--- author: Akbar Rahman date: \today title: MMME2047 // Heat Transfer tags: [ heat_transfer ] uuid: d3ba66c2-e486-464a-a4df-f23f2155ee6d lecture_slides: [ ./lecture_slides/6ConvHeatTransfer-without-written-comments.pptx ] lecture_notes: [ ./lecture_notes/ConvectHeatTrans2022-2023.pdf ] exercise_sheets: [ ./exercise_sheets/ExamplesConvectionHeatTransfer.pdf ] --- # Convection - conduction and radiation heat transfer can be estimated by calculations and properties - convection is dependent on fluid properties, flow type, and flow characteristics The rate of convective heat transfer, $\dot Q$, is given by \begin{equation} \dot Q = hA(T_f-T_w) \label{eqn:convectionheattransfer} \end{equation} where $T_w$ is the wall temperature, $T_f$ is the fluid temperature, $A$ is the area of heat flow, and $h$ is the heat transfer coefficient. ## Thermal Resistance Equation \ref{eqn:convectionheattransfer} can also be expressed in terms of thermal resistance, $R_\text{thermal}$: $$\dot Q = \frac{T_f-T_w}{\sum R_\text{thermal}}$$ where $R_\text{thermal} = \frac{1}{hA}$. In a way this analogous to Ohm's law, specifically with resistors in series ($I = \frac{\Deta V}{\sum R_\text{electrical}}$).