Experimental Investigation of Cycle Properties, Noise, and Air Pollutant Emissions of an APS3200 Auxiliary Power Unit

Teresa Siebel,Jan Zanger,Andreas Huber,Karsten Knobloch,Friedrich Bake,Manfred Aigner

doi:10.1115/1.4038159

Teresa Siebel, Jan Zanger + Show 4 more

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https://doi.org/10.1115/1.4038159

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Abstract

Auxiliary power unit (APU) operators face increasingly stricter airport requirements concerning exhaust gas and noise emission levels. To simultaneously reduce exhaust gas and noise emissions and to satisfy the increasing demand of electric power on board, optimization of the current technology is necessary. Prior to any possible demonstration of optimization potential, detailed data of thermodynamic properties and emissions have to be determined. Therefore, the investigations presented in this paper were conducted at a full-scale APU of an operational aircraft. A Pratt & Whitney (East Hartford, CT) APS3200, commonly installed in the Airbus A320 aircraft family, was used for measurements of the reference data. In order to describe the APS3200, the full spectrum of feasible power load and bleed air mass flow combinations were adjusted during the study. Their effect on different thermodynamic and performance properties, such as exhaust gas temperature, pressure as well as electric and overall efficiency is described. Furthermore, the mass flows of the inlet air, exhaust gas, and fuel input were determined. Additionally, the work reports the exhaust gas emissions regarding the species CO2, CO, and NOx as a function of load point. Moreover, the acoustic noise emissions are presented and discussed. With the provided data, the paper serves as a database for validating numerical simulations and provides a baseline for current APU technology.

Highlights

Many airports experience a constantly rise in aircraft operations and a simultaneous increase in public concern about pollutant and noise emissions
The present paper describes an experimental investigation of the thermodynamic properties and exhaust gas and noise emissions of a full-scale Hamilton Sundstrand ( Pratt & Whitney) APS3200, as installed on commercial airplanes like the Airbus A320
The bleed air produced by the load compressor flowed into a bleed control valve (BCV), which controled the amount of air delivered to the aircraft system and the air discharge to the auxiliary power units (APU) exhaust duct

Summary

Introduction

Many airports experience a constantly rise in aircraft operations and a simultaneous increase in public concern about pollutant and noise emissions. In order to reduce the impact on surrounding areas, airports are implementing air quality and noise mitigation plans. On ground auxiliary power units (APU) are seen as one of the major sources of pollutant and noise emissions [1]. In contrast to the airport specification of reduced APU-usage, aircrafts require increasing amounts of electrical power. The objective for higher passenger comfort with improved air conditioning and consumer electronics will further increase the demand of electricity. To meet these contradictory demands, optimization of todays APUs is necessary

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