The students should develop an understanding of and competence in the formulation and solution of material and energy balance problems in engineering; develop competence in using basic flowsheet analysis and appropriate computational tools; improve their group work and problem solving skills; gain an ability to extract a simplified version of a problem from a complex situation. Students will also develop a preliminary understanding in the use of process simulator (e. g. , Hysis) to formulate and solve material and energy problems around simple models of unit operations and recycles. Mass conservation related topics include: unit systems and unit conversions; properties of solids, fluids and gases; mass balance calculations on batch and flow systems; balances on multiple units processes, balances on reactive systems, recycle, bypass and purge calculations; equilibrium compositions of reacting systems; vapour pressure and humidity. Energy conservation includes the following topics: apply the first law of thermodynamics to flow and batch systems in process industries; understand thermodynamic properties such as internal energy, enthalpy and heat capacity; conduct energy balances for sensible heat changes, phase transformations and reactive processes for practical industrial systems; understand the applications of psychrometry, refrigeration, heat of formation and combustion in industry.
Unit details and rules
| Academic unit | Chemical and Biomolecular Engineering |
|---|---|
| Credit points | 6 |
| Prerequisites
?
|
None |
| Corequisites
?
|
None |
|
Prohibitions
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|
CHNG1103 OR CHNG5707 |
| Assumed knowledge
?
|
University level mathematics, calculus, linear algebra and statistics |
| Available to study abroad and exchange students | No |
Teaching staff
| Coordinator | Alejandro Montoya, alejandro.montoya@sydney.edu.au |
|---|---|
| Lecturer(s) | Raffaella Mammucari, raffaella.mammucari@sydney.edu.au |
