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Statements

Subject Item
n2:RIV%2F00216305%3A26210%2F13%3APU106101%21RIV14-MSM-26210___
rdf:type
n10:Vysledek skos:Concept
rdfs:seeAlso
http://steelsim2013.cz
dcterms:description
Thermal contact conductance is an important parameter for describing heat transfer between two bodies. When two solids are put in contact and heat transfer occurs, the temperature drop is observed at the interface between solids. It is caused by an imperfect joint which occurs because of real surfaces are not perfectly smooth and flat. An experimental device for the evaluation of thermal contact conductance was designed and fabricated in Heat Transfer and Fluid Flow Laboratory. The principal of this investigation is the unsteady measurement of temperatures of two solids which are put in contact. The surface temperature and heat transfer coefficient can be calculated from measured temperatures by an inverse heat transfer task. The paper describes experimental device and the determination of thermal contact conductance between two solids with different contact pressure and initial temperatures. The measured data and computed values of thermal contact conductance were presented and compared with other Thermal contact conductance is an important parameter for describing heat transfer between two bodies. When two solids are put in contact and heat transfer occurs, the temperature drop is observed at the interface between solids. It is caused by an imperfect joint which occurs because of real surfaces are not perfectly smooth and flat. An experimental device for the evaluation of thermal contact conductance was designed and fabricated in Heat Transfer and Fluid Flow Laboratory. The principal of this investigation is the unsteady measurement of temperatures of two solids which are put in contact. The surface temperature and heat transfer coefficient can be calculated from measured temperatures by an inverse heat transfer task. The paper describes experimental device and the determination of thermal contact conductance between two solids with different contact pressure and initial temperatures. The measured data and computed values of thermal contact conductance were presented and compared with other
dcterms:title
Estimation of Thermal Contact Conductance from unsteady temperature measurements Estimation of Thermal Contact Conductance from unsteady temperature measurements
skos:prefLabel
Estimation of Thermal Contact Conductance from unsteady temperature measurements Estimation of Thermal Contact Conductance from unsteady temperature measurements
skos:notation
RIV/00216305:26210/13:PU106101!RIV14-MSM-26210___
n10:predkladatel
n13:orjk%3A26210
n3:aktivita
n22:P
n3:aktivity
P(EE2.3.20.0188)
n3:dodaniDat
n15:2014
n3:domaciTvurceVysledku
n16:8785309 n16:8752338 n16:3415619
n3:druhVysledku
n4:D
n3:duvernostUdaju
n17:S
n3:entitaPredkladatele
n14:predkladatel
n3:idSjednocenehoVysledku
73303
n3:idVysledku
RIV/00216305:26210/13:PU106101
n3:jazykVysledku
n9:eng
n3:klicovaSlova
Thermal contact conductance, inverse algorithm, heat transfer coefficient
n3:klicoveSlovo
n5:Thermal%20contact%20conductance n5:heat%20transfer%20coefficient n5:inverse%20algorithm
n3:kontrolniKodProRIV
[AC7A4E3A741A]
n3:mistoKonaniAkce
Ostrava
n3:mistoVydani
Ostrava
n3:nazevZdroje
Steelsim 2013
n3:obor
n8:BJ
n3:pocetDomacichTvurcuVysledku
3
n3:pocetTvurcuVysledku
3
n3:projekt
n7:EE2.3.20.0188
n3:rokUplatneniVysledku
n15:2013
n3:tvurceVysledku
Pohanka, Michal Kvapil, Jiří Horský, Jaroslav
n3:typAkce
n23:WRD
n3:zahajeniAkce
2013-09-10+02:00
s:numberOfPages
6
n19:hasPublisher
VŠB - Technical university of Ostrava
n20:isbn
978-80-260-3912-9
n11:organizacniJednotka
26210