Modelling of trans-esterification of waste cooking oil in a batch stirred tank reactor /

To model the transesterification of waste cooking oil (WCO), the physio-chemical details has been obtained by transesterification of waste cooking oil in a 1-Litre stirred tank reactor (STR) and 2-D Particle Image Velocimetry (PIV) technique. For this study, the L9 Taguchi orthogonal array (OA) desi...

Full description

Saved in:
Bibliographic Details
Main Author: Adeyemi, Nabeel Adedapo
Format: Thesis
Language:English
Published: Kuala Lumpur: Kulliyyah of Engineering, International Islamic University Malaysia, 2013
Subjects:
Online Access:http://studentrepo.iium.edu.my/handle/123456789/5001
Tags: Add Tag
No Tags, Be the first to tag this record!
LEADER 042790000a22002770004500
008 130719t2013 my a g m 000 0 eng d
040 |a UIAM  |b eng 
041 |a eng 
043 |a a-my--- 
050 0 0 |a TP359.B46 
100 1 |a Adeyemi, Nabeel Adedapo 
245 1 |a Modelling of trans-esterification of waste cooking oil in a batch stirred tank reactor /  |c by Nabeel Adedapo Adeyemi 
260 |a Kuala Lumpur:   |b Kulliyyah of Engineering, International Islamic University Malaysia,   |c 2013 
300 |a xxii, 170 leaves :  |b ill. ;  |c 30cm. 
502 |a Thesis (Ph.D)--International Islamic University Malaysia, 2013. 
504 |a Includes bibliographical references (leaves 146-155). 
520 |a To model the transesterification of waste cooking oil (WCO), the physio-chemical details has been obtained by transesterification of waste cooking oil in a 1-Litre stirred tank reactor (STR) and 2-D Particle Image Velocimetry (PIV) technique. For this study, the L9 Taguchi orthogonal array (OA) design was used to determine the effect of temperature, impeller speed and impeller bottom distance (IBC) on the fatty acid methyl ester (FAME) yield. Single step transesterification with NaOH catalysis was carried out on waste cooking oil (WCO) between 60-70° C due to the low level of FFA. Under the experimental conditions, optimum FAME yield was obtained at 60° C and 70° C, 700 rpm and 25 mm IBC between 5-15 min for 6-blade radial impeller (unbaffled) and 60° C, 700 rpm and 20 mm IBC in 10 min for mixed flow impeller (baffled) in the 1-L STR. The peak yield time, which had not been considered in previous studies, is detailed here. An exponential expression was established to derive FAME yield resulting from a 2nd-order rate model. The work also showed a novel technique based on absorbance spectra and analogue signal to monitor reaction time. The local dissipation rate, mean velocities and turbulent kinetic energy (TKE) in the impeller region of the radial and mixed flow impellers were evaluated via 2-D PIV technique. Large eddy simulation (LES) analogy used to estimate dissipation rate showed even dissipation regime (30 times more than the computed mean dissipation rate in the tank) for mixed flow impeller. Comparison of the PIV data with three turbulent flow models (kappa-epsilon (к-ε), shear stress transport (sst) kappa-omega (к-ω) and Reynold's stress model (RSM)) was carried out at impeller speed between 600 – 700 rpm. The RSM agreed with PIV results while comparing mean, radial and axial velocity, kinetic energy and energy dissipation against the к-ε and sst (к-ω) models at positions below the impeller for the mixed flow impeller. The knowledge of the suitability of the RSM to simulate flow using the mixed-flow impeller is extended here. Subsequently, the transesterification was simulated based on the eddy dissipation model (EDM) incorporating reaction parameters. Mean energy from PIV was used to provide the dissipation/turbulent ratio in the EDM. Based upon a eulerian-eulerian framework, a gradient method was used to obtain FAME yield defined in ANSYS Fluent by special user defined functions (UDF), assuming non-homogenous, statistically isotropic turbulence. The model was able to simulate the reaction for unbaffled 1 and 2-L STR, where the yield was 18 and 23% lesser to experimental result respectively. The model gives a fair comparison of numerical and experimental yields and extends the tools available from modelling transesterification of oil. Taking cognizance of the result, further validation of the developed UDF for large scale tank is suggested to improve the model. 
596 |a 1 
655 7 |a Theses, IIUM local 
690 |a Dissertations, Academic  |x Kulliyyah of Engineering  |z IIUM 
710 2 |a International Islamic University Malaysia.  |b Kulliyyah of Engineering 
856 4 |u http://studentrepo.iium.edu.my/handle/123456789/5001 
900 |a hab-ls 
999 |c 437884  |d 468146 
952 |0 0  |6 T TP 000359 B46 A233M 2013  |7 0  |8 THESES  |9 759033  |a IIUM  |b IIUM  |c MULTIMEDIA  |g 0.00  |o t TP 359 B46 A233M 2013  |p 00011289013  |r 2017-10-20  |t 1  |v 0.00  |y THESIS 
952 |0 0  |6 TS CDF TP 359 B46 A233M 2013  |7 0  |8 THESES  |9 851117  |a IIUM  |b IIUM  |c MULTIMEDIA  |g 0.00  |o ts cdf TP 359 B46 A233M 2013  |p 00011289014  |r 2017-10-26  |t 1  |v 0.00  |y THESISDIG