Editing Nusselt number

{{Short description|Ratio of a fluid's rates of convective and conductive heat transfer}}
{{Use dmy dates|date=April 2020}}

In [[Thermal fluids|thermal fluid dynamics]], the '''Nusselt number''' ({{math|'''Nu'''}}, after [[Wilhelm Nusselt]]{{r|çengel|p=336}}) is the ratio of total [[heat transfer]] to [[heat conduction|conductive]] heat transfer at a [[boundary (thermodynamic)|boundary]] in a [[fluid]]. Total heat transfer combines conduction and [[convection]]. Convection includes both [[advection]] (fluid motion) and [[diffusion]] (conduction). The conductive component is measured under the same conditions as the convective but for a hypothetically motionless fluid. It is a [[dimensionless number]], closely related to the fluid's [[Rayleigh number]].<ref name="çengel">{{cite book |last1=Çengel |first1=Yunus A. |title=Heat and Mass Transfer |url=https://archive.org/details/HeatAndMassTransferByCengel2ndEdition |date=2002 |publisher=McGraw-Hill |edition=2nd}}</ref>{{rp|466}}

A Nusselt number of order one represents heat transfer by pure conduction.{{r|çengel|p=336}} A value between one and 10 is characteristic of [[slug flow]] or [[laminar flow]].<ref name=whiting>{{cite web |title=The Nusselt Number |url=http://pages.jh.edu/~virtlab/heat/nusselt/nusselt.htm |website=Whiting School of Engineering |access-date=3 April 2019}}</ref> A larger Nusselt number corresponds to more active convection, with [[turbulent flow]] typically in the 100–1000 range.<ref name=whiting/> 

A similar non-dimensional property is the [[Biot number]], which concerns [[thermal conductivity]] for a solid body rather than a fluid. The [[mass transfer]] analogue of the Nusselt number is the [[Sherwood number]].

==Definition==
The Nusselt number is the ratio of total heat transfer (convection + conduction) to conductive heat transfer across a boundary. The convection and conduction heat flows are [[Parallel (geometry)|parallel]] to each other and to the surface normal of the boundary surface, and are all [[perpendicular]] to the [[mean]] fluid flow in the simple case.

:<math>\mathrm{Nu}_L = \frac{\mbox{Total heat transfer }}{\mbox{Conductive heat transfer }} = \frac{h}{k/L} = \frac{hL}{k}</math>

where ''h'' is the [[convective]] [[heat transfer coefficient]] of the flow, ''L'' is the [[characteristic length]], and ''k'' is the [[thermal conductivity]] of the fluid.

* Selection of the characteristic length should be in the direction of growth (or thickness) of the boundary layer; some examples of characteristic length are: the outer diameter of a cylinder in (external) [[cross flow]] (perpendicular to the cylinder axis), the length <!-- height or width? --> of a vertical plate undergoing [[natural convection]], or the diameter of a sphere. For complex shapes, the length may be defined as the volume of the fluid body divided by the surface area.
* The thermal conductivity of the fluid is typically (but not always) evaluated at the [[film temperature]], which for engineering purposes may be calculated as the [[mean]]-average of the bulk fluid temperature and wall surface temperature.

In contrast to the definition given above, known as ''average Nusselt number'', the local Nusselt number is defined by taking the length to be the distance from the surface boundary<ref name="çengel" />{{page needed|date=February 2022}} to the local point of interest.

:<math>\mathrm{Nu}_x = \frac{h_x x}{k}</math>

The ''mean'', or ''average'', number is obtained by integrating the expression over the range of interest, such as:<ref>{{cite journal|title=Transitional natural convection flow and heat transfer in an open channel|year=2012|author=E. Sanvicente|doi=10.1016/j.ijthermalsci.2012.07.004|volume=63|pages=87–104|journal=International Journal of Thermal Sciences|display-authors=etal}}</ref>

:<math>\overline{\mathrm{Nu}}=\frac{\frac{1}{L} \int_0^L h_x\ dx\ L}{k}=\frac{\overline{h} L}{k}</math>

==Context==
An understanding of convection boundary layers is necessary to understand convective heat transfer between a surface and a fluid flowing past it. A thermal boundary layer develops if the fluid free stream temperature and the surface temperatures differ. A temperature profile exists due to the energy exchange resulting from this temperature difference.
[[Image:Thermal Boundary Layer.jpg|400px|thumb|Thermal Boundary Layer]]

The heat transfer rate can be written using [[Newton's law of cooling]] as

:<math>Q_y=hA\left( T_s-T_\infty \right)</math>,

where ''h'' is the [[heat transfer coefficient]] and ''A'' is the heat transfer surface area. Because heat transfer at the surface is by conduction, the same quantity can be expressed in terms of the [[thermal conductivity]] ''k'':

:<math>Q_y=-kA\frac{\partial }{\partial y}\left. \left( T-T_s \right) \right|_{y=0}</math>.

These two terms are equal; thus

:<math>-kA\frac{\partial }{\partial y}\left. \left( T-T_s \right) \right|_{y=0}=hA\left( T_s-T_\infty \right)</math>.

Rearranging,

:<math>\frac{h}{k}=\frac{\left. \frac{\partial \left( T_s-T \right)}{\partial y} \right|_{y=0}}{\left( T_s-T_\infty \right)}</math>.

Multiplying by a representative length ''L'' gives a dimensionless expression:

:<math>\frac{hL}{k}=\frac{\left. \frac{\partial \left( T_s-T \right)}{\partial y} \right|_{y=0}}{\frac{\left( T_s-T_\infty \right)}{L}}</math>.

The right-hand side is now the ratio of the temperature gradient at the surface to the reference temperature gradient, while the left-hand side is similar to the Biot modulus. This becomes the ratio of conductive thermal resistance to the convective thermal resistance of the fluid, otherwise known as the Nusselt number, Nu.

:<math>\mathrm{Nu} = \frac{h}{k/L} = \frac{hL}{k}</math>.

==Derivation==
The Nusselt number may be obtained by a non-dimensional analysis of [[Fourier's law]] since it is equal to the dimensionless temperature gradient at the surface:

:<math>q = -k A \nabla T</math>, where ''q'' is the [[heat transfer rate]], ''k'' is the constant [[thermal conductivity]] and ''T'' the [[fluid]] [[temperature]].
Indeed, if: <math>\nabla' = L \nabla </math> and <math>T' = \frac{T-T_h}{T_h-T_c}</math>

we arrive at

:<math>-\nabla'T' = \frac{L}{kA(T_h-T_c)}q=\frac{hL}{k}</math>

then we define

:<math>\mathrm{Nu}_L=\frac{hL}{k}</math>

so the equation becomes

:<math>\mathrm{Nu}_L=-\nabla'T'</math>

By integrating over the surface of the body:

<math>\overline{\mathrm{Nu}}=-{{1} \over {S'}} \int_{S'}^{} \mathrm{Nu} \, \mathrm{d}S'\!</math>,

where <math>S' = \frac{S}{L^2}</math>.

==Empirical correlations==
Typically, for free convection, the average Nusselt number is expressed as a function of the [[Rayleigh number]] and the [[Prandtl number]], written as:

:<math>\mathrm{Nu} = f(\mathrm{Ra}, \mathrm{Pr})</math>

Otherwise, for forced convection, the Nusselt number is generally a function of the [[Reynolds number]] and the [[Prandtl number]], or

:<math>\mathrm{Nu} = f(\mathrm{Re}, \mathrm{Pr})</math>

[[Wiktionary:empirical|Empirical]] correlations for a wide variety of geometries are available that express the Nusselt number in the aforementioned forms.

=== Free convection ===

====Free convection at a vertical wall====
Cited{{r|incropera|p=493}} as coming from Churchill and Chu:

:<math>\overline{\mathrm{Nu}}_L \ = 0.68 + \frac{0.663\, \mathrm{Ra}_L^{1/4}}{\left[1 + (0.492/\mathrm{Pr})^{9/16} \, \right]^{4/9} \,} \quad \mathrm{Ra}_L \le 10^8 </math>

====Free convection from horizontal plates====
If the characteristic length is defined

:<math>L \ = \frac{A_s}{P}</math>

where <math>\mathrm{A}_s</math> is the surface area of the plate and <math>P</math> is its perimeter.

Then for the top surface of a hot object in a colder environment or bottom surface of a cold object in a hotter environment{{r|incropera|p=493}}

:<math>\overline{\mathrm{Nu}}_L \ = 0.54\, \mathrm{Ra}_L^{1/4} \, \quad 10^4 \le \mathrm{Ra}_L \le 10^7</math>

:<math>\overline{\mathrm{Nu}}_L \ = 0.15\, \mathrm{Ra}_L^{1/3} \, \quad 10^7 \le \mathrm{Ra}_L \le 10^{11}</math>

And for the bottom surface of a hot object in a colder environment or top surface of a cold object in a hotter environment{{r|incropera|p=493}}

:<math>\overline{\mathrm{Nu}}_L \ = 0.52\, \mathrm{Ra}_L^{1/5} \, \quad 10^5 \le \mathrm{Ra}_L \le 10^{10}</math>

====Free convection from enclosure heated from below====
Cited<ref name="bejanauth">{{cite book |author-link=Adrian Bejan |last1=Bejan |first1=Adrian|title=Convection Heat Transfer |url=https://www.researchgate.net/profile/Gamal-Abdelaziz-2/post/How_to_calculate_Nusselt_number_if_an_enclosure_is_heated_from_two_sides_horizontally_and_vertically/attachment/5f511b80ed60840001ca5842/AS%3A931720878649344%401599150976439/download/Adrian+Bejan%28auth.%29-Convection+Heat+Transfer%2C+Fourth+Edition+%282013%29.pdf?_tp=eyJjb250ZXh0Ijp7ImZpcnN0UGFnZSI6InB1YmxpY2F0aW9uIiwicGFnZSI6InF1ZXN0aW9uIn19 |url-access=limited |edition=4th |publisher=Wiley |year=2013 |isbn=978-0-470-90037-6 }}</ref> as coming from Bejan:

:<math>\overline{\mathrm{Nu}}_L \ = 0.069\, \mathrm{Ra}_L^{1/3}Pr^{0.074} \, \quad 3 * 10^5 \le \mathrm{Ra}_L \le 7 * 10^{9}</math>

This equation <i>"holds when the
horizontal layer is sufficiently wide so that the effect of the short vertical sides
is minimal."</i>

It was empirically determined by Globe and Dropkin in 1959:<ref>{{Cite journal |last1=Globe |first1=Samuel |last2=Dropkin |first2=David |date=1959 |title=Natural-Convection Heat Transfer in Liquids Confined by Two Horizontal Plates and Heated From Below |url=https://asmedigitalcollection.asme.org/heattransfer/article-abstract/81/1/24/397579/Natural-Convection-Heat-Transfer-in-Liquids?redirectedFrom=fulltext |journal=Journal of Heat Transfer |volume=81 |issue=1 |pages=24–28 |doi=10.1115/1.4008124 |via=ASME Digital Collection|url-access=subscription }}</ref> <i>"Tests were made in cylindrical containers having copper tops and bottoms and insulating walls."</i> The containers used were around 5" in diameter and 2" high.

===Flat plate in laminar flow===

The local Nusselt number for laminar flow over a flat plate, at a distance <math>x</math> downstream from the edge of the plate, is given by{{r|incropera|p=490}}

:<math>\mathrm{Nu}_x\ = 0.332\, \mathrm{Re}_x^{1/2}\, \mathrm{Pr}^{1/3}, (\mathrm{Pr} > 0.6) </math>

The average Nusselt number for laminar flow over a flat plate, from the edge of the plate to a downstream distance <math>x</math>, is given by{{r|incropera|p=490}}

:<math>\overline{\mathrm{Nu}}_x \ = {2} \cdot 0.332\, \mathrm{Re}_x^{1/2}\, \mathrm{Pr}^{1/3}\ = 0.664\, \mathrm{Re}_x^{1/2}\, \mathrm{Pr}^{1/3}, (\mathrm{Pr} > 0.6) </math>

===Sphere in convective flow===

In some applications, such as the evaporation of spherical liquid droplets in air, the following correlation is used:<ref>{{cite book |last1=McAllister |first1=Sara |last2=Chen |first2=Jyh-Yuan |last3=Fernández Pello |first3=Carlos |title=Fundamentals of combustion processes |date=2011 |publisher=Springer |location=New York |isbn=978-1-4419-7942-1 |page=159 |chapter=Droplet Vaporization in Convective Flow |doi=10.1007/978-1-4419-7943-8 |lccn=2011925371 |series=Mechanical Engineering}}</ref>
:<math>\mathrm{Nu}_D \ = {2} + 0.4\, \mathrm{Re}_D^{1/2}\, \mathrm{Pr}^{1/3}\, </math>

===Forced convection in turbulent pipe flow===

====Gnielinski correlation====
Gnielinski's correlation for turbulent flow in tubes:<ref name="incropera">{{cite book |author-link=Frank P. Incropera |last1=Incropera |first1=Frank P. |last2=DeWitt |first2=David P. |title=Fundamentals of Heat and Mass Transfer |url=https://archive.org/details/fundamentalsheat00incr_617 |url-access=limited |edition=6th |location=Hoboken |publisher=Wiley |year=2007 |isbn=978-0-471-45728-2 }}</ref>{{rp|pp=490,515}}<ref name="Gnielinski1975">{{cite journal |last=Gnielinski |first=Volker |title=Neue Gleichungen für den Wärme- und den Stoffübergang in turbulent durchströmten Rohren und Kanälen |pages=8–16 |year=1975 |journal=Forsch. Ing.-Wes. |volume=41 |issue=1|doi=10.1007/BF02559682 |s2cid=124105274 }}</ref>

:<math>\mathrm{Nu}_D = \frac{ \left( f/8 \right) \left( \mathrm{Re}_D - 1000 \right) \mathrm{Pr} } {1 + 12.7(f/8)^{1/2} \left( \mathrm{Pr}^{2/3} - 1 \right)}</math>

where f is the [[Darcy friction factor]] that can either be obtained from the [[Moody chart]] or for smooth tubes from correlation developed by Petukhov:{{r|incropera|p=490}}

:<math>f= \left( 0.79 \ln \left(\mathrm{Re}_D \right)-1.64 \right)^{-2}</math>

The Gnielinski Correlation is valid for:{{r|incropera|p=490}}

:<math>0.5 \le \mathrm{Pr} \le 2000</math>
:<math>3000 \le \mathrm{Re}_D \le 5 \times 10^{6}</math>

====Dittus–Boelter equation====
The Dittus–Boelter equation (for turbulent flow) as introduced by W.H. McAdams<ref>{{cite journal |last1=Winterton |first1=R.H.S. |title=Where did the Dittus and Boelter equation come from? |journal=International Journal of Heat and Mass Transfer |date=February 1998 |volume=41 |issue=4–5 |pages=809–810 |doi=10.1016/S0017-9310(97)00177-4 |publisher=Elsevier|bibcode=1998IJHMT..41..809W |url=http://herve.lemonnier.sci.free.fr/TPF/NE/Winterton.pdf}}</ref> is an [[explicit function]] for calculating the Nusselt number. It is easy to solve but is less accurate when there is a large temperature difference across the fluid. It is tailored to smooth tubes, so use for rough tubes (most commercial applications) is cautioned. The Dittus–Boelter equation is:

:<math>\mathrm{Nu}_D = 0.023\, \mathrm{Re}_D^{4/5}\, \mathrm{Pr}^{n}</math>

where:
:<math>D</math> is the inside diameter of the circular duct
:<math>\mathrm{Pr}</math> is the [[Prandtl number]]
:<math>n = 0.4</math> for the fluid being heated, and <math>n = 0.3</math> for the fluid being cooled.{{r|incropera|p=493}}

The Dittus–Boelter equation is valid for{{r|incropera|p=514}}
:<math>0.6 \le \mathrm{Pr} \le 160</math>
:<math>\mathrm{Re}_D \gtrsim 10\,000</math>
:<math>\frac{L}{D} \gtrsim 10</math>

The Dittus–Boelter equation is a good approximation where temperature differences between bulk fluid and heat transfer surface are minimal, avoiding equation complexity and iterative solving. Taking water with a bulk fluid average temperature of {{cvt|20|C}}, viscosity {{val|10.07e-4|u=Pa.s}} and a heat transfer surface temperature of {{cvt|40|C}} (viscosity {{val|6.96e-4|u=Pa.s}}, a viscosity correction factor for <math>({\mu} / {\mu_s})</math> can be obtained as 1.45. This increases to 3.57 with a heat transfer surface temperature of {{cvt|100|C}} (viscosity {{val|2.82e-4|u=Pa.s}}), making a significant difference to the Nusselt number and the heat transfer coefficient.

====Sieder–Tate correlation====
The Sieder–Tate correlation for turbulent flow is an [[implicit function]], as it analyzes the system as a nonlinear [[boundary value problem]]. The Sieder–Tate result can be more accurate as it takes into account the change in [[viscosity]] (<math>\mu</math> and <math>\mu_s</math>) due to temperature change between the bulk fluid average temperature and the heat transfer surface temperature, respectively. The Sieder–Tate correlation is normally solved by an iterative process, as the viscosity factor will change as the Nusselt number changes.<ref>{{cite web |url=http://www.profjrwhite.com/math_methods/pdf_files_hw/sgtm3.pdf |title=Temperature Profile in Steam Generator Tube Metal |access-date=23 September 2009 |archive-url=https://web.archive.org/web/20160303224930/http://www.profjrwhite.com/math_methods/pdf_files_hw/sgtm3.pdf |archive-date=3 March 2016 |url-status=dead }}</ref>

:<math>\mathrm{Nu}_D = 0.027\,\mathrm{Re}_D^{4/5}\, \mathrm{Pr}^{1/3}\left(\frac{\mu}{\mu_s}\right)^{0.14}</math>{{r|incropera|p=493}}

where:
:<math>\mu</math> is the fluid viscosity at the bulk fluid temperature
:<math>\mu_s</math> is the fluid viscosity at the heat-transfer boundary surface temperature

The Sieder–Tate correlation is valid for{{r|incropera|p=493}}

:<math>0.7 \le \mathrm{Pr} \le 16\,700</math>
:<math>\mathrm{Re}_D \ge 10\,000</math>
:<math>\frac{L}{D} \gtrsim 10</math>

===Forced convection in fully developed laminar pipe flow===
For fully developed internal laminar flow, the Nusselt numbers tend towards a constant value for long pipes.

For internal flow:

:<math>\mathrm{Nu} = \frac{h D_h}{k_f}</math>

where:

:''D<sub>h</sub>'' = [[Hydraulic diameter]]
:''k<sub>f</sub>'' = [[thermal conductivity]] of the fluid
:''h'' = [[convective]] [[heat transfer coefficient]]

====Convection with uniform temperature for circular tubes====
From Incropera & DeWitt,{{r|incropera|pp=486-487}}

:<math>\mathrm{Nu}_D = 3.66</math>

OEIS sequence {{OEIS link|A282581}} gives this value as <math>\mathrm{Nu}_D = 3.6567934577632923619...</math>.

====Convection with uniform heat flux for circular tubes====
For the case of constant surface heat flux,{{r|incropera|pp=486-487}}

:<math>\mathrm{Nu}_D = 4.36</math>

==See also==
* [[Sherwood number]] (mass transfer Nusselt number)
* [[Churchill–Bernstein equation]]
* [[Biot number]]
* [[Reynolds number]]
* [[Convection (heat transfer)|Convective heat transfer]]
* [[Heat transfer coefficient]]
* [[Thermal conductivity]]

==References==
{{Reflist}}

==External links==
* [http://www.jhu.edu/virtlab/heat/nusselt/nusselt.htm Simple derivation of the Nusselt number from Newton's law of cooling] (Accessed 23 September 2009)

{{NonDimFluMech}}
{{Authority control}}

[[Category:Convection]]
[[Category:Dimensionless numbers of fluid mechanics]]
[[Category:Dimensionless numbers of thermodynamics]]
[[Category:Fluid dynamics]]
[[Category:Heat transfer]]