Effects of reaction pathway and particle heat absorption on gasifier: a numerical study

doi:10.16085/j.issn.1000-6613.2016.02.006

Chemical Industry and Engineering Progree ›› 2016, Vol. 35 ›› Issue (02): 376-382.DOI: 10.16085/j.issn.1000-6613.2016.02.006

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Effects of reaction pathway and particle heat absorption on gasifier: a numerical study

ZHONG Hanbin¹, LAN Xingying², GAO Jinsen²

1 College of Chemistry and Chemical Engineering, Xi'an Shiyou University, Xi'an710065, Shaanxi, China;
2 State Key Laboratory of Heavy Oil Processing, China University of Petroleum-Beijing, Beijing 102249, China

Received:2015-07-02 Revised:2015-07-27 Online:2016-02-05 Published:2016-02-05

反应路径和颗粒吸热对气化炉数值模拟的影响

钟汉斌¹, 蓝兴英², 高金森²

1 西安石油大学化学化工学院, 陕西西安 710065;
2 中国石油大学(北京)重质油国家重点实验室, 北京 102249

通讯作者: 蓝兴英,教授,博士生导师,研究方向为清洁油品生产、重质油加工、多相反应工程。E-mail:lanxy@cup.edu.cn。
作者简介:钟汉斌(1986-),男,博士,讲师,研究方向为重质油加工、多相流反应工程及计算流体力学。E-mail:hanbinzhong@126.com
基金资助:
国家重点基础研究发展计划项目(2012CB215003)。

Abstract

Abstract: The gasification technology is an efficient way to process inferior crude oil,unconventional oil and coal with lower emissions,and numerical simuation is an important method to reveal the complex flow and reaction behavior in the gasifier. In order to evaluate the influence of volatile reaction pathway and particle reaction heat absorption ratio,the Orimulsion gasification process in an entrained-flow gasifier was simulated with Eulerian-Lagrangian method. The homogenous reactions and heterogeneous reactions were described by the finite-rate/eddy-dissipation model and particle surface reaction model,respectively. The simulation results demonstrate that the reaction pathway of volatile mainly affects temperature and species distributions in the near-nozzle region,while those at the outlet of the gasifier change only slightly. However,the effect of particle heat absorption ratio is almost negligible due to the lower amount of fixed carbon in the Orimulsion and the small reaction heat of coke combustion.

Key words: gasification, numerical study, reaction pathway, heat absorption, orimulsion

摘要： 气化工艺是实现劣质原油、非常规石油资源和煤炭高效清洁加工的有效途径,数值模拟是揭示气化炉内复杂流动反应行为的重要手段。为了考察挥发分反应路径和颗粒反应热吸收率对预测结果的影响,以奥里乳化油气流床气化过程为例采用欧拉-拉格朗日方法对气化炉进行数值模拟研究,均相反应和非均相反应过程分别通过有限速率/涡耗散反应模型和颗粒表面化学反应模型描述。结果表明,挥发分反应路径主要影响气化炉内气化反应的过程,如靠近喷嘴处的温度和组分分布,但对最终气化炉出口处的温度和组分分布影响相对较小。而由于原料中较低的固定碳质量分数以及较少的焦炭燃烧反应热,颗粒反应热吸收率对预测结果影响很小。

关键词: 气化, 数值模拟, 反应历程, 吸热, 奥里乳化油

CLC Number:

TQ021.1

ZHONG Hanbin, LAN Xingying, GAO Jinsen. Effects of reaction pathway and particle heat absorption on gasifier: a numerical study[J]. Chemical Industry and Engineering Progree, 2016, 35(02): 376-382.

钟汉斌, 蓝兴英, 高金森. 反应路径和颗粒吸热对气化炉数值模拟的影响[J]. 化工进展, 2016, 35(02): 376-382.

References

[1] 曹湘洪. 高油价时代渣油加工工艺路线的选择[J]. 石油炼制与化工,2009,40(1):1-9.
[2] ASHIZAWA M,HARA S,KIDOGUCHI K,et al. Gasification characteristics of extra-heavy oil in a research-scale gasifier[J]. Energy,2005,30(11/12):2194-2205.
[3] SILAEN A,WANG T. Effect of turbulence and devolatilization models on coal gasification simulation in an entrained-flow gasifier[J]. International Journal of Heat and Mass Transfer,2010,53(9/10):2074-2091.
[4] CHUI E H,MAJESKI A J,LU D Y,et al. Simulation of entrained flow coal gasification[J]. Energy Procedia,2009,1(1):503-509.
[5] WANG T,SILAEN A,HSU H-W,et al. Investigation of heat transfer and gasification of two different fuel injectors in an entrained flow coal gasifier[J]. Journal of Thermal Science and Engineering Applications,2010,2(1):011001-011010.
[6] Fluent Inc. Fluent 6.3 User's Guide[M]. 2006.
[7] 蒋德军,许建良,刘海峰,等. 脱油沥青气化炉内气化反应数值模拟[J]. 华东理工大学学报(自然科学版) 2011,37(2):151-155.
[8] LAN X,ZHONG H,GAO J. CFD simulation on the gasification of asphalt water slurry in an entrained flow gasifier[J]. Petroleum Science,2014,11(2):308-317.
[9] 吴玉新,蔡春荣,张建胜,等. 二次氧量对分级气化炉气化特性影响的分析和比较[J]. 化工学报,2012,63(2):369-374.
[10] SUN Z,DAI Z,ZHOU Z,et al. Numerical simulation of industrial opposed multiburner coal-water slurry entrained flow gasifier[J]. Industrial & Engineering Chemistry Research,2012,51(6):2560-2569.
[11] 钟汉斌,蓝兴英,高金森,等. 奥里乳化油气流床气化过程的数值模拟研究[J]. 现代化工,2013,33(2):107-110.
[12] WATANABE H,OTAKA M,HARA S,et al. Modelling and simulation for extra heavy oil gasification on entrained flow gasifier[C]//Proceedings of the IJPGC'02:2002 International Joint Power Generation Conference,USA:ASME,2002:667-674.
[13] GONG J S,FU W B,ZHONG B J. A study on the pyrolysis of asphalt[J]. Fuel,2003,82:49-52.
[14] WESTBROOK C K,DRYER F L. Simplified reaction mechanisms for the oxidation of hydrocarbon fuels in flames[J]. Combustion Science and Technology,1981,27(1/2):31-43.
[15] JONES W P,LINDSTEDT R P. Global reaction schemes for hydrocarbon combustion[J]. Combustion and Flame,1988,73(3):233-249.
[16] BUSTAMANTE F,ENICK R M,KILLMEYER R P,et al. Uncatalyzed and wall-catalyzed forward water-gas shift reaction kinetics[J]. AIChE Journal,2005,51(5):1440-1454.
[17] HARRIS D J,SMITH I W. Intrinsic reactivity of petroleum coke and brown coal char to carbon dioxide,steam and oxygen[J]. Symposium (International) on Combustion,1991,23(1):1185-1190.
[18] 钟汉斌. 重油残渣水浆气化工艺基础的数值模拟研究[D]. 北京:中国石油大学(北京)化学工程学院,2013

Effects of reaction pathway and particle heat absorption on gasifier: a numerical study

反应路径和颗粒吸热对气化炉数值模拟的影响

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