting the temperature and velocity distribution across various sections of the domain, as predicted by the CFD simulation.

Methodology

CFD Overview

CFD refers to the numerical simulation process used to describe the flow of fluids within a computational domain. This is based on the governing conservation equations (Navier-Stokes equations) for mass, momentum, energy, and other factors. The fluid domain is discretised into small volumes, known as cells, where the appropriate conservation equations are applied to each cell. These equations are then solved simultaneously using numerical techniques to model the flow behaviour.

Modelling Strategy & Assumptions

  • The flow is considered to be 3D, steady-state, incompressible, and turbulent.
  • The continuity, momentum, and energy conservation equations are solved in 3D (x, y, z) along with the equations corresponding to the turbulent model.
  • Solar radiation is modelled using ASHRAE data for the Cyberjaya location.
  • An external domain is created to enclose the generator set building and surrounding structures, accurately representing the ambient conditions.

Geometry Description

Comprehensive 3D Modelling

Comprehensive 3D Generator Set Modelling

Data Input

  • The generator set has a discharge airflow rate of 3,480 m³/min (CMM) and an exhaust flow rate of 529 m³/min (CMM).
  • The exhaust temperature is 510°C, while the ambient temperature is 38.2°C.
  • Wind is blowing from the south at a speed of 1.75 m/s, measured at a height of 10 metres. 
  • These conditions will affect how heat and exhaust dissipate in an open space.

Simulation Settings - Meshing

CFD Analysis Results

These were the results of the CFD Analysis:

Temperature Distribution

Velocity Distribution

Conclusion

The natural ventilation CFD analysis confirmed that, despite the high exhaust temperatures, there was no occurrence of short-circuiting or backflow inside the building, particularly around the generator set inlet area. This suggests that the proposed design effectively manages thermal conditions and airflow, ensuring safe operation even under extreme circumstances.

In conclusion, CFD simulation provides confidence that the temperature distribution and airflow management within the building are adequate, and the system is designed to prevent any negative impacts such as short-circuiting or backflow. The results support the viability of the proposed design in maintaining optimal operating conditions while mitigating potential thermal hazards.