Modeling, simulation and analysis for coal and coke-oven gas to synthetic natural gas

doi:10.11949/j.issn.0438-1157.20151375

Abstract

Abstract:

Coal to synthetic natural gas (SNG) process is regarded as one of promising way to tackle with haze in north China and is developed rapidly in China. However, coal to SNG processes suffer from the high energy consumption and CO₂ emission due to the high carbon contents of coal. In China, there is 7×10¹⁰ m³ coke-oven gas (COG) produced in coke plants annually. Most of the hydrogen-rich COG is utilized as fuel or discharged directly into the air. Such situation is a waste of precious hydrogen resource and causes serious economic loss and environmental pollution either. The co-feed process of coal and COG to SNG is a promising solution for these problems. In the co-feed process, CH₄ of COG reacts with CO₂ in a dry methane reforming unit to reduce emissions and H₂ of COG can adjust the H/C ratio of syngas. This paper makes a modeling, simulation and system analysis for the co-feed process of coal and COG to SNG. The results show that the energy efficiency of the co-feed process increases by 8%, while at the same time, CO₂ emission is reduced by 60% in comparison to the conventional coal to SNG process.

Key words: computer simulation, syngas, systems engineering, coke-oven gas, natural gas

摘要：

近年来中国的煤制天然气项目快速发展。然而煤制天然气项目的CO₂排放量大、污水产量高难处理,生产过程能效低。与此同时,中国焦炭工业每年产生约700亿立方米的副产物焦炉气,这些富氢的焦炉气大多被燃烧或直接排放进入大气,对环境造成严重影响,同时还浪费了巨大的经济价值。煤和焦炉气联供制天然气新工艺可有效解决这些问题。焦炉气与煤元素互补,焦炉气中的氢气可用来调节合成气的氢碳比;甲烷可通过甲烷干重整过程降低煤制烯烃过程排放的CO₂,提高碳元素利用率,实现节能减排。本文针对煤和焦炉气联供制天然气这个新的工艺过程进行建模、模拟与分析,发现新过程的能效比煤天然气烃过程提高了约8个百分点,而CO₂排放量则减少了约60%。

关键词: 计算机模拟, 合成气, 系统工程, 焦炉气, 天然气

CLC Number:

TQ536.1

MAN Yi, YANG Siyu, XIAO Honghua, QIAN Yu. Modeling, simulation and analysis for coal and coke-oven gas to synthetic natural gas[J]. CIESC Journal, 2015, 66(12): 4941-4947.

满奕, 杨思宇, 萧鸿华, 钱宇. 煤和焦炉气联供制合成天然气过程的建模、模拟与分析[J]. 化工学报, 2015, 66(12): 4941-4947.

References 20

[1]	Yang Shuhong (杨舒鸿), Ding Yanjun (丁艳军). Life cycle assessment on synthetic natural gas (SNG) technology [J]. Modern Chemical Industry (现代化工), 2012, 32(9): 4-7.
[2]	National Bureau of Statistics (国家统计局). China Energy Statistics Yearbook (中国能源统计年鉴) [M]. Beijing: China Statistics Press, 2014.
[3]	Li Chuanri (李传锐), Liu Yongjian (刘永健), Li Chunqi (李春启), Zuo Yubang (左玉帮)). Analysis of the present status, the policy and application development of coal to SNG in China [J]. Chemical Industry (化学工业), 2015, 33(1): 1-9.
[4]	Li H, Yang S, Zhang J, Kraslawski A, Qian Y. Analysis of rationality of coal-based synthetic natural gas (SNG) production in China [J]. Energy Policy, 2014, 71: 180-188.
[5]	Li H, Yang S, Zhang J, Qian Y. Coal-based synthetic natural gas (SNG) for municipal heating in China: analysis of haze pollutants and greenhouse gases (GHGs) emissions [J]. Journal of Cleaner Production, 2015. http://dx.doi.org/10.1016/j.jclepro.2015.04.078
[6]	Man Y, Yang S, Xiang D, Li X, Qian Y. Environmental impact and techno-economic analysis of the coal gasification process with/without CO2 capture [J]. Journal of Cleaner Production, 2014, 71: 59-66.
[7]	Razzaq R, Li C, Zhang S. Coke oven gas: availability, properties, purification, and utilization in China [J]. Fuel, 2013, 113: 287-99.
[8]	Qian Y, Man Y, Peng L, Zhou H. Integrated process of coke-oven gas tri-reforming and coal gasification to methanol with high carbon utilization and energy efficiency [J]. Industrial & Engineering Chemistry Research, 2015, 54(9): 2519-2525.
[9]	Zheng Anqing (郑安庆), Feng Jie (冯杰), Ge Lingjuan (葛玲娟), Yi Qun (易群), Li Wenying (李文英). Modeling and optimization of polygeneration system with coke-oven gas and coal gasified gas by Aspen Plus (Ⅰ) [J]. CIESC Journal (化工学报), 2010, 61 (4): 969-978.
[10]	Yi Qun (易群), Wu Yanli (吴彦丽), Fan Yang (范洋), Hu Changchun(胡长淳), Chu Qi (褚琦), Feng Jie (冯杰), Li Wenying (李文英). Economic evaluation of industrial chain extension solutions for coke oven gas to methanol and chemicals [J]. CIESC Journal (化工学报), 2014, 65 (3): 1003-1011.
[11]	Lin H, Jin H, Gao L, Zhang N. A polygeneration system for methanol and power production based on coke oven gas and coal gas with CO2 recovery [J]. Energy, 2014, 74: 174-180.
[12]	Man Y, Yang S, Zhang J, Qian Y. Conceptual design of coke-oven gas assisted coal to olefins process for high energy efficiency and low CO2 emission [J]. Applied Energy, 2014, 133: 197-205.
[13]	Man Y, Yang S, Qian Y. Conceptual design of coal and coke-oven gas co-feed process to synthetic natural gas with high efficiency and low emission [J]. Industrial & Engineering Chemistry Research, 2015. Submitted.
[14]	Li S, Jin H, Gao L. Cogeneration of substitute natural gas and power from coal by moderate recycle of the chemical unconverted gas [J]. Energy, 2013, 55: 658-667.
[15]	Liu X, Yang S, Hu Z, Qian Y. Simulation and assessment of an integrated acid gas removal process with higher CO2 capture rate [J]. Computers & Chemical Engineering, 2015, 83: 48-57. http://dx.doi. org/10.1016/j.compchemeng.2015.01.008
[16]	Usman M, Wan Daud W M A, Abbas H F. Dry reforming of methane: Influence of process parameters-a review [J]. Renewable and Sustainable Energy Reviews, 2015, 45: 710-744.
[17]	Man Yi(满奕), Yang Siyu(杨思宇), Xiang Dong(项东), Qian Yu(钱宇).Modeling, simulation and analysis for the co-feed process of coal and coke-oven gas to olefins [J]. CIESC Journal (化工学报), 2014, 65(12): 4850-4856.
[18]	Aw M S, Zorko M, ?rnivec I G O, Pintar A. Progress in the synthesis of catalyst supports: synergistic effects of nanocomposites for attaining long-term stable activity in CH4-CO2 dry reforming [J]. Industrial & Engineering Chemistry Research, 2015, 54(15): 3775- 3787.
[19]	Li S, Ji X, Zhang X, Gao L, Jin H. Coal to SNG: technical progress, modeling and system optimization through exergy analysis [J]. Applied Energy, 2014, 136: 98-109.
[20]	Datang Energy and Chemical Co., Ltd (大唐能源化工). Coal to SNG project introduction of Datang Corporation in Chifeng, Inner Mongolia [R]. 2009.