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Evaluation of suitability of water hyacinth as feedstock for bio-energy production / Cornelis JohannesJ. SchabortSchabort, Cornelis Johannes January 2014 (has links)
The suitability of water hyacinth (Eichornia crassipes) as a viable feedstock for renewable energy
production was investigated in this project. Water hyacinth used in this study was harvested from
the Vaal River near Parys in the northwest region of the Free State province, South Africa (26°54′S
27°27′E). The wet plants were processed in the laboratory at the North-West University by
separating the roots from the leaves and the stems, thus obtaining two separate water hyacinth
feedstock.
Characterisation of the feedstock showed that the stems and leaves are more suitable for bio-energy
production than roots, due to the higher cellulose and hemicellulose content and very low lignin
content of the stems and leaves. Water hyacinth was evaluated as feedstock for the production of
bio-ethanol gel, bio-ethanol, bio-oil and bio-char. The recovery of water from the wet plants for use
in bio-refining or for use as drip-irrigation in agriculture was also investigated.
Cellulose was extracted from water hyacinth feedstock to be used as a gelling agent for the
production of ethanol-gel fuel. A yield of 200 g cellulose/kg dry feedstock was obtained. The
extracted cellulose was used to produce ethanol-gel with varying water content. The gel with
properties closest to the SANS 448 standard contained 90 vol% ethanol and 10 vol% water, with 38
wt% cellulose.
This gel was found to ignite readily and burn steadily, without flaring, sudden deflagrations,
sparking, splitting, popping, dripping or exploding from ignition until it had burned to extinction, as
required by SANS 448. The only specifications that could not be met were the viscosity (23,548 cP)
and the high waste residue (32 wt%) left after burning. The other major concern is the extremely
high costs involved with the manufacturing of ethanol-gel from water hyacinth cellulose. It can be
concluded that ethanol-gel cannot be economically produced using water hyacinth as feedstock.
Chemical and enzymatic extraction of water from the feedstock, which is stems and leaves or roots,
showed that the highest yield of water was obtained using a combination of Celluclast 1.5 L, Pectinex
Ultra SP-L and additional de-ionised water. A yield of 0.89 ± 0.01 gwater/gwater in biomass was realised. This
is, however, only 0.86 wt% higher than the highest yield obtained (0.87 ± 0.01 gwater/gwater in biomass)
using only Pectinex Ultra SP-L and de-ionised water. It is recommended to use only Pectinex Ultra
SP-L and de-ionised water at a pH of 3.5 and a temperature of 40°C. Using one enzyme instead of
two reduces operating costs and simplifies the chemical extraction process. The extracted water, both filtered and unfiltered, was not found to be suitable for domestic use
without further purification to reduce the total dissolved solids (TDS), potassium and manganese
levels. Both the unfiltered and filtered water were, however, found to be suitable for industrial and
agricultural purposes, except for the high TDS levels. If the TDS and suspended particle level can be
reduced, the extracted water would be suitable for domestic, industrial and agricultural use.
The potential fermentation of the sugars derived from the water hyacinth, using ultrasonic
pretreatment, was investigated. Indirect ultrasonic treatment (ultrasonic bath) proved to be a better
pretreatment method than direct sonication (ultrasonic probe). The optimum sugar yield for the
ultrasonic bath pretreatment with 5% NaOH was found to be 0.15 g sugar/g biomass (0.47 g sugar/g
available sugar) using an indirect sonication energy input of 27 kJ/g biomass. The optimum sugar
yield is lower than those reported in other studies using different pretreatment methods.
Theoretically a maximum of 0.24 g ethanol can be obtained per g available sugar. This relates to an
ethanol yield of 0.08 g ethanol/kg wet biomass. The low yield implies that ethanol production from
water hyacinth is not economically feasible.
The production of bio-oil and bio-char from water hyacinth through thermochemical liquefaction of
wet hyacinth feedstock was investigated. An optimum bio-char yield of 0.55 g bio-char/g biomass
was achieved using an inert atmosphere (nitrogen) at 260°C and the stems and leaves as feedstock.
With the roots as feedstock a slightly lower optimum yield of 0.45 g bio-char/g biomass was found
using a non-reducing atmosphere (carbon monoxide) at 280°C. The bio-oil yield was too low to
accurately quantify.
As water is required during thermochemical liquefaction, it was found unnecessary to dry the
biomass to the same extent as was the case with the pretreatment and fermentation of the water
hyacinth, making this a more feasible route for biofuel production. Bio-char produced through
liquefaction of roots as the feedstock and leaves and stems as the other feedstock had a higher
heating value (HHV) of 10.89 ± 0.45 MJ/kg and 23.31 ± 0.45 MJ/kg respectively. Liquefaction of
water hyacinth biomass increased the HHV of the feedstock to a value comparable to that of low
grade coal. This implies a possible use of water hyacinth for co-gasification.
The most effective route for bio-energy production in the case of water hyacinth was found to be
thermochemical liquefaction (12.8 MJ/kg wet biomass). Due to the high production costs involved, it is recommended to only use water hyacinth as a feedstock for biofuel production if no alternative
feedstock are available. / MIng (Chemical Engineering), North-West University, Potchefstroom Campus, 2014
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Evaluation of suitability of water hyacinth as feedstock for bio-energy production / Cornelis JohannesJ. SchabortSchabort, Cornelis Johannes January 2014 (has links)
The suitability of water hyacinth (Eichornia crassipes) as a viable feedstock for renewable energy
production was investigated in this project. Water hyacinth used in this study was harvested from
the Vaal River near Parys in the northwest region of the Free State province, South Africa (26°54′S
27°27′E). The wet plants were processed in the laboratory at the North-West University by
separating the roots from the leaves and the stems, thus obtaining two separate water hyacinth
feedstock.
Characterisation of the feedstock showed that the stems and leaves are more suitable for bio-energy
production than roots, due to the higher cellulose and hemicellulose content and very low lignin
content of the stems and leaves. Water hyacinth was evaluated as feedstock for the production of
bio-ethanol gel, bio-ethanol, bio-oil and bio-char. The recovery of water from the wet plants for use
in bio-refining or for use as drip-irrigation in agriculture was also investigated.
Cellulose was extracted from water hyacinth feedstock to be used as a gelling agent for the
production of ethanol-gel fuel. A yield of 200 g cellulose/kg dry feedstock was obtained. The
extracted cellulose was used to produce ethanol-gel with varying water content. The gel with
properties closest to the SANS 448 standard contained 90 vol% ethanol and 10 vol% water, with 38
wt% cellulose.
This gel was found to ignite readily and burn steadily, without flaring, sudden deflagrations,
sparking, splitting, popping, dripping or exploding from ignition until it had burned to extinction, as
required by SANS 448. The only specifications that could not be met were the viscosity (23,548 cP)
and the high waste residue (32 wt%) left after burning. The other major concern is the extremely
high costs involved with the manufacturing of ethanol-gel from water hyacinth cellulose. It can be
concluded that ethanol-gel cannot be economically produced using water hyacinth as feedstock.
Chemical and enzymatic extraction of water from the feedstock, which is stems and leaves or roots,
showed that the highest yield of water was obtained using a combination of Celluclast 1.5 L, Pectinex
Ultra SP-L and additional de-ionised water. A yield of 0.89 ± 0.01 gwater/gwater in biomass was realised. This
is, however, only 0.86 wt% higher than the highest yield obtained (0.87 ± 0.01 gwater/gwater in biomass)
using only Pectinex Ultra SP-L and de-ionised water. It is recommended to use only Pectinex Ultra
SP-L and de-ionised water at a pH of 3.5 and a temperature of 40°C. Using one enzyme instead of
two reduces operating costs and simplifies the chemical extraction process. The extracted water, both filtered and unfiltered, was not found to be suitable for domestic use
without further purification to reduce the total dissolved solids (TDS), potassium and manganese
levels. Both the unfiltered and filtered water were, however, found to be suitable for industrial and
agricultural purposes, except for the high TDS levels. If the TDS and suspended particle level can be
reduced, the extracted water would be suitable for domestic, industrial and agricultural use.
The potential fermentation of the sugars derived from the water hyacinth, using ultrasonic
pretreatment, was investigated. Indirect ultrasonic treatment (ultrasonic bath) proved to be a better
pretreatment method than direct sonication (ultrasonic probe). The optimum sugar yield for the
ultrasonic bath pretreatment with 5% NaOH was found to be 0.15 g sugar/g biomass (0.47 g sugar/g
available sugar) using an indirect sonication energy input of 27 kJ/g biomass. The optimum sugar
yield is lower than those reported in other studies using different pretreatment methods.
Theoretically a maximum of 0.24 g ethanol can be obtained per g available sugar. This relates to an
ethanol yield of 0.08 g ethanol/kg wet biomass. The low yield implies that ethanol production from
water hyacinth is not economically feasible.
The production of bio-oil and bio-char from water hyacinth through thermochemical liquefaction of
wet hyacinth feedstock was investigated. An optimum bio-char yield of 0.55 g bio-char/g biomass
was achieved using an inert atmosphere (nitrogen) at 260°C and the stems and leaves as feedstock.
With the roots as feedstock a slightly lower optimum yield of 0.45 g bio-char/g biomass was found
using a non-reducing atmosphere (carbon monoxide) at 280°C. The bio-oil yield was too low to
accurately quantify.
As water is required during thermochemical liquefaction, it was found unnecessary to dry the
biomass to the same extent as was the case with the pretreatment and fermentation of the water
hyacinth, making this a more feasible route for biofuel production. Bio-char produced through
liquefaction of roots as the feedstock and leaves and stems as the other feedstock had a higher
heating value (HHV) of 10.89 ± 0.45 MJ/kg and 23.31 ± 0.45 MJ/kg respectively. Liquefaction of
water hyacinth biomass increased the HHV of the feedstock to a value comparable to that of low
grade coal. This implies a possible use of water hyacinth for co-gasification.
The most effective route for bio-energy production in the case of water hyacinth was found to be
thermochemical liquefaction (12.8 MJ/kg wet biomass). Due to the high production costs involved, it is recommended to only use water hyacinth as a feedstock for biofuel production if no alternative
feedstock are available. / MIng (Chemical Engineering), North-West University, Potchefstroom Campus, 2014
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Investigation Of Alkaline Pretreatment Parameters On A Multi-product Basis For The Co-production Of Glucose And Hemicellulose Based Films From Corn CobsToraman, Hilal Ezgi 01 July 2012 (has links) (PDF)
There is an increasing trend in the world for using renewable sources of fuels and
chemicals due to the continuous depletion of fossil fuel reserves besides the
environmental issues related with the exploitation of these resources.
Lignocellulosic biomass is seen as the most promising candidate to be used instead
of fossil sources because of its availability, relatively low price and less competition
with food and feed crops. In this study, corn cobs, a lignocellulosic agricultural
waste, were subjected to alkaline pretreatment for the co-production of glucose
and hemicellulose based films with a multi-product approach in order to diversify
the product range and to increase the revenues of the process. The pretreatment
applied to lignocellulosic agricultural waste has a significant impact on the
quantities and properties of the products that can be produced from the
lignocellulosic feedstock upon pretreatment. Within the context of this study, the
parameters utilized during the alkaline pretreatment of corn cobs were investigated
in terms of their effect on the amount of glucose obtained through the enzymatic
v
hydrolysis of the cellulosic portion and on the mechanical properties of the films
obtained through the solvent casting of the hemicellulosic portion of corn cob. The
pretreatment parameters including the alkaline type and concentration, addition
and type of boron compound as well as the duration of pretreatment, were
optimized with respect to the amounts and the properties of the products.
Following the pretreatments conducted with 24 % KOH and 1% NaBH4, which were
the initial pretreatment parameters in the study, a glucose yield of 22 % and a
tensile energy to break of 2.1 MJ/m3 were obtained. Upon the optimization of the
pretreatment procedure, the optimum pretreatment conditions were determined
as 5 % NaOH, 1 % NaBH4 and 3 hours and a glucose yield of approximately 31% and
a tensile energy to break of around 1.7 MJ/m3 were obtained.
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