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Heat and mass transfer are processes modelled by similar mathematical equations in the case of diffusion and convection. Through this [course_title], you will understand the balance between convection and diffusion that determines the total transport rates in chemical processes, as well as gives rise to many of the empirical correlations used in chemical engineering construction. Moreover, learn about the three fundamental modes of heat transfer that deals with the movement of heat and temperature grades.
Assessment
This course does not involve any written exams. Students need to answer 5 assignment questions to complete the course, the answers will be in the form of written work in pdf or word. Students can write the answers in their own time. Each answer needs to be 200 words (1 Page). Once the answers are submitted, the tutor will check and assess the work.
Certification
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Course Credit: NPTEL
Course Curriculum
Why do we study transport processes? | 00:30:00 | ||
Transport by convection and diffusion. | 00:31:00 | ||
Dimensional analysis Completed | 00:28:00 | ||
Dimensional analysis: Force on a particle settling in a fluid. | 00:29:00 | ||
Dimensional analysis: Heat transfer in a heat exchanger | 00:30:00 | ||
Dimensional analysis: Mass transfer from a particle suspended in a fluid Completed | 00:31:00 | ||
Dimensional analysis: Power of an impeller | 00:28:00 | ||
Dimensional analysis: Scaling up of an impeller | 00:28:00 | ||
Dimensional analysis: Convection and diffusion | 00:28:00 | ||
Dimensional analysis: Physical interpretation of dimensionless groups Completed | 00:29:00 | ||
Dimensional analysis: Correlations for dimensionless groups | 00:33:00 | ||
Dimensional analysis: Natural and forced convection | 00:30:00 | ||
Continuum description of fluids | 00:34:00 | ||
Conservation equations and constitutive relations | 00:29:00 | ||
Diffusion: Mechanism of mass diffusion in gases | 00:31:00 | ||
Diffusion: Estimation of mass diffusion coefficient | 00:30:00 | ||
Diffusion: Momentum diffusion coefficient Completed | 00:32:00 | ||
Diffusion: Thermal diffusion coefficient | 00:31:00 | ||
Unidirectional transport: Conservation equation for heat & mass transfer | 00:28:00 | ||
Unidirectional transport: Conservation equation for momentum transfer | 00:31:00 | ||
Unidirectional transport: Similarity solution for infinite domain | 00:30:00 | ||
Unidirectional transport: Similarity solution for infinite domain continued Completed | 00:30:00 | ||
Unidirectional transport: Similarity solution for mass transfer into a falling film | 00:38:00 | ||
Unidirectional transport: Similarity solution for decay of a pulse | 00:32:00 | ||
Similarity solution for decay of a pulse (continued) | 00:32:00 | ||
Unidirectional transport: Separation of variables for transport in a finite domain | 00:27:00 | ||
Unidirectional transport: Separation of variables for transport in a finite domain (continued) | 00:29:00 | ||
Unidirectional transport: Separation of variables for transport in a finite domain (continued) | 00:28:00 | ||
Unidirectional transport: Separation of variables for transport in a finite domain (continued) | 00:36:00 | ||
Balance laws in cylindrical co-ordinates. Heat transfer across wall of a pipe Completed | 00:31:00 | ||
Balance laws in cylindrical co-ordinates. Unsteady heat conduction from a cylinder Completed | 00:30:00 | ||
Balance laws in cyclindrical co-ordinates. Unsteady heat conduction from a cylinder (continued) | 00:31:00 | ||
Balance laws in cylindrical co-ordinates. Unsteady heat conduction from a cylinder | 00:30:00 | ||
Balance laws in cylindrical co-ordinates. Similarity solution for heat conduction from a wire | 00:34:00 | ||
Effect of body force in momentum transfer. Falling film | 00:33:00 | ||
Unidirectional transport: Effect of pressure in momentum transfer. Flow in a pipe | 00:33:00 | ||
Unidirectional transport: Friction factor for flow in a pipe | 00:29:00 | ||
Unidirectional transport: Laminar and turbulent flow in a pipe Completed | 00:36:00 | ||
Unidirectional transport: Laminar and turbulent flow in a pipe (continued) | 00:30:00 | ||
Unidirectional transport: Oscillatory flow in a pipe. Solution using complex variables | 00:27:00 | ||
Unidirectional transport: Oscillatory flow in a pipe. Solution using complex variables (continued) | 00:29:00 | ||
Oscillatory flow in a pipe. Solution using complex variables (continued) Completed | 00:30:00 | ||
Oscillatory flow in a pipe. Low and high Reynold’s number solutions. Completed | 00:34:00 | ||
Unidirectional transport: Spherical co-ordinates. Heat conduction from a sphere. | 00:31:00 | ||
Mass and energy balance equations in Cartesian co-ordinates | 00:31:00 | ||
Mass and energy balance equations in Cartesian co-ordinates. Vector notation Completed | 00:33:00 | ||
Mass and energy balance equations in spherical co-ordinates Completed | 00:35:00 | ||
kumaran lec48 | 00:28:00 | ||
Momentum balance: Incompressible Navier- Stokes equations | 00:35:00 | ||
Balance equation: Convection and diffusion dominated regimes | 00:30:00 | ||
Diffusion equation: Heat conduction in a rectangular solid | 00:32:00 | ||
Diffusion equation: Heat conduction in a rectangular solid (continued) | 00:33:00 | ||
Diffusion equation: Heat conduction around a spherical inclusion | 00:31:00 | ||
Diffusion equation: Heat conduction around a spherical inclusion Completed | 00:30:00 | ||
Diffusion equation: Effective conductivity of a composite Completed | 00:33:00 | ||
Diffusion equation: Spherical harmonic solutions | 00:31:00 | ||
Diffusion equation: Conduction from a point source. | 00:33:00 | ||
Diffusion equation: Method of Greens functions. | 00:32:00 | ||
Diffusion equation: Method of images Completed | 00:29:00 | ||
Diffusion equation: Equivalence of spherical harmonics and multipole expansio | 00:29:00 | ||
Assessment | |||
Submit Your Assignment | 00:00:00 | ||
Certification | 00:00:00 |
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