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Carbon Dioxide Gasification of Hydrothermally Treated Manure-Derived HydrocharSaha, Pretom 13 June 2019 (has links)
No description available.
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Gasification kinetics of blends of waste tyre and typical South African coals / Chaitamwari GuraiGurai, Chaitamwari January 2015 (has links)
With increasing energy demand globally and, in particular, in South Africa coupled with
depletion of the earth’s fossil energy resources and growing problem of disposal of nonbiodegradable
waste such as waste tyres, there is a need and effort globally to find alternative
energy from waste material including waste tyres. One possible way of exploiting waste tyre
for energy or chemicals recovery is through gasification for the production of syngas, and this
is what was investigated in this study. The possibility of gasification of waste tyre blended with
coal after pyrolysis was investigated and two Bituminous coals were selected for blending with
the waste tyre in co-gasification. A sample of ground waste tyre / waste tire, WT, a high vitrinite
coal from the Waterberg coalfield (GG coal) and a high inertinite coal from the Highveld
coalfield (SF coal) were used in this investigation.
The waste tyre sample had the highest volatile matter content of 63.8%, followed by GG coal
with 27% and SF coal with 23.8%. SF coal had the highest ash content of 21.6%, GG coal had
12.6% and waste tyre had the lowest of 6.6%. For the chars, SF char still had the highest ash
of 24.8%, but WT char had higher ash, 14.7%, when compared to GG char with 13.9% ash.
The vitrinite content in GG coal was 86.3%, whilst in SF coal it was 25% and SF coal had a
higher inertinite content of 71% when compared to GG coal with 7.7%. SF char had the highest
BET surface area of 126m2/g, followed by GG char with 113m2/g, and WT had the lowest
value of 35.09m2/g. The alkali indices of the SF, WT and GG chars were calculated to be 8.2,
4.2 and 1.7 respectively.
Coal samples were prepared by crushing and milling to particle sizes less than 75μm before
charring in a packed bed balance reactor at temperatures up to 1000oC.Waste tyre samples were
charred at the same conditions before milling to < 75μm particle size. Coal and WT chars were
blended in ratios of 75:25, 50:50 and 25:75 before gasification experimentation. Carbon
dioxide gasification was conducted on the blends and the pure coal and WT chars in a
Thermogravimetric analyser (TGA) at 900oC, 925oC, 950oC and 975oC and ambient pressure.
100% CO2 was used at a flow rate of 2L/min.
Reactivity of the pure char samples was found to be in the order SF > GG > WT, and the
relationship between the coal chars’ reactivities could be explained by the high ash content of
the SF char and low reactivity of the WT char corresponds to its low BET surface area. In
general, the coal/WT char mixtures were less reactive than the respective coal, but more
reactive than the pure WT char, the only exception being the 75% GG char blend which was
initially more reactive than the GG char, and reactivity decreased with increasing WT content.
For all samples reactivity increased with increasing temperature.
The relationship between the reactivities of the GG char and its blends and that of the SF char
and its blends was found to be affected by the amount of WT char added, especially at the
lower temperatures 900oC and 925oC. SF coal is more reactive than GG coal, but at 900oC and
925oC, the reactivity of GG/WT blends improves in relation to the SF/WT blends with an
increase in the ratio of WT in the blends, i.e. the 25% GG char blend is more reactive than the
25% SF char blend. The reactivity of the coal/WT blends was also checked against predicted
conversion rates based on the conversion rates of the pure WT and coal samples. At 900oC and
925oC, the reactivities of the blends of both coal chars with WT char were found to be greater
than the predicted conversion rates, and for the GG/WT blends the deviation increased with
increasing WT ratios, while for the SF/WT blends the deviation increased with increasing SF
ratios. These findings suggest the presence of synergism or enhancement between the coal
chars and WT char in gasification reactions.
The random pore model (RPM) was used to model the gasification results and it was found to
adequately describe the experimental data. Activation energies determined with the RPM were
found to be 205.4kJ/mol, 189.9kJ/mol and 173.9kJ/mol for SF char, WT char and GG char
respectively. The activation energies of the coal/WT blends were found to be lower than those
of both the pure coal and the pure WT chars. For the GG/WT blends the activation energy
decreased with increasing WT char ratio, while for the SF/WT blends the activation energy
decreased with increasing SF char ratio.
The trends of the activation energies and conversion rates of the blends point to synergism or
enhancement between the coal and WT chars in CO2 gasification reactions, and in the GG/WT
blends this enhancement is driven more by the WT char, while in SF/WT blends it is driven by
SF chars. It is possible that enhancement of the reactions is caused by mineral matter catalysis
of the gasification reactions. The ash contents and alkali indices of the pure samples follow the
order SF > WT > GG. / MIng (Chemical Engineering), North-West University, Potchefstroom Campus, 2015
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Gasification kinetics of blends of waste tyre and typical South African coals / Chaitamwari GuraiGurai, Chaitamwari January 2015 (has links)
With increasing energy demand globally and, in particular, in South Africa coupled with
depletion of the earth’s fossil energy resources and growing problem of disposal of nonbiodegradable
waste such as waste tyres, there is a need and effort globally to find alternative
energy from waste material including waste tyres. One possible way of exploiting waste tyre
for energy or chemicals recovery is through gasification for the production of syngas, and this
is what was investigated in this study. The possibility of gasification of waste tyre blended with
coal after pyrolysis was investigated and two Bituminous coals were selected for blending with
the waste tyre in co-gasification. A sample of ground waste tyre / waste tire, WT, a high vitrinite
coal from the Waterberg coalfield (GG coal) and a high inertinite coal from the Highveld
coalfield (SF coal) were used in this investigation.
The waste tyre sample had the highest volatile matter content of 63.8%, followed by GG coal
with 27% and SF coal with 23.8%. SF coal had the highest ash content of 21.6%, GG coal had
12.6% and waste tyre had the lowest of 6.6%. For the chars, SF char still had the highest ash
of 24.8%, but WT char had higher ash, 14.7%, when compared to GG char with 13.9% ash.
The vitrinite content in GG coal was 86.3%, whilst in SF coal it was 25% and SF coal had a
higher inertinite content of 71% when compared to GG coal with 7.7%. SF char had the highest
BET surface area of 126m2/g, followed by GG char with 113m2/g, and WT had the lowest
value of 35.09m2/g. The alkali indices of the SF, WT and GG chars were calculated to be 8.2,
4.2 and 1.7 respectively.
Coal samples were prepared by crushing and milling to particle sizes less than 75μm before
charring in a packed bed balance reactor at temperatures up to 1000oC.Waste tyre samples were
charred at the same conditions before milling to < 75μm particle size. Coal and WT chars were
blended in ratios of 75:25, 50:50 and 25:75 before gasification experimentation. Carbon
dioxide gasification was conducted on the blends and the pure coal and WT chars in a
Thermogravimetric analyser (TGA) at 900oC, 925oC, 950oC and 975oC and ambient pressure.
100% CO2 was used at a flow rate of 2L/min.
Reactivity of the pure char samples was found to be in the order SF > GG > WT, and the
relationship between the coal chars’ reactivities could be explained by the high ash content of
the SF char and low reactivity of the WT char corresponds to its low BET surface area. In
general, the coal/WT char mixtures were less reactive than the respective coal, but more
reactive than the pure WT char, the only exception being the 75% GG char blend which was
initially more reactive than the GG char, and reactivity decreased with increasing WT content.
For all samples reactivity increased with increasing temperature.
The relationship between the reactivities of the GG char and its blends and that of the SF char
and its blends was found to be affected by the amount of WT char added, especially at the
lower temperatures 900oC and 925oC. SF coal is more reactive than GG coal, but at 900oC and
925oC, the reactivity of GG/WT blends improves in relation to the SF/WT blends with an
increase in the ratio of WT in the blends, i.e. the 25% GG char blend is more reactive than the
25% SF char blend. The reactivity of the coal/WT blends was also checked against predicted
conversion rates based on the conversion rates of the pure WT and coal samples. At 900oC and
925oC, the reactivities of the blends of both coal chars with WT char were found to be greater
than the predicted conversion rates, and for the GG/WT blends the deviation increased with
increasing WT ratios, while for the SF/WT blends the deviation increased with increasing SF
ratios. These findings suggest the presence of synergism or enhancement between the coal
chars and WT char in gasification reactions.
The random pore model (RPM) was used to model the gasification results and it was found to
adequately describe the experimental data. Activation energies determined with the RPM were
found to be 205.4kJ/mol, 189.9kJ/mol and 173.9kJ/mol for SF char, WT char and GG char
respectively. The activation energies of the coal/WT blends were found to be lower than those
of both the pure coal and the pure WT chars. For the GG/WT blends the activation energy
decreased with increasing WT char ratio, while for the SF/WT blends the activation energy
decreased with increasing SF char ratio.
The trends of the activation energies and conversion rates of the blends point to synergism or
enhancement between the coal and WT chars in CO2 gasification reactions, and in the GG/WT
blends this enhancement is driven more by the WT char, while in SF/WT blends it is driven by
SF chars. It is possible that enhancement of the reactions is caused by mineral matter catalysis
of the gasification reactions. The ash contents and alkali indices of the pure samples follow the
order SF > WT > GG. / MIng (Chemical Engineering), North-West University, Potchefstroom Campus, 2015
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The effects of chemical and physical properties of chars derived from inertinite–rich, high ash coals on gasification reaction kinetics / Gregory Nworah OkoloOkolo, Gregori Nworah January 2010 (has links)
With the increasing global energy demand and the decreasing availability of good
quality coals, a better understanding of the important properties that control the
behaviour of low–grade coals and the subsequent chars in various utilisation
processes, becomes pertinent. An investigation was therefore undertaken, to study the
effects of chemical and physical properties imparted on chars during pyrolysis on the
subsequent gasification reaction kinetics of typical South African inertinite–rich, high
ash Highveld coals. An attempt was made at following these changes in the transition
from coals to chars by a detailed characterisation of both the parent coals and the
respective chars. These changes were determined using various conventional and
advanced techniques, which included among others, carbon crystallite analysis using
XRD and char carbon forms analysis using petrography.
Three of the four original coals were characterised as Bituminous Medium rank C
(coals B, C and C2), while coal D2 was found to be slightly lower in rank
(Bituminous Medium rank D). The coals were rich in inertinites (> 54 vol. %, mmb
with coal C2 having as high as 79 vol. %, mmb) and high in ash content (> 26.7 wt. %,
db) and cabominerite and minerite contents (26 – 39 vol. %, mmb). The inertinitevitrinite
ratios of the coals were found to range from 1.93 to 26.3.
Characterization results show that both volatile matter and inherent moisture content
decreased, while ash, fixed carbon and elemental carbon contents increased from
coals to chars, indicating that the pyrolysis process was efficient. Elemental hydrogen,
oxygen and nitrogen contents decreased, whereas total sulphur contents increased
from coals to chars. This reveals that the total sulphur contained in the char samples
was associated with the char carbon matrix and the minerals. Hydrogen–carbon and
oxygen–carbon ratios decreased considerably from coals to chars showing that the
chars are more aromatic and denser products than the original coals. Despite the fact
that mineral matter increased from coals to chars, the relative abundance of the
different mineral phases and ash components did not exhibit significant variation
amongst the samples. The alkali index was, however, found to vary considerably
among the subsequent chars. Petrographic analysis of the coals and char carbon forms
analysis of the chars reveal that total reactive components (TRC) decrease while the total inert components (TIC) increase from coals to chars. The 0% gain in TIC
observed in char C2 was attributed to its relatively high partially reacted maceral char
carbon forms content. Total maceral reflectance shifted to higher values in the chars
(4.43 – 5.28 Rsc%) relative to the coals (1.15 – 1.63 Rsc%) suggesting a higher
structural ordering in the chars. Carbon crystallite analyses revealed that the chars
were condensed (smaller in size) relative to the parent coals. Lattice parameters: interlayer
spacing, d002, increased, while the average crystallite height, Lc, crystallite
diameter, La, and number of aromatic layers per crystallite, Nave, decreased from coals
to chars. Carbon aromaticity generally increased whereas the fraction of amorphous
carbon and the degree of disorder index decreased from parent coals to the respective
chars. Both micropore surface area and microporosity were observed to increase while
the average micropore diameter decreased from coals to chars. This shows that blind
and closed micropores were “opened up” during the charring process.
Despite the original coal samples not showing much variation in their properties
(except for their maceral content), it was generally observed that the subsequent chars
exhibited substantial differences, both amongst themselves and from the parent coals.
The increasing orders of magnitude of micropore surface area, microporosity, fraction
of amorphous carbon and structural disorderliness were found to change in the
transition, a good indication that the chars’ properties varied from that of the
respective parent coals.
Isothermal CO2 gasification experiments were conducted on the chars in a Thermax
500 thermogravimetric analyser in the temperature range of 900 – 950 °C with varying
concentrations of CO2 (25 – 100 mol. %) in the CO2–N2 reaction gas mixture at
ambient pressure (0.875 bar in Potchefstroom). The effects of temperature and CO2
concentration were observed to be in conformity with established trends. The initial
reactivity of the chars was found to increase in the order: chars C2 < C < B < D2, with
char D2 reactivity greater than the reactivity of the other chars by a factor > 4.
Gasification reactivity results were correlated with properties of the parent coals and
chars. Except for the rank parameter (the vitrinite reflectance), no significant trend
was observed with any other coal petrographic property. Correlations with char
properties gave more significant and systematic trends. Major factors affecting the
gasification reactivity of the chars as it pertains to this investigation are: parent coal vitrinite reflectance, and: aromaticity, fraction of amorphous carbon, degree of
disorder and alkali indices, micropore surface area, microporosity and average
micropore diameter of the chars.
The random pore model (chemical reaction controlling) was found to adequately
describe the gasification reaction experimental data (both conversions and conversion
rates). The determined activation energy ranged from 163.3 kJ·mol–1 for char D2 to
235.7 kJ·mol–1 for char B; while the order of reaction with respect to CO2
concentration ranged between 0.52 to 0.67 for the four chars. The lower activation
energy of char D2 was possibly due to its lower rank, lower coal vitrinite reflectance
and higher alkali index. The estimated kinetic parameters of the chars in this study
correspond very well with published results in open literature. It was possible to
express the intrinsic reactivity, rs, of the chars (rate of carbon conversion per unit total
surface area) using kinetic results, in empirical Arrhenius forms. / Thesis (M.Ing. (Chemical Engineering))--North-West University, Potchefstroom Campus, 2011.
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The effects of chemical and physical properties of chars derived from inertinite–rich, high ash coals on gasification reaction kinetics / Gregory Nworah OkoloOkolo, Gregori Nworah January 2010 (has links)
With the increasing global energy demand and the decreasing availability of good
quality coals, a better understanding of the important properties that control the
behaviour of low–grade coals and the subsequent chars in various utilisation
processes, becomes pertinent. An investigation was therefore undertaken, to study the
effects of chemical and physical properties imparted on chars during pyrolysis on the
subsequent gasification reaction kinetics of typical South African inertinite–rich, high
ash Highveld coals. An attempt was made at following these changes in the transition
from coals to chars by a detailed characterisation of both the parent coals and the
respective chars. These changes were determined using various conventional and
advanced techniques, which included among others, carbon crystallite analysis using
XRD and char carbon forms analysis using petrography.
Three of the four original coals were characterised as Bituminous Medium rank C
(coals B, C and C2), while coal D2 was found to be slightly lower in rank
(Bituminous Medium rank D). The coals were rich in inertinites (> 54 vol. %, mmb
with coal C2 having as high as 79 vol. %, mmb) and high in ash content (> 26.7 wt. %,
db) and cabominerite and minerite contents (26 – 39 vol. %, mmb). The inertinitevitrinite
ratios of the coals were found to range from 1.93 to 26.3.
Characterization results show that both volatile matter and inherent moisture content
decreased, while ash, fixed carbon and elemental carbon contents increased from
coals to chars, indicating that the pyrolysis process was efficient. Elemental hydrogen,
oxygen and nitrogen contents decreased, whereas total sulphur contents increased
from coals to chars. This reveals that the total sulphur contained in the char samples
was associated with the char carbon matrix and the minerals. Hydrogen–carbon and
oxygen–carbon ratios decreased considerably from coals to chars showing that the
chars are more aromatic and denser products than the original coals. Despite the fact
that mineral matter increased from coals to chars, the relative abundance of the
different mineral phases and ash components did not exhibit significant variation
amongst the samples. The alkali index was, however, found to vary considerably
among the subsequent chars. Petrographic analysis of the coals and char carbon forms
analysis of the chars reveal that total reactive components (TRC) decrease while the total inert components (TIC) increase from coals to chars. The 0% gain in TIC
observed in char C2 was attributed to its relatively high partially reacted maceral char
carbon forms content. Total maceral reflectance shifted to higher values in the chars
(4.43 – 5.28 Rsc%) relative to the coals (1.15 – 1.63 Rsc%) suggesting a higher
structural ordering in the chars. Carbon crystallite analyses revealed that the chars
were condensed (smaller in size) relative to the parent coals. Lattice parameters: interlayer
spacing, d002, increased, while the average crystallite height, Lc, crystallite
diameter, La, and number of aromatic layers per crystallite, Nave, decreased from coals
to chars. Carbon aromaticity generally increased whereas the fraction of amorphous
carbon and the degree of disorder index decreased from parent coals to the respective
chars. Both micropore surface area and microporosity were observed to increase while
the average micropore diameter decreased from coals to chars. This shows that blind
and closed micropores were “opened up” during the charring process.
Despite the original coal samples not showing much variation in their properties
(except for their maceral content), it was generally observed that the subsequent chars
exhibited substantial differences, both amongst themselves and from the parent coals.
The increasing orders of magnitude of micropore surface area, microporosity, fraction
of amorphous carbon and structural disorderliness were found to change in the
transition, a good indication that the chars’ properties varied from that of the
respective parent coals.
Isothermal CO2 gasification experiments were conducted on the chars in a Thermax
500 thermogravimetric analyser in the temperature range of 900 – 950 °C with varying
concentrations of CO2 (25 – 100 mol. %) in the CO2–N2 reaction gas mixture at
ambient pressure (0.875 bar in Potchefstroom). The effects of temperature and CO2
concentration were observed to be in conformity with established trends. The initial
reactivity of the chars was found to increase in the order: chars C2 < C < B < D2, with
char D2 reactivity greater than the reactivity of the other chars by a factor > 4.
Gasification reactivity results were correlated with properties of the parent coals and
chars. Except for the rank parameter (the vitrinite reflectance), no significant trend
was observed with any other coal petrographic property. Correlations with char
properties gave more significant and systematic trends. Major factors affecting the
gasification reactivity of the chars as it pertains to this investigation are: parent coal vitrinite reflectance, and: aromaticity, fraction of amorphous carbon, degree of
disorder and alkali indices, micropore surface area, microporosity and average
micropore diameter of the chars.
The random pore model (chemical reaction controlling) was found to adequately
describe the gasification reaction experimental data (both conversions and conversion
rates). The determined activation energy ranged from 163.3 kJ·mol–1 for char D2 to
235.7 kJ·mol–1 for char B; while the order of reaction with respect to CO2
concentration ranged between 0.52 to 0.67 for the four chars. The lower activation
energy of char D2 was possibly due to its lower rank, lower coal vitrinite reflectance
and higher alkali index. The estimated kinetic parameters of the chars in this study
correspond very well with published results in open literature. It was possible to
express the intrinsic reactivity, rs, of the chars (rate of carbon conversion per unit total
surface area) using kinetic results, in empirical Arrhenius forms. / Thesis (M.Ing. (Chemical Engineering))--North-West University, Potchefstroom Campus, 2011.
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