Numerical Simulation Research on Heat Transfer in Particle Flow Round Tubes

doi:10.12068/j.issn.1005-3026.2016.05.012

Abstract

Abstract: At present， air is a commonly-used heat transfer medium to recover waste heat of slag particles in blast furnace (BF) after dry granulation， which has a low thermal efficiency owing to its low specific heat capacity. Therefore， using gravity bed waste heat boiler to recover waste heat in the high temperature BF slag particles was proposed. Considering the particles as continuous viscous flow， a three dimensional numerical model was built to simulate the heat transfer of BF slag particles flowing around tubes based on the CFD software of Fluent. The effects of the inlet velocity of particles and water， and the inlet temperature of water on the efficiency of heat exchanging in waste heat boiler were investigated. The simulation results show that the efficiency of heat transfer improves with increasing the inlet velocity of particles and water， and the heat recovery rate of the former drops. However， when the inlet temperature of water increases， the heat transfer coefficient keeps invariant and the heat recovery rate reduces.

Key words: particle flow, round tube, heat transfer, gravity bed waste heat boiler, numerical simulation

CLC Number:

TF09

YU Qing-bo， PENG Jia-yan， REN Hui-lai， LIU Jun-xiang. Numerical Simulation Research on Heat Transfer in Particle Flow Round Tubes[J]. Journal of Northeastern University Natural Science, 2016, 37(5): 663-667.

References

[1]Barati M，Esfahani S，Utigard T A.Energy recovery from high temperature slags［J］.General Information，2011，36(9):5440-5449.
[2]Liu J，Yu Q，Duan W，et al.Experimental investigation on ligament formation for molten slag granulation［J］.Applied Thermal Engineering，2014，73:888-893.
[3]刘军祥，于庆波，谢华清，等.冶金渣颗粒余热回收的实验研究［J］.东北大学学报(自然科学版)，2014，35(2):245-248.(Liu Jun-xiang，Yu Qing-bo，Xie Hua-qing，et al.Experimental study on waste heat recovery for metallurgical slag particles［J］.Journal of Northeastern University (Natural Science)，2014，35(2):245-248.)
[4]Campbell C S.Rapid granular flows［J］.Annual Review of Fluid Mechanics，2003，22(2):57-90.
[5]Chen J，Akiyama T，Nogami H，et al.Modeling of solid flow in moving beds ［J］.ISIJ International，1993，33 (6):664-671.
[6]Natarajan V V R，Hunt M L.Heat transfer in vertical granular flows ［J］.Experimental Heat Transfer，1997，10(2):89-107.
[7]武锦涛，陈纪忠，阳永荣．移动床中颗粒接触传热的数学模型［J］.化工学报，2006，57(4):719-725.(Wu Jin-tao，Chen Ji-zhong，Yang Yong-rong.Model of contact heat transfer in granular moving bed ［J］.Journal of Chemical Industry and Engineering，2006，57(4):719-725.)
[8]Hiromi T.Particles flow pattern around tube and local in moving heat transfer bed ［J］.AIChE Journal，1996，42(6):1621-1626.
[9]Yusuf R，Halvorsen B，Melaaen M C.Eulerian-Eulerian simulation of heat transfer between a gas - solid fluidized bed and an immersed tube-bank with horizontal tubes ［J］.Chemical Engineering Science，2011，66(8):1550-1564.
[10]Dan C，Wachs A.Direct numerical simulation of particulate flow with heat transfer ［J］.International Journal of Heat and Fluid Flow，2010，31(6):1050-1057.
[11]Uhlmann M.An immersed boundary method with direct forcing for the simulation of particulate flows ［J］.Journal of Computational Physics，2005，209(2):448-476.
[12]陶文铨.数值传热学［M］.西安:西安交通大学出版社，2001:1-5.(Tao Wen-quan.Numerical heat transfer ［M］.Xi'an :Xi′an Jiaotong University Press，2001:1-5.)(上接第641页)

[1]	ZHU Qing-feng， YAN Bo， FENG Zhi-xin， ZUO Yu-bo. Numerical Simulation and Experimental Investigation on Hot Rolling Process of 2195 Aluminum Alloy at Different Speeds [J]. Journal of Northeastern University(Natural Science), 2023, 44(4): 502-509.
[2]	ZHAO Wen ， SUN Yuan， BAI Qian， XIA Yun-peng. Excavation Field Test and Parameters Optimization of the Transverse Pilot Tunnel with Small Diameter Tube Curtain Construction Method [J]. Journal of Northeastern University(Natural Science), 2023, 44(3): 432-439.
[3]	WU Fei， LI Yi-neng， WANG Meng-hui. Research on Light-Curing Assisted Molding Process of Extrusion-based Ceramic 3D Printing [J]. Journal of Northeastern University(Natural Science), 2022, 43(9): 1283-1290.
[4]	YUAN Yang， XU Tao， ZHOU Guang-lei， LE Zhi-hua. Simulation Method of Damage and Fracture for Brittle Rock Based on Microplane Model and Regularization [J]. Journal of Northeastern University(Natural Science), 2022, 43(8): 1141-1148.
[5]	LI Xue-jiao， YANG Hong-ying， ZHAO He-fei， HU Hong-sheng. Numerical Simulation Study on Gas Gathering Structure of Aluminum Reduction Cell [J]. Journal of Northeastern University(Natural Science), 2022, 43(7): 966-972.
[6]	SUN Hao ， ZHU Dong-feng ， JIN Ai-bing ， CHEN Shuai-jun. Failure Characteristics and Crack Evolution Laws of Hard Rock Under Nonlinear Unloading Rates [J]. Journal of Northeastern University(Natural Science), 2022, 43(7): 1010-1018.
[7]	LYU Chao， SUN Ming-he， YIN Hong-xin， LIU Fang. Simulation Study on the Effect of Venturi Pyrolysis Reactor Structure on Flow Field [J]. Journal of Northeastern University(Natural Science), 2022, 43(6): 821-826.
[8]	HOU Duan-xu， WEI De-zhou， CUI Bao-yu， ZHAO Qiang. Effect of Feed Concentration on Separation Performance of Cyclone Separation Column [J]. Journal of Northeastern University(Natural Science), 2022, 43(5): 718-723.
[9]	AN Long， ZHANG Jia-hua， LI Yuan-hui， HAN Lin. Simulation and Parameters Optimization of Medium Deep Hole Blasting in Steeply Narrow Vein Mine Under Confinement [J]. Journal of Northeastern University(Natural Science), 2022, 43(4): 567-574.
[10]	LI Bao-kuan， OU Hai-bin， YU Yang， LI Meng-zhen. An Coupled Model of Multiphysics and Selective Reduction in Titanium Slag EAF [J]. Journal of Northeastern University(Natural Science), 2022, 43(2): 206-213.
[11]	HAO Bo， DAI Hao， LUY Chao. Influence of Water Entry Angle on High-Speed Projectiles in the Water Entry Process [J]. Journal of Northeastern University(Natural Science), 2022, 43(2): 221-227.
[12]	ZHAO Meng， XIAO Ming， CHEN Jun-tao， ZUO Shuang-ying. Stability Analysis of Surrounding Rock of Underground Caverns Considering Contact State of Interbedded Layered Rock Mass [J]. Journal of Northeastern University(Natural Science), 2022, 43(2): 243-250.
[13]	WANG Xin， ZHAO Wen， BAI Qian. Expansion Type of In-situ Expansion of the Intersection Between Main Tunnel and Shaft in the Existing Tunnel [J]. Journal of Northeastern University(Natural Science), 2022, 43(10): 1469-1476.
[14]	ZHANG Xiao-hu， ZHANG Sheng， ZHAO Liang， DONG Hui. Numerical Analysis of Gas-Solid Heat Transfer Characteristics in Shaft Furnace for Calcination of Sintered Magnesia [J]. Journal of Northeastern University(Natural Science), 2022, 43(1): 40-47.
[15]	LI Gang， KANG Jin， CUI Zhen， HU Peng. Functional Experiment and Simulation Study of Explosion Isolation Flap Valves [J]. Journal of Northeastern University(Natural Science), 2021, 42(8): 1166-1173.