Experiment of simulation study on gas-solid fluidization on Martian environments

doi:10.16085/j.issn.1000-6613.2023-1147

Chemical Industry and Engineering Progress ›› 2024, Vol. 43 ›› Issue (8): 4203-4209.DOI: 10.16085/j.issn.1000-6613.2023-1147

• Chemical processes and equipment • Previous Articles

Experiment of simulation study on gas-solid fluidization on Martian environments

MA Yongli¹(), LI Muyang¹, MA Zihao¹, WANG Haoran¹, WANG Maolong¹, FEI Yaohan¹, ZHANG Lubin¹, LIU Mingyan¹^,²()

^1.School of Chemical Engineering and Technology, Tianjin University, Tianjin 300350, China
^2.State Key Laboratory of Chemical Engineering (Tianjin University), Tianjin 300350, China

Received:2022-07-09 Revised:2023-09-19 Online:2024-09-02 Published:2024-08-15
Contact: LIU Mingyan

火星上的气固流态化模拟实验

马永丽¹(), 李沐阳¹, 马子皓¹, 王浩然¹, 王茂隆¹, 费瑶寒¹, 张露滨¹, 刘明言¹^,²()

^1.天津大学化工学院，天津 300350
^2.化学工程联合国家重点实验室(天津大学)，天津 300350

通讯作者: 刘明言
作者简介:马永丽（1989—），女，副教授，硕士生导师，研究方向为化学工程。E-mail: mayl@tju.edu.cn。

Abstract

Abstract:

In order to understand the gas-solid fluidization behavior on Mars, the computational particle fluid dynamics (CPFD) method was applied to analyze the fluidization phenomenon in the gas-solid fluidization bed reactor under different gravity conditions. The fluid velocity distribution characteristics in the gas-solid fluidized bed were studied, and the relationship between the pressure fluctuation of the bed and the environmental gravity and superficial fluidized gas velocity was obtained. The results showed that under the Martian environment, increasing superficial gas velocity could promote the formation of well-developed gas-solid fluidization, but the higher superficial gas velocity would increase the degree of disorder of the gas-solid flow field in the bed, which had a certain negative impact on the stable operating of the fluidized bed. The research results had certain guiding significance for future gas-solid fluidization operations used for on-site production of materials and energy on Mars.

Key words: fluidized bed, fluidization, numerical simulation, gas-solid, Mars

摘要：

为了了解火星上的气固流态化行为，本文应用计算颗粒流体力学方法对不同重力条件下的气固流化床反应器中的流态化现象进行了数值模拟研究。分析了火星环境条件下气固流化床内的流体速度分布特性，探索了床层压力波动特性与环境重力和表观气速等因素间的关系。结果表明，在火星环境条件下，提高表观气速可以促进气固流态化的形成和充分发展；但是较高的表观气速会使流化床内的气固流场紊乱程度增加，不利于维持稳定的气固流态化状态。研究结果对于未来在火星上开展物质和能源等就地生产用气固流态化单元操作具有一定的指导意义。

关键词: 流化床, 流态化, 数值模拟, 气固, 火星

CLC Number:

TQ03

MA Yongli, LI Muyang, MA Zihao, WANG Haoran, WANG Maolong, FEI Yaohan, ZHANG Lubin, LIU Mingyan. Experiment of simulation study on gas-solid fluidization on Martian environments[J]. Chemical Industry and Engineering Progress, 2024, 43(8): 4203-4209.

马永丽, 李沐阳, 马子皓, 王浩然, 王茂隆, 费瑶寒, 张露滨, 刘明言. 火星上的气固流态化模拟实验[J]. 化工进展, 2024, 43(8): 4203-4209.

Figures/Tables 6

References 11

1	王景涛.微重力应用导引[M]. 北京: 中国科学技术出版社, 1988.
	WANG Jingtao. Microgravity application guidance[M]. Beijing: China Science and Technology Press, 1988.
2	龙勉. 如何在地球表面模拟空间微重力环境或效应：从空间细胞生长对微重力响应谈起[J]. 科学通报, 2014, 59(20): 2004-2015．
	LONG Mian. How to simulate the microgravity environment or effects of space on the Earth's surface: starting with the response of space cell growth to microgravity[J]. Chinese Science Bulletin, 2014, 59(20): 2004-2015.
3	HUANG Yu, ZHU Chongqiang, XIANG Xiang, et al. Liquid-gas-like phase transition in sand flow under microgravity[J]. Microgravity Science and Technology, 2015, 27(3): 155-170.
4	LEIDICH Jared, THOMAS Evan A, KLAUS David M. A novel testing protocol for evaluating particle behavior in fluid flow under simulated reduced gravity conditions[C]//SAE Technical Papers, International Conference on Environmental Systems, SAE International, USA, 2009.
5	STOCKER Dennis, BROOKER John, ZINGARELLI Erin, et al. Effects of gravity on swirl-stabilized fluidized beds[C]//44th AIAA Aerospace Sciences Meeting and Exhibit. Reno, Nevada. Reston, Virigina: AIAA, 2006: AIAA2006-1136.
6	JOVANOVIC Goran N, SORNCHAMNI Thana, ATWATER James E, et al. Magnetically assisted liquid–solid fluidization in normal and microgravity conditions: Experiment and theory[J]. Powder Technology, 2004, 148(2/3): 80-91.
7	WANG Xuesong, MILES Nick J, KINGMAN Sam. Numerical study of centrifugal fluidized bed separation[J]. Minerals Engineering, 2006, 19(10): 1109-1114.
8	SERCEL J, DREYER C, WALTON O, et al. Microgravity granular material research facility for ISS[C]//Earth and Space 2018. Cleveland, Ohio. Reston, VA: American Society of Civil Engineers, 2018: 49-60.
9	孙铭阳, 韦鲁滨, 朱学帅, 等. 液固分选流化床三相流场模拟中各粘性流动模型的适用性[J]. 过程工程学报, 2016, 16(1): 10-17.
	SUN Mingyang, WEI Lubin, ZHU Xueshuai, et al. Applicability of each viscous flow model in liquid-solid separation fluidized bed three-phase flow field simulation[J]. Journal of Process Engineering, 2016, 16(1): 10-17.
10	蔡进, 李涛, 孙启文, 等. 气固流化床固体浓度分布的冷模研究[J]. 过程工程学报, 2008, 8(5): 839-844.
	CAI Jin, LI Tao, SUN Qiwen, et al. Cold mode study of solids concentration distribution in gas-solid fluidized bed[J]. Journal of Process Engineering, 2008, 8(5): 839-844.
11	王文娟, 王治国, 仝少凯, 等. 基于DDPM的水力压裂套管孔眼冲蚀预测[J]. 当代化工, 2023, 52(2): 398-402.
	WANG Wenjuan, WANG Zhiguo, TONG Shaokai, et al. Prediction of perforaton erosion of hydraulic fracturing casing based on DDPM[J]. Contemporary Chemical Industry, 2023, 52(2): 398-402.

[1]	ZOU Xu, FU Liangliang, HU Fangling, SONG Jia, GAO Jiahui, ZHANG Qingjin, XU Guangwen, BAI Dingrong. Basic research on high-temperature thermochemical reactions of industrial inorganic solid waste [J]. Chemical Industry and Engineering Progress, 2024, 43(7): 3756-3767.
[2]	WANG Qingtai, ZHANG Sai, WANG Jiemin. Numerical simulation for non-uniform compression of porous electrodes in vanadium flow batteries [J]. Chemical Industry and Engineering Progress, 2024, 43(6): 2940-2949.
[3]	ZHANG Haixia, ZHU Zhiping, ZHANG Siyuan. Research and application progress of circulating fluidized bed gasification with high-alkaline coal [J]. Chemical Industry and Engineering Progress, 2024, 43(5): 2254-2278.
[4]	WU Da, JIANG Shujiao, WEI Qiang, YUAN Shenghua, YANG Gang, ZHANG Cheng. Research progress on efficient utilization technology of residue in energy transition [J]. Chemical Industry and Engineering Progress, 2024, 43(5): 2343-2353.
[5]	WU Qi, BAI Boyang, YIN Yongjie, MA Xiaoxun. Relationship between the structure of macerals of Ordos lignite and its pyrolysis characteristics [J]. Chemical Industry and Engineering Progress, 2024, 43(5): 2370-2385.
[6]	WANG Xinyu, WANG Chao, ZHANG Mengjuan, LIU Fangzheng, LI Hanyang, WANG Zhenglin, JIA Xin, SONG Xingfei, XU Guangwen, HAN Zhennan. Process stability verification of the two-stage fluidized bed gasification for pine particles to produce clean gas [J]. Chemical Industry and Engineering Progress, 2024, 43(5): 2576-2586.
[7]	SUN Xian, LIU Jun, WANG Xiaohui, SUN Changyu, CHEN Guangjin. Review of experimental and numerical simulation research on the development of natural gas hydrate reservoir with underlying gas [J]. Chemical Industry and Engineering Progress, 2024, 43(4): 2091-2103.
[8]	DU Yongliang, LIANG Zhuobin, GONG Yaoxu, BI Haojie, XU Zhiyuan, YUAN Hongying. Air gap membrane distillation research status and applications [J]. Chemical Industry and Engineering Progress, 2024, 43(4): 1655-1666.
[9]	SUN Chao, AI Shiqin, LIU Yuechan. Numerical simulation plate side flow heat transfer new plate-shell heat exchanger with considering physical property changes and shell heat transfer [J]. Chemical Industry and Engineering Progress, 2024, 43(4): 1676-1689.
[10]	ZHU Yanni, WANG Wei, SUN Yanchenhao, WEI Gang, ZHANG Dawei. Numerical simulation of centrifugal spray drying based on single-droplet evaporation [J]. Chemical Industry and Engineering Progress, 2024, 43(4): 1700-1710.
[11]	ZHAO Jilong, GUO Yuxiang, CHEN Hongxia, YUAN Dazhong, DU Xiaoze. Experimental and numerical simulation on heat transfer characteristics of vertical cesium heat pipes [J]. Chemical Industry and Engineering Progress, 2024, 43(4): 1711-1719.
[12]	YU Yanfang, DING Pengcheng, MENG Huibo, SHI Bowen, YAO Yunjuan. Heat transfer enhancement of non-Newtonian fluid in the blade-type static mixer [J]. Chemical Industry and Engineering Progress, 2024, 43(3): 1145-1156.
[13]	YIN Shaowu, LI Xianxian, HAN Jiawei, LU Ming, TONG Lige, WANG Li. Heat charge and release characteristics of household off-peak electricity thermal storage heating system [J]. Chemical Industry and Engineering Progress, 2024, 43(3): 1206-1213.
[14]	LI Jing, FANG Qing, ZHOU Wenhao, WU Guoliang, WANG Jiahui, ZHANG Hua, NI Hongwei. Effect of baffle configuration on the multiphase flow behaviors of vanadium shale leaching tank [J]. Chemical Industry and Engineering Progress, 2024, 43(2): 619-627.
[15]	JIAN Yu, CHEN Baoming, GONG Hanyu. Enhanced heat transfer characteristics of phase change heat storage systems based on hierarchically structured skeletons [J]. Chemical Industry and Engineering Progress, 2024, 43(2): 649-658.

Experiment of simulation study on gas-solid fluidization on Martian environments

火星上的气固流态化模拟实验

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 6

References 11

Related Articles 15

Recommended Articles

Metrics

Comments