Archive
Special Issues
Numerical Simulation of Heat Transfer Performance of Calender Roll Structure in Glass Calendering
International Journal of Mechanical Engineering and Applications
Volume 5, Issue 2, April 2017, Pages: 118-128
Received: May 10, 2017; Published: May 10, 2017
Authors
Geng Tie, School of Mechanical and Electrical Engineering, Henan University of Technology, Zhengzhou, China
Sheng Jie, School of Mechanical and Electrical Engineering, Henan University of Technology, Zhengzhou, China
Hu Jinzhong, School of Mechanical and Electrical Engineering, Henan University of Technology, Zhengzhou, China
Article Tools
Abstract
This paper analyzes the heat transfer characteristics of Heat transfer characteristics during photovoltaic glass calendering, establish the forming process numerical simulation equation, adopt Computational Fluid Dynamics(CFD) numerical simulation method, by introducing reasonable simplification and hypothesis, a mathematical model for the flow and heat transfer of cooling water In different structure calendering roll cavity was established. The effect of the cooling water channel structure on the heat transfer performance of the calender roll was analyzed by FLUENT simulation results.
Keywords
Photovoltaic Glass, Calendering, FLUENT, Calendering Roll, Numerical Simulation
Geng Tie, Sheng Jie, Hu Jinzhong, Numerical Simulation of Heat Transfer Performance of Calender Roll Structure in Glass Calendering, International Journal of Mechanical Engineering and Applications. Vol. 5, No. 2, 2017, pp. 118-128. doi: 10.11648/j.ijmea.20170502.17
References
[1]
Cuce E, Young C H, Riffat S B. Performance investigation of heat insulation solar glass for low-carbon buildings [J]. Energy Conversion & Management, 2014, 88: 834-841.
[2]
J. Eisenträger, K. Naumenko, H. Altenbach, et al. A user-defined finite element for laminated glass panels and photovoltaic modules based on a layer-wise theory [J]. Composite Structures, 2015, 133: 265-277.
[3]
Wu Zhen-zhen. Finite element analysis of the process of photovoltaic glass calendering [D]. Henan University of Technology, 2015.
[4]
Zhao D Q, Tang Y, Huang Z G. Glass Toughening System Modeling and Simulation of Flow Field Based on Fluent [J]. Mechanical & Electrical Engineering Technology, 2016.
[5]
Isaev S A, Leontiev A I, Baranov P A, et al. Numerical Simulation of the Intensification of the Heat Exchange in a Plane-Parallel Channel with a Cylindrical Shallow Dimple on the Heated Wall [J]. Journal of Engineering Physics & Thermophysics, 2016, 89(5): 1186-1201.
[6]
Geng Tie, Yan Liqun. On the research of heat transfer enhancement technology of artificial roughness. [J] Machinery Design & Manufacture 2011, (02): 252-253.
[7]
Fang Qiang. Production Technology, Equipment and Practice of Solar Ultra - white Glass [J]. 2007 Proceedings of China Float Glass and Glass New Technology Development Seminar, 2010: 29-33.
[8]
Bei Mu. Photovoltaic glass production process [J]. Display device technology, 2010, 2: 1-2.
[9]
Ledoux M, Hami A E. 1. Mechanics and Fluid [M] // Fluid Mechanics: Analytical Methods. John Wiley & Sons, Inc. 2017.
[10]
Cao Yingjia. FLUENT for Corrugated tube Heat Exchanger [D]. Wuhan University of Technology, 2012.
[11]
Lu X Y, Li X G, Liu J M, et al. Numerical Simulation of Flow Fluid in Elbow Pipe Based on FLUENT and the Establishment of the Pressure Model [J]. Applied Mechanics & Materials, 2015, 713-715: 39-42.
[12]
Li L, Du X, Zhang Y, et al. Numerical simulation on flow and heat transfer of fin-and-tube heat exchanger with longitudinal vortex generators [J]. International Journal of Thermal Sciences, 2015, 92: 85-96.
[13]
Bhattacharyya S, Chattopadhyay H, Bandyopadhyay S. Numerical Simulation of Fluid Flow and Heat Transfer Enhancement in a Circular Wavy Channel [J]. Advances in Mechanical Engineering (Hindawi Publishing Corporati, 2015, 2013(6): 1104-1116.
PUBLICATION SERVICES
RESOURCES
SPECIAL SERVICES
Science Publishing Group
1 Rockefeller Plaza,
10th and 11th Floors,
New York, NY 10020
U.S.A.
Tel: (001)347-983-5186