International Scientific Journal

External Links


In this paper, the effect of different forms of electric heating wire forms on the anti-icing performance of the refrigerated container was studied based on numerical simulation. The heat transfer and the thermal conductivity of the refrigerated container door wall, and the uniformity of air-flow distribution in the refrigerated container are analyzed. The heating wire form 2 has the best anti-icing performance and meets the anti-icing requirement when the thermal conductivity is from 0.005-0.01 W/mK. The electric heating wires nearest to the inner wall surface is the optimal anti-icing solution. The spare electric heating wires placement can be determined according to the thickness of the refrigerated container door. The specific lay-out of electric heating wires in the future can be further optimized in combination with carbon emissions.
PAPER REVISED: 2022-11-25
PAPER ACCEPTED: 2022-11-28
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2023, VOLUME 27, ISSUE Issue 5, PAGES [3501 - 3512]
  1. Liu, E. H., et al., Fractal Calculus for Refrigerated Transportation of Perishable Foods Energy Consumption and Energy Saving, Thermal Science, 25 (2021), 2B, pp. 1255-1260
  2. Devireddy, R. V., Biopreservation: Heat/Mass Transfer Challenges and Biochemical/Genetic Adaptations In Biological Systems, Heat Transfer Research., 44 (2013), 3-4, pp. 245-272
  3. Yang, F. Y., et al., Research on Quasi-Two-Stage compression cycle characteristics of referigeration system for cold storage, Thermal Science, 26 (2022), 3B, pp. 2765-2770
  4. Wang, J. F., et al., Effect of Glazing with Different Materials on the Quality of Tuna during Frozen Storage, Foods, 9 (2020), 231
  5. Tan, M. T., et al., Storage Time Prediction of Glazed Frozen Squids during Frozen Storage at Different Temperatures Based on Neural Network, International Journal of Food Properties, 23 (2020), 1, pp. 1663-1677
  6. Ibrahim, Y., et al., The 3-D Printed Electro-Thermal anti- or de-Icing System for Composite Panels, Cold Regions Science and Technology, 166 (2019), 102844
  7. Nilsson, F., et al., Modelling Anti-Icing of Railway Overhead Catenary Wires by Resistive Heating, International Journal of Heat and Mass Transfer, 143 (2019), 118505
  8. Redondo, O., et al., Anti-Icing and De-icing Coatings Based Joule's Heating of Graphene Nanoplatelets, Composites Science and Technology, 164 (2018), Aug., pp. 65-73
  9. Voigt, A. L., et al., Conception, Implementation and Evaluation of Induction Wire Heating System Applied to Hot Wire GTAW (IHW-GTAW), Journal of Materials Processing Tech., 281 (2020), 116615
  10. Li, J., et al., Study on Optimization of Condensation Prevention and Power Consumption of Refrigerator Glass Door, Proceedings, China Household Appliance Technology Conference, China, 2019, pp. 339-350
  11. Zhao, Z. H., et al., Novel Sandwich Structural Electric Heating Coating for anti-Icing/de-Icing on Complex Surfaces, Surface and Coatings Technology, 404 (2020), 126489
  12. Xue, C. H., et al., Superhydrophobic anti-Icing Coatings with Self-Deicing Property Using Melanin Nanoparticles from Cuttlefish Juice, Chemical Engineering Journal, 424 (2021), 130553
  13. Zhao, Z. H., et al., The Development of Electric Heating Coating with Temperature Controlling Capability for anti-Icing/deIcing, Cold Regions Science and Technology, 184 (2021), 103234
  14. Zhao, Z. H., et al., Development of High-Efficient Synthetic Electric Heating Coating for anti-icing/de-Icing, Surface and Coatings Technology, 349 (2018), Sept., pp. 340-346
  15. Omid, H. B., et al., A Novel Full-Scale External Geothermal Heating System for Bridge Deck de-Icing, Applied Thermal Engineering, 185 (2021), 116365
  16. Heymsfied, E., et al., Developing anti-Icing Airfield Runways Using Surface Embedded Heat Wires and Renewable Energy, Sustainable Cities and Society, 52 (2020), 101712
  17. Yang, Z. H., et al., Energy-Saving Optimization of Anti-condensation Heating Wire for Refrigerator, Proceedings, 2019 China Household Appliance Technology Conference, China, 2019, pp. 246-250
  18. Gaedtke, M., et al., Application of a Lattice Boltzmann Method Combined with a Smagorinsky Turbulence Model to Satially Resolved Heat Flux Inside a Refrigerated Vehicle, Comput. Math. Appl., 76 (2018), 10, pp. 2315-2329
  19. Jara, P. B. T., et al., Thermal Behavior of a Refrigerated Vehicle: Process Simulation, Int. J.Refrig., 100 (2018), Apr., pp. 124-130
  20. Nikitin, M. N., Numerical Analysis of Refrigerated Display Designs in Terms of Cooling Efficiency, Int. J. Therm. Sci., 148 (2020), 106157
  21. Radwan, A., et al., Thermal and Electrical Performances of Semi-Transparent Photovoltaic Glazing Integrated with Translucent Vacuum Insulation Panel and Vacuum Glazing, Energ. Convers. Manage., 215 (2020), 112920
  22. Li, W., Simulation and Experimental Study on Temperature Field of Refrigerator Against Condensation, Journal of Appliance Science and Technology, 02 (2021), 2, pp. 104-110
  23. Han, J.W., et al., Computational Fluid Dynamics Simulation Determine Combined Mode to Conserve Energy in Refrigerated Vehicles, Journal Food Process Eng., 39 (2016), 2, pp. 186-195
  24. Li, J., et al., Effect of Coverage Percentage of Vacuum Insulation Panels on Inner Temperature Distribution of Refrigerated Container, Food and Machinery, 32 (2016), 07, pp. 99-102+165
  25. Guo, J. M., et al., Numerical Simulation on Temperature Field Effect of Stack Method of Garden Stuff for Fresh-Keeping Transportation, Transactions of the Chinese Society for Agricultural Engineering, 28 (2012), 13, pp. 231-236
  26. Liu, X. F., Nan, X. H., Improvement on Characteristics of Air-Flow Field in Cold Storage with Uniform Air Supply Duct, Transactions of the Chinese Society of Agricultural Engineering, 32 (2016), 01, pp. 91-96
  27. Xu, H. P., et al., Carbon Emission Analysis of Passive Timber Buildings in Severe Cold Region Based on Type Comparison, Architecture Technology, 52 (2021), 3, pp. 324-328

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence