1 / 23

ERT 216 HEAT & MASS TRANSFER Sem 2/ 2012-2013

ERT 216 HEAT & MASS TRANSFER Sem 2/ 2012-2013. Prepared by; Miss Mismisuraya Meor Ahmad School of Bioprocess Engineering University Malaysia Perlis. HEAT TRANSFER (3) RADIATION. Radiation. Radiation  Energy transfer through a space by electromagnetic radiation.

simon-tyson
Download Presentation

ERT 216 HEAT & MASS TRANSFER Sem 2/ 2012-2013

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. ERT 216HEAT & MASS TRANSFERSem 2/ 2012-2013 Prepared by; Miss Mismisuraya Meor Ahmad School of Bioprocess Engineering University Malaysia Perlis

  2. HEAT TRANSFER(3) RADIATION

  3. Radiation Radiation  Energy transfer through a space by electromagnetic radiation. There are many types of electromagnetic radiation. But we just discuss the electromagnetic radiation that is propagated as a result of a temp. difference. Thermal Radiation (electromagnetic radiation emitted by a body as a result of its temp.)

  4. Physical Mechanism All type of radiation were propagated at the speed of light (C), 3 x 108 m/s This speed of light is equal to the product of wavelength (ʎ) & frequency (v) of the radiation Unit wavelength (ʎ) can be in cm, angstroms (1A = 10 cm) or micrometers (1μm = 10 m) Diagram shown a portion of the electromagnetic spectrum Thermal radiation lies in the range from 0.1 to 100 μm, while visible-light portion of the spectrum is very narrow (0.35 to 0.75 μm)

  5. Physical Mechanism Black Body Radiation Black body absorbs all radiation incident upon it. Called black body radiation because materials appear black to the eye. They appear black because they do not reflect any radiation. “STEFAN-BOLTZMANN LAW” Eb : The emissive power of a blackbody (unit  watt) σ : Stefan-Boltzmann constant T : Absolute Temp.

  6. Total Radiation over all wavelength Total Radiation, Eb = Eb (0 - ∞) =  between zero & infinity wavelength (over all the wavelength)

  7. Radiation emitted between wavelength zero to ʎ1 Radiation emitted between wavelength ʎ1 to ʎ2 Radiation emitted between wavelength ʎ2 to ∞

  8. Radiation energy emitted between wavelength ʎ1 & ʎ2 Eb(ʎ1-ʎ2) Would be calculated using: Where  so that, get from Figure 8.6 or Table 8.1. Used ʎT relation Value of  and

  9. Figure 8.6: Fraction of blackbody radiation in wavelength interval

  10. Incident radiation heat transfer (qin) Incident radiation (qin) can be calculated between two wavelengths ʎ1 & ʎ2 : qin = Area x Eb(ʎ1-ʎ2)

  11. Radiation Properties When radiant energy strikes a material surface, part of the radiation if reflected, part is absorbed and part is transmitted, as shown above. • Reflection radiation (qrefl.)  reflectivity, ρ = qrefl /qin • Absorbed radiation (qabs.)  absorptivity, α = qabs./qin • Transmitted radiation (qtrans.)  transmissivity, ז = qtrans./qin Most solid bodies do not transmit thermal radiation, so that transmissivity may be take as zero (ז=0)

  12. Radiation Properties Incident radiation heat transfer (qin) Example  on glass plate Can break down in to the following radiation classification: Therefore: qrefl. = qin x ρ qabs.= qin x α qtrans.=qin x ז So that, Total incident radiation  where  Kirchhoff’s Identity (emissivities = absorption)  discussed the total properties of the particular material over all wavelengths

  13. Example 8.1 (Transmission & absorption in glass plate) A glass plate 30 cm square is used to view radiation from a furnace. The transmissivity of the glass is 0.5 from 0.2 to 3.5 μm. The emissivity may be assumed to be 0.3 up to 3.5 μm and 0.9 above that. The transmissivity of the glass is zero except in the range from 0.2 to 3.5 μm. Assuming that the furnace is a blackbody at 2000 °C, calculate the energy absorbed in the glass and the energy transmitted.

  14. Solution

  15. Radiation Shape Factor (F12) In order to calculate the net radiant exchange (q rad) between 2 surface  it is necessary to find shape factor (F12) from provided graphs. Then q rad can be calculate using equation: F12: Fraction of energy leaving surface 1 that reaches surface 2 & So that,

  16. Value of F12 Parallel Rectangles F12 obtained from the value of ratio (X/D) Parallel Disks F12 obtained from the value of ratio (d/X) Perpendicular Rectangles F12 obtained from the value of ratio (Z/X)

  17. Example 8.2 (Heat Transfer between Black Surfaces) Two parallel black plates 0.5 by 1.0 m are spaced 0.5 m apart. One plate is maintained at 1000 °C and the orther at 500 °C. What is the net radiant heat exchange between the two plates?

  18. Solution

  19. Heat Exchange between Non Black Bodies The calculation of radiation heat transfer: Black Surface/ Bodies is relatively easy because  all the radiant energy which strikes a surface is absorbed. The main problem to determine geometric shape factor (F12), but once this is accomplished, the calculation heat exchange is very simple using Non Black Body more complex because  for all the energy striking a surface will not be absorbed (part will be reflected back to another heat transfer surface & part may be reflected out of the system entirely). The radiant energy can be also reflected back and forth between the heat transfer surfaces several times.

  20. Heat Exchange between Non Black Bodies So, the net radiation heat exchange between two non black bodies/surfaces: & where  Emissivity, ϵ relates the radiation on the ‘gray surface’

  21. The Radiation Heat Transfer Coefficient Convection  Radiation heat transfer problems are often very closely associated with convection problems, and the total heat transfer by both convection & radiation is often the objective of an analysis , it is worthwhile to put both processes on a common basic by defining a radiation heat transfer coefficient, hr as: Radiation  The total heat transfer (sum of the convection & radiation):

  22. The Radiation Heat Transfer Coefficient In many instances the convection heat transfer coefficient is not strongly dependent on temp. However, this is not so with the radiation heat transfer coefficient. The value of hrcan be calculated from:

More Related