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Tags: heat conduction

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  1. Heat Conduction in a Slab X55T0 and Sub-cases

    05 Mar 2014 | Papers | Contributor(s): Donald E. Amos

    A slab is heated on both faces with known fluxes which are partly dissipated by conduction into the slab, partly lost to the exterior media, and partly stored in a boundary layer with only heat...

    http://nanohub.org/resources/20381

  2. Theory of Heat Conduction with Type 5 Boundary Condition

    19 Feb 2014 | Papers | Contributor(s): Donald E. Amos

    In the classical theory, the general solution of the heat conduction problem is expressed in terms of the Green's function. Terms which take into account volumetric heat generation, an initial...

    http://nanohub.org/resources/20365

  3. Green's Function For Radial Heat Conduction in Two-Region Composite Cylinders With Perfect Boundary Contact

    20 Mar 2013 | Papers | Contributor(s): Donald E. Amos

    This paper presents the derivation of the Green's function for composite cylinders 0<r<a and r>a in perfect contact on the surface r=a. Because the source function can be in either...

    http://nanohub.org/resources/16482

  4. 1-D Green's Functions For Heat Conduction Between Semi-infinite Slabs With Perfect and Imperfect Boundary Contact

    17 Jan 2013 | Papers | Contributor(s): Donald E. Amos

    This document presents two derivations for 1-D Green's functions for semi-infinite slabs in contact along the boundary x=0. The case of imperfect contact with a heat transfer coefficient h is...

    http://nanohub.org/resources/15237

  5. Theory of Heat Conduction for Two Region Problems Using Green's Functions

    03 Apr 2012 | Papers | Contributor(s): Donald E. Amos

    This paper derives equations which describe transient temperature distributions in adjacent regions which share a common boundary. These regions consist of materials with distinct, constant...

    http://nanohub.org/resources/13671

  6. Green's Functions For Heat Conduction in Adjacent Materials

    11 Mar 2012 | Papers | Contributor(s): Donald E. Amos

    This paper considers classical linear, transient heat conduction problems set in Regions 1 and 2 defined by the half planes x>0 and x

    http://nanohub.org/resources/12856

  7. Transient Heat Conduction in Adjacent Quadrants Separated by a Thermal Resistance

    19 Jan 2012 | Papers | Contributor(s): Donald E. Amos, James Vere Beck, Filippo de Monte

    Abstract Two linear, transient heat conduction problems set in quadrants 1 and 2 of the (x,y) plane are solved. In each problem, the quadrants have distinct, constant physical properties and are...

    http://nanohub.org/resources/12465

  8. Carslaw and Jaeger solutions cataloged using the Beck and Litkouhi heat conduction notation

    07 Nov 2011 | Teaching Materials | Contributor(s): James Vere Beck, Greg Walker

    The analytical solutions of Carslaw and Jaeger are cataloged using the Beck and Litkouhi heat conduction notation. This document was contributed by James V. Beck and Elaine P. Scott. Heat...

    http://nanohub.org/resources/12470

  9. Transient Heat Conduction in Adjacent Materials Heated on Part of the Common Boundary

    01 Nov 2011 | Papers | Contributor(s): Donald E. Amos

    This paper considers a classical linear, transient heat conduction problem set in Regions 1 and 2 defined by the half planes x>0 and x

    http://nanohub.org/resources/12390

  10. Donald E. Amos

    http://nanohub.org/members/59706

  11. Analytic conduction solutions

    01 Sep 2011 | Tools | Contributor(s): Greg Walker, James Vere Beck

    High-precision analytic conduction in parallelepipeds using Green's functions

    http://nanohub.org/resources/cond3d

  12. Lecture 9: Introduction to Phonon Transport

    17 Aug 2011 | Online Presentations | Contributor(s): Mark Lundstrom

    This lecture is an introduction to phonon transport. Key similarities and differences between electron and phonon transport are discussed.

    http://nanohub.org/resources/11869

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