High Temperature Air Combustion From Energy Conservation to Pollution Reduction
Auteurs : Tsuji Hiroshi, Gupta Ashwani K., Hasegawa Toshiaki, Katsuki Masashi, Kishimoto Ken, Morita Mitsunobu
Maximize efficiency and minimize pollution: the breakthrough technology of high temperature air combustion (HiTAC) holds the potential to overcome the limitations of conventional combustion and allow engineers to finally meet this long-standing imperative. Research has shown that HiTAC technology can provide simultaneous reduction of CO2 and nitric oxide emissions and reduce energy consumption for a specific process or requirement.
High Temperature Air Combustion: From Energy Conservation to Pollution Reduction provides the first comprehensive exposition of the principles and practice of HiTAC. With a careful balance of theory and practice, it reviews the historical background, clearly describes HiTAC combustion phenomena, and shows how to simulate and apply the technology for significant energy savings, reduced equipment size, and lower emissions. It offers design guidelines for high performance industrial furnaces, presents field trials of practical furnaces, and explores potential applications of HiTAC in other fields, including the conversion of solid waste fuels to cleaner fuels, stationary gas turbine engines, internal combustion engines, and other advanced energy-to-power conversion systems.
Developed through an intensive research project sponsored by the Japanese government, HiTAC now promises to revolutionize our paradigm for using all kinds of fossil, alternative, waste, and derived fuels for energy conversion and utilization in industry. This book is your opportunity to understand its principles, learn about the technology, and begin to use it to the benefit of your application, your company, and the environment.
Date de parution : 09-2019
15.6x23.4 cm
Date de parution : 12-2002
Ouvrage de 402 p.
15.6x23.4 cm
Thèmes de High Temperature Air Combustion :
Mots-clés :
High Temperature Air Combustion; Preheated Air; Preheated Air Temperature; Furnace Length; Adiabatic Flame Temperature; High Temperature Air; Flame Temperature; Combustion Technology; Heat Recirculation; Global Reaction Model; Natural Gas; Flame Strain Rate; Heat Recovery Rate; Nongray Gas; Radiative Heat Transfer; Reheating Furnace; Combustion Chamber; Heat Balance; Burning Velocity; NOx Concentration; Heat Loss; Maximum Flame Temperature; Pah Formation; Furnace Height; Combustion Rate