垃圾焚烧炉关键服役材料发展现状及研究趋势

doi:10.11896/cldb.20090010

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Abstract The disposal of municipal waste has almost become one of the most serious urban problems faced by governments all over the world. As an important treatment means, incineration can not only achieve the purpose of reducing capacity and weight, but also realize the cascade utilization of energy and maximize the benefit of garbage resources. As a key equipment in the process of waste incineration, the physicochemical characteristics of waste, incineration temperature, flue gas composition and other factors in the process of use will have a certain impact on the life of the key service materials of waste incineration. Therefore, the research and development of key service materials with high temperature resistance, corrosion resistance and long life is the key to ensure the normal and orderly operation of waste incinerator and safe production. Typical key service materials of waste incinerator mainly include refractory materials, metal tube wall coating materials, flue gas treatment materials, etc.
In recent years, with the development of garbage incinerators towards large scale and automation, it is difficult for the existing ordinary refractories to meet the requirements of the fire resistance of waste incinerators. Therefore, the selection of refractory materials for waste incinerators has put forward higher special requirements. At present, the research of refractories for incinerators mainly focuses on the development of corrosion resistance of chromium-containing refractories and the development of chromium-free refractories represented by silicon carbide. In view of the serious corrosion of waste incineration fly ash on the metal tube wall of incinerators, researchers and enterprises are actively developing anti-corrosive coating protective materials, such as surfacing coating protective materials, thermal spraying protective materials and laser cladding protective materials. The harmless disposal of flue gas is also a key issue in the research of key service materials for waste incineration. The current research mainly focuses on the development of catalyst materials for flue gas de-N and de-S, the development of dust removal filter materials for flue gas treatment, especially the longevity design of new fiber materials with high temperature and corrosion resistance.
In this paper, according to the types and characteristics of waste incinerators, the research progress of typical key service materials of waste incinerators, such as refractory materials, metal tube wall coating materials and flue gas treatment materials, were summarized systematically. The existing problems and the future development trends of typical key service materials of waste incinerators were also summarized and proposed, respectively, which could provide a valuable reference for further popularization and application of typical key service materials of waste incinerators in China.

Key words： waste incinerator refractory material corrosion protection flue gas treatment

Published: 26 September 2021

CLC number:	TB304
	TQ175

Fund:National Key R&D Program of China (2018YFC1902504).

About author:: Gongqi Liureceived his B.S. degree in resource recycling science and engineering from Shandong University of Technology in 2016. He is currently pursuing his Ph.D. at Beijing University of Technology under the supervision of Prof. Yufeng Wu. His research has focused on comprehensive utilization of secondary resources.
Zhaohui Wangis currently a professor and the vice dean of Faculty of Materials and Manufacturing, Beijing University of Technology. He received his Ph. D. in materials processing engineering from University of Science and Technology Beijing in 2007. He is the member of teaching team of National Superior Course “Introduction of Materials Science and Engineering”. He has presided over twenty projects supported by National Key Research and Development Program of China, National Natural Science Fundation of China, Beijing Natural Science Foundation, Beijing Municipal Science and Technology Commission and some enterprises. He has published more than 40 papers, authorized over 20 patents and obtained the “Second Prize of China Nonferrous Metal Industry Science and Technology Award” etc.

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Cite this article:

LIU Gongqi,WU Yufeng,YANG Tianwei, et al. The Development Status and Research Trend of Key Service Materials for Waste Incinerators[J]. Materials Reports, 2021, 35(17): 17125-17135.

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http://www.mater-rep.com/EN/10.11896/cldb.20090010 OR http://www.mater-rep.com/EN/Y2021/V35/I17/17125

1 Yang B, Zhong Z Q, Huang Q X, et al. Guangdong Electric Power, 2016, 29(6), 5(in Chinese).
杨波,钟志强,黄巧贤,等. 广东电力, 2016, 29(6), 5.
2 Beylot A, Villeneuve J. Waste Management, 2013, 33(12), 2781.
3 Sipra A T, Gao N, Sarwar H. Fuel Processing Technology, 2018, 175, 131.
4 Zhou Y. Shanxi Science and Technology, 2014, 29(1), 16(in Chinese).
周圆. 山西科技, 2014, 29(1), 16.
5 Hong J, Chen Y, Wang M, et al. Renewable & Sustainable Energy Reviews, 2017, 69, 168.
6 Qin L, Huang X, Xue Q, et al. Environmental Pollution, 2020, 258, 113710.
7 Nixon J D, Wright D G, Dey P K, et al. Waste Management, 2013, 33(11), 2234.
8 Zhi T, Chen X, Liu D, et al. Journal of Environmental Sciences, 2016, 48(10), 169.
9 Bai J Y, Bai Z G. Thermal Power Generation, 2008, 37(1), 109(in Chinese).
白建云,白正刚.热力发电, 2008, 37(1), 109.
10 Yang P. Energy Conservation, 2020, 39(7), 123(in Chinese).
杨盼.节能, 2020, 39(7), 123.
11 Frandsen F J. Fuel, 2005, 84(10), 1277.
12 Yang N, Zhang H, Chen M, et al. Waste Management, 2012, 32(12), 2552.
13 Xia Z, Shan P, Chen C, et al. Waste Management, 2020, 104, 183.
14 Tillman D A, Duong D, Miller B. Energy & Fuels, 2009, 23(7), 3379.
15 Zhu J Z, Chen L Q, Gan K. Journal of South China University of Technology (Natural Science Edition), 2005, 33(3), 78(in Chinese).
祝建中,陈烈强,甘轲. 华南理工大学学报(自然科学版), 2005, 33(3), 78.
16 Jiang X G, Wu L, Li X D, et al. Environmental Pollution and Control, 2018, 40(10), 1181(in Chinese).
蒋旭光,吴磊,李晓东,等. 环境污染与防治, 2018, 40(10), 1181.
17 Nielsen H P, Frandsen F J, Dam-Johansen K, et al. Progress in Energy and Combustion Science, 2000, 26(3), 283.
18 Shen X Z, Yan J H, Bai C S, et al. Thermal Power Generation, 2006, 35(7), 24(in Chinese).
沈祥智,严建华,白丛生,等. 热力发电, 2006, 35(7), 24.
19 Yan J H, Lu S Y, Li X D, et al. Journal of Engineering Thermophysics, 2004, 25(1), 155(in Chinese).
严建华,陆胜勇,李晓东,等. 工程热物理学报, 2004, 25(1), 155.
20 Singh H, Sidhu T S, Karthikeyan J, et al. Surface & Coatings Technology, 2015, 261, 375.
21 Caneghem J V, Brems A, Lievens P, et al. Progress in Energy & Combustion Science, 2012, 38(4), 551.
22 Fu Z C, Zhou F F. Energy Research and Management, 2018(3), 130(in Chinese).
付志臣,周飞飞. 能源研究与管理, 2018(3), 130.
23 Zhan H S, Cai B L, Wang F Y, et al. Refractories, 2020, 54(3), 271(in Chinese).
占华生,蔡斌利,王峰裕,等. 耐火材料, 2020, 54(3), 271.
24 Hua X. Industrial Heating, 2001(3), 28(in Chinese).
华夏. 工业加热, 2001(3), 28.
25 Boom A D, Degrez M, Hubaux P, et al. Waste Management, 2011, 31(7), 1505.
26 Mu L, Cai J, Chen J, et al. Energy & Fuels, 2015, 29(3), 1812.
27 Zhang L. Industrial Furnace, 2009, 31(6), 40(in Chinese).
张丽. 工业炉, 2009, 31(6), 40.
28 Yun S N, Jiang M X, Gao L C, et al. Journal of Xi’an University of Architecture & Technology (Natural Science Edition), 2002, 34(2), 165(in Chinese).
云斯宁,蒋明学,高里存,等. 西安建筑科技大学学报(自然科学版), 2002, 34(2), 165.
29 Zhao J Z, Liu Z X, Chen L B, et al. Refractories, 2000, 34(6), 353(in Chinese).
赵继增,刘忠选,陈路兵,等. 耐火材料, 2000, 34(6), 353.
30 Gui M X. Foreign Refractiories, 2002, 27(1), 33(in Chinese).
桂明玺. 国外耐火材料, 2002, 27(1), 33.
31 Ma Z J, Xing H Z. Refractories, 2015, 49(S3), 469(in Chinese).
马治杰,邢宏智.耐火材料, 2015, 49(S3), 469.
32 Wang L, Zhang Y Q. Power Equipment,2007,21(4),316(in Chinese).
王雷,张运翘. 发电设备, 2007, 21(4), 316.
33 Xu C. Information Recording Materials, 2020, 21(4), 28(in Chinese).
徐陈. 信息记录材料, 2020, 21(4), 28.
34 Gui J H. Foreign Refractiories, 2001, 26(2), 15(in Chinese).
桂剑红. 国外耐火材料, 2001, 26(2), 15.
35 Miyaji T, Sakamoto S, Kudo E. Taikabutsu Overseas, 2002, 2(22), 173.
36 Motoki H, Junichi H, Moda J. Journal of the Technical Association of Refractories, 2004, 3(24), 226.
37 Sekine K, Tsuchiya Y, Kozuka H. Journal of the Technical Association of Refractories, 2005, 25(3), 231.
38 Chen D, Huang A, Gu H Z, et al. Ceramics International, 2015, 41, 14748.
39 Wang Y C, Gao W J. Liaoning Building Materials, 2003(4), 18(in Chinese).
王迎春,高文军. 辽宁建材, 2003(4), 18.
40 Zhu D L. Liaoning Urban and Rural Environmental Science & Technology, 2000, 20(4), 26(in Chinese).
朱德龙. 辽宁城乡环境科技, 2000, 20(4), 26.
41 Moda J, Tanaka K, Kitamura S. Journal of the Technical Association of Refractories, 2008, 3(28), 204.
42 Li J Y, Zhan H S, Liu S H, et al. Refractories, 2020, 54(3), 246(in Chinese).
李金雨,占华生,刘淑焕,等. 耐火材料, 2020, 54(3), 246.
43 Moda J, Wang Z, Ariyoshi K. Journal of the Technical Association of Refractories, 2006, 2(26), 123.
44 Narushima T, Goto T, Iguchi Y, et al. Journal of the American Ceramic Society, 2005, 73(12), 3580.
45 Xiang Y B, Wang W W, Si Y C, et al. Refractories, 2020, 54(3), 228(in Chinese).
相宇博,王文武,司瑶晨,等.耐火材料, 2020, 54(3), 228.
46 Ren C M. Study on high temperature corrosion mechanism and protection technology of waste incineration power plant. Master’s Thesis, North China Electric Power University (Beijing), China, 2018(in Chinese).
任朝明. 垃圾焚烧发电厂高温腐蚀机理及防护技术研究.硕士学位论文, 华北电力大学(北京), 2018.
47 Phongphiphat A, Ryu C, Finney K N, et al. Journal of Hazardous Materials, 2011, 186(1), 218.
48 Skrifvars B J, Backman R, Hupa M, et al. Corrosion Science, 2008, 50(5), 1274.
49 Viklund P, Hjrnhede A, Henderson P, et al. Fuel Processing Technology, 2013, 105, 106.
50 Sun W. Study on characteristics of ash accumulation in fluidized bed waste incineration and simulation experiment of cold ash accumulation. Master’s Thesis, Zhejiang University, China, 2006(in Chinese).
孙巍. 流化床垃圾焚烧积灰特性研究及冷态积灰模拟实验. 硕士学位论文, 浙江大学, 2006.
51 Mohammad D, Davoud H. Engineering Failure Analysis, 2012, 19, 87.
52 Viklund P, Rnhede A H, Henderson P, et al. Fuel Processing Technology, 2013, 105, 106.
53 Lai Z Y, Ma X Q, Tang Y T, et al.Applied Thermal Engineering, 2014, 66, 145.
54 Xu L, Tan W, Zhu Q X, et al. Materials Protection, 2018, 51(5), 131(in Chinese).
徐霖,谭伟,朱青霞,等. 材料保护, 2018, 51(5), 131.
55 Kawahara Y. Coatings, 2016, 6(3), 34.
56 Sun H H, Liu A G, Meng F L. Transactions of Materials and Heat Treatment, 2013, 34(S2), 96(in Chinese).
孙焕焕,刘爱国,孟凡玲. 材料热处理学报, 2013, 34(S2), 96.
57 Fan H P. Journal of Henan Science and Technology, 2018(8), 25(in Chinese).
范蕙萍.河南科技, 2018(8), 25.
58 Wang X J, Yang J. Corrosion ＆ Protection, 2011, 32(8), 655(in Chinese).
王晓军,杨洁. 腐蚀与防护, 2011,32(8), 655.
59 Lu C F. Modern Manufacturing Technology and Equipment, 2019(12), 166(in Chinese).
卢常飞.现代制造技术与装备, 2019(12), 166.
60 Wu H L. Research on dioxin emission characteristics and key control technology of incinerator. Master’s Thesis, Zhejiang University, China, 2012(in Chinese).
吴海龙. 焚烧炉二恶英排放特性及关键控制技术研究. 硕士学位论文, 浙江大学, 2012.
61 Kathuria Y P. Surface & Coatings Technology, 2000, 132(2), 262.
62 Zhao Y X, Wang S G, Ye Q F, et al. Surface Technology, 2018, 47(1), 21(in Chinese).
赵雅萱,王少刚,叶庆丰,等. 表面技术, 2018, 47(1), 21.
63 Li G W, Liang H. Industrial Boiler, 2018(2), 51(in Chinese).
李广伟,梁华. 工业锅炉, 2018(2), 51.
64 Ye L, Ruan X Y, Hu H C, et al. Thermal Spray Technology, 2020, 12(1), 69(in Chinese).
叶林,阮新宇,胡海城,等.热喷涂技术, 2020, 12(1), 69.
65 Sidhu T S, Agrawal R D, Prakash S. Surface & Coatings Technology, 2005, 198(1), 441.
66 Hernas A, Imosa M, Formanek B, et al. Journal of Materials Processing Technology, 2004, 157, 348.
67 Yang S, Chen N, Liu W, et al. Surface & Coatings Technology, 2004, 183(2), 254.
68 Li X Z. Study on preparation and properties of the laser cladding Ni-Cr-Mo and Ni-Mo series coatings. Master’s Thesis, North China Electric Power University (Beijing), China, 2014(in Chinese).
李欣芷. Ni-Cr-Mo及Ni-Mo系熔覆层的制备及其特性研究. 硕士学位论文, 华北电力大学(北京), 2014.
69 Wang L, Zhou Z, Wang G H, et al. Thermal Spray Technology, 2017, 9(1), 1(in Chinese).
王利,周正,王国红,等. 热喷涂技术, 2017, 9(1), 1.
70 Zhao L P. Preparation and characterization of wear resistance and corrosion resistance cladding layers.Ph.D.Thesis, North China Electric Power University, China, 2012(in Chinese).
赵丽萍. 耐磨损、耐腐蚀熔覆层的制备及其特性研究.博士学位论文, 华北电力大学, 2012.
71 Lin H. China Environmental Protection Industry, 2019, 249(3), 43(in Chinese).
林欢.中国环保产业, 2019, 249(3), 43.
72 Cheng Y, Oleszek S, Shiota K, et al. Waste Management, 2020, 105, 575.
73 Xu M L, Yan J H, Ma Z Y, et al. Proceedings of the CSEE, 2007, 27(8), 16(in Chinese).
许明磊,严建华,马增益,等.中国电机工程学报, 2007, 27(8), 16.
74 Yan J H, Zhu H M, Jiang X G, et al. Journal of Zhejiang University (Enginee-ring Science), 2008, 42(10), 1812(in Chinese).
严建华,祝红梅,蒋旭光,等. 浙江大学学报(工学版), 2008, 42(10), 1812.
75 Feng T, Yan J H, Li X D, et al. Environmental Pollution & Control, 2011, 33(5), 40(in Chinese).
冯涛,严建华,李晓东,等. 环境污染与防治, 2011, 33(5), 40.
76 Yuan C, Lin H, Wu C, et al. Chemosphere, 2005, 59(1), 135.
77 Domingo J, Marques M, Mari M, et al. Environmental Research, 2020, 187, 109631.
78 Xu M L, Yan J H, Ma Z Y, et al. Proceedings of the CSEE, 2007, 27(23), 32(in Chinese).
许明磊,严建华,马增益,等.中国电机工程学报,2007,27(23),32.
79 Shao J M, Wang Z H, Lin F W, et al. Clean Coal Technology, 2020, 27(3), 211(in Chinese).
邵嘉铭,王智化,林法伟,等. 洁净煤技术, 2020, 27(3), 211.
80 Loethgren C, Bavel B V. Chemosphere, 2005, 61(3), 405.
81 Takaoka M, Liao P, Takeda N, et al. Chemosphere, 2003, 53(2), 153.
82 Zhang W B, Mei L T. Industrial Safety and Environmental Protection, 2008, 34(4), 40(in Chinese).
张文斌,梅连廷.工业安全与环保, 2008, 34(4), 40.
83 Li Y, Zhao Y J. Resources Economization & Environmental Protection, 2016, 164(2), 166(in Chinese).
李勇,赵彦杰. 资源节约与环保, 2016, 164(2), 166.
84 Wu Y F. Electric Power Environmental Protection, 2017, 33(2), 22(in Chinese).
吴曰丰.电力科技与环保, 2017, 33(2), 22.
85 Lin X, Ma Y, Chen Z, et al. Environmental Pollution, 2020, 265, 114888.
86 Li J. Technological Development of Enterprise, 2018, 37(9), 95(in Chinese).
李娟. 企业技术开发, 2018, 37(9), 95.
87 Hu Z, Jiang E, Ma X. Fuel, 2019, 245, 160.
88 Van Caneghem J, De Greef J, Block C, et al. Journal of Cleaner Production, 2016, 112, 4452.
89 Yu G Y, Xie X M, Hua Y L, et al. Guangzhou Chemical Industry, 2020, 48(14),125(in Chinese).
于杲旸,解晓明,华玉龙,等.广州化工, 2020, 48(14), 125.
90 Gohlke O, Weber T, Seguin P, et al. Waste Management, 2010, 30, 1348.
91 Goemans M, Clarysse P, Joannes J, et al. Chemosphere,2004,54,1357.
92 Gomez-Garcia M A, Pitchon V, Kiennemann A. Environment Internatio-nal, 2005, 31(3), 445.
93 Wang F. Resources Economization & Environmental Protection, 2018(5), 140(in Chinese).
王飞. 资源节约与环保, 2018(5), 140.
94 Pena D A, Uphade B S, Smirniotis P G. Journal of Catalysis, 2004, 221(2), 421.
95 Zhou H Q, Song X D, Tao X B, et al. Journal of Shanghai University of Electric Power, 2018, 34(3), 287(in Chinese).
周洪权,宋学顶,陶晓波,等.上海电力学院学报,2018,34(3),287.
96 Hyounduk J, Eunseuk P, Minsu K, et al. Waste Management,2017,61,283.
97 Wang S Z. Hi-Tech Fiber and Application,1999,24(6),12(in Chinese).
王曙中.高科技纤维与应用, 1999, 24(6), 12.
98 Deng H P. Huadian Technology, 2010, 32(11), 72(in Chinese).
邓辉鹏.华电技术, 2010, 32(11), 72.
99 Liu S H, Chen Y T, Feng H L. Science & Technology Information, 2009,31,890(in Chinese).
柳少华,陈延涛,冯会玲. 科技信息, 2009,31,890.