Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach

ROY, APOORVA DEEP ;DHIMAN,  Sushil Kumar .
Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach. 
Articles in Press, [S.l.], v. 0, n.0, p. , april 2024. 
ISSN 0039-2480.
Available at: <https://www.sv-jme.eu/article/estimation-of-surface-temperature-and-heat-flux-over-a-hollow-cylinder-and-slab-using-inverse-heat-conduction-approach/>. Date accessed: 08 may. 2024. 
doi:http://dx.doi.org/.

ROY, A., & Dhiman,  .
(0).
Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach.
Articles in Press, 0(0), .
doi:http://dx.doi.org/

@article{.,
	author = {APOORVA DEEP  ROY and  Sushil Kumar  Dhiman},
	title = {Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach},
	journal = {Articles in Press},
	volume = {0},
	number = {0},
	year = {0},
	keywords = {surface temperature and heat flux, inverse heat conduction, energy balance approach, hollow cylinder and flat plate, derived equations; },
	abstract = {A non-iterative approximation of Inverse Heat Conduction Problem has been developed through energy balance between the control volumes. Heat Flow domain along surface normal was divided into three control volumes and studied as three cases viz. on a heated hollow metallic cylinder cooled in crossflow of air, a heating flat plate in still air, and a heated flat plate when cooled in still air with random air blows. The time derivatives of temperature and heat flux estimates at the surface appearing in derived equations were evaluated by approximate expressions. Both estimates were obtained from the derived equations by simultaneous measurement of temperature-time histories at two locations, one at inner surface and the other anywhere within control volume along the surface normal. Deviation was checked by real time simultaneous measurement of temperature-time history at the outer surface along the surface normal. Comparison between the estimated surface temperature-time history using the derived equations and the real time measurement showed deviations within 0.5% for cylinder, within 0.03% for plate in still air and within 0.5% when air blows were given. Heat fluxes estimated using these time histories were correspondingly arrived at consistent and close approximations for all cases. Estimates from the derived equations were additionally compared with reported equations from the literature where also they showed reasonably good agreements.},
	issn = {0039-2480},	pages = {},	doi = {},
	url = {https://www.sv-jme.eu/article/estimation-of-surface-temperature-and-heat-flux-over-a-hollow-cylinder-and-slab-using-inverse-heat-conduction-approach/}
}

ROY, A.,Dhiman,  .
0 April 0. Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach. Articles in Press. [Online] 0:0

%A ROY, APOORVA DEEP 
%A Dhiman,  Sushil Kumar 
%D 0
%T Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach
%B 0
%9 surface temperature and heat flux, inverse heat conduction, energy balance approach, hollow cylinder and flat plate, derived equations; 
%! Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach
%K surface temperature and heat flux, inverse heat conduction, energy balance approach, hollow cylinder and flat plate, derived equations; 
%X A non-iterative approximation of Inverse Heat Conduction Problem has been developed through energy balance between the control volumes. Heat Flow domain along surface normal was divided into three control volumes and studied as three cases viz. on a heated hollow metallic cylinder cooled in crossflow of air, a heating flat plate in still air, and a heated flat plate when cooled in still air with random air blows. The time derivatives of temperature and heat flux estimates at the surface appearing in derived equations were evaluated by approximate expressions. Both estimates were obtained from the derived equations by simultaneous measurement of temperature-time histories at two locations, one at inner surface and the other anywhere within control volume along the surface normal. Deviation was checked by real time simultaneous measurement of temperature-time history at the outer surface along the surface normal. Comparison between the estimated surface temperature-time history using the derived equations and the real time measurement showed deviations within 0.5% for cylinder, within 0.03% for plate in still air and within 0.5% when air blows were given. Heat fluxes estimated using these time histories were correspondingly arrived at consistent and close approximations for all cases. Estimates from the derived equations were additionally compared with reported equations from the literature where also they showed reasonably good agreements.
%U https://www.sv-jme.eu/article/estimation-of-surface-temperature-and-heat-flux-over-a-hollow-cylinder-and-slab-using-inverse-heat-conduction-approach/
%0 Journal Article
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%& 
%P 1
%J Articles in Press
%V 0
%N 0
%@ 0039-2480
%8 2024-04-11
%7 2024-04-11

ROY, APOORVA DEEP, &  Sushil Kumar  Dhiman.
"Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach." Articles in Press [Online], 0.0 (0): . Web.  08 May. 2024

TY  - JOUR
AU  - ROY, APOORVA DEEP 
AU  - Dhiman,  Sushil Kumar 
PY  - 0
TI  - Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach
JF  - Articles in Press
DO  - 
KW  - surface temperature and heat flux, inverse heat conduction, energy balance approach, hollow cylinder and flat plate, derived equations; 
N2  - A non-iterative approximation of Inverse Heat Conduction Problem has been developed through energy balance between the control volumes. Heat Flow domain along surface normal was divided into three control volumes and studied as three cases viz. on a heated hollow metallic cylinder cooled in crossflow of air, a heating flat plate in still air, and a heated flat plate when cooled in still air with random air blows. The time derivatives of temperature and heat flux estimates at the surface appearing in derived equations were evaluated by approximate expressions. Both estimates were obtained from the derived equations by simultaneous measurement of temperature-time histories at two locations, one at inner surface and the other anywhere within control volume along the surface normal. Deviation was checked by real time simultaneous measurement of temperature-time history at the outer surface along the surface normal. Comparison between the estimated surface temperature-time history using the derived equations and the real time measurement showed deviations within 0.5% for cylinder, within 0.03% for plate in still air and within 0.5% when air blows were given. Heat fluxes estimated using these time histories were correspondingly arrived at consistent and close approximations for all cases. Estimates from the derived equations were additionally compared with reported equations from the literature where also they showed reasonably good agreements.
UR  - https://www.sv-jme.eu/article/estimation-of-surface-temperature-and-heat-flux-over-a-hollow-cylinder-and-slab-using-inverse-heat-conduction-approach/

@article{{}{.},
	author = {ROY, A., Dhiman,  .},
	title = {Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach},
	journal = {Articles in Press},
	volume = {0},
	number = {0},
	year = {0},
	doi = {},
	url = {https://www.sv-jme.eu/article/estimation-of-surface-temperature-and-heat-flux-over-a-hollow-cylinder-and-slab-using-inverse-heat-conduction-approach/}
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TY  - JOUR
AU  - ROY, APOORVA DEEP 
AU  - Dhiman,  Sushil Kumar 
PY  - 2024/04/11
TI  - Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach
JF  - Articles in Press; Vol 0, No 0 (0): Articles in Press
DO  - 
KW  - surface temperature and heat flux, inverse heat conduction, energy balance approach, hollow cylinder and flat plate, derived equations, 
N2  - A non-iterative approximation of Inverse Heat Conduction Problem has been developed through energy balance between the control volumes. Heat Flow domain along surface normal was divided into three control volumes and studied as three cases viz. on a heated hollow metallic cylinder cooled in crossflow of air, a heating flat plate in still air, and a heated flat plate when cooled in still air with random air blows. The time derivatives of temperature and heat flux estimates at the surface appearing in derived equations were evaluated by approximate expressions. Both estimates were obtained from the derived equations by simultaneous measurement of temperature-time histories at two locations, one at inner surface and the other anywhere within control volume along the surface normal. Deviation was checked by real time simultaneous measurement of temperature-time history at the outer surface along the surface normal. Comparison between the estimated surface temperature-time history using the derived equations and the real time measurement showed deviations within 0.5% for cylinder, within 0.03% for plate in still air and within 0.5% when air blows were given. Heat fluxes estimated using these time histories were correspondingly arrived at consistent and close approximations for all cases. Estimates from the derived equations were additionally compared with reported equations from the literature where also they showed reasonably good agreements.
UR  - https://www.sv-jme.eu/article/estimation-of-surface-temperature-and-heat-flux-over-a-hollow-cylinder-and-slab-using-inverse-heat-conduction-approach/

ROY, APOORVA DEEP, AND Dhiman,  Sushil Kumar.
"Estimation of Surface Temperature and Heat Flux over a Hollow Cylinder and Slab using Inverse Heat Conduction Approach" Articles in Press [Online], Volume 0 Number 0 (11 April 2024)