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CE20091: Reaction engineering

Follow this link for further information on academic years Academic Year: 2015/6
Further information on owning departmentsOwning Department/School: Department of Chemical Engineering
Further information on credits Credits: 6
Further information on unit levels Level: Intermediate (FHEQ level 5)
Further information on teaching periods Period: Semester 1
Further information on unit assessment Assessment Summary: EX 100%
Further information on unit assessment Assessment Detail:
  • Examination (EX 100%)
Further information on supplementary assessment Supplementary Assessment: Like-for-like reassessment (where allowed by programme regulations)
Further information on requisites Requisites:
Further information on descriptions Description: Aims:
To provide students with the ability to produce engineering designs of ideal reactors where the rate of reaction is controlled by chemical and biochemical reaction kinetics.

Learning Outcomes:
After successfully completing this unit students should be able to:
* complete problems on heterogeneous catalytic reactors if they are supplied with global rate data;
* understand the essential features that control microorganism growth and design fermenters for batch and continuous cultivation to apply a reaction engineering analysis to the controlled growth of microorganisms in biological reactors;
* to use global or homogenous kinetic expressions to formulate material and energy balances for batch CSTR and plug flow reactors that exhibit ideal behaviour with reversible and multiple reaction steps.

Skills:
Analysis and problem solving (taught/facilitated and assessed).

Content:
Basic reactor designs: batch, CSTR, plug flow; application of stoichiometric tables; chemical equilibrium; definition of reaction rate, elementary reactions and temperature dependence; mass and energy balances developed for ideal batch, CSTR, plug flow reactors; ideal batch reactor: constant volume, variable volumes, variable temperature and pressure; expansion factor, irreversible and reversible reactions; performance comparison between batch, CSTR, plug flow; optimisation: multiple reaction; parallel, series, series-parallel, selectivity and yield, optimum temperature, isothermal, adiabatic and non-adiabatic modes of operation, multiple reactions temperature effects; introduction to biochemical techniques and their potential for transfer to large scale; microorganism growth kinetics and kinetics of product formation; the effects of environmental variables such as pH and temperature on performance.
Further information on programme availabilityProgramme availability:

CE20091 is Compulsory on the following programmes:

Department of Chemical Engineering
  • UECE-AFM01 : MEng(Hons) Biochemical Engineering (Year 2)
  • UECE-AKM01 : MEng(Hons) Biochemical Engineering with Year long work placement (Year 2)
  • UECE-AFB05 : BEng(Hons) Chemical Engineering (Year 2)
  • UECE-AKB05 : BEng(Hons) Chemical Engineering with Year long work placement (Year 2)
  • UECE-AFM05 : MEng(Hons) Chemical Engineering (Year 2)
  • UECE-AKM05 : MEng(Hons) Chemical Engineering with Year long work placement (Year 2)

Notes:
* This unit catalogue is applicable for the 2015/16 academic year only. Students continuing their studies into 2016/17 and beyond should not assume that this unit will be available in future years in the format displayed here for 2015/16.
* Programmes and units are subject to change at any time, in accordance with normal University procedures.
* Availability of units will be subject to constraints such as staff availability, minimum and maximum group sizes, and timetabling factors as well as a student's ability to meet any pre-requisite rules.