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12.5.20112011-23411Jung Ho Ahn
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Contents
• Introduction• Objective• Experimental procedure• Result• Conclusion
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IntroductionABE fermentation• Acetone-butanol-ethanol fermentation• Produce feed stock chemicals & liquid fuels from
renewable biomass• Product inhibition is a severe problem for
bioconversion– Low concentration of fermentative product (< 5 wt%)– Cost intensive (product sep, downstream processing,
waste water treatment)
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IntroductionButanol• Main product of ABE fermentation• Primary inhibitory product affecting the
bioconversion• Less volatile than water
– Distillation unfavorable
• Butanol concentration <5 %– Energy consumption for butanol purification exceed
energy content of butanol recovered
• More efficient butanol recovery process required
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• Based on selective permeation of ABE components through a membrane in preference to water
• Advantage– Coupling with fermentation
• Inhibitory products from fermentation broth removed continuously as soon as they are formed (productivity )
– Only membrane permeated components undergo liquid-vapor phase change
• Economical than distillation– No external mass separating agent involved
• No harmful effect on the microorganisms in the fermentation broth– Non-porous membrane
• Fermentation medium can be retained by the membrane without clogging the pores of asymmetric membranes
• Disadvantage– Very few organophilic membranes available for this application
IntroductionWhy pervaporation?
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IntroductionMembrane material
• Polydimethylsiloxane (PDMS) most widely used
• Poly ether block amide (PEBA) 2533 used in this study– 80 wt% organophilic
poly(tetramethylene glycol) soft segments + 20 wt% nylon 12 hard segments
– High affinity to butanol• Butanol dissolves PEBA at
elevated temperatures
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Objective
• Explore the applicability utilizing PEBA 2533 membranes for the separation of ABE from dilute aqueous solution pertinent to ABE removal from fermentation broths
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Experimental Procedure
1. Evaluation of permselectivity from separation of binary mixtures by membrane
2. Study effect of feed composition, operating temperature, membrane thickness on membrane performance
3. Study of quaternary ethanol-butanol-acetone-water mixture separation
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ResultEffect of feed concentration• Pervaporative
enrichment of ABE solvents from respective aqueous solutions through PEBA 2533 membrane investigated
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ResultEffect of feed concentration
• Result showed preferential sorption
• PEBA 2533 dissolves only in butanol at elevated temperature– Indication of strong affinity
• Unlike ethanol and acetone butanol is partially miscible to water– Forces that retain butanol molecules
in water weak• Membrane permeability
– Butanol > Acetone > Ethanol
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ResultEffect of feed concentration
• High solubility plasticize membrane• Swelling effect
• Selectivity high at low feed organic concentrations
• Selectivity higher after phase separation
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ResultEffect of temperature
• Water permeation rate large at high temperature
• Magnitude of temperature dependence of water flux affected by organic compound present in feed– Butanol > Ethanol > Acetone
• Partial flux of organic compounds follow different trend
• Molecular size of ethanol and acetone relatively small– Diffusion through membrane easy– Increase in vapor pressure
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ResultEffect of temperature
• Increase in temperature will help retain more butanol molecule in water– Decrease in repulsive force between butanol and water molecule
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ResultEffect of membrane thickness
• Thinner membrane desired– Higher permeation flux– Concentration polarization in boundary
layer• Boundary layer effect most significant for
butanol-water separation• Permeation flux and membrane selectivity
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ResultEffect of membrane thickness
• Concentration polarization influenced by permeation flux and membrane selectivity
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ResultPervaporation of quaternary aqueous ABE mixtures
• Data consistent with those obtained from binary mixtures separation, and the membrane selectivity still follow Butanol > Acetone > Ethanol
• Coupling effects among permeating species in the system
– Permeant-permeant interaction– Permeant-membrane interaction
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Conclusion
• PEBA membrane can be used to extract butanol
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Electrodialysis as a useful technique for lactic acid separation
from a model solution and a fermentation broth
2011-21120라승환
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Introduction
Lactic acid
- food industry, beverage production, pharmaceutical industry chemical industry, medicine
- fermentation method : calcium lactate lactic acid
Electrodialysis
BPM : bipolar membrane
AEM : anion exchange membrane
CEM : cation exchange membrane
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Previous study
Lactic acid fermentation (Boyaval) - total cell recycling, ultrafiltration, electrodialysis : 85 g/L
Lactic acid fermentation (Yao) - similar system, H2SO4 (donor of proton) : 90 g/L
Two-stage electrodialysis (Lee) - (first) lactate:115g/L, current efficiency: 90%, - (second) converted lactic acid : 88-93 %, current efficiency: 80% - total energy consumption : 0.78-0.97 kWh/kg
Electrodialysis with double exchange (Heriban) - lactic acid (model solution) : 236.8g/L, energy consumption : 1.3-2.3 kWh/kg
Two- & three- compartment electrodialysis with bipolar membrane (Kim) - high volumetric productivity : 71.7 g/L.h
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Methods
Lactic acid fermentation
Pretreatment
- Ultrafiltration (remove the cells)
- Decolourisation (decrease electrodialysis efficiency : dye fixing on the membrane)
- Removal of multivalent metal ions (irreversible damage to the electrodialysis membrane: bipolar)
Desalting electrodialysis
Electrodialysis with bipolar membranes
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Results
Desalting electrodialysis
- determination of the limiting current
Maximum : 8.8 mA/cm2
Current density : 7.8 mA/cm2
Constant voltage : 18 V
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Results
Desalting electrodialysis (Model sodium lactate solution)
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Results
Desalting electrodialysis (fermentation broth)
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Results
Desalting electrodialysis
(Model sodium lactate solution) (Fermentation broth)
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Results
- current density lactate transport
- concentrate & diluate volume (water passage)
- other component (glucose: no effect, salt: current efficiency)
- lower initial lactate con. transport rate
Desalting electrodialysis
Two-level electrodialysis
- initial lactate con. : 36.6 g/L
- final con. : 146 g/L (4-times higher)
- current efficiency : 64%, Energy consumption : 0.34 kWh/kg
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Results
Electrodialysis with bipolar membranes (Sodium lactate lactic acid)
Current density : 67.6 mA/cm2
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Results
Electrodialysis with bipolar membranes (Sodium lactate lactic acid)
(Model sodium lactate solution)
Final lactic acid conc. : 29.7-156.8 g/LConversion : 85-98 %Energy consumption : 1.1 kWh/kgFinal base conc. : 0.35-1.45 mol/LCurrent efficiency : 70-80 %
(Fermentation broth)
Final lactic acid conc. : 121-151 g/LConversion : 92-95 %Energy consumption : 1 kWh/kgFinal base conc. : 1.07-1.32 mol/LCurrent efficiency : 70-80 %
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Conclusions
Two-stage electrodialysis is a suitable and efficient technique
First ED step final lactate conc. : 175 g/L
Second ED step final lactic acid conc. : 151 g/L
Total required energy : 1.5 kWh/1kg
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2011-23405 Minsoo Kim
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§ Introduction
£ Fermentation of concentrated sugar solution
1. Benefits
① High ethanol concentration broth → Decrease of purification costs
② Less water carried through the system → Reduce equipment size
→ Low capital cost
③ Reduced waste → Low waste treatment costs
④ High cell concentrations → Increase volumetric productivity
2. Limitation
∙ Product inhibition
→ To relieve this problem membrane distillation system was studied
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§ Introduction
£ Membrane distillation
1. Components
① Warm feed
② Porous hydrophobic membrane
→ poly(tetrafluoroethylene) (PTFE)
③ Cold fluid on permeate side
2. Driving force
Partial vapor pressure gradient
Warm Feed
Cool Permeate
Hydrophobic Microporous Membrane
Vapor Space
Evap
ora
tion
Con
den
sati
on
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§ Materials and methods
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§ Materials and methods
→ Effect on the specific ethanol production rate at three feed medium
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§ Results and discussion
£ Continuous fermentation of concentrated glucose solution A
1. Experimental condition
∙ Fixed PTFE module size
∴ High cell concentrations → Ethanol accumulation
∴ Control feed rate of glucose solution A → Constant cell concentrations
2. Conclusion
① Specific ethanol production rate
∙ With ethanol stripping : 0.21 gEtOH/gcell∙h
∙ Without ethanol stripping : 0.06 g/g ∙h
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§ Results and discussion
② Usage of PTFE module
→ Low ethanol concentration of fermentation broth
= High ethanol concentrated solution removed from the broth
→ Higher cell activity
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§ Results and discussion£ Continuous fermentation of concentrated glucose solution B
1. Experimental condition
∙ Cell growth not controlled
( Feed rate controlled → Maintain glucose concentration constant )
∙ Control yeast concentration
( Production rate by yeast cells = removal rate by PTFE module )
→ Due to the size of the module ( limiting factor )
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§ Results and discussion£ Continuous fermentation of concentrated glucose solution B
2. Conclusion
① Specific ethanol production rate : 0.22 g/g∙h → Relatively low →
Increased feed rate → Specific ethanol production rate : 0.38 g/g∙h →
Decrease cell concentration to 18 g/l → Specific ethanol production rate
: 0.4 g/g∙h
② Average ethanol concentration in the cold trap after 180 hour : 350 g/l
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§ Results and discussion£ Continuous fermentation of concentrated molasses
1. Conclusion
∙ Flocculation of the yeast cells was adversely affected ; cell washout
occurred
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Thank you