Analysis of influencing factors on inhibition of lignite pulverization by liquefaction residue during co-pyrolysis in rotary kiln

doi:10.11949/j.issn.0438-1157.20171114

Abstract

Abstract:

The inhibitory effects of coal direct liquefaction residue (CDLR) on lignite pulverization were studied in a kilo rotary kiln during co-pyrolysis. Different CDLR to lignite quantity and particle size ratios were investigated in the study. The results showed that, with CDLR quantity ratio increased from 10% to 40% at 550℃, the co-pyrolysis char pulverization rate β was decreased from 7.55% to 1.98%, and the granulation rate λ was increased from 2.73% to 4.90%. Increasing CDLR quantity ratio effectively inhibited lignite pulverization and mixing granulation. Mixing 3-1 mm CDLR with 3-1 mm lignite reached the pulverization rate β of 2.82%, which is lower than the pulverization rate when mixing 6-3/13-6/25-13 mm CDLR with the same size lignite. Mixing 3-1 mm CDLR with 3-1 mm lignite reached the granulation rate λ of 24.99%, which was much higher than λ of mixing larger CDLR. Gray relational analysis indicated that the influence of CDLR size ratio on β and λ was greater than quantity ratio. A model of CDLR to lignite size and quantity ratio inhibiting lignite pulverization in rotary kiln during pyrolysis was constructed. The ratio factors affected pyrolysis along with other internal factors including strength of particle capturing, pore structure reinforcing and particle layer crossing behavior.

Key words: lignite pulverization, coal direct liquefaction residue, ratio factor, pyrolysis, granulation, particle size distribution, inhibitory effect, rotary kiln

摘要：

在公斤级回转窑中研究了共热解过程不同液化残渣与褐煤质量配比及粒度配比因素对抑制褐煤粉化效果的影响。结果表明：550℃共热解条件下，随液化残渣的添加比例由10%升至40%，共热解半焦的粉化率β由7.55%降至1.98%，造粒率λ由2.73%升至4.90%，液化残渣添加量的提升有效促进了对粉化的抑制及混合造粒；3～1 mm液化残渣与3～1 mm褐煤的共热解半焦β为2.82%，较与6～3/13～6/25～13 mm褐煤颗粒热解后的产物粉化率均低，而λ则达到24.99%，远高于其他粒度配比下的产物造粒率。灰色关联分析显示，粒度配比因素对β和λ的影响权重均大于质量配比因素。结合分析上述配比因素影响粉化抑制作用的内在诱因（强化粘连捕集颗粒行为，促进孔隙充填补强作用，颗粒穿层行为影响），形成了回转窑热解过程配比因素对抑制褐煤粉化的影响过程模型。

关键词: 褐煤粉化, 煤直接液化残渣, 配比因素, 热解, 造粒, 粒度分布, 抑制, 回转窑

CLC Number:

TQ536.9

QU Yang, CHU Mo, ZHU Shuquan, ZHANG Chao, HAO Chengliang, XU Fang. Analysis of influencing factors on inhibition of lignite pulverization by liquefaction residue during co-pyrolysis in rotary kiln[J]. CIESC Journal, 2018, 69(5): 2166-2174.

曲洋, 初茉, 朱书全, 张超, 郝成亮, 徐芳. 回转窑内利用液化残渣共热褐煤以抑制其粉化的影响因素分析[J]. 化工学报, 2018, 69(5): 2166-2174.

References 30

[1]	HAN J, WANG X, YUE J, et al. Catalytic upgrading of coal pyrolysis tar over char-based catalysts[J]. Fuel Processing Technology, 2014, 122:98-106.
[2]	ZHOU Q, TAO Z, MEI Z, et al. Lignite upgrading by multi-stage fluidized bed pyrolysis[J]. Fuel Processing Technology, 2013, 116:35-43.
[3]	刘丽华, 初茉, 党彤彤, 等. 热提质褐煤预氧化后自燃特性变化及其自由基原位分析[J]. 化工学报, 2017, 68(10):3967-3977. LIU L H, CHU M, DANG T T, et al. Free radical in situ analysis and change of spontaneous combustion characteristics after pre-oxidation for thermal upgraded lignite[J]. CIESC Journal, 2017, 68(10):3967-3977.
[4]	初茉, 高晶晶. 褐煤低温热解提质试验研究[J]. 煤炭科学技术, 2012, 40(10):95-99. CHU M, GAO J J. Experiment study on low temperature pyrolysis upgrading of lignite[J]. Coal Science and Technology, 2012, 40(10):95-99.
[5]	李初福, 门卓武, 翁力, 等. 固体热载体回转窑煤热解工艺模拟与分析[J]. 煤炭学报, 2015, 40(S1):203-207. LI C F, MEN Z W, WEN L, et al. Process simulation and analysis for coal pyrolysis with rotary kiln using solid heat carrier[J]. Journal of China Coal Society, 2015, 40(S1):203-207.
[6]	王凯, 陈士超, 尤立. 大型煤炭干馏回转窑换热装置的研制[J]. 矿山机械, 2017, (6):71-74. WANG K, CHEN S C, YOU L, et al. Development of heat exchanger for large coal carbonization rotary kiln[J]. Mining and Processing Equipment, 2017, (6):71-74.
[7]	WANG X G, ZHANG Y, DONG L, et al. Experimental study on the pyrolysis of Shenhua coal to produce hydrogen[J]. Journal of Thermal Science, 2013, 22:184-189.
[8]	ZHANG Y M, WANG Y, CAI L G, et al. Dual bed pyrolysis gasification of coal:process analysis and pilot test[J]. Fuel Processing Technology, 2013, 112:624-634.
[9]	李青松. 褐煤化工技术[M]. 北京:化学工业出版社, 2014:100-140. LI Q S. Lignite Chemical Processes[M]. Beijing:Chemical Industry Press, 2014:100-140.
[10]	曲洋, 初茉, 丁力, 等. 热提质过程中褐煤的碎裂特性[J]. 中国矿业大学学报, 2014, 43(3):508-513. QU Y, CHU M, DING L, et al. Fragmentation characteristic of lignite during heat upgrading[J]. Journal of China University of Mining & Technology, 2014, 43(3):508-513.
[11]	曲洋, 初茉, 郝成亮, 等. 褐煤热碎性对提质工艺的影响分析[J]. 煤炭工程, 2015, 47(12):118-120. QU Y, CHU M, HAO C L, et al. Analysis for the impact of lignite heat fragmentation characteristic on upgrading process[J]. Coal Engineering, 2015, 47(12):118-120.
[12]	CUI H, YANG J L, LIU Z Y, et al. Characteristics of residues from thermal and catalytic coal hydroliquefaction[J]. Fuel, 2003, 82:1549-1556.
[13]	LI J, YANG J L, LIU Z Y. Hydrogenation of heavy liquids from a direct coal liquefaction residue for improved oil yield[J]. Fuel Processing Technology, 2009, 90:490-495.
[14]	李建广, 房倚天, 张永奇, 等. 煤直接液化残渣快速热解半焦特性的研究[J]. 燃料化学学报, 2008, 36(3):273-278. LI J G, FANG Y T, ZHANG Y Q, et al. Property of char from fast pyrolysis direct coal liquefaction residue[J]. Journal of Fuel Chemistry and Technology, 2008, 36(3):273-278.
[15]	孙任晖, 高鹏, 芦海云, 等. 神东煤与煤液化残渣混合样及共热解半焦黏结性研究[J]. 煤炭工程, 2015, 47(11):129-132. SUN R H, GAO P, LU H Y, et al. Caking property of Shendong coal and direct coal liquefaction residue mixture and its pyrolysis semi-coke[J]. Coal Engineering, 2015, 47(11):129-132.
[16]	新日本制铁株式会社. 一种高炉焦炭的制作方法:JPH04309594A[P]. 1992-11-02. Nippon Steel Corporation. A method of making blast furnace coke:JPH04309594A[P]. 1992-11-02.
[17]	XU B, SUN R H, CHU M, et al. Synergies in co-pyrolysis of lignite and coal liquefaction residue[C]//30th Annual International Pittsburgh Coal Conference, 2013:2599-2616.
[18]	LI X H, XUE Y L, FENG J, et al. Co-pyrolysis of lignite and Shendong coal direct liquefaction residue[J]. Fuel, 2015, 144:342-348.
[19]	李晓红, 马江山, 薛艳利, 等. 褐煤与煤直接液化残渣共热解产物半焦性能研究[J]. 燃料化学学报, 2015, 43(11):1281-1286. LI X H, MA J S, XUE Y L, et al. Properties of semi-coke from co-pyrolysis of lignite and direct liquefaction residue of Shendong coal[J]. Journal of Fuel Chemistry and Technology, 2015, 43(11):1281-1286.
[20]	畅志兵, 初茉, 孙任晖, 等. 煤直接液化残渣与褐煤共热解动力学研究[J]. 煤炭科学技术, 2015, 43(3):138-141. CHANG Z B, CHU M, SUN R H, et al. Study on co-pyrolysis kinetics of coal direct liquefaction residue and lignite[J]. Coal Science and Technology, 2015, 43(3):138-141.
[21]	刘文郁. 煤直接液化残渣热解特性研究[D]. 北京:煤炭科学研究总院, 2005:55-62. LIU W Y. Pyrolysis of direct coal liquefaction residue[D]. Beijing:China Coal Research Institute, 2005:55-62.
[22]	李丽丽. 神东煤直接液化残渣与煤共热解相互作用研究[D]. 太原:太原理工大学, 2016:20-29. LI L L. Interaction study on co-pyrolysis between Shendong coal direct liquefaction residue and coal[D]. Taiyuan:Taiyuan University of Technology, 2016:20-29.
[23]	曲洋, 初茉, 申国栋, 等. 回转窑提质过程宝日褐煤热碎性工艺因素分析[J]. 中国矿业大学学报, 2016, 45(2):386-392. QU Y, CHU M, SHEN G D, et al. Analysis of factors affecting Baori lignite heat fragmentation during upgrading in rotary kiln[J]. Journal of China University of Mining & Technology, 2016, 45(2):386-392.
[24]	QU Y, CHU M, SHEN G D, et al. Inhibitory effect of coal direct liquefaction residue on lignite pulverization during co-pyrolysis[J]. Fuel Processing Technology, 2016, 147:57-63.
[25]	WANG C Y, HAO S X, SUN W J, et al. Fractal dimension of coal particles and their CH4 adsorption[J]. International Journal of Mining Science and Technology, 2012, 22:855-858.
[26]	YI Z, CHENG F J, WEI C. Methane adsorption behavior on coal having different pore structures[J]. International Journal of Mining Science and Technology, 2012, 22:757-761.
[27]	ARNTZ M M H D, OTTER W K, BRIELS W J, et al. Granular mixing and segregation in a horizontal rotating drum:a simulation study on the impact of rotational speed and fill level[J]. AIChE Journal, 2008, 54(12):3133-3146.
[28]	LEE S H, KIM S D, LEE D H, et al. Particle size reduction of anthracite coals during devolatilization in a thermobalance reactor[J]. Fuel, 2002, 81:1633-1638.
[29]	曲洋, 初茉, 张超, 等. 热作用过程油页岩颗粒的碎裂/粉化特性[J]. 化工学报, 2017, 68(10):3934-3942. QU Y, CHU M, ZHANG C, et al. Characteristics of oil shale particles fragmentation/pulverization during thermal effect[J]. CIESC Journal, 2017, 68(10):3934-3942.
[30]	刘思峰, 蔡华, 杨英杰, 等. 灰色关联分析研究进展[J]. 系统工程理论与实践, 2013, 33(8):2041-2044. LIU S F, CAI H, YANG Y J, et al. Advance in grey incidence analysis modelling[J]. Systems Engineering-Theory&Practice, 2013, 33(8):2041-2044.