Flow characteristics of biomass particles and quartz sands in 3D fluidized bed

doi:10.16085/j.issn.1000-6613.2017.02.010

Abstract

Abstract: Waste wood,peanut shells,rice husk,and pomace of sugarcane were chosen as experiment raw materials and mixed with quartz sands at different mass ratio to investigate the influence of biomass species and mass ratio in a 3D laboratory fluidized bed. The bed size is 1000mm in height and 120mm×32mm of cross section horizontally. The pressure fluctuation inside the bed was recorded and analyzed. The results show that biomass species and mass ratio had negligible effect on minimum fluidization velocity when mass ratio was less than 0.02. Fast Fourier transform was employed to obtain the power spectral density of pressure fluctuation signals. It's shown that the PSD of pressure fluctuation at lower velocity ranged from 10Hz to 15Hz when rice husk was added,and increased to about 20Hz to 25Hz when the velocity increased. Pomace of sugarcane,peanut shells,and waste wood had no main frequency at lower velocity,but when the velocity increased the main frequency was found to be ranged from 10Hz to 15Hz.

Key words: biomass, pressure fluctuation, fluidized bed, power spectral density

摘要： 选择锯花、花生壳、稻壳、蔗渣为实验对象，将不同质量的生物质与石英砂混合作为床料，加入三维流化床试验台内混合流动，测量床内的压差脉动信号，床高1000mm，截面尺寸为120mm×32mm。实验结果表明当生物质质量分数小于等于2%时，生物质的种类及质量分数对最小流化速度的影响可以忽略不计。利用快速傅里叶变换变换分析压差脉动信号，研究双组分流动特征。结果表明，添加稻壳时压力脉动在低气速下主频位于10~15Hz区间内，并随着气速的增加向20~25Hz的高频区移动；蔗渣、花生壳及锯花等片状生物质在较低气速下主频消失，较高气速下主频存在于10~15Hz区间内。

关键词: 生物质, 压力脉动, 流化床, 功率谱密度

CLC Number:

TQ051

GU Jiawen, ZHONG Zhaoping, WANG Heng. Flow characteristics of biomass particles and quartz sands in 3D fluidized bed[J]. Chemical Industry and Engineering Progree, 2017, 36(02): 473-480.

顾佳雯, 仲兆平, 王恒. 三维流化床内生物质及石英砂混合颗粒的流动特性[J]. 化工进展, 2017, 36(02): 473-480.

References

[1] 苏学泳,王智微,程从明. 生物质在流化床中的热解和气化研究[J]. 燃料化学学报,2000,28(4):298-305. SU X Y,WANG Z W,CHENG C M. Study on biomass pyrolysis and gasification in a fluidized bed[J]. Journal of Fuel Chemistry and Technology,2000,28(4):298-305.
[2] CUI H P,GRACE J R. Fluidization of biomass particles:a review of experimental multiphase flow aspects[J]. Chemical Engineering Science,2007,62:45-55.
[3] CHEN Y M, LIM C J,GRACE J R,et al. Characterization of pressure fluctuations from a gas-solid fluidized bed by structure density function analysis[J]. Chemical Engineering Science,2015,129:156-167.
[4] FELIPE C A S,ROCHA S C S. Prediction of minimum fluidization velocity of gas-solid fluidized beds by pressure fluctuation measurements——analysis of the standard deviation methodology[J]. Powder Technology,2007,174(3):104-113.
[5] SHAO Y J,REN B,JIN B S,et al. Experimental flow behaviors of irregular particles with silica sand in solid waste fluidized bed[J]. Powder Technology,2013,234:67-75.
[6] ZHANG Y,JIN B S,ZHONG W Q. Experimental investigation on mixing and segregation behavior of biomass particle in fluidized bed[J]. Chemical Engineering and Processing:Process Intensification,2009,48(3):745-754.
[7] OR-AMPAI J,CHALERMSINSUWAN B,MEKASUT L,et al. Effect of flow pattern on power spectral density of pressure fluctuation in various fluidization regimes[J]. Powder Technology,2013,233:215-226.
[8] LEON L,MEYER J P. The characterization of flow regimes with power spectral density distributions of pressure fluctuations during condensation in smooth and micro-fin tubes[J]. Experimental Thermal and Fluid Science,2006,31(2):127-140.
[9] HIROYUKI K,AGARI M,OGURA H,et al. Frequency analysis of pressure fluctuation in fluidized bed plenum and its confidence limit for detection of various modes of fluidization[J]. Advanced Power Technology,2000,11(4):459-475.
[10] SCHAAF J,SCHNOUTEN J C,JOHNSSON F,et al. Non-intrusive determination of bubble and slug length scales in fluidized beds by decomposition of the power spectral density of pressure time series[J]. International Journal of Multiphase Flow,2002(28):865-880.
[11] 胡小康,刘小成,徐俊,等. 循环流化床提升管内压力脉动特性[J]. 化工学报,2010,61(4):825-831. HU X K,LIU X C,XU J,et al. Characteristics of pressure fluctuations in CFB riser[J]. CIESC Journal,2010,61(4):825-831.
[12] COOLEY J W,TUKEY J W. An algorithm for the machine calculation of complex Fourier series[J]. Mathematics of Computation,1965,19(19):297-301.
[13] 赵贵兵,李天铎,阳永荣,等. 气固两相流压力波动信号分析[J]. 中国粉体技术,2001,7(3):6-9. ZHAO G B,LI T D,YANG Y R,et al. Analyzing components of pressure fluctuation in gas-solid fluidized bed[J]. China Powder Science and Technology,2001,7(3):6-9.
[14] 赵贵兵,陈纪忠,阳永荣. 流化床压力脉动信号时间延迟相关性[J]. 化工学报,2002,53(12):1281-1287. ZHAO G B,CHEN J Z,YANG Y R. Delay time correlation of time of pressure fluctuation in bubbling fluidized bed[J]. Journal of Chemical Industry and Engineering(China),2002,53(12):1281-1287.

[1]	WANG Shuaiqing, YANG Siwen, LI Na, SUN Zhanying, AN Haoran. Research progress on element doped biomass carbon materials for electrochemical energy storage [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4296-4306.
[2]	WU Ya, ZHAO Dan, FANG Rongmiao, LI Jingyao, CHANG Nana, DU Chunbao, WANG Wenzhen, SHI Jun. Research progress on highly efficient demulsifiers for complex crude oil emulsions and their applications [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4398-4413.
[3]	ZHENG Mengqi, WANG Chengye, WANG Yan, WANG Wei, YUAN Shoujun, HU Zhenhu, HE Chunhua, WANG Jie, MEI Hong. Application and prospect of algal-bacterial symbiosis technology in zero liquid discharge of industrial wastewater [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4424-4431.
[4]	GUAN Hongling, YANG Hui, JING Hongquan, LIU Yuqiong, GU Shouyu, WANG Haobin, HOU Cuihong. Lignin-based controlled release materials and application in drug delivery and fertilizer controlled-release [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3695-3707.
[5]	YU Dingyi, LI Yuanyuan, WANG Chenyu, JI Yongsheng. Preparation of lignin-based pH responsive hydrogel and its application in controlled drug release [J]. Chemical Industry and Engineering Progress, 2023, 42(6): 3138-3146.
[6]	WU Fengzhen, LIU Zhiwei, XIE Wenjie, YOU Yating, LAI Rouqiong, CHEN Yandan, LIN Guanfeng, LU Beili. Preparation of biomass derived Fe/N co-doped porous carbon and its application for catalytic degradation of Rhodamine B via peroxymonosulfate activation [J]. Chemical Industry and Engineering Progress, 2023, 42(6): 3292-3301.
[7]	WANG Xue, XU Qiyong, ZHANG Chao. Hydrothermal carbonization of the lignocellulosic biomass and application of the hydro-char [J]. Chemical Industry and Engineering Progress, 2023, 42(5): 2536-2545.
[8]	WANG Zhiwei, GUO Shuaihua, WU Mengge, CHEN Yan, ZHAO Junting, LI Hui, LEI Tingzhou. Recent advances on catalytic co-pyrolysis of biomass and plastic [J]. Chemical Industry and Engineering Progress, 2023, 42(5): 2655-2665.
[9]	LIU Jing, LIN Lin, ZHANG Jian, ZHAO Feng. Research progress in pore size regulation and electrochemical performance of biomass-based carbon materials [J]. Chemical Industry and Engineering Progress, 2023, 42(4): 1907-1916.
[10]	WAN Maohua, ZHANG Xiaohong, AN Xingye, LONG Yinying, LIU Liqin, GUAN Min, CHENG Zhengbai, CAO Haibing, LIU Hongbin. Research progress on the applications of MXene in the fields of biomass based energy storage nanomaterials [J]. Chemical Industry and Engineering Progress, 2023, 42(4): 1944-1960.
[11]	YANG Ziqiang, LI Fenghai, GUO Weijie, MA Mingjie, ZHAO Wei. Review on phosphorus migration and transformation during municipal sewage sludge heat treatment [J]. Chemical Industry and Engineering Progress, 2023, 42(4): 2081-2090.
[12]	XING Xianjun, LUO Tian, BU Yuzheng, MA Peiyong. Preparation of biochar from walnut shells activated by H₃PO₄ and its application in Cr(Ⅵ) adsorption [J]. Chemical Industry and Engineering Progress, 2023, 42(3): 1527-1539.
[13]	FAN Yunpei, JIN Jing, LIU Dunyu, WANG Jingjie, LIU Qiuqi, XU Kailong. Mercury removal by CaSO₄ oxygen carrier during in-situ gasification and chemical-looping combustion of coal [J]. Chemical Industry and Engineering Progress, 2023, 42(3): 1638-1648.
[14]	ZHENG Yunwu, PEI Tao, LI Donghua, WANG Jida, LI Jirong, ZHENG Zhifeng. Production of hydrocarbon-rich bio-oil by catalytic biomass pyrolysis over metal oxide improved P/HZSM-5 catalyst [J]. Chemical Industry and Engineering Progress, 2023, 42(3): 1353-1364.
[15]	YANG Chengruixue, HUANG Qiyuan, RAN Jiansu, CUI Yuntong, WANG Jianjian. Palladium nanoparticles supported by phosphoric acid-modified SiO₂ as efficient catalysts for low-temperature hydrodeoxygenation of vanillin in water [J]. Chemical Industry and Engineering Progress, 2023, 42(10): 5179-5190.