Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/wiley/transient-combined-radiative-and-conductive-heat-transfer-in-plastics-065BRm4Yk0
References (22)
-
Parham Sadooghi, C. Aghanajafi (2004)
Radiation effects on a ceramic layerRadiation Effects and Defects in Solids, 159
-
Z. Hashin, S. Shtrikman (1962)
A Variational Approach to the Theory of the Effective Magnetic Permeability of Multiphase MaterialsJournal of Applied Physics, 33
-
R. Siegel (1992)
Finite Difference Solution for Transient Cooling of a Radiating-Conducting Semitransparent LayerJournal of Thermophysics and Heat Transfer, 6
-
(1992)
Heat Transfer , 9 , 55 ( -
R. Viskanta (1982)
RADIATION HEAT TRANSFER: INTERACTION WITH CONDUCTION AND CONVECTION AND APPROXIMATE METHODS IN RADIATION, 1
-
H. Reiss (1988)
Radiative Transfer in Nontransparent, Dispersed Media -
R. Viskanta, P. Bathla (1967)
Unsteady energy transfer in a layer of gray gas by thermal radiationZeitschrift für angewandte Mathematik und Physik ZAMP, 18
-
G. Slack (1973)
Nonmetallic crystals with high thermal conductivityJournal of Physics and Chemistry of Solids, 34
-
Ching-fen Tsai, G. Nixon (1986)
TRANSIENT TEMPERATURE DISTRIBUTION OF A MULTILAYER COMPOSITE WALL WITH EFFECTS OF INTERNAL THERMAL RADIATION AND CONDUCTIONNumerical Heat Transfer Part A-applications, 10
-
R. Siegel (1987)
Transient radiative cooling of a droplet-filled layerJournal of Heat Transfer-transactions of The Asme, 109
-
Parham Sadooghi, C. Aghanajafi (2003)
Coating Effects on Transient Cooling a Hot Spherical BodyJournal of Fusion Energy, 22
-
J. King, K. Tucker, B. Vogt, E. Weber, Congling Quan (1999)
Electrically and thermally conductive nylon 6,6Polymer Composites, 20
-
R. Siegel (1995)
Refractive Index Effects on Transient Cooling of a Semitransparent Radiating LayerJournal of Thermophysics and Heat Transfer, 9
-
(1979)
Heat and Mass Transfer in Low Temperature Equipment -
B. Song, R. Viskanta (1989)
Deicing of solids using radiant heatingJournal of Thermophysics and Heat Transfer, 4
-
C. Lii, M. Özişik (1972)
Transient radiation and conduction in an absorbing, emitting, scattering slab with reflective boundariesInternational Journal of Heat and Mass Transfer, 15
-
C. Wong, R. Bollampally (1999)
Thermal conductivity, elastic modulus, and coefficient of thermal expansion of polymer composites filled with ceramic particles for electronic packagingJournal of Applied Polymer Science, 74
-
R. Viskanta, M. Mengüç (1989)
Radiative Transfer in Dispersed MediaApplied Mechanics Reviews, 42
-
X. Lu, Gu Xu (1997)
Thermally conductive polymer composites for electronic packagingJournal of Applied Polymer Science, 65
-
T. Ping, M. Lallemand (1989)
Transient radiative—conductive heat transfer in flat glasses submitted to temperature, flux and mixed boundary conditionsInternational Journal of Heat and Mass Transfer, 32
-
P. Bathla, R. Viskanta (1968)
Effect of surroundings on the transient energy transfer in a layer of radiating gasFlow Turbulence and Combustion, 19
-
K. Weston, J. Hauth (1973)
Unsteady, Combined Radiation and Conduction in an Absorbing, Scattering, and Emitting MediumJournal of Heat Transfer-transactions of The Asme, 95
- Publisher
- Wiley
- Copyright
- Copyright © 2005 Society of Plastics Engineers
- ISSN
- 1083-5601
- eISSN
- 1548-0585
- DOI
- 10.1002/vnl.20033
- Publisher site
- See Article on Publisher Site
Abstract
By the addition of metal and oxide particles to plastics, thermal transport properties, heat capacity, and density of polymers can be varied systematically. Radiation effects in a particle filled with various fillers become more important and transient temperature responses including radiation can be significantly different from those by conduction alone. Transient combined conduction–radiation heat transfer is analyzed in a non‐gray layer of plastics, submitted to several thermal and radiative boundary conditions. The numerical method is an implicit finite difference procedure with nonuniform space and time increments. Coupling problems for the prescribed temperatures, prescribed radiative–conductive heat exchange laws, and mixed kind thermal boundary conditions are worked out for opaque as well as vitreous interfaces with specular reflections. Solutions are given to demonstrate the effect of different parameters, such as radiation–conduction parameter, radiation–convection parameter, and emissivity of the surfaces on temperature distribution and heat flux profiles across the layer. J. VINYL. ADDIT. TECHNOL., 11:28–37, 2005. © 2005 Society of Plastics Engineers
Journal
Journal of Vinyl & Additive Technology – Wiley
Published: Mar 1, 2005