Development of carbonisation-activation system for production of biochar and activated carbon from oil palm kernel shell
Activated carbon is commonly produced through carbonisation process followed by activation process in two separate reactors. These two-steps or separate processes of carbonisation and activation contribute to energy and time consumption, the cost of materials and apparatus and low yield of activ...
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| Main Author: | |
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| Format: | Thesis |
| Language: | English |
| Published: |
2018
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| Online Access: | http://psasir.upm.edu.my/id/eprint/68525/1/FBSB%202018%2013%20IR.pdf http://psasir.upm.edu.my/id/eprint/68525/ |
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| Institution: | Universiti Putra Malaysia |
| Language: | English |
| Summary: | Activated carbon is commonly produced through carbonisation process
followed by activation process in two separate reactors. These two-steps or
separate processes of carbonisation and activation contribute to energy and
time consumption, the cost of materials and apparatus and low yield of
activated carbon produced. Therefore, the carbonisation-activation system was
designed to enable the activation stage to be continuously conducted after
carbonisation without termination of the operation. This process could reduce
the production cost, energy and time without compromising on the yield and
quality of the activated carbon produced, while at the same time avoiding the
involvement of chemical agent in the process.
Currently, the industry produce biochar by purchasing it from local or from
backyard industry, which is producing it through conventional drum kiln or pit
kiln methods, where this conventional heating methods will causes to
environmental issue such as gaseous emission and particulate matter
emission. Therefore, a study of the production of biochar with high higher
heating value (HHV) and low gaseous emission from oil palm kernel shell using
a microwave-assisted pre-carbonisation system was conducted. Microwave
function is to provide heat to biomass materials that has the ability to reduce
the treatment time and energy consumption during the pre-carbonisation
process. Biochar with high HHV of 27.63 MJ/kg was obtained, whereby the
emissions of the particulate matter <10 μm (PM10) was 35 μg/m3 below the
standard limits set by the Malaysian Ambient Air Quality Standards (2014).
Therefore, the biochar produced using microwave-assisted pre-carbonisation
technology proposed in this study can be used as co-combustion for renewable
energy generation. The small-scale carbonisation-activation system using electric vertical reactor
was developed to produce activated carbon from oil palm kernel shell as a
preliminary study. The process from this preliminary study had resulted a high
activated carbon yield of 32%, high fixed carbon content of 88.6% with surface
area of 305.67 m2/g. The activated carbon was further tested as bio-adsorbent
on the removal of methylene blue. About 99.7% of methylene blue has been
adsorbed using minimum dosage of bio-adsorbent 0.6 g/L for 24 hours of
treatment time. The results have been correlated in the Freundlich isotherm
which was well fitted to the experimental data over the methylene blue
experimental concentration range with correlation coefficients of R2=0.992.
In order to improve the surface area and yield of oil palm kernel shell activate
carbon, a double insulated carbonisation-activation reactor was developed.
This reactor was double insulated using low cement castable and covered
around the internal space of the reactor with stainless steel plated and fibre
glass jacketed heat insulation layer, which allow efficient heat transfer into the
bed of material in the reactor. The optimisation carbonisation conditions
achieved from carbonisation process using microwave-assisted precarbonisation
system was applied to the new development double insulated
carbonisation-activation system. The temperature of carbonisation process
was 400°C for three hours carbonisation time. The activated carbon produced
gave the surface area of 935 ± 36.7 m2/g and 30% yield within only seven
hours retention time which is the highest compare to the preliminary systems
(small-scale carbonisation-activation system).
The concentration of carbon monoxide was 8.98 mg/m3 lower than permitted
level set by the Malaysian Ambient Air Quality Standards 2015. The activated
carbon produced was then used as a bio-adsorbent to treat palm oil mill
effluent (POME) final discharge at various dosages using 40 g/L bio-adsorbent,
the total suspended solid (TSS), chemical oxygen demand (COD), colour and
biological oxygen demand (BOD) were reduced from 240 mg/L, 604 mg/L,
3170 ADMI unit and 100 mg/L to 18 mg/L, 189 mg/L, 80 ADMI unit and 5.1
mg/L, respectively. The concentrations meet the river water quality standard
set by Department of Environment Malaysia (DOE), suitable to be applied for
wastewater treatment in the palm oil mill. Therefore, the high quality of
activated carbon produced using the carbonisation-activation system
developed in this study shown it potential for the various application in the palm
oil industry. |
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