Characteristics of mass and heat transfer in lignite pyrolysis with solid heat carrier

doi:10.11949/j.issn.0438-1157.20150598

CIESC Journal ›› 2016, Vol. 67 ›› Issue (4): 1136-1144.DOI: 10.11949/j.issn.0438-1157.20150598

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Characteristics of mass and heat transfer in lignite pyrolysis with solid heat carrier

LI Fangzhou, LI Wenying, FENG Jie

Key Laboratory of Coal Science and Technology of Ministry of Education and Shanxi Province, Training Base of State Key Laboratory of Coal Science and Technology Jointly Constructed by Shanxi Province and Ministry of Science and Technology, Taiyuan University of Technology, Taiyuan 030024, Shanxi, China

Received:2015-05-12 Revised:2015-11-06 Online:2016-04-05 Published:2016-04-05
Supported by:
supported by the National Natural Science Foundation of China (51276120, U1361202), the Higher Specialized Research Fund for the Doctoral Program (20121402110016) and the National High Technology Research and Development Program of China(2011AA05A202).

固体热载体法褐煤热解过程中的传质传热特性

李方舟, 李文英, 冯杰

太原理工大学煤科学与技术教育部和山西省重点实验室, 山西省煤科学与技术省部共建国家重点实验室培育基地, 山西太原 030024

通讯作者: 李文英
基金资助:
国家自然科学基金项目(51276120,U1361202);高等学校博士学科点专项科研基金(20121402110016);国家高技术研究发展计划项目(2011AA05A202)。

Abstract

Abstract:

A comprehensive numerical model coupled two correlative one-dimensional unsteady heat conduction equations of spherical particle with distributed activation energy model has been developed for heat and mass transfer mechanism in lignite pyrolysis with solid heat carrier. The finite volume method and the genetic algorithm optimization toolbox based on Matlab software were employed to calculate the thermal and dynamic parameters, separately, and the reliability of the predictions was further validated by thermogravimetric data of the Hulunbuir lignite and temperature measuring experiment on a laboratory-scale fixed bed reactor, respectively. It was found that the variations in mass and heat transfer during lignite pyrolysis with solid heat carrier showed a complex coupling characteristic. The time-dependent rules of temperature field in radial direction have been obtained by varying operation conditions, such as coal particle radius, the initial temperature and feed amount of solid heat carrier. Besides, the relationship between the releasing rate of pyrolytic products and temperature field revealed that the change of temperature field with heating time in lignite pyrolysis was the primary cause of different distribution of the pyrolytic products.

Key words: solid heat carrier, lignite pyrolysis, heat transfer, mass transfer, numerical simulation

摘要：

为揭示在固定床反应器中固体热载体法快速热解褐煤工艺过程中的热、质传递机理,建立了固体热载体法褐煤热解过程中的传质传热模型。模型包括球型颗粒的一维非稳态导热方程和基于分布活化能模型的动力学模块,分别采用有限容积法与Matlab软件中遗传算法工具箱对二者进行数值计算。通过呼伦贝尔褐煤热重实验数据与温度测定实验数据分别验证了预测的动力学参数及颗粒传热模型结果。研究发现,热、质变化在固体热载体法褐煤热解工艺中呈现复杂的耦合特性。此外,考察了在不同初始温度、热载体进料比与煤颗粒半径条件下,褐煤在热解过程中颗粒内部温度场在径向上随时间的变化规律,并分析了产物释放速率与温度场的关联性,结果表明热历程改变是工艺条件对热解产物分布造成影响的根本原因。

关键词: 固体热载体, 褐煤热解, 传热, 传质, 数值模拟

CLC Number:

TQ021

LI Fangzhou, LI Wenying, FENG Jie. Characteristics of mass and heat transfer in lignite pyrolysis with solid heat carrier[J]. CIESC Journal, 2016, 67(4): 1136-1144.

李方舟, 李文英, 冯杰. 固体热载体法褐煤热解过程中的传质传热特性[J]. 化工学报, 2016, 67(4): 1136-1144.

References 27

[1]	李文英, 邓靖, 喻长连. 褐煤固体热载体热解提质工艺进展[J]. 煤化工, 2012, 40(1): 1-5. LI W Y, DENG J, YU C L. Development of lignite pyrolysis with solid heat carrier[J]. Coal Chem. Ind., 2012, 40(1): 1-5.
[2]	LIANG P, WANG Z F, BI J C. Simulation of coal pyrolysis by solid heat carrier in a moving-bed pyrolyzer[J]. Fuel, 2008, 87(4/5): 435-442.
[3]	郭治, 杜铭华, 杜万斗. 固体热载体褐煤热解过程的数学模型与模拟计算[J]. 神华科技, 2010, 8(2): 69-72. GUO Z, DU M H, DU W D. The mathematical model and simulation of solid heat carrier pyrolysis of lignite[J]. Shenhua Sci. Technol., 2010, 8(2): 69-72.
[4]	王洪亮, 蒙涛, 张华, 等. 球型固体热载体煤粉热解过程传热计算及分析[J]. 洁净煤技术, 2014, 20(3): 90-94. WANG H L, MENG T, ZHANG H, et al. Heat transfer calculation and analysis of coal particle pyrolysis with solid ball heat carrier[J]. Clean Coal Technol., 2014, 20(3): 90-94.
[5]	ZHAO Y X, SERIO M A, SOLOMON P R. A general model for devolatilization of large coal particles[J]. Symp. (Int.) Combust., 1996, 26(2): 3145-3151.
[6]	刘训良, 曹欢, 王淦, 等. 煤颗粒热解的传热传质分析[J]. 计算物理, 2014, 31(1): 59-66. LIU X L, CAO H, WANG G, et al. Numerical analysis of heat and mass transfer during pyrolysis of coal particle[J]. Chin. J. Comput. Phys., 2014, 31(1): 59-66.
[7]	LIU X L, WANG G, PAN G, et al. Numerical analysis of heat transfer and volatile evolution of coal particle[J]. Fuel, 2013, 106: 667-673.
[8]	ADESANYA B A, PHAM H N. Mathematical modelling of devolatilization of large coal particles in a convective environment[J]. Fuel, 1995, 74(6): 896-902.
[9]	胡国新, 田学伟, 许伟, 等. 大颗粒煤在移动床中的热解模型[J]. 上海交通大学学报, 2001, 35(5): 733-736. HU G X, TIAN X W, XU W, et al. Devolatilization model of large coal particles in moving bed[J]. J. Shanghai Jiaotong Univer., 2001, 35(5): 733-736.
[10]	CHERN J S, HAYHURST A N. A simple theoretical analysis of the pyrolysis of an isothermal particle of coal[J]. Combust. Flame, 2010, 157(5): 925-933.
[11]	SUN J, CHEN M M. A theoretical analysis of heat transfer due to particle impact[J]. Int. J. Heat Mass Transfer, 1988, 31(5): 969-975.
[12]	NATARAJAN V V R, HUNT M L. Heat transfer in vertical granular flows[J]. Exp. Heat Transfer, 1997, 10(2): 89-107.
[13]	WATSON L V, MCCARTHY J J. Heat conduction in granular materials[J]. AIChE J., 2001, 47(5): 1052-1059.
[14]	BHARADWAJ R, KETTERHAGEN W R, HANCOCK B C. Discrete element simulation study of a Freeman powder rheometer[J]. Chem. Eng. Sci., 2010, 65(21): 5747-5756.
[15]	WAKAO N, KAGUEI S, FUNAZKRI T. Effect of fluid dispersion coefficients on particle-to-fluid heat transfer coefficients in packed beds: correlation of Nusselt numbers[J]. Chem. Eng. Sci., 1979, 34(3): 325-336.
[16]	RANZ W E. Friction and transfer coefficients for single particles and packed beds[J]. Chem. Eng. Prog., 1952, 48(5): 247-253.
[17]	ROWE P N, CLAXTON K T, LEWIS J B. Heat and mass transfer from a single sphere in an extensive flowing fluid[J]. Trans. Inst. Chem. Eng., 1965, 43(1): T14-T31.
[18]	GUNN D J. Transfer of heat or mass to particles in fixed and fluidised beds[J]. Heat Mass Transfer, 1978, 21(4): 467-476.
[19]	郭雪岩, 柴辉生, 晁东海. 大颗粒流化床传热数值模拟与气固传热模型比较[J].上海理工大学学报, 2012, 34(1): 81-87. GUO X Y, CHAI H S, CHAO D H. Numerical simulation of large particle fluidized bed and comparison of gas-particle heat transfer models[J]. J. Univ. Shanghai Sci. Technol., 2012, 34(1): 81-87.
[20]	杨景标, 张彦文, 蔡宁生. 煤热解动力学的单一反应模型和分布活化能模型比较[J]. 热能动力工程, 2010, 25(3): 301-305. YANG J B, ZHANG Y W, CAI N S. A comparison of a single reaction model with a distributed activation energy one based on coal pyrolysis kinetics[J]. J. Eng. Therm. Energy Power, 2010, 25(3): 301-305.
[21]	陶文铨. 数值传热学[M]. 上海: 上海交通大学出版社, 2001: 79-103. TAO W Q. Numerical Heat Transfer[M]. Shanghai: Shanghai Jiaotong University Press, 2001: 79-103.
[22]	CAI J M, YAO F S, YI W M, et al. New temperature integral approximation for nonisothermal kinetics[J]. AIChE J., 2006, 52(4): 1554-1557
[23]	GAO F. Applications of matlab in mathematical analysis[J]. J. Software, 2011, 6(7): 1225-1229.
[24]	孙玉凤, 高虹, 王通洲. 生物质热解分布活化能模型的遗传算法实现[J]. 沈阳理工大学学报, 2010, 29(3): 63-66. SUN Y F, GAO H, WANG T Z. Application of genetic algorithm in distributed activation energy model of biomass pyrolysis[J]. J. Shenyang Ligong Univ., 2010, 29(3): 63-66.
[25]	MUSTAFA G, SEMMIN F. A direct search method for determination of DAEM kinetic parameters from nonisothermal TGA data (note)[J]. Appl. Math. Comput., 2002, 130: 619-628.
[26]	MIURA K, MAKI T. A simple method for estimating f(E) and k0(E) in the distributed activation energy mode[J]. Energy Fuels, 1998, 12: 864-869.
[27]	YI Q, FENG J, LU B C, et al. Energy evaluation for lignite pyrolysis by solid heat carrier coupled with gasification[J]. Energy Fuels, 2013, 27(8): 4523-4533.

Characteristics of mass and heat transfer in lignite pyrolysis with solid heat carrier

固体热载体法褐煤热解过程中的传质传热特性

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