Ethanol purification using membrane technology
The rapid depletion of non-renewable energy such as fossil fuels has prompted the search for alternative cleaner energy resources in order to meet the world’s rising energy demand and reduce greenhouse gas emissions. Bioethanol has been actively studied in recent years as one of the potential...
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| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2022
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| Online Access: | https://hdl.handle.net/10356/155120 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The rapid depletion of non-renewable energy such as fossil fuels has prompted the search for
alternative cleaner energy resources in order to meet the world’s rising energy demand and
reduce greenhouse gas emissions. Bioethanol has been actively studied in recent years as one
of the potential substitutes for fossil fuels. It can be derived from plants through fermentation.
To date, conventional distillation is the most practiced technology for ethanol purification due
to its high energy efficiency at moderate ethanol concentration. However, it becomes
significantly more energy intensive as ethanol concentration falls below 5 wt%. Membrane
processes are generally considered to be more selective and less energy intensive owing to their
high surface area available for mass and heat transfer. Therefore, by developing a low energy
membrane process that can potentially replace distillation for ethanol pre-concentration, energy
consumption can be reduced significantly.
The first part of this thesis focused on developing a low-energy purification process for ethanol
extraction from dilute aqueous solution (2 wt% ethanol in water) by integrating supported ionic
liquid membrane (SILM) with perstraction. Preliminary screening tests were performed for the
selection of a suitable ionic liquid (IL) and membrane support from three
trihexyl(tetradecyl)phosphonium ionic liquids (THTDP) ILs and three commercial polymeric
flat-sheet membranes. The optimized combination of solvent and membrane was assessed in a
perstraction system. At a feed concentration of 2 wt% ethanol, the selected SILM was able to
maintain its functionality for ~240 hours without observable phase intermixing. Despite being
subjected to constant lateral shear on the aqueous side, the SILM retained its integrity by
maintaining a high ethanol flux of > 2.2 kg/m2 h and selectivity of > 320. Subsequently, the
extracted ethanol was recovered from IL by single-stage vacuum-distillation with a final purity
of 80% and an overall selectivity of 200.
In the second part, two membrane distillation (MD) processes were designed. They include airgap
membrane distillation (AGMD) and vacuum membrane distillation (VMD). Parameters
including feed temperature, vacuum pressure and feed concentration were varied. Commercial
PTFE membranes and in-house modified FAS-coated ceramic membranes were employed. No
flux was obtained for all parameters applied in both MD systems due to extensive wetting of
the PTFE membranes and ceramic membranes by the IL. Characterization results suggest that
the amphiphilic nature of IL results in some chemical affinity with the hydrophobic fluoroalkyl
groups in PTFE and FAS coating, which may be the cause of wetting.
In the last part, an online detection tool called ultrasonic time-domain reflectometry (UTDR)
was employed to study the wetting dynamics of PTFE membranes by THTDP IL. By
combining UTDR with offline characterization methods such as contact angle, liquid entry
pressure, Fourier-transform infrared spectroscopy and field emission scanning electron
microscopy, wetting behavior of the microporous membranes was quantitatively and
qualitatively analyzed. |
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