• Microbalance and an overview of heat conduction and diffusion problems
• To calculate the pressure loss over pipe and pipeline systems
• The definition of convective transport of heat and mass transfer and how you can apply it
• The distribution of components over immiscible phase and the importance of this distribution for many applications
• The difference in flow behaviour of water and toothpaste and the reasons of this difference
• The definitions of heat radiation, black and grey bodies
• How to calculate the heat loss by radiation

Week 1: Microbalances in Transport Phenomena

• A short summary of microbalances in tubular reactors (plug flow), with in parallel the introduction of the ‘microbalance’ for subjects which were not covered in TP101x Transport Phenomena, such as Fourier and Fick's law in different geometries (diffusion through membranes).

Week 2: The momentum balance

• The momentum balance is a new subject and can be combined with mass and energy balance.
• Introduction of the pressure drop by means of a force balance and the definition of the friction factor for tubes, bends and other pipe connections. A link can be made to the mechanical energy balance.

Week 3: Convection: Mass and Heat transport

• Convective transport is much more powerful than diffusion. It is also much more complex and in most cases can only be treated using (dimensionless) correlations for the transfer coefficients.
• Along with convective heat transfer the analogy is introduced with mass transfer.

Week 4: Mass transfer

• Mass transfer between two phases is introduced. Further the partition coefficient between two phases is explained.

Week 5: Laminar flow

• Definition of Newtonian and non-Newtonian fluids and the derivation of the velocity profile between two parallel flat plates and in a tube.

Week 6: Radiation

• Introduction of the radiation; heat transfer (Stefan-Boltzmann).
• Illustration by its relevance in practice (radiation, emission, transparency, “grey” bodies).