Access the full text.
Sign up today, get DeepDyve free for 14 days.
Haitao Zhang, Qifu Huang, Chao Hu, Qizhao Lin (2018)
Numerical study on heat transfer and energy storage in a glass furnace regeneratorGlass Technology-european Journal of Glass Science and Technology Part A, 59
(1993)
Thermal Engineering Calculations of Metallurgical Furnaces, 3 rd ed
(2013)
Performance and Optimization for Energy Savings
Gottfried Scheiblechner (2008)
Chimney‐Type Checker‐Block Packing and Latest Developments in Checkerwork Design
Grzegorz Wołkowycki (2016)
Experimental Results on the Fixed Matrix Regenerator Effectiveness for a Glass Stove FurnaceHeat Transfer Engineering, 37
(1982)
Veitscher chimney type and checkers block packing methods for glass tank regenerator,
S. Sadrameli (2016)
Mathematical models for the simulation of thermal regenerators: A state-of-the-art reviewRenewable & Sustainable Energy Reviews, 58
Juan Yu, Mingchuan Zhang, W. Fan, Yuegui Zhou, Guofeng Zhao (2002)
Study on performance of the ball packed-bed regenerator: experiments and simulationApplied Thermal Engineering, 22
V. Dzyuzer, S. Minin, K. Alikina (2017)
Fume Heat Recovery Efficiency in High-Capacity Glassmaking FurnacesGlass and Ceramics, 74
A Zanoli, WD Leahy, R Vidil, D Lagarenne (1991)
Experimental studies of thermal performance of various cruciform regenerator packingGlass Technol., 32
D. Lechevalier, I. Cabodi, O. Citti, M. Gaubil, J. Poiret (2012)
New Cruciform Solutions to Upgrade your Regenerator
(2018)
European Journal of Glass Science and Technology
M. Zarrinehkafsh, S. Sadrameli (2004)
Simulation of fixed bed regenerative heat exchangers for flue gas heat recoveryApplied Thermal Engineering, 24
(2002)
experiments and simulation,” Appl
Davide Basso, C. Cravero, A. Reverberi, B. Fabiano (2015)
CFD Analysis of Regenerative Chambers for Energy Efficiency Improvement in Glass Production PlantsEnergies, 8
(1991)
Lagarenne, “Experimental studies of thermal performance of various cruciform regenerator packing,
R. Beerkens, J. Limpt (2008)
Energy efficiency benchmarking of glass furnacesGlass science and technology, 77
(2017)
Regenerator design study combining numerical simulations and statistical tools,
Vishal Sardeshpande, R. Anthony, U. Gaitonde, R. Banerjee (2011)
Performance analysis for glass furnace regeneratorApplied Energy, 88
(2020)
Lower CO2 emissions with type 8 cruciforms –Industrial feedback,
(1979)
Heat Transfer Enhancement in Flame Furnaces
(2014)
Postmortem analysis of magnesia and magnesia zircon checkers after one campaign in a soda-lime glass melting furnace,
V. Dzyuzer (2012)
Methods for increasing the energy-efficiency of glass furnacesGlass and Ceramics, 69
(2002)
Rational use of the refractories and optimal designs of the packing products for glass-melting furnace regenerators,
C. Cravero, Davide Domenico, Philippe Leutcha (2020)
A CFD Based Approach for the Simulation of Gas Recirculation Systems in Regenerative Chambers for Glass Production Plants Consistent with Functional Details Found in Real GeometriesTecnica Italiana-Italian Journal of Engineering Science
C. Cravero, D. Marsano (2017)
Numerical Simulation of Regenerative Chambers for Glass Production Plants with a Non-Equilibrium Heat Transfer Model, 12
Grzegorz Wołkowycki (2016)
Effectiveness of high temperature innovative geometry fixed ceramic matrix regenerators used in glass furnacesArchives of Thermodynamics, 37
V. Dzyuzer (2013)
Boundary conditions for calculating the regenerator and checker brickwork in a glassmaking furnaceGlass and Ceramics, 70
The influence of the shape and dimensions of the chimney blocks on regenerative heat transfer in a glass-making furnace with a horseshoe-shaped flame is considered. Chimney blocks with various combinations of the cross-section area, height, and wall thickness have been studied. To evaluate the efficiency of the blocks, the regenerator design parameters were used. It has been established that the smallest volume and weight of the high-temperature zone of the packing, limited by a flue gas temperature of 1100°C, can be achieved by using TL 15/15 blocks, characterized by a specific volume of 0.259 m3/m3 and a specific heating surface of 18.9 m2/m3. In the sulfate condensation zone and the low-temperature zone of the packing, TG 15/15 blocks should be used, for which the specific volume and specific heating surface are 0.296 m3/m3 and 17.4 m2/m3, respectively.
Refractories and Industrial Ceramics – Springer Journals
Published: Sep 1, 2022
Keywords: glass-making furnace; regenerator; chimney block; heat transfer coefficient; temperature
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.