Investigating Effective Duct Length Estimation Methods for a Centrifugal Fan-Duct Interface System by Monitoring the Stabili zation of Velocity and Pressure Levels-Developing Pressure Estimation Equations by Using Air Duct Mean Velocity, Replacing the Need for Pressure Sensors

摘要

This paper investigates the two methods used in determining the point of airflow stabilization in a fan-duct connection system, known as the effective duct length equations. Two methods, widely used in the industry, are a standard-based equation and the number of diameters rule. The two methods were assessed by comparing the velocity and pressure results in the air duct system. An industry-standard centrifugal fan was used as the basis of the analysis. The methodology employed was using a computational fluid dynamics (CFD) software package to model the system. Airflow stream lines and airflow pressure contours were recorded. Data were collected and tabulated for analysis. Graphs were generated for discussions. This paper discusses the development of a mathematical pressure-mean air-velocity relationship. The results collected confirmed the following: 1. The tvo methods used to determine the effective duct length-standard-based equation and number of diameters rule-are in agreement. 2. The effective duct length criteria can be judged by air velocity measurements when positioning the air velocity sensor at the top part of the air duct. 3. For pressure measurements, analysis has shown that it is possible to obtain the pressure values by using the mean air velocity measurements taken at the 100% effective duct length position, thus eliminating the need to install pressure sensors and rely on air velocity sensors for velocity and pressure measurements. In conclusion, CFD techniques can be used to improve the accuracy of airflow stabilization in an air duct system. Measurement and control instruments can be positioned and calibrated effectively, therefore improving the performance of fan-air duct systems by reducing fan energy with accurate measurement and control systems. This paper demonstrates how the velocity sensors can also be used to determine pressure levels in the air duct, removing the need to install pressure sensors in air ducts. One static pressure sensor installed in a building can be used to obtain static pressure. Signals from the velocity sensors in air ducts and the static pressure sensor can be fed into a central computer building management system to obtain pressure levels in air ducts. This presents a saving in materials and installation costs.