Model for the formation of initial deposited layer by K-containing species and influence analysis of flue gas conditions

doi:10.11949/0438-1157.20190337

Abstract

Abstract:

Aiming at the two main mechanisms of initial deposition layer of ash deposition, namely, condensation and thermophoresis mechanism, a mathematical model for the formation of initial deposition layer by K-containing species was established. The rationality of the model was validated by the experimental results in the literature which indicates that considering the changes of the thickness of the deposition layer and the surface temperature have a reasonable improvement. The model was used to study the deposition process of K-containing gas and aerosol particles on the heating surface, and to investigate the effects of K-containing species composition, flue gas temperature and velocity. The results show that, because of the difference in the relative concentrations of K-containing gas and aerosol particles, both condensation and thermophoresis deposition may play a major role in the formation of the initial deposition layer at the beginning of the deposition process, while thermophoretic deposition dominates the later stage. The effects of flue gas temperature and velocity on the deposition process is similar, that is, the higher flue gas temperature and velocity, the higher the initial deposition rate, the lower the later deposition rate, and the lower the thickness of the deposited layer.

Key words: biomass combustion, deposition, initial deposition layer, model

摘要：

针对积灰初始沉积层形成的两种主要机理即凝结和热泳机理，建立了含K成分形成初始沉积层的数学模型，采用文献中的实验结果检验了模型，表明考虑沉积层厚度、表面温度随位置和时间的变化对模型预测有合理的改善。应用该模型研究含K气体成分和气溶胶颗粒在受热面上的沉积过程，并考察烟气中含K成分组成、烟温和烟速等因素的影响。研究表明，由于烟气中含K气体成分和气溶胶颗粒相对浓度的差异，凝结和热泳在沉积过程开始时都可能对初始沉积层的形成起主要作用，而在沉积过程后期热泳沉积则占据主导地位；烟温和烟速对含K成分沉积过程的影响相似，即较高的烟气温度和速度，其初期沉积速率高，而后期沉积速率相对低，形成的沉积层厚度较低。

关键词: 生物质燃烧, 积灰, 初始沉积层, 模型

CLC Number:

TK 6

Hengqing SUN, Changdong SHENG. Model for the formation of initial deposited layer by K-containing species and influence analysis of flue gas conditions[J]. CIESC Journal, 2019, 70(9): 3495-3502.

孙恒清, 盛昌栋. 含K成分形成初始沉积层的数学模型及烟气条件影响分析[J]. 化工学报, 2019, 70(9): 3495-3502.

Figures/Tables 7

Fig.1 Schematic diagram of formation of initial deposition layer

Fig.2 Comparison of deposition mass of K-containing species calculated by model with experimental and model results of Hansen

Fig.3 Comparison of deposition mass of K-containing species calculated by model with the sum of model results of two mechanisms

Fig.4 Variations of deposition rate, temperature, condensation deposition rate and thermophoresis deposition rate along time under different concentration ratio of KCl to K2SO4

Fig.5 Variations of deposition rate of K-containing species and deposition layer thickness along time under different flue gas temperature and velocity

Fig.6 Variations of deposition layer thickness along time under conditions of x=2∶1, T g=1273 K, v=9 m/s

Fig.7 Variations of the maximum deposition thickness on heating surface under conditions of x=2∶1, T g=1273 K, v=9 m/s

References 32

1	Jenkins B M , Baxter L L , Miles T R , et al . Combustion properties of biomass [J]. Fuel Processing Technology, 1998, 54(1/2/3): 17-46.
2	胡理乐, 李亮, 李俊生 . 生物质能源的特点及其环境效应[J]. 能源与环境, 2012, (1): 47-49.
	Hu L L , Li L , Li J S . Characteristics of biomass energy and its environmental effects [J]. Energy and Environment, 2012, (1): 47-49.
3	喻火明 . 电站锅炉受热面积灰结渣在线监测的研究[D]. 北京: 华北电力大学, 2006.
	Yu H M . Researches of on-line monitoring of heating surface fouling and slagging in power plant boiler [D]. Beijing: North China Electric Power University, 2006.
4	Bryers R W . Fireside slagging, fouling, and high-temperature corrosion of heat-transfer surface due to impurities in steam-raising fuels [J]. Progress in Energy & Combustion Science, 1996, 22(1): 29-120.
5	Hansen L A , Nielsen H P , Frandsen F J , et al . Influence of deposit formation on corrosion at a straw-fired boiler [J]. Fuel Processing Technology, 2000, 64: 189-209.
6	黄海珍, 于秀敏, 陈海波, 等 . 煤与生物质混合燃烧特性实验研究[J]. 化工进展, 2006, 25(s1): 599-603.
	Huang H Z , Yu X M , Chen H B , et al . Experimental study on combustion characteristics of co-firing by coal and biomass [J]. Chemical Industry and Engineering Progress, 2006, 25(s1): 599-603.
7	Zheng Y , Jensen P A , Jensen A D , et al . Ash transformation during co-firing coal and straw [J]. Fuel, 2007, 86: 1008-1020.
8	徐明厚 . 燃煤可吸入颗粒物的形成与排放[M]. 北京: 科学出版社, 2009.
	Xu M H . Formation and Discharge of Inhalable Particulate Matter by Burning Coal [M]. Beijing: Science Press, 2009.
9	张志潮, 刘晶, 杨应举, 等 . 燃煤锅炉烟气中Na₂SO₄生成的化学动力学研究[J]. 化工学报, 2018, 69(8): 3643-3650.
	Zhang Z C , Liu J , Yang Y J , et al . Study on chemical kinetics of Na₂SO₄ formation in coal fired flue gas [J]. CIESC Journal, 2018, 69(8): 3643-3650.
10	刘涛, 陈雪莉, 李德侠, 等 . 生物质与煤混合灰的熔融及黏温特性[J]. 化工学报, 2012, 63(4): 1217-1225.
	Liu T , Chen X L , Li D X , et al . Blending ash fusion and viscosity-temperature characteristics of biomass and coal[J]. CIESC Journal, 2012, 63(4): 1217-1225.
11	Baxter L L . Ash deposition during biomass and coal combustion: a mechanistic approach [J]. Biomass & Bioenergy, 1993, 4(2): 85-102.
12	Xu M , Yu D , Yao H , et al . Coal combustion-generated aerosols: formation and properties [J]. Proceedings of the Combustion Institute, 2011, 33(1): 1681-1697.
13	Zhan Z , Wendt J O L . Role of sodium in coal in determining deposition rates [J]. Energy & Fuels, 2017, 31: 2198-2202.
14	Huang L Y , Norman J S , Pourkashanian M , et al . Prediction of ash deposition on superheater tubes from pulverized coal combustion[J]. Fuel, 1996, 37(3): 271-279.
15	Zhan Z , Fry A , Zhang Y , et al . Ash aerosol formation from oxy-coal combustion and its relation to ash deposit chemistry[J]. Proceedings of the Combustion Institute, 2015, 35(2): 2373-2380.
16	Zhan Z , Fry A R , Wendt J O L . Deposition of coal ash on a vertical surface in a 100 kW downflow laboratory combustor: a comparison of theory and experiment [J]. Proceedings of the Combustion Institute, 2017, 36(2): 2091-2101.
17	Li J , Zhu M , Zhang Z , et al . Characterisation of ash deposits on a probe at different temperatures during combustion of a Zhundong lignite in a drop tube furnace[J]. Fuel Processing Technology, 2016, 144: 155-163.
18	Kleinhans U , Rück R , Schmid S , et al . Alkali vapor condensation on heat exchanging surfaces: laboratory-scale experiments and a mechanistic CFD modeling approach[J]. Energy & Fuels, 2016, 30: 9793-9800.
19	Zhan Z , Fry A R , Wendt J O L . Relationship between submicron ash aerosol characteristics and ash deposit compositions and formation rates during air- and oxy-coal combustion [J]. Fuel, 2016, 181: 1214-1223.
20	Capablo J . Formation of alkali salt deposits in biomass combustion [J]. Fuel Processing Technology, 2016, 153: 58-73.
21	Hansen S B , Jensen P A , Frandsen F J , et al . Mechanistic model for ash deposit formation in biomass suspension-firing (1): Model verification by use of entrained flow reactor experiments [J]. Energy & Fuels, 2017, 31: 2771-2789.
22	Hansen S B , Jensen P A , Frandsen F J , et al . Mechanistic model for ash deposit formation in biomass suspension-firing (2): Model verification by use of full scale tests[J]. Energy & Fuels, 2017, 31: 2790-2802.
23	Capablo J , Salvadó J . Estimating heat transfer losses caused by alkali salt deposits in biomass combustion [J]. Renewable Energy, 2017, 105: 449-457.
24	Hansen S B . model for deposition build-up in biomass boilers[D]. Copenhagen: Technical University of Denmark, 2015.
25	耶菲莫夫 . 无机化合物性质手册[M]. 西安: 陕西科学技术出版社, 1987.
	Ефимов А И . Handbook of Inorganic Compounds Properties[M]. Xi’an: Shaanxi Science and Technology Press, 1987
26	伊赫桑·巴伦 . 纯物质热化学数据手册[M]. 北京: 科学出版社, 2003.
	Barin I . Pure Substance Thermochemical Data Manual [M]. Beijing: Science Press, 2003.
27	Knacke O , Kubaschewski O , Hesselmann K . Thermochemical Properties of Inorganic Substances[M]. 2nd ed. Verlag Stahleisen, 1991.
28	Zhou H , Jensen P A , Frandsen F J . Dynamic mechanistic model of superheater deposit growth and shedding in a biomass fired grate boiler [J]. Fuel, 2007, 86(10/11): 1519-1533.
29	Brock J R . On the theory of thermal forces acting on aerosol particles[J]. Journal of Colloid Science, 1962, 17(8): 768-780.
30	Davies C N . Definitive equations for the fluid resistance of spheres[J]. The Proceedings of the Physical Society, 1945, 57: 259- 270.
31	Kassman H , Bäver L , Åmand L E . The importance of SO₂ and SO₃ for sulphation of gaseous KCl — an experimental investigation in a biomass fired CFB boiler[J]. Combustion and Flame, 2010, 157: 1649-1657.
32	Kassman H , Pettersson J , Steenari B M , et al . Two strategies to reduce gaseous KCl and chlorine in deposits during biomass combustion - injection of ammonium sulphate and co-combustion with peat[J]. Fuel Processing Technology, 2013, 105: 170-180.

[1]	Jiahao SONG, Wen WANG. Study on coupling operation characteristics of Stirling engine and high temperature heat pipe [J]. CIESC Journal, 2023, 74(S1): 287-294.
[2]	Mengya LIAN, Yingying TAN, Lin WANG, Feng CHEN, Yifei CAO. Heating performance of air preheated integrated ground water heat pump air-conditioning system [J]. CIESC Journal, 2023, 74(S1): 311-319.
[3]	Zhenghao JIN, Lijie FENG, Shuhong LI. Energy and exergy analysis of a solution cross-type absorption-resorption heat pump using NH₃/H₂O as working fluid [J]. CIESC Journal, 2023, 74(S1): 53-63.
[4]	Cheng CHENG, Zhongdi DUAN, Haoran SUN, Haitao HU, Hongxiang XUE. Lattice Boltzmann simulation of surface microstructure effect on crystallization fouling [J]. CIESC Journal, 2023, 74(S1): 74-86.
[5]	Ke LI, Jian WEN, Biping XIN. Study on influence mechanism of vacuum multi-layer insulation coupled with vapor-cooled shield on self-pressurization process of liquid hydrogen storage tank [J]. CIESC Journal, 2023, 74(9): 3786-3796.
[6]	Hao WANG, Zhenlei WANG. Model simplification strategy of cracking furnace coking based on adaptive spectroscopy method [J]. CIESC Journal, 2023, 74(9): 3855-3864.
[7]	Guoze CHEN, Dong WEI, Qian GUO, Zhiping XIANG. Optimal power point optimization method for aluminum-air batteries under load tracking condition [J]. CIESC Journal, 2023, 74(8): 3533-3542.
[8]	Jintong LI, Shun QIU, Wenshou SUN. Oxalic acid and UV enhanced arsenic leaching from coal in flue gas desulfurization by coal slurry [J]. CIESC Journal, 2023, 74(8): 3522-3532.
[9]	Wenxiang NI, Jing ZHAO, Bo LI, Xiaolin WEI, Dongyin WU, Di LIU, Qiang WANG. Study on waste heat boiler ash deposition characteristics in sensible heat recovery process of converter gas [J]. CIESC Journal, 2023, 74(8): 3485-3493.
[10]	Xudong YU, Qi LI, Niancu CHEN, Li DU, Siying REN, Ying ZENG. Phase equilibria and calculation of aqueous ternary system KCl + CaCl₂ + H₂O at 298.2, 323.2, and 348.2 K [J]. CIESC Journal, 2023, 74(8): 3256-3265.
[11]	Chengying ZHU, Zhenlei WANG. Operation optimization of ethylene cracking furnace based on improved deep reinforcement learning algorithm [J]. CIESC Journal, 2023, 74(8): 3429-3437.
[12]	Linqi YAN, Zhenlei WANG. Multi-step predictive soft sensor modeling based on STA-BiLSTM-LightGBM combined model [J]. CIESC Journal, 2023, 74(8): 3407-3418.
[13]	Yuying GUO, Jiaqiang JING, Wanni HUANG, Ping ZHANG, Jie SUN, Yu ZHU, Junxuan FENG, Hongjiang LU. Water-lubricated drag reduction and pressure drop model modification for heavy oil pipeline [J]. CIESC Journal, 2023, 74(7): 2898-2907.
[14]	Chunyu LIU, Huanyu ZHOU, Yue MA, Changtao YUE. Drying characteristics and mathematical model of CaO-conditioned oil sludge [J]. CIESC Journal, 2023, 74(7): 3018-3027.
[15]	Weiming SHAO, Wenxue HAN, Wei SONG, Yong YANG, Can CHEN, Dongya ZHAO. Dynamic soft sensor modeling method based on distributed Bayesian hidden Markov regression [J]. CIESC Journal, 2023, 74(6): 2495-2502.