Particles flowing process across aligned tubes in a moving bed

DENG Sheng-an; LOU Guo-feng; XU Ke-jun; WEN Zhi; LIU Xun-liang; DOU Rui-feng; SU Fu-yong

doi:10.13374/j.issn2095-9389.2018.06.012

Volume 40 Issue 6

Jun. 2018

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DENG Sheng-an, LOU Guo-feng, XU Ke-jun, WEN Zhi, LIU Xun-liang, DOU Rui-feng, SU Fu-yong. Particles flowing process across aligned tubes in a moving bed[J]. Chinese Journal of Engineering, 2018, 40(6): 735-742. doi: 10.13374/j.issn2095-9389.2018.06.012

Citation:

DENG Sheng-an, LOU Guo-feng, XU Ke-jun, WEN Zhi, LIU Xun-liang, DOU Rui-feng, SU Fu-yong. Particles flowing process across aligned tubes in a moving bed[J]. Chinese Journal of Engineering, 2018, 40(6): 735-742. doi: 10.13374/j.issn2095-9389.2018.06.012

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Particles flowing process across aligned tubes in a moving bed

doi: 10.13374/j.issn2095-9389.2018.06.012

1) School of Energy and Environmental Engineering, University of Science and Technology Beijing, Beijing 100083, China
2) Beijing Key Laboratory of Energy Saving and Emission Reduction for Metallurgical Industry, University of Science and Technology Beijing, Beijing 100083, China

Received Date: 2017-12-11

Abstract

Abstract

Many solid particles in industrial processes require heating or cooling, such as calcinated petroleum coke, blast furnace slag, and steel slag. A moving bed with tubes is a viable design for facilitating such complex heat transfer processes. As particles are the primary heat carriers in this flow, the flow pattern of particles across the tubes in a moving bed is the main determinant of the heattransfer mechanism. The characteristics of particle flows across a tube structure are vastly different from those of a continuous-medium flow. Therefore, the flow pattern of particles moving across a bed of tubes must be studied prior to the heat-transfer mechanism. A simple pseudo-funnel flow model that can calculate parameters such as velocity field and residence time was established in this study for particle-flow modeling, and the range of parameters required to describe particles flowing across tubes was discussed. Using a movingbed test device made of transparent PMMA material, the flow of particles across aligned tubes banks was measured and a set of experimental results were obtained. Simultaneously, the discrete element method (DEM) was used for numerical simulations of the particleflow distribution in the system, and the obtained results were compared and verified by experimental results. Computational results from the quasi-funnel flow model were then compared with the DEM numerical simulation results to find the set of parameters required to describe particles flowing across aligned tube banks in the pseudo-funnel flow model. By setting appropriate values of the abovementioned parameters, the relative error between the two models could be reduced to 3%. This study provides a foundation for future studies on heat transfer processes in moving granular beds and the design and optimization of similar heat exchange devices.
- granular flow,
- flow characteristic,
- moving bed,
- discrete element method,
- residence time

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References(13)

References

[2]	Zhang R Q, Yang H R, Lu J F, et al. Theoretical and experimental analysis of bed-to-wall heat transfer in heat recovery processing. Powder Technol, 2013, 249:186
[3]	Jaeger H M, Nagel S R. Physics of the granular state. Science, 1992, 255(5051):1523
[4]	Niegsch J, Köneke D, Weinspach P M. Heat transfer and flow of bulk solids in a moving bed. Chem Eng Process, 1994, 33(2):73
[5]	Kurochkin Y P. Heat transfer between tubes of different sections and a stream of granular material. J Eng Phys Thermophys, 1966, 10(6):447
[8]	Takeuchi H. Particles flow pattern and local heat transfer around tube in moving bed. AIChE J, 1996, 42(6):1621
[9]	Baumann T, Zunft S. Theoretical and experimental investigation of a moving bed heat exchanger for solar central receiver power plants. J Phys Conf Series, 2012, 395(1):ArtNo. 012055
[10]	Baumann T, Zunft S, Tamme R. Moving bed heat exchangers for use with heat storage in concentrating solar plants:a multiphase model. Heat Transfer Eng, 2014, 35(3):224
[11]	Bartsch P, Baumann T, Zunft S. Granular flow field in moving bed heat exchangers:a continuous model approach. Energy Procedia, 2016, 99:72
[12]	Polderman H G, Boom J, De Hilster E, et al. Solids flow velocity profiles in mass flow hoppers. Chem Eng Sci, 1987, 42(4):737
[13]	Cleary P W. Industrial particle flow modelling using discrete element method. Eng Comput, 2009, 26(6):698
[14]	Yang W J, Zhou Z Y, Yu A B. Discrete particle simulation of solid flow in a three-dimensional blast furnace sector model. Chem Eng J, 2015, 278:339
[16]	Liu J X, Yu Q B, Peng J Y, et al. Thermal energy recovery from high-temperature blast furnace slag particles. Int Commun Heat Mass Transfer, 2015, 69:23
[17]	Santos K G, Campos A V P, Oliveira O S, et al. Dem simulations of dynamic angle of repose of acerola residue:a parametric study using a response surface technique. Blucher Chem Eng Proc, 2015, 1(2):11326