The Influence of the Position of the Steel Element to Heat Flow in the Wall of the Industrial Freezer

Martin Mohapl; Petra Vojkůvková

doi:10.4028/www.scientific.net/AMR.941-944.2474

Paper Titles

Energy Consumption Analysis of Thermal Regeneration of Activated Cokes Loaded with SO₂
p.2457

The Influence from the Return Water Temperature of Condenser on the Cooling Capacity and Power Consumption of the Cold-Water Screw Unit Used on Cold Storage
p.2461

Application of Thermal Contact Resistance in Simulation of Heat Dissipation by CPU Heat Sinks Based on ANSYS
p.2465

Heat Transfer Capacity of Composite Cooling System for Automobile Lithium-Ion Battery with Heat Pipe and Phase Change Materials
p.2469

The Influence of the Position of the Steel Element to Heat Flow in the Wall of the Industrial Freezer
p.2474

Effect of Model Structure on Thermal Conductivity of Sandwich Composites
p.2478

Thermal Insulative Performance of Bamboo Leaf Aerogel Opacified Using Activated Carbon Compared with Carbon Black
p.2482

The Influence of Induction Heating to Remelting Temperature Radial Distribution
p.2486

Theoretical Analysis and Experimental Study on Heat-Transfer in Cryogenic Gas Atomization Jet Cooling Nickel-Base Alloy
p.2490

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 941-944The Influence of the Position of the Steel Element...

The Influence of the Position of the Steel Element to Heat Flow in the Wall of the Industrial Freezer

Abstract:

This contribution defines physical heat behaving of a selected construction part of a wall in an industrial freezer. This study is focused on the specific selected example of possible solution of the connection between the insulated wall and a load-bearing rolled steel I-shaped beam. The aim of this study characterizes the impact on thermal losses of exchanging coldness and the field of temperatures in different variants of the selected element installation based on executive parametrical simulations. This article also shows thermo-graphical measuring and monitoring of the element and describes possible risks of the real selected solution.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 941-944)

Pages:

2474-2477

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.941-944.2474

Citation:

Cite this paper

Online since:

June 2014

Authors:

Martin Mohapl*, Petra Vojkůvková

Keywords:

Heat Conduction, Heat Insulation, Industrial Freezer, Numerical Simulation, Software CalA

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] KOSUTOVA, Katarina, Ondrej SIKULA a Josef PLASEK. Thermal Bonds of Buildings Structures in Energy Conservation - A Case Study. In: DENG, W. AASRI Procedia. 2012, pp.14-19. ISSN 22126716. DOI: 10. 1016/j. aasri. 2012. 09. 007.

DOI: 10.1016/j.aasri.2012.09.007

Google Scholar

[2] ČSN 73 0540-2. Thermal protection of buildings - Part 2: Requirements. Praha: CNI, 2011. (Czech technical standard).

Google Scholar

[3] ČSN EN 13469. Thermal insulating products for building equipment and industrial installations - Determination of water vapour transmission properties of preformed pipe insulation. Praha: CNI, 2013. (Czech technical standard).

DOI: 10.3403/30420754

Google Scholar

[4] ČSN 14 8102. Thermal insulation of cooling and freezing plants. Praha: CNI, 1993. (Czech technical standard).

Google Scholar

[5] ŠIKULA, Ondřej, Jitka MOHELNÍKOVÁ a Josef PLÁŠEK. Thermal CFD Analysis of Tubular Light Guides. Energies. 2013, vol. 6, no. 12, pp.6304-6321. Available from: http: /www. mdpi. com/1996-1073/6/12/6304.

DOI: 10.3390/en6126304

Google Scholar

[6] SNOPEK, Milan. The solution selected aspects of cooling slauhtergouse. Brno, 2013. 260p., Master's thesis. Brno University of Technology, Faculty of Civil Engineering, Institute of Building Services.

Google Scholar

[7] ŠIKULA, O.; PLÁŠEK, J.: CalA 3. 2 v 1024; Calculation Area (CalA) 3. 2 v 1024. (authorized software). http: /www. fce. vutbr. cz/TZB/sikula. o/cala_uvod. html.

Google Scholar

[8] ŠIKULA, Ondřej. Manuál k softwaru CalA. V Tribunu EU vyd. 1. Brno: Tribun EU, 2009, 43 s. ISBN 978-80-7399-879-0. Available from: http: /www. researchgate. net/publication/47124995_Manul_k_softwaru_CalA_>.

Google Scholar

[9] ISO, EN. 10211 (2007) Thermal Bridges in Building Construction–Heat Flows and Surface Temperatures–Detailed Calculations. 2007. (Technical standard).

DOI: 10.3403/30143206u

Google Scholar