University of Mumbai Syllabus For Semester 8 (BE Fourth Year) Advanced Transport Phenomenon: Knowing the Syllabus is very important for the students of Semester 8 (BE Fourth Year). Shaalaa has also provided a list of topics that every student needs to understand.
The University of Mumbai Semester 8 (BE Fourth Year) Advanced Transport Phenomenon syllabus for the academic year 2021-2022 is based on the Board's guidelines. Students should read the Semester 8 (BE Fourth Year) Advanced Transport Phenomenon Syllabus to learn about the subject's subjects and subtopics.
Students will discover the unit names, chapters under each unit, and subtopics under each chapter in the University of Mumbai Semester 8 (BE Fourth Year) Advanced Transport Phenomenon Syllabus pdf 2021-2022. They will also receive a complete practical syllabus for Semester 8 (BE Fourth Year) Advanced Transport Phenomenon in addition to this.
University of Mumbai Semester 8 (BE Fourth Year) Advanced Transport Phenomenon Revised Syllabus
University of Mumbai Semester 8 (BE Fourth Year) Advanced Transport Phenomenon and their Unit wise marks distribution
University of Mumbai Semester 8 (BE Fourth Year) Advanced Transport Phenomenon Course Structure 2021-2022 With Marking Scheme
| # | Unit/Topic | Weightage |
|---|---|---|
| 100 | Differential Equations | |
| 200 | Shell Balance | |
| 300 | Convective Transport | |
| 400 | Simplification of Equation 1 | |
| 500 | Simplification of Equation 2 | |
| 600 | Unsteady State Microscopic Balances with and Without Generation | |
| Total | - |
Syllabus
- Differential equations of heat transfer (Conduction), mass transfer (molecular diffusion) with application like CVD reactors.
- velocity distribution in laminar flow, temperature distribution in solids and laminar flow, concentration distributions in solids and in laminar flow.
- Convective momentum transport in boundary layer.
- Convective heat transport in boundary layer.
- Convective Mass transport in boundary layer.
- Formulation of differential equations for wetted wall column, thin film evaporator (only model formulation, solution not expected).
- Simplification of continuity equation and equation of motion in Cartesian, cylindrical and spherical coordinates for different steady state engineering problems
- e.g. flow through trough, pipes and ducts, conical sections, etc for Newtonian and Power law fluids.
- Simplification of equation of energy with and without viscous dissipation for steady state chemical engineering problems.
- Applications should be limited to Newtonian and Power law fluids.
- Simplification of continuity equation for multicomponent system with applications to chemical engineering problems like absorption, absorption with reaction, adsorption, diffusion, extraction, etc.
- Laminar flow in a tube, conduction with/without heat generation, gas absorption in liquid droplets with/without reaction.
- Solution to partial differential equations developed in earlier modules using various numerical methods like finite element method, Crank-Nicholson method, Laplace equation.
- Emphasis should be given to write the computer programs and analysis of simulated values using SciLab/MATLAB for home/class assignments.
