Space-time Fourier transform: Difference between revisions

Revision as of 01:33, 13 April 2013

The Gebhart factors are used in radiative heat transfer, it is a means to describe the ratio of radiation absorbed by any other surface versus the total emitted radiation from given surface. As such, it becomes the radiation exchange factor between a number of surfaces. The Gebhart factors calculation method is supported in several radiation heat transfer tools, such as TMG ^[1] and TRNSYS.

The method was introduced by Benjamin Gebhart in 1957.^[2] Although a requirement is the calculation of the view factors beforehand, it requires less computational power, compared to using ray tracing with the Monte Carlo Method (MCM).^[3] Alternative methods are to look at the radiosity, which Hottel ^[4] and others build upon.

Equations

The Gebhart factor can be given as:

B_{i j} = \frac{Energy absorbed at A_{j} originating as emission at A_{i}}{Total radiation emitted from A_{i}}

.^[4]

The Gebhart factor approach assumes that the surfaces are gray and emits and are illuminated diffusely and uniformly.^[3]

This can be rewritten as:

B_{i j} = \frac{Q_{i j}}{ϵ_{i} \cdot A_{i} \cdot σ \cdot T_{i}^{4}}

where

$B_{i j}$ is the Gebhart factor

$Q_{i j}$ is the heat transfer from surface i to j

$ϵ$ is the emissivity of the surface

$A$ is the surface area

$T$ is the temperature

The denominator can also be recognized from the Stefan–Boltzmann law.

The $B_{i j}$ factor can then be used to calculate the net energy transferred from one surface to all other, for an opaque surface given as:^[2]

$q_{i} = A_{i} \cdot ϵ_{i} \cdot σ \cdot T_{i}^{4} - \sum_{j = 1}^{N_{s}} A_{j} \cdot ϵ_{j} \cdot σ \cdot B_{j i} \cdot T_{j}^{4}$

where

$q_{i}$ is the net heat transfer for surface i

Looking at the geometric relation, it can be seen that:

ϵ_{i} \cdot A_{i} \cdot B_{i j} = ϵ_{j} \cdot A_{j} \cdot B_{j i}

This can be used to write the net energy transfer from one surface to another, here for 1 to 2:

q_{1 - 2} = A_{1} \cdot ϵ_{1} \cdot B_{12} \cdot σ \cdot (T_{1}^{4} - T_{2}^{4})

Realizing that this can be used to find the heat transferred (Q), which was used in the definition, and using the view factors as auxiliary equation, it can be shown that the Gebhart factors are:^[5]

B_{i j} = F_{i j} \cdot ϵ_{j} + \sum_{k = 1}^{N_{s}} ((1 - ϵ_{k}) \cdot F_{i k} \cdot B_{k j})

where

$F_{i j}$ is the view factor for surface i to j

And also, from the definition we see that the sum of the Gebhart factors must be equal to 1.

\sum_{j = 1}^{N_{s}} (B_{i j}) = 1

Several approaches exists to describe this as a system of linear equations that can be solved by Gaussian elimination or similar methods. For simpler cases it can also be formulated as a single expression.

References

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↑ Template:Cite web
↑ ^2.0 ^2.1 B. Gebhart, "Surface temperature calculations in radiant surroundings of arbitrary complexity--for gray, diffuse radiation. International Journal of Heat and Mass Transfer".
↑ ^3.0 ^3.1 Chin, J. H., Panczak, T. D. and Fried, L. (1992), "Spacecraft thermal modeling. International Journal for Numerical Methods in Engineering".
↑ ^4.0 ^4.1 Korybalski, Michael E. Clark, John A. (John Alden), "Algebraic Methods for the Calculation of Radiation Exchange in an Enclosure"
↑ D. E. BORNSIDE, T. A. KINNEY AND R. A. BROWN, "Finite element/Newton method for the analysis of Czochralski crystal growth with diffuse-grey radiative heat transfer . International Journal for Numerical Methods in Engineering".

[1] Template:Cite web

[Gebhart-2] 2.0 ^2.1 B. Gebhart, "Surface temperature calculations in radiant surroundings of arbitrary complexity--for gray, diffuse radiation. International Journal of Heat and Mass Transfer".

[Chin-3] 3.0 ^3.1 Chin, J. H., Panczak, T. D. and Fried, L. (1992), "Spacecraft thermal modeling. International Journal for Numerical Methods in Engineering".

[Korybalski-4] 4.0 ^4.1 Korybalski, Michael E. Clark, John A. (John Alden), "Algebraic Methods for the Calculation of Radiation Exchange in an Enclosure"

[5] D. E. BORNSIDE, T. A. KINNEY AND R. A. BROWN, "Finite element/Newton method for the analysis of Czochralski crystal growth with diffuse-grey radiative heat transfer . International Journal for Numerical Methods in Engineering".

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+The '''''Gebhart factors''''' are used in [[radiative heat transfer]], it is a means to describe the ratio of radiation absorbed by any other surface versus the total emitted radiation from given surface. As such, it becomes the radiation exchange factor between a number of surfaces. The Gebhart factors calculation method is supported in several radiation heat transfer tools, such as TMG <ref>{{cite web
+| url = http://www.apic.com.tw/support/ideas_data/ESCTMG/TrainingData/Tmg/TMG_Radiation.pdf
+| title = Radiation
+| work = SDRC
+| date = 2000-01-01
+| accessdate = 2010-11-26
+| publisher = SDRC/APIC
+}}</ref> and TRNSYS.
+The method was introduced by Benjamin Gebhart in 1957.<ref name="Gebhart">B. Gebhart, "[http://www.sciencedirect.com/science/article/B6V3H-481MR6M-3D/2/45002ab06cfbe37d6ba2dbf9658d8c67 Surface temperature calculations in radiant surroundings of arbitrary complexity--for gray, diffuse radiation. International Journal of Heat and Mass Transfer]".</ref> Although a requirement is the calculation of the [[view factor]]s beforehand, it requires less computational power, compared to using ray tracing with the [[Monte Carlo Method]] (MCM).<ref name="Chin">Chin, J. H., Panczak, T. D. and Fried, L. (1992), "[http://onlinelibrary.wiley.com/doi/10.1002/nme.1620350403/abstract Spacecraft thermal modeling. International Journal for Numerical Methods in Engineering]".</ref> Alternative methods are to look at the [[radiosity (heat transfer)|radiosity]], which Hottel <ref name="Korybalski">Korybalski, Michael E. Clark, John A. (John Alden), "[http://hdl.handle.net/2027.42/46657 Algebraic Methods for the Calculation of Radiation Exchange in an Enclosure]"</ref>  and others build upon.
+== Equations ==
+The Gebhart factor can be given as:
+:<math>B_{ij} = \frac{\mbox{Energy absorbed at }A_{j}\mbox{ originating as emission at } A_{i}}{\mbox{Total radiation emitted from }A_{i}}</math>
+.<ref name="Korybalski" />
+The Gebhart factor approach assumes that the surfaces are gray and emits and are illuminated diffusely and uniformly.<ref name="Chin" />
+This can be rewritten as:
+:<math> B_{ij} = \frac{ Q_{ij}} {\epsilon_{i}  \cdot A_{i}  \cdot \sigma  \cdot T_{i}^{4}}</math>
+where
+* <math>B_{ij}</math> is the Gebhart factor
+* <math>Q_{ij}</math> is the heat transfer from surface i to j
+* <math>\epsilon</math> is the [[emissivity]] of the surface
+* <math>A</math> is the surface area
+* <math>T</math> is the temperature
+The denominator can also be recognized from the [[Stefan–Boltzmann law]].
+The <math>B_{ij}</math>  factor can then be used to calculate the net energy transferred from one surface to all other, for an opaque surface given as:<ref name="Gebhart" />
+<math>q_{i} = A_{i} \cdot \epsilon_i \cdot \sigma \cdot T_{i}^4 - \sum_{j=1}^{N_s} A_{j} \cdot \epsilon_{j} \cdot \sigma \cdot B_{ji} \cdot T_{j}^4  </math>
+where
+* <math>q_{i}</math> is the net heat transfer for surface i
+Looking at the geometric relation, it can be seen that:
+:<math> \epsilon_{i} \cdot  A_{i}  \cdot B_{ij} = \epsilon_{j}  \cdot A_{j}  \cdot B_{ji}</math>
+This can be used to write the net energy transfer from one surface to another, here for 1 to 2:
+:<math>q_{1-2} = A_{1} \cdot  \epsilon_{1}  \cdot B_{12}  \cdot \sigma  \cdot (T_{1}^4-T_{2}^4)</math>
+Realizing that this can be used to find the heat transferred (Q), which was used in the definition, and using the [[view factor]]s as auxiliary equation, it can be shown that the Gebhart factors are:<ref>D. E. BORNSIDE, T. A. KINNEY AND R. A. BROWN, "[http://onlinelibrary.wiley.com/doi/10.1002/nme.1620300109/abstract Finite element/Newton method for the analysis of Czochralski crystal growth with diffuse-grey radiative heat transfer . International Journal for Numerical Methods in Engineering]".</ref>
+:<math>B_{ij} =  F_{ij}  \cdot \epsilon_j  + \sum_{k=1}^{N_s}((1-\epsilon_k) \cdot F_{ik}  \cdot B_{kj})</math>
+where
+* <math>F_{ij}</math> is the view factor for surface i to j
+And also, from the definition we see that the sum of the Gebhart factors must be equal to 1.
+:<math> \sum_{j=1}^{N_s}(B_{ij}) = 1</math>
+Several approaches exists to describe this as a system of linear equations that can be solved by [[Gaussian elimination]] or similar methods. For simpler cases it can also be formulated as a single expression.
+==See also==
+* [[Radiosity (heat transfer)|Radiosity]]
+* [[Thermal radiation]]
+* [[Black body]]
+== References ==
+{{Reflist}}
+[[Category:Heat transfer]]

Space-time Fourier transform: Difference between revisions

Revision as of 01:33, 13 April 2013

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