* Cantinho Satkeys

Refresh History
  • JP: try65hytr Pessoal  4tj97u<z 2dgh8i k7y8j0 r4v8p xe4s
    Hoje às 04:43
  • cereal killa: try65hytr pessoal,esta calor do karago  r4v8p 43e5r6
    01 de Julho de 2026, 22:01
  • j.s.: try65hytr a todos  49E09B4F
    30 de Junho de 2026, 21:02
  • JP: try65hytr Pessoal  4tj97u<z  2dgh8i k7y8j0 r4v8p
    30 de Junho de 2026, 05:31
  • JP: try65hytr Pessoal  4tj97u<z 2dgh8i k7y8j0 classic
    26 de Junho de 2026, 05:05
  • cereal killa: ghyt74 e continuaçao bom sao joao  wwd46l0'
    24 de Junho de 2026, 12:16
  • JP: try65hytr Pessoal  4tj97u<z 2dgh8i k7y8j0 xe4s
    24 de Junho de 2026, 04:05
  • FELISCUNHA: ghyt74   4tj97u<z e bom São João  h7i37
    23 de Junho de 2026, 10:55
  • j.s.: dgtgtr a todos  49E09B4F
    20 de Junho de 2026, 15:51
  • FELISCUNHA: ghyt74   49E09B4F  e bom fim de semana  4tj97u<z
    20 de Junho de 2026, 11:31
  • JP: try65hytr Pessoal  4tj97u<z 2dgh8i k7y8j0
    19 de Junho de 2026, 04:41
  • romi: Beleza
    19 de Junho de 2026, 04:28
  • cereal killa: try65hytr pessoal  2dgh8i
    18 de Junho de 2026, 23:28
  • JP: dgtgtr Pessoal  2dgh8i k7y8j0 r4v8p
    18 de Junho de 2026, 19:48
  • joaozinho_bosco: boas tardes.......há quanto tempo
    18 de Junho de 2026, 14:35
  • j.s.: dgtgtr a todos  49E09B4F
    16 de Junho de 2026, 18:24
  • JP: try65hytr Pessoal  2dgh8i k7y8j0 classic
    16 de Junho de 2026, 05:44
  • j.s.: bom fim de semana  4tj97u<z
    13 de Junho de 2026, 11:23
  • j.s.: ghyt74 a todos  49E09B4F
    13 de Junho de 2026, 11:23
  • JP: try65hytr A Todos  4tj97u<z 2dgh8i k7y8j0 r4v8p
    12 de Junho de 2026, 05:28

Autor Tópico: Advanced Heat Transfer: Thermal Radiation  (Lida 384 vezes)

0 Membros e 1 Visitante estão a ver este tópico.

Online mitsumi

  • Sub-Administrador
  • ****
  • Mensagens: 133976
  • Karma: +0/-0
Advanced Heat Transfer: Thermal Radiation
« em: 17 de Abril de 2021, 11:35 »
MP4 | Video: h264, 1280x720 | Audio: AAC, 44100 Hz
Language: English | Size: 2.12 GB | Duration: 7h 33m

What you'll learn
Classify electromagnetic radiation, and identify thermal radiation
Understand the idealized blackbody, and calculate the total and spectral blackbody emissive power
Calculate the fraction of radiation emitted in a specified wavelength band using the blackbody radiation functions
Understand the concept of radiation intensity, and define spectral directional quantities using intensity
Develop a clear understanding of the properties emissivity, absorptivity, relflectivity, and transmissivity on spectral, directional, and total basis
Apply Kirchhoff's law to determine the absorptivity of a surface when its emissivity is known
Define view factor, and understand its importance in radiation heat transfer calculations
Develop view factor relations, and calculate the unknown view factors in an enclosure by using these relations
Calculate radiation heat transfer between black surfaces
Determine radiation heat transfer between diffuse and gray surfaces in an enclosure using the concept of radiosity
Quantify the effect of radiation shields on the reduction of radiation heat transfer between two surfaces
Requirements
Fundamentals of Heat Transfer Course
Engineering Thermodynamics Course
Description
We start this course with a discussion of electromagnetic waves and the electromagnetic spectrum, with particular emphasis on thermal radiation. Then we introduce the idealized blackbody, blackbody radiation, and blackbody radiation function, together with the Stefan-Boltzmann law, Planck's law, and Wien's displacement law.

Radiation is emitted by every point on a plane surface in all directions into the hemisphere above the surface. The quantity that describes the magnitude of radiation emitted or incident in a specified direction in space is the radiation intensity. Various radiation fluxes such as emissive power, irradiation, and radiosity are expressed in terms of intensity. This is followed by a discussion of radiative properties of materials such as emissivity, absorptivity, reflectivity, and transmissivity and their dependence on wavelength, direction, and temperature. The greenhouse effect is presented as an example of the consequences of the wavelength dependence of radiation properties.

We then discuss view factors and the rules associated with them. View factor expressions and charts for some common configurations are given, and the crossed-strings method is presented. We then discuss radiation heat transfer, first between black surfaces and then between nonblack surfaces using the radiation network approach. We continue with radiation shields and discuss the its radiation effects.

Who this course is for:
Engineering Students

Screenshots


Download link:
Só visivel para registados e com resposta ao tópico.

Only visible to registered and with a reply to the topic.

Links are Interchangeable - No Password - Single Extraction