View factor explained

In radiative heat transfer, a view factor,

F_A

, is the proportion of the radiation which leaves surface

that strikes surface

. In a complex 'scene' there can be any number of different objects, which can be divided in turn into even more surfaces and surface segments.View factors are also sometimes known as configuration factors, form factors, angle factors or shape factors.

Relations

Summation

Radiation leaving a surface within an enclosure is conserved. Because of this, the sum of all view factors from a given surface,

S_i

, within the enclosure is unity as defined by the summation rule

	n
\sum
	j=1

{F
	S_i\rarrS_j

} = 1

where

is the number of surfaces in the enclosure. Any enclosure with

surfaces has a total

n²

view factors.

For example, consider a case where two blobs with surfaces A and B are floating around in a cavity with surface C. All of the radiation that leaves A must either hit B or C, or if A is concave, it could hit A. 100% of the radiation leaving A is divided up among A, B, and C.

Confusion often arises when considering the radiation that arrives at a target surface. In that case, it generally does not make sense to sum view factors as view factor from A and view factor from B (above) are essentially different units. C may see 10% of A 's radiation and 50% of B 's radiation and 20% of C 's radiation, but without knowing how much each radiates, it does not even make sense to say that C receives 80% of the total radiation.

Reciprocity

The reciprocity relation for view factors allows one to calculate

F_i

if one already knows

F_j

and is given as

A_iF_i=A_jF_j

where

A_i

and

A_j

are the areas of the two surfaces.

Self-viewing

For a convex surface, no radiation can leave the surface and then hit it later, because radiation travels in straight lines. Hence, for convex surfaces,

F_i=0.

For concave surfaces, this doesn't apply, and so for concave surfaces

F_i>0.

Superposition

The superposition rule (or summation rule) is useful when a certain geometry is not available with given charts or graphs. The superposition rule allows us to express the geometry that is being sought using the sum or difference of geometries that are known.

F₁=F₁+F_1\rarr.

^[1]

View factors of differential areas

Taking the limit of a small flat surface gives differential areas, the view factor of two differential areas of areas

\hbox{d}A₁

and

\hbox{d}A₂

at a distance s is given by:

dF₁=

	\cos\theta₁\cos\theta₂
	\pis²

\hbox{d}A₂

where

\theta₁

and

\theta₂

are the angle between the surface normals and a ray between the two differential areas.

The view factor from a general surface

A₁

to another general surface

A₂

is given by:^[2]

F₁=

	1
	A₁

\int
	A₁

\int
	A₂

	\cos\theta₁\cos\theta₂
	\pis²

\hbox{d}A₂\hbox{d}A_1.

Similarly the view factor

F_{2 →}

is defined as the fraction of radiation that leaves

A₂

and is intercepted by

A₁

, yielding the equation

F_ = \frac \int_ \int_ \frac\, \hboxA_2\, \hboxA_1.

The view factor is related to the etendue.

Example solutions

For complex geometries, the view factor integral equation defined above can be cumbersome to solve. Solutions are often referenced from a table of theoretical geometries. Common solutions are included in the following table:

Table 1: View factors for common geometries!Geometry!Relation
Parallel plates of widths, w_i,w_j with midlines connected by perpendicular of length L	$F_=\frac$ where $W_i=w_i/L,W_j=w_j/L$
Inclined parallel plates at angle, \alpha , of equal width, w , and a common edge	$F_=1-sin(\frac)$
Perpendicular plates of widths, w_i,w_j with a common edge	$F_=\frac$
Three sided enclosure of widths, w_i,w_j,w_k	$F_=\frac$

Nusselt analog

A geometrical picture that can aid intuition about the view factor was developed by Wilhelm Nusselt, and is called the Nusselt analog. The view factor between a differential element dA_i and the element A_j can be obtained projecting the element A_j onto the surface of a unit hemisphere, and then projecting that in turn onto a unit circle around the point of interest in the plane of A_i.The view factor is then equal to the differential area dA_i times the proportion of the unit circle covered by this projection.

The projection onto the hemisphere, giving the solid angle subtended by A_j, takes care of the factors cos(θ₂) and 1/r²; the projection onto the circle and the division by its area then takes care of the local factor cos(θ₁) and the normalisation by π.

The Nusselt analog has on occasion been used to actually measure form factors for complicated surfaces, by photographing them through a suitable fish-eye lens.^[3] (see also Hemispherical photography). But its main value now is essentially in building intuition.

External links

A large number of 'standard' view factors can be calculated with the use of tables that are commonly provided in heat transfer textbooks.

List of view factors for specific geometry cases
View3D, a computer program (FOSS) for calculating view factors in 2D and 3D.

Notes and References

Heat and Mass Transfer, Yunus A. Cengel and Afshin J. Ghajar, 4th Edition
Book: Principles of heat and mass transfer . 2013 . Wiley . 978-0-470-50197-9 . Incropera . Frank P. . 7. ed., international student version . Hoboken, NJ . DeWitt . David P. . Bergman . Theodore L. . Lavine . Adrienne S..
Michael F. Cohen, John R. Wallace (1993), Radiosity and realistic image synthesis. Morgan Kaufmann,, p. 80

View factor explained

Relations

Summation

Reciprocity

Self-viewing

Superposition

View factors of differential areas

Example solutions

Nusselt analog

See also

External links

Notes and References