Gas Turbines Modeling, Simulation, and Control Using Artificial Neural Networks
Auteurs : Asgari Hamid, Chen XiaoQi
Gas Turbines Modeling, Simulation, and Control: Using Artificial Neural Networks provides new approaches and novel solutions to the modeling, simulation, and control of gas turbines (GTs) using artificial neural networks (ANNs). After delivering a brief introduction to GT performance and classification, the book:
- Outlines important criteria to consider at the beginning of the GT modeling process, such as GT types and configurations, control system types and configurations, and modeling methods and objectives
- Highlights research in the fields of white-box and black-box modeling, simulation, and control of GTs, exploring models of low-power GTs, industrial power plant gas turbines (IPGTs), and aero GTs
- Discusses the structure of ANNs and the ANN-based model-building process, including system analysis, data acquisition and preparation, network architecture, and network training and validation
- Presents a noteworthy ANN-based methodology for offline system identification of GTs, complete with validated models using both simulated and real operational data
- Covers the modeling of GT transient behavior and start-up operation, and the design of proportional-integral-derivative (PID) and neural network-based controllers
Gas Turbines Modeling, Simulation, and Control: Using Artificial Neural Networks not only offers a comprehensive review of the state of the art of gas turbine modeling and intelligent techniques, but also demonstrates how artificial intelligence can be used to solve complicated industrial problems, specifically in the area of GTs.
Introduction to Modeling of Gas Turbines. White-Box Modeling, Simulation, and Control of GTs. Black-Box Modeling, Simulation, and Control of GTs. ANN-Based System Identification for Industrial Systems. Modeling and Simulation of a Single-Shaft GT. Modeling and Simulation of Dynamic Behavior of an IPGT. Modeling and Simulation of the Start-Up Operation of an IPGT by Using NARX Models. Design of Neural Network-Based Controllers for GTs.
Hamid Asgari received his Ph.D in mechanical engineering from the University of Canterbury, Christchurch, New Zealand in 2014. He obtained his ME in aerospace engineering from Tarbiat Modares University, Tehran, Iran, and his BE in mechanical engineering from Iran University of Science and Technology, Tehran. He has worked more than 15 years in his professional field as a lead mechanical engineer and project coordinator in highly prestigious industrial companies. During his professional experience, he has been a key member of engineering teams in design, research and development, and maintenance planning departments. He has invaluable theoretical and hands-on experience in technical support, design, and maintenance of a variety of mechanical equipment and rotating machinery, such as gas turbines, pumps, and compressors, in large-scale projects in power plants and in the oil and gas industry.
XiaoQi Chen is a professor in the Department of Mechanical Engineering at the University of Canterbury, Christchurch, New Zealand. After obtaining his BE in 1984 from South China University of Technology, Guangzhou, he received the China-UK Technical Co-Operation Award for his MS study in the Department of Materials Technology at Brunel University, London, UK (1985–1986) and his Ph.D study in the Department of Electrical Engineering and Electronics at the University of Liverpool, UK (1986–1989). He has been a senior scientist at the Singapore Institute of Manufacturing Technology (1992–2006) and a recipient of the Singapore National Technology Award (1999). His research interests include mechatronic systems, mobile robotics, assistive devices, and manufacturing automation. He has been elected to Fellow of IPENZ and Fellow of SME.
Date de parution : 07-2017
15.6x23.4 cm
Date de parution : 09-2015
15.6x23.4 cm
Thèmes de Gas Turbines Modeling, Simulation, and Control :
Mots-clés :
NARX Model; Ann Model; ANN-Based System Identification; Simulink Model; ANNs; Turbine Outlet Temperature; Artificial Intelligence; Pid Controller; Artificial Neural Network-Based System Identification; GT Performance; Artificial Neural Networks; Compressor Pressure Ratio; Automation; White Box Models; Black-Box Modeling; Fuel Flow Rate; Black-Box Modelling; Time Series Data Sets; Control; Condition Monitoring; GTs; Power Plant; Gas Turbine Control; Ann Method; Gas Turbine Manufacturing; Data Sets; Gas Turbine Modeling; NN Model; Gas Turbine Modelling; Ann Architecture; Gas Turbine Simulation; Uc T1; Gas Turbines; Combustion Chamber; IPGTs; TR1 TR2 TR3; Industrial Power Plant Gas Turbines; GT Model; Intelligent Control; Ann Technique; Intelligent Design; Controller Block; Intelligent Modeling; RMSE Value; Intelligent Modelling; Fuel Mass Flow Rate; Intelligent Techniques; Practical GT; Machine Control Systems Design; Mechatronics; Modeling; Modelling; NARX Models; Neural Network-Based Controllers; Neural Networks; PID Controllers; Proportional-Integral-Derivative Controllers; Simulation; Single-Shaft GTs; Single-Shaft Gas Turbines; System Identification; Turbomachinery; White-Box Modeling; White-Box Modelling