: Zhihua Wang, Kefa Cen, Junhu Zhou, Jianren Fan
: Simultaneous Multi-Pollutants Removal in Flue Gas by Ozone
: Springer-Verlag
: 9783662435144
: Advanced Topics in Science and Technology in China
: 1
: CHF 48.60
:
: Genetik, Gentechnik
: English
: 117
: Wasserzeichen/DRM
: PC/MAC/eReader/Tablet
: PDF

Simultaneous Multi-Pollutants Removal in Flue Gas by Ozone mainly introduces the multi-pollution control technology in flue gas by ozone oxidation. Based on the authors' recent research works, the book will provide readers with the updated fundamental research findings, comprised of the detail kinetic mechanisms between ozone and gas components in flue gas integrated with experimental and kinetic modeling work. The demonstration case of the multi-pollutant removal technology by ozone is also presented. The book is suitable for the researchers working in the areas of energy and environmental protection, and pollutant control technology.

Zhihua Wang is a Professor at the State Key Laboratory of Clean Energy Utilization of Zhejiang University;Kefa Cen is the Academician of Chinese Academy of Engineering, and the director of Institute for Thermal Power Engineering of Zhejiang University;Junhu Zhou is a Qiushi Scholar Professor at the State Key Laboratory of Clean Energy Utilization of Zhejiang University;Jianren Fan is the Cheung Kong Scholar Professor at the State Key Laboratory of Clean Energy Utilization of Zhejiang University.
Cover1
Title Page3
Copyright Page4
Preface5
Table of Contents8
1 Development of Pollution Control Technology During Coal Combustion11
1.1 Introduction11
1.2 Existing Air Pollution Control Technologies12
1.2.1 Desulfurization Technology12
1.2.1.1 Circulating Fluidized-Bed Technology13
1.2.1.2 Wet Flue-Gas Desulfurization Technology13
1.2.1.3 Spray Dry Flue-Gas Desulfurization Technology13
1.2.1.4 Calcium Injection/Humidification Desulfurization Technology in Furnace14
1.2.1.5 Electron-Beam (E-Beam) FGD Technology14
1.2.1.6 Seawater FGD Technology14
1.2.2 Denitrification Technology15
1.2.2.1 Low-Oxygen Combustion Technology15
1.2.2.2 Staged-Air Combustion Technology16
1.2.2.3 Flue-Gas Recirculation16
1.2.2.4 Reburning Technology16
1.2.2.5 SCR17
1.2.2.6 SNCR18
1.2.2.7 Advanced Reburning Technology18
1.2.2.8 Oxygen-Enhanced Combustion19
1.2.2.9 Hybrid Selective Reduction Technology19
1.2.3 Hg Removal Technology20
1.2.3.1 Absorbent21
1.2.3.2 Coal-Washing or Coal Drying Technology21
1.2.3.3 Conventional Pollution Control Device21
1.2.3.4 Corona Discharge Plasma Technology22
1.2.3.5 Semi-Dry Based Hg Removal Technology22
1.2.4 VOCs Control Technology23
1.2.4.1 Adsorption Method23
1.2.4.2 Catalytic Combustion Technology24
1.2.4.3 Biological Control Technology24
1.3 Simultaneous Multi-Pollutants Removal Technology25
1.3.1 In-Furnace Multi-Pollutants Emission Control Technology25
1.3.1.1 O2/CO2 Combustion with Ca-Based Sorbent25
1.3.1.2 Low-NOx Burner Combined with Ca-Based Sorbent26
1.3.1.3 Limestone/Urea Injection in Furnace26
1.3.1.4 Multi-Pollutants Removal with Organic Calcium Injection26
1.3.2 Flue Gas Multi-Pollutants Emission Control Technology27
1.3.2.1 Multi-Pollutants Removal Technology Combined with SCR/SNCR27
1.3.2.2 Metal-Based Absorbent Multi-Pollutants Removal Technology29
1.3.2.3 Free-Radical Based Multi-Pollutants Removal Technology30
1.3.2.4 Wet Chemical Multi-Pollutants Removal Technology31
References32
2 Principle of Multi-Pollutants Removal Technology in Flue Gas by Ozone40
2.1 Introduction40
2.2 Ozone Characteristics42
2.3 Ozone Generation Methods43
2.3.1 Electrode Type45
2.3.2 Feed Gas47
2.3.3 Dielectric Material48
2.3.4 Mixed Discharges49
2.3.5 Pulsed Discharge50
2.4 Summary52
References52
3 Chemical Kinetics and Oxidation Mechanisms Between O3 and NOx/SO2/Hg57
3.1 Introduction on Kinetics Modelling57
3.2 Kinetic Modelling Results62
3.2.1 Kinetic Modelling Between O3 and NOx62
3.2.2 Kinetic Modelling Between O3 and Hg64
3.3 Oxidation Experimental Results66
3.3.1 Experimental Setup66
3.3.2 Oxidation Mechanism Between O3 and NO68
3.3.3 Oxidation Mechanism Between O3 and SO271
3.3.4 Oxidation Mechanism Between O3 and Hg72
3.3.5 Oxidation Mechanism Between O3 and CO74
3.4 Competitive Reaction Mechanism Between Different Pollutants75
3.4.1 Reaction Competition Between NO and SO2 with Ozone75
3.4.2 Reaction Competition Between NO and Hg0 with Ozone76
3.5 Summary77
References78
4 Simultaneous Multi-Pollutants Removal with Ozone and Wet Scrubber79
4.1 Introduction79
4.2 Experimental Section81
4.3 Effect of pH Value on NO2 Removal82
4.4 Effect of Tetravalent-S Components on NO2 Removal86
4.4.1 Effect of the Sole SO3 2-87
4.4.2 Effect of pH with the Existence of Tetravalent-S Components88
4.4.3 Effect of the Initial NO2 Concentration90
4.5 Simultaneous Removal of SO2 and NO291
4.5.1 Effect of SO2 on NO2 Removal91
4.5.2 Effect of NO2 on SO2 Removal93
4.6 NOx Wet Removal with Excess Ozone Oxidization94
4.7 Simultaneous Desulfurization and Denitrification Scheme Incorporated with Ozone Oxidization and Dual-Tower Scrubbing96
4.8 Summary98
References99
5 Application and Economic Analysis of the Multi-Pollutants Removal Technology Incorporated with Ozone Oxidization and Alkali Solution Adsorption102
5.1 Application Scheme of O3 and FGD102
5.2 Economic Analysis of the Ozone Generation Technology105
5.3 Economic Analysis of the O3 and FGD System107
5.4 Summary111
References112
Index114