MCL242: Difference between revisions
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| credits = 4 | | credits = 4 | ||
| credit_structure = 3-1-0 | | credit_structure = 3-1-0 | ||
| pre_requisites = MCL140 & APL106 | | pre_requisites = [[MCL140]] & [[APL106]] | ||
| overlaps = CLL251 | | overlaps = [[CLL251]] | ||
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== MCL242 : Heat and Mass Transfer == | == MCL242 : Heat and Mass Transfer == | ||
Modes of heat transfer, energy carriers and continuum approximation. Mechanisms of mass transfer. Unified view of momentum, heat and mass transfer. Conduction: Fourier's law, heat diffusion equation, 1-D steady state conduction in extended surfaces, heat generation, lumped capacitance and 1D transient models, semi-infinite wall. Diffusion mass transfer in 1D: steady state and transient. Convection: Forced and free convection - mass, momentum and energy conservation equations, scaling analysis and significance of non-dimensional numbers, thermal boundary layers, heat transfer in external and internal laminar and turbulent flows, and use of correlations. Convective mass transfer. Boiling and condensation: physical phenomena and correlations. Heat exchanger types and analysis: LMTD and effectiveness-NTU method. Radiation: properties, Laws, view factor, 3-surface network for diffuse- gray surfaces. Gas radiation. | Modes of heat transfer, energy carriers and continuum approximation. Mechanisms of mass transfer. Unified view of momentum, heat and mass transfer. Conduction: Fourier's law, heat diffusion equation, 1-D steady state conduction in extended surfaces, heat generation, lumped capacitance and 1D transient models, semi-infinite wall. Diffusion mass transfer in 1D: steady state and transient. Convection: Forced and free convection - mass, momentum and energy conservation equations, scaling analysis and significance of non-dimensional numbers, thermal boundary layers, heat transfer in external and internal laminar and turbulent flows, and use of correlations. Convective mass transfer. Boiling and condensation: physical phenomena and correlations. Heat exchanger types and analysis: LMTD and effectiveness-NTU method. Radiation: properties, Laws, view factor, 3-surface network for diffuse- gray surfaces. Gas radiation. | ||
Latest revision as of 16:38, 14 April 2026
| MCL242 | |
|---|---|
| Heat and Mass Transfer | |
| Credits | 4 |
| Structure | 3-1-0 |
| Pre-requisites | MCL140 & APL106 |
| Overlaps | CLL251 |
MCL242 : Heat and Mass Transfer
Modes of heat transfer, energy carriers and continuum approximation. Mechanisms of mass transfer. Unified view of momentum, heat and mass transfer. Conduction: Fourier's law, heat diffusion equation, 1-D steady state conduction in extended surfaces, heat generation, lumped capacitance and 1D transient models, semi-infinite wall. Diffusion mass transfer in 1D: steady state and transient. Convection: Forced and free convection - mass, momentum and energy conservation equations, scaling analysis and significance of non-dimensional numbers, thermal boundary layers, heat transfer in external and internal laminar and turbulent flows, and use of correlations. Convective mass transfer. Boiling and condensation: physical phenomena and correlations. Heat exchanger types and analysis: LMTD and effectiveness-NTU method. Radiation: properties, Laws, view factor, 3-surface network for diffuse- gray surfaces. Gas radiation.