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Pregled bibliografske jedinice broj: 679714

Calculation of the heat transfer coefficient based on experiments by the Liscic probes


Liščić, Božidar; Singer, Saša
Calculation of the heat transfer coefficient based on experiments by the Liscic probes // Thermal engineering of steel alloy systems / Krauss, George ; Hashmi, Saleem (ur.).
New York: Elsevier Science, 2014. str. 1-54


CROSBI ID: 679714 Za ispravke kontaktirajte CROSBI podršku putem web obrasca

Naslov
Calculation of the heat transfer coefficient based on experiments by the Liscic probes

Autori
Liščić, Božidar ; Singer, Saša

Vrsta, podvrsta i kategorija rada
Poglavlja u knjigama, znanstveni

Knjiga
Thermal engineering of steel alloy systems

Urednik/ci
Krauss, George ; Hashmi, Saleem

Izdavač
Elsevier Science

Grad
New York

Godina
2014

Raspon stranica
1-54

ISBN
978-0-08-096532-1

Ključne riječi
finite difference method, finite volume method, heat transfer, heat transfer coefficient, Ipsen--Liscic flux sensor, Liscic/Nanmac probe, Liscic/Petrofer probe, measurement of transient temperatures, monotone smoothing, quenching, splines, surface heat flux density, temperature gradient method, test for cooling intensity

Sažetak
Heat transfer mechanisms at quenching in evaporable liquid quenchants, and at high pressure gas quenching in vacuum furnaces, are described. In three different Liscic probes, the temperature gradient method is used to evaluate the cooling intensity at quenching in laboratory and workshop environments. Calculation of the heat transfer coefficient is based on temperatures measured in time at a near-surface point in the probe. After smoothing, they are used as an input for the one-dimensional heat conduction equation. The surface heat flux density is calculated to reproduce the input temperature, by finite differences or finite volumes.

Izvorni jezik
Engleski

Znanstvena područja
Matematika, Strojarstvo



POVEZANOST RADA


Projekti:
037-1193086-2771 - Numeričke metode u geofizičkim modelima (Singer, Saša, MZOS ) ( POIROT)

Ustanove:
Prirodoslovno-matematički fakultet, Matematički odjel, Zagreb,
Hrvatska akademija znanosti i umjetnosti

Profili:

Avatar Url Saša Singer (autor)

Avatar Url Božidar Liščić (autor)

Citiraj ovu publikaciju:

Liščić, Božidar; Singer, Saša
Calculation of the heat transfer coefficient based on experiments by the Liscic probes // Thermal engineering of steel alloy systems / Krauss, George ; Hashmi, Saleem (ur.).
New York: Elsevier Science, 2014. str. 1-54
Liščić, B. & Singer, S. (2014) Calculation of the heat transfer coefficient based on experiments by the Liscic probes. U: Krauss, G. & Hashmi, S. (ur.) Thermal engineering of steel alloy systems. New York, Elsevier Science, str. 1-54.
@inbook{inbook, author = {Li\v{s}\v{c}i\'{c}, Bo\v{z}idar and Singer, Sa\v{s}a}, year = {2014}, pages = {1-54}, keywords = {finite difference method, finite volume method, heat transfer, heat transfer coefficient, Ipsen--Liscic flux sensor, Liscic/Nanmac probe, Liscic/Petrofer probe, measurement of transient temperatures, monotone smoothing, quenching, splines, surface heat flux density, temperature gradient method, test for cooling intensity}, isbn = {978-0-08-096532-1}, title = {Calculation of the heat transfer coefficient based on experiments by the Liscic probes}, keyword = {finite difference method, finite volume method, heat transfer, heat transfer coefficient, Ipsen--Liscic flux sensor, Liscic/Nanmac probe, Liscic/Petrofer probe, measurement of transient temperatures, monotone smoothing, quenching, splines, surface heat flux density, temperature gradient method, test for cooling intensity}, publisher = {Elsevier Science}, publisherplace = {New York} }
@inbook{inbook, author = {Li\v{s}\v{c}i\'{c}, Bo\v{z}idar and Singer, Sa\v{s}a}, year = {2014}, pages = {1-54}, keywords = {finite difference method, finite volume method, heat transfer, heat transfer coefficient, Ipsen--Liscic flux sensor, Liscic/Nanmac probe, Liscic/Petrofer probe, measurement of transient temperatures, monotone smoothing, quenching, splines, surface heat flux density, temperature gradient method, test for cooling intensity}, isbn = {978-0-08-096532-1}, title = {Calculation of the heat transfer coefficient based on experiments by the Liscic probes}, keyword = {finite difference method, finite volume method, heat transfer, heat transfer coefficient, Ipsen--Liscic flux sensor, Liscic/Nanmac probe, Liscic/Petrofer probe, measurement of transient temperatures, monotone smoothing, quenching, splines, surface heat flux density, temperature gradient method, test for cooling intensity}, publisher = {Elsevier Science}, publisherplace = {New York} }




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