Journal of Environmental Accounting and Management
Discussion on Approach to Renovation of Industrial Coal-Fired Boilers in China
Journal of Environmental Accounting and Management 3(1) (2015) 23--30 | DOI:10.5890/JEAM.2015.03.002
Yiqiong Lu$^{1}$,$^{2}$, Shengguang Zhao$^{1}$,$^{3}$
$^{1}$ Department of Environmental Protection, Shenhua Group Corporation Limited, Beijing China, 100011
$^{2}$ School of Environment and Resources, Renmin University of China, Beijing, 100086
$^{3}$ School of Energy, Power and Mechanical Engineering, North China Electric Power University, Beijing, 102206
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Abstract
This paper analyzed the present status of industrial coal-fired boilers and relevant policies and standard requirements, and had in-depth discussion on alternative ways of industrial coal-fired boilers, pollution control and management optimization for energy saving. It pointed out that options for elimination and replacement of industrial coal-fired boilers are new energy high efficiency boilers, industrial waste heat utilization, heat pump, new energy and renewable energy. For pollutant control, it provided feasible technologies on controlling dust, sulfur dioxide and nitrogen oxides respectively. Energy conservation measures including evenly hierarchical coal feeding technology, low nitrogen high efficiency combustion technology and etc. are stated as well. It ends up with brief analysis of relevant necessary supporting measures for the whole renovation scheme.
Acknowledgments
This study was supported by National Natural Science Foundation of China (Grant No. 41471466), Beijing Municipal Natural Science Foundation (Grand No. 8154051).
References
-
[1]  | General Administration of Quality Supervision of China, Inspection and Quarantine, Standardization Administration of China, (2009), The Minimum Allowable Values of Energy Efficiency and Energy Efficiency Grades of Industrial Boilers (GB 24500-2009). |
-
[2]  | Ministry of Industry and Information Technology of China, (2009), The First Catalog of Outmoded High Energy Consumption Electromechanical Devices. |
-
[3]  | Zhou, H., Zheng, L.G. and Cen, K.F., (2010), Computational intelligence approach for NOx emissions minimization in a coal-fired utility boiler, Energy Conversion and Management 51(3): 580-586. |
-
[4]  | Yu, J. (2012), Status and transformation measures of industrial coal-fired boiler in China, Clean Coal Technology 18(3): 89-113. |
-
[5]  | Ming, Y. and Dixon, R.K. (2012), Investing in efficient industrial boiler systems in China and Vietnam, Energy Policy 40: 432-437. |
-
[6]  | Liang, X. (2012), Comparison between high efficient pulverized coal industrial boiler and CWM industrial boiler, Clean Coal Technology 18(5): 88-96. |
-
[7]  | Fan, W. (2012), Development and investment analysis of pulverized coal industrial boiler, Clean Coal Technology 18(4): 4-7. |
-
[8]  | State Council of China, (2012), The 12th Five Year Plan for Energy Conservation and Pollution Reduction. |
-
[9]  | Ministry of Industry and Information Technology of China, (2012), The Second Catalog of Outmoded High Energy Consumption Electromechanical Devices. |
-
[10]  | Ministry of Environmental Protection of China, National Development and Reform Commission of China, Ministry of Finance of China, (2012), The 12th Five Year Plan Air Pollution Prevention and Control Action Plan for Key Areas. |
-
[11]  | Ministry of Environmental Protection of China, (2012), National Environmental Statistics Bulletin 2011. |
-
[12]  | Ministry of Environmental Protection of China, (2013), National Environmental Statistics Bulletin 2012. |
-
[13]  | Ministry of Environmental Protection of China, National Development and Reform Commission of China, four other departments of China, (2013), Implementation Rules for the Action Plan for Preventing and Controlling Air Pollution in Beijing, Tianjin, Hebei and the Surrounding Areas. |
-
[14]  | State Council of China, (2013), Air Pollution Prevention and Control Action Plan. |
-
[15]  | Ministry of Environmental Protection of China, (2013), Technical Policy on Comprehensive Prevention and Treatment of PM2.5. |
-
[16]  | Noam L. (2013), Sustainability ethics and metrics: Strategies for damage control and prevention, Journal of Environmental Accounting and Management 1(1): 15-24. |
-
[17]  | Smrekar, J., Potočnik, P. and Senegačnik, A. (2013), Multi-step-ahead prediction of NOx emissions for a coal-based boiler, Applied Energy 106: 89-99. |
-
[18]  | Ministry of Industry and Information Technology of China, (2014), The Third Catalog of Outmoded High Energy Consumption Electromechanical Devices. |
-
[19]  | Ministry of Environmental Protection of China, General Administration of Quality Supervision of China, Inspection and Quarantine of China, (2014), Emission standard of air pollutants for boiler (GB13271-2014). |
-
[20]  | National Development and Reform Commission of China, Ministry of Environmental Protection of China, other five ministries of China, (2014), Comprehensive Enhancement Implementation Scheme for Energy conservation and Environmental Protection for Coal Fired Boilers. |
-
[21]  | Li, L., Lei, Y.L. and Pan, D.Y. (2014), Study on the Driving Factors of CO2 Emissions in China’s Coal Consumption Using the STIRPAT Model, Journal of Environmental Accounting and Management 2(4): 325-334. |
-
[22]  | Yu, J.H. and Wang, S.W. (2014), Pulverized Coal Fired Industrial Boiler and Development Prospect, Industrial Boiler 1: 1-5. |
-
[23]  | Liu, F.Q. (2014), The Present Situation and Development Trend of Industrial Boiler, Applied Energy Technology 9: 10-20. |
-
[24]  | Lu, Y.Q. (2014), Estimation of Black Carbon Emission of China, Journal of Environmental Accounting and management 2(2): 115- 122. |
-
[25]  | Zhang, W.H. (2014), Suggestions and Measures for Promoting the Energy Conservation and Emission Reduction of Coal-fired Industrial Boilers, Energy and Energy Conservation 9: 66-90. |
-
[26]  | Yao, D.D. and Wang, Y.G. (2014), Research and Applications of Optimization Control Systems of Energy Saving in Industrial Boiler, Journal of Jiangnan University (Natural Science Edition) 13(5): 536-540. |