update notes on heat transfer
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@ -9,12 +9,24 @@ lecture_notes: [ ./lecture_notes/ConvectHeatTrans2022-2023.pdf ]
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exercise_sheets: [ ./exercise_sheets/ExamplesConvectionHeatTransfer.pdf ]
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exercise_sheets: [ ./exercise_sheets/ExamplesConvectionHeatTransfer.pdf ]
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---
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---
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# Errata
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## Grashof Number (formula booklet, lecture slides p. 24, lecture recording 2, 1:19:30)
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The Grashof number formula should be written with $\nu$, not $\mu$,
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It is correctly written in lecture notes (p. 8), [Wikipedia](https://en.wikipedia.org/wiki/Grashof_number),
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and on this page.
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Somehow it is also incorrect in the formula booklet.
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You can check which one is correct by checking which results in a dimensionless Grashof number.
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# Convection
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# Convection
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- conduction and radiation heat transfer can be estimated by calculations and properties
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- conduction and radiation heat transfer can be estimated by calculations and properties
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- convection is dependent on fluid properties, flow type, and flow characteristics
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- convection is dependent on fluid properties, flow type, and flow characteristics
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The rate of convective heat transfer, $\dot Q$, is given by
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The rate of convective heat transfer, $\dot Q$, is given by Newton's law of cooling:
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\begin{equation}
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\begin{equation}
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\dot Q = hA(T_f-T_w)
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\dot Q = hA(T_f-T_w)
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@ -33,3 +45,91 @@ $$\dot Q = \frac{T_f-T_w}{\sum R_\text{thermal}}$$
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where $R_\text{thermal} = \frac{1}{hA}$.
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where $R_\text{thermal} = \frac{1}{hA}$.
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In a way this analogous to Ohm's law, specifically with resistors in series ($I = \frac{\Delta V}{\sum R_\text{electrical}}$).
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In a way this analogous to Ohm's law, specifically with resistors in series ($I = \frac{\Delta V}{\sum R_\text{electrical}}$).
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## Analysis of how Convection Works
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At a hot wall, the velocity of the fluid touching it will be zero.
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Therefore the heat transfer into the fluid must happen by conduction.
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This means that the local heat flux per unit area, $\dot Q''$ (dot for rate, double dash for per
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unit area) is given by:
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$$\dot Q'' = -k \frac{\delta T}{\delta y}|_{\text{wall}}$$
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where $k$ is the conductivity of the wall
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![](./images/convection.png)
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The heated fluid is carried away by convection, therefore at steady state we can say that:
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$$\dot Q'' = -k \frac{\delta T}{\delta y}|_\text{wall} = -h(T_\infty - T_\text{wall})$$
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Rearranging allows $h$ to be found.
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# Nusselt Number - Relation Between Fluid Conductivity and Convection
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Nusselt number is a dimensionless number:
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$$\text{Nu} = \frac{hL}{k_f}$$
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where $k_f$ is conductivity of the fluid, $L$ is the representative length (e.g. diameter, length,
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internal width, etc.).
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Since $h$ is unknown a lot of the time, sometimes Nusselt number must be found through approximating
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by other dimensionless numbers: Prandtl, Reynolds, and Grashof.
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Nusselt number for a laminar forced flow is around 3.66.
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For a turbulent forced flow it is estimated to be:
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$$\text{Nu}_x = 0.023\text{Re}_x^{0.8}\text{Pr}^{0.4}$$
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For a laminar forced flow over a flat plate:
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$$\text{Nu}_x = 0.332\text{Re}_x^{0.5}\text{Pr}^{0.33}$$
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For natural convection of a vertical wall:
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\begin{align*}
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\text{Nu}_x = 0.59(\text{Gr}_x\text{Pr})^{0.25} &\text{ for }10^3 < \text{GrPr} < 10^9 \\
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\text{Nu}_x = 0.13(\text{Gr}_x\text{Pr})^{0.25} &\text{ for }10^9 < \text{GrPr} < 10^{12}
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\end{align*}
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[removing annoying html syntax highlighti]: >
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# Prandtl Number
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This number relates thickness of velocity boundary layer to thickness of thermal boundary layer:
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$$\text{Pr} = \frac{c_p\mu}{k_f} = \frac{\nu}{\alpha}$$
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where $\nu$ is the kinematic viscosity and $\alpha$ is the thermal diffusivity (equations given in
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lecture notes p. 5).
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# Grashof Number
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Grashof number compares the buoyancy of the fluid (due to compressibility, $\beta = T^{-1}$,
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where $T$ is the film temperature, or average temperature between fluid and wall, in kelvin)
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and the viscous resistance to buoyant motion.
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$$\text{Gr} = \frac{g\beta L^3\rho^2\Delta T}{\nu^2}$$
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where $g$ is acceleration due to gravity, $L$ is the height or length of the tube, $\rho$ is density
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of the fluid, $\Delta T = T_\text{wall} - T_\infty$, and $\nu$ is the kinematic viscosity.
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# Axisymmetric Shenanigans
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Axisymmetric shapes are symmetric about an axis.
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$$\dot Q' = -kA\frac{\mathrm dT}{\mathrm dr} = -k2\pi r\frac{\mathrm dT}{\mathrm dr}$$
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Note that the single dash on $\dot Q'$ implies *per unit length*.
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For any length, $L$, $A = 2\pi rL$.
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In this case, the temperature profile is no longer linear, even if $k$ is constant:
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$$R_\text{th} = \frac{\ln r_o - \ln r_i}{2\pi kL}$$
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# Definitions
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- *lagging* - insulation
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