Abstract
Hybrid fuzzy-PID controller is a controller that makes fuzzy and PID controller in parallel, it adopts fuzzy control when away from the operating point taking the advantages of solving the nonlinear uncertainty with fuzzy controller. And it adopts PID control around the work area by using PID to control the characteristics of high precision. The fuzzy PID controller is applied to the VAV BOX for many factors influenced by VAV terminal control. It effectively solves the problems of the VAV air conditioning system which is lag, big inertia, random interference and nonlinear. In addition it is verified in the VAV air conditioning test platform, and achieves the expected control effect.
Project of Shenyang Bureau of science and technology (F11-256-4-00)
Project of Liaoning Key Laboratory of Department of education (LS2010115)
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Wu Zhengsong, Liu Guixiong, Chen Jiashi (2007) VAV terminal device to control the development and simulation technology. Autom Inf Eng 6:5–7
Chen, Song Xiaoli (2004) Simulation of VAV system terminal device. Refrig Air Cond 1:7–9
Tolga N (2009) Simulation comparison of VAV and VRF air conditioning systems in an existing building for the cooling season. Energy Build 41:1143–1150
Chen Wu, Deng Shiming, Cai Zhenxiong (2005) VAV air conditioning system dynamic modeling and control of supply fans. HVAC 35(8):104–109
Hu Yuling (2007) A study on fuzzy neural network control of VAV air conditioning system. J Beijing Inst Civil Eng Arch 49(3):25–31
Li Weifeng, Huang Lei (2008) Application of adaptive fuzzy control in the VAV terminal device. J Huangshi Inst Technol 3(5):45–51
Stanke D (2005) Designing dual path, multiple-zone system. ASHRAE J 47(5):20–30
Liu Guopeng (2008) Supply fan control methods for VAV systems using a fan airflow station. ASHRAE Trans 9(2):451–457
WangJun, Wang Rui-xiang (2006) New method for optimizing control variable air volume (VAV) air conditioning system. J Shanghai Jiaotong Univ 4(6):248–252
A’Ni Dong, Qinghua Hu (2008) The simulation study of adaline PID control and decoupling for the VAV system. In: 2008 international conference on wireless communications, networking and mobile computing, WiCOM 2008, IEEE, New York, p 4679120
Yamakawa Yuit, Yamazaki Takanori, Kamimura Kazuyuki, Kurosu Shiqeru (2007) Stability analysis of interacting systems in air-conditioning system. In: Proceedings of the SICE annual conference, Takamatsu, pp 2220–2225
Kasahara Masato, Matsuba Tadahiko (1999) Design and tuning of robust PID controller for HVAC systems. ASHRAE Trans PA 105:154–166
Arunas L, Vidmantas M (2005) Evolutionary learning in identification of fuzzy model of air flow supply system. In: Intelligent data acquisition and advanced computing systems: technology and applications, IDAACS 2005. IEEE, Sofia, pp 101–107
Huang Gongsheng, Dexter AL (2008) Realization of robust nonlinear model predictive control by offline optimisation. J Process Control 18(5):431–438
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2014 Springer-Verlag Berlin Heidelberg
About this paper
Cite this paper
Wei, Jl., Li, Sj., Wang, Xd., Guo, M. (2014). Design of VAV BOX Controller Based on Fuzzy-PID Hybrid Control. In: Qi, E., Shen, J., Dou, R. (eds) Proceedings of 2013 4th International Asia Conference on Industrial Engineering and Management Innovation (IEMI2013). Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-40060-5_11
Download citation
DOI: https://doi.org/10.1007/978-3-642-40060-5_11
Published:
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-642-40059-9
Online ISBN: 978-3-642-40060-5
eBook Packages: Business and EconomicsBusiness and Management (R0)