Temperature and Thermal Stress Analysis of a Hot Blast Stove with an Internal Combustion Chamber

In this study, the temperature and thermal stress fields of an internal combustion hot blast stove were calculated and analysed. Turbulent, species transport, chemical reaction, radiation, and porous media models were implemented in a computational fluid dynamics model. Thermal boundary conditions o...

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Veröffentlicht in:	Processes 2023-03, Vol.11 (3), p.707
Hauptverfasser:	Park, Donghwi, Guo, Feng, Choi, Jongrak, Park, Joo-Hyoung, Kim, Naksoo
Format:	Artikel
Sprache:	eng
Schlagworte:	Adiabatic Analysis Boundary conditions Chemical reactions Combustion Combustion chambers Computational fluid dynamics Computer applications Corrosion Explosions Finite element analysis Finite element method Flue gas Fluid dynamics Fluid flow Heat transfer Hot blast Internal combustion Linings Mathematical analysis Methods Ovens & stoves Porous media Pressure vessels Process controls Refractories industry Strain gauges Stress analysis Stress corrosion cracking Stress distribution Temperature Temperature distribution Temperature effects Thermal diffusivity Thermal properties Thermal stress
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description	In this study, the temperature and thermal stress fields of an internal combustion hot blast stove were calculated and analysed. Turbulent, species transport, chemical reaction, radiation, and porous media models were implemented in a computational fluid dynamics model. Thermal boundary conditions on the structure of the hot blast stove were calculated based on the analytic adiabatic Y-plus method. A method to interpolate the thermal boundary conditions to a finite element mesh was developed, and the boundary conditions were mapped through the proposed method. In the on-gas period, the vortex was generated in the dome, and it made the variation of the temperature field in the checker chamber. The maximum temperature of the flue gas reached 1841 K in the on-gas period. In the on-blast period, the flow was considerably even compared to the on-gas period, and the average blast temperature reached 1345 K. The outer region of the checker chamber is shown to be continuously exposed to a higher temperature, which makes the region the main domain in managing the deterioration of the refractory linings. The shell temperature did not change during the operation due to the lower thermal diffusivity of the refractory linings, where the inner surface of the refractory had a maximum temperature change from 1441 K to 1659 K. The maximum temperature of the shell was 418.4 K at the conical region of the checker chamber side. The conical region had the higher maximum and middle principal thermal stresses due to the presence of a large temperature gradient around the conical region, where the largest maximum and middle principal stresses were 300.6 MPa and 192.0 MPa, respectively. The conical region was found to be a significant area of interest where it had a higher temperature and thermal stress.
doi_str_mv	10.3390/pr11030707
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Turbulent, species transport, chemical reaction, radiation, and porous media models were implemented in a computational fluid dynamics model. Thermal boundary conditions on the structure of the hot blast stove were calculated based on the analytic adiabatic Y-plus method. A method to interpolate the thermal boundary conditions to a finite element mesh was developed, and the boundary conditions were mapped through the proposed method. In the on-gas period, the vortex was generated in the dome, and it made the variation of the temperature field in the checker chamber. The maximum temperature of the flue gas reached 1841 K in the on-gas period. In the on-blast period, the flow was considerably even compared to the on-gas period, and the average blast temperature reached 1345 K. The outer region of the checker chamber is shown to be continuously exposed to a higher temperature, which makes the region the main domain in managing the deterioration of the refractory linings. The shell temperature did not change during the operation due to the lower thermal diffusivity of the refractory linings, where the inner surface of the refractory had a maximum temperature change from 1441 K to 1659 K. The maximum temperature of the shell was 418.4 K at the conical region of the checker chamber side. The conical region had the higher maximum and middle principal thermal stresses due to the presence of a large temperature gradient around the conical region, where the largest maximum and middle principal stresses were 300.6 MPa and 192.0 MPa, respectively. The conical region was found to be a significant area of interest where it had a higher temperature and thermal stress.</description><identifier>ISSN: 2227-9717</identifier><identifier>EISSN: 2227-9717</identifier><identifier>DOI: 10.3390/pr11030707</identifier><language>eng</language><publisher>Basel: MDPI AG</publisher><subject>Adiabatic ; Analysis ; Boundary conditions ; Chemical reactions ; Combustion ; Combustion chambers ; Computational fluid dynamics ; Computer applications ; Corrosion ; Explosions ; Finite element analysis ; Finite element method ; Flue gas ; Fluid dynamics ; Fluid flow ; Heat transfer ; Hot blast ; Internal combustion ; Linings ; Mathematical analysis ; Methods ; Ovens & stoves ; Porous media ; Pressure vessels ; Process controls ; Refractories industry ; Strain gauges ; Stress analysis ; Stress corrosion cracking ; Stress distribution ; Temperature ; Temperature distribution ; Temperature effects ; Thermal diffusivity ; Thermal properties ; Thermal stress</subject><ispartof>Processes, 2023-03, Vol.11 (3), p.707</ispartof><rights>COPYRIGHT 2023 MDPI AG</rights><rights>2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/). 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Turbulent, species transport, chemical reaction, radiation, and porous media models were implemented in a computational fluid dynamics model. Thermal boundary conditions on the structure of the hot blast stove were calculated based on the analytic adiabatic Y-plus method. A method to interpolate the thermal boundary conditions to a finite element mesh was developed, and the boundary conditions were mapped through the proposed method. In the on-gas period, the vortex was generated in the dome, and it made the variation of the temperature field in the checker chamber. The maximum temperature of the flue gas reached 1841 K in the on-gas period. In the on-blast period, the flow was considerably even compared to the on-gas period, and the average blast temperature reached 1345 K. The outer region of the checker chamber is shown to be continuously exposed to a higher temperature, which makes the region the main domain in managing the deterioration of the refractory linings. The shell temperature did not change during the operation due to the lower thermal diffusivity of the refractory linings, where the inner surface of the refractory had a maximum temperature change from 1441 K to 1659 K. The maximum temperature of the shell was 418.4 K at the conical region of the checker chamber side. The conical region had the higher maximum and middle principal thermal stresses due to the presence of a large temperature gradient around the conical region, where the largest maximum and middle principal stresses were 300.6 MPa and 192.0 MPa, respectively. The conical region was found to be a significant area of interest where it had a higher temperature and thermal stress.</abstract><cop>Basel</cop><pub>MDPI AG</pub><doi>10.3390/pr11030707</doi><orcidid>https://orcid.org/0000-0001-6810-0647</orcidid><orcidid>https://orcid.org/0000-0003-3844-0661</orcidid><oa>free_for_read</oa></addata></record>
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source	Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; MDPI - Multidisciplinary Digital Publishing Institute
subjects	Adiabatic Analysis Boundary conditions Chemical reactions Combustion Combustion chambers Computational fluid dynamics Computer applications Corrosion Explosions Finite element analysis Finite element method Flue gas Fluid dynamics Fluid flow Heat transfer Hot blast Internal combustion Linings Mathematical analysis Methods Ovens & stoves Porous media Pressure vessels Process controls Refractories industry Strain gauges Stress analysis Stress corrosion cracking Stress distribution Temperature Temperature distribution Temperature effects Thermal diffusivity Thermal properties Thermal stress
title	Temperature and Thermal Stress Analysis of a Hot Blast Stove with an Internal Combustion Chamber
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