个人信息Personal Information
教授
博士生导师
硕士生导师
性别:男
毕业院校:大连理工大学
学位:博士
所在单位:化工学院
学科:化工过程机械. 流体机械及工程. 安全科学与工程
办公地点:西部校区实验楼H305室
联系方式:Tel:13998448116 0411-84986273
电子邮箱:xlz@dlut.edu.cn
Numerical simulation and experimental validation of oil shale drying in pneumatic conveying dryer
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论文类型:期刊论文
发表时间:2018-04-04
发表刊物:DRYING TECHNOLOGY
收录刊物:SCIE、EI、Scopus
卷号:36
期号:5
页面范围:617-629
ISSN号:0737-3937
关键字:CFD; Eulerian-Lagrangian; heat and mass transfer; oil shale; pneumatic drying
摘要:Oil shale is an important unconventional energy and has enormous reserves in the world. However, the high moisture content impedes its utilization in the restoration and combustion process. This paper explores experimental and numerical studies on the drying performance of the Liu Shu River oil shale in a pneumatic conveying dryer (4.8 cm ID, 1.8 m high). The experiments were carried out under the different operation conditions. The 3-D modeling was done with a computational fluid dynamics package, in which the gas phase is modeled as a continuum using Euler approach, and the particle phase is modeled by a discrete phase model with a Lagrangian approach. The effects of inlet air velocity, particle size, solid mass flow rate, and inlet air temperature on the drying performance of oil shale particles are investigated. It is found that the simulated values are in good agreement with experimental data. The developed model of Nu = 0.035Re(p)(1.15)Pr(0.333) is thus suitable to describe the oil shale pneumatic drying process. Generally, it is concluded that the moisture evaporation occurs mainly at the constant rate drying stage in the pneumatic drying process due to very short residence time. The drying rate increases as the inlet air velocity and temperture increase, while increasing the particle size or the solid mass flow rate decreases the drying rate. It is the breakthrough to improve the drying efficiency by increasing the slip velocity and extending pariticle residence time in the dryer. Gas temperature and particle size have the significant influence on degree of particle drying. But the mass flow rate and gas velocity are the important parameters for the energy efficiency in the drying process.