Modeling dynamic responses of aircraft environmental control systems by coupling with cabin thermal environment simulations

Haishen Yin; Xiong Shen; Yan Huang; Zhuangbo Feng; Zhengwei Long; Ran Duan; Chao-Hsin Lin; Daniel Wei; Balasubramanyam Sasanapuri; Qingyan Chen

doi:10.1007/s12273-016-0278-3

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Research Article

Modeling dynamic responses of aircraft environmental control systems by coupling with cabin thermal environment simulations

Haishen Yin^¹, Xiong Shen^¹(

), Yan Huang^¹, Zhuangbo Feng^¹, Zhengwei Long^¹, Ran Duan^¹, Chao-Hsin Lin^², Daniel Wei^³, Balasubramanyam Sasanapuri^⁴, Qingyan Chen^{¹^,⁵}

1Tianjin Key Laboratory of Indoor Air Environmental Quality Control, School of Environmental Science and Engineering, Tianjin University, Tianjin 300072, China

2Environmental Control Systems, Boeing Commercial Airplanes, Everett, WA 98203, USA

3Boeing Research & Technology - China, Beijing 100027, China

4ANSYS Fluent India Pvt Ltd, Pune, India

5School of Mechanical Engineering, Purdue University, West Lafayette, IN 47907, USA

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Abstract

Commercial aircraft use environmental control systems (ECSs) to control the thermal environment in cabins and thus ensure passengers’ safety, health, and comfort. This study investigated the interaction between ECS operation and cabin thermal environment. Simplified models were developed for the thermodynamic processes of the key ECS components in a commercial software program, ANSYS Simplorer. A computational fluid dynamics (CFD) program, ANSYS Fluent, was employed to simulate the thermal environment in a cabin. Through the coupling of Simplorer and Fluent, a PID control method was applied to the aircraft ECS in Simplorer to achieve dynamic control of the temperature of the supply air to the cabin, which was used as a Fluent input. The calculated supply air temperature agreed with the corresponding experimental data obtained from an MD-82 aircraft on the ground. The coupled model was then used to simulate a complete flight for the purpose of studying the interaction between ECS operation and the cabin thermal environment. The results show that the PID controller in the ECS can maintain the cabin air temperature within ±0.6 K of the set point, with an acceptable air temperature distribution. The coupled models can be used for the design and analysis of the ECS and cabin thermal environment for commercial airplanes.

Keywords

temperature field coupled simulation thermal control aircraft ECS

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Building Simulation

Volume 9 Issue 4,
August 2016

Pages 459-468

DOI: 10.1007/s12273-016-0278-3

Cite this article:

Yin H, Shen X, Huang Y, et al. Modeling dynamic responses of aircraft environmental control systems by coupling with cabin thermal environment simulations. Building Simulation, 2016, 9(4): 459-468. https://doi.org/10.1007/s12273-016-0278-3

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Received: 07 October 2015

Revised: 31 December 2015

Accepted: 18 January 2016

Published: 10 March 2016