Pyrolytic oil from automotive paint sludge via activated carbon assisted microwave pyrolysis / Syarifah Nor Faizah Syed Abdul Rahman

Abundance of automotive paint sludge (APS), SW416 led to disposal problem due to its nature that contains high moisture content and limitation of landfill. APS contains valuable components that could be recovered. Microwave pyrolysis technique was applied to treat and convert the APS into pyrolytic...

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Main Author: Syed Abdul Rahman, Syarifah Nor Faizah
Format: Thesis
Language:English
Published: 2019
Online Access:https://ir.uitm.edu.my/id/eprint/83295/1/83295.pdf
https://ir.uitm.edu.my/id/eprint/83295/
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spelling my.uitm.ir.832952023-11-16T09:28:36Z https://ir.uitm.edu.my/id/eprint/83295/ Pyrolytic oil from automotive paint sludge via activated carbon assisted microwave pyrolysis / Syarifah Nor Faizah Syed Abdul Rahman Syed Abdul Rahman, Syarifah Nor Faizah Abundance of automotive paint sludge (APS), SW416 led to disposal problem due to its nature that contains high moisture content and limitation of landfill. APS contains valuable components that could be recovered. Microwave pyrolysis technique was applied to treat and convert the APS into pyrolytic oil which later can be upgraded into alternative fuel. Previously, APS was converted into pyrolytic oil using the same technique with addition of catalyst. However, APS pyrolytic oil obtained has low yield and high carcinogenic compounds of nitrogenated and polycyclic aromatic hydrocarbon (PAH). Application of activated carbon (AC) as microwave absorber in this study enhances pyrolytic oil yield. Microwave pyrolysis of APS was carried out at three microwave powers of 500, 600, and 700 W at three different radiation time of 30, 40, and 50 minutes. Response surface methodology (RSM) has been used to determine process parameters of microwave power and radiation time that gave highest pyrolytic oil yield. The behavior of pyrolytic oil yield over radiation time at optimum condition was evaluated by using first-order and second-order kinetic model. APS pyrolytic oil obtained at optimum condition also been evaluated for its fuel properties in terms of calorific value (CV), density, viscosity, chemical bonding and compounds. In the presence of AC, increment of microwave power from 500 W to 600 W led to increment of pyrolytic oil yield from 1.01% to 2.08%, 1.70% to 3.90%, and 1.83% to 4.52% for the process at 30, 40, and 50 minutes, respectively. Further increment of microwave power to 700 led to reduction of pyrolytic oil yield to 2.36%, 2.63%, and 2.93% for the process at 30, 40 and 50 minutes, respectively. Pyrolytic oil yield increased with radiation time regardless of microwave power and application of AC. It was found that process with the presence of AC at 600 W and 50 minutes gave the highest pyrolytic oil yield of 4.52%. Based on the model developed using RSM, it was suggested that the best operating condition for microwave pyrolysis of APS process was 620 W with 50 minutes with predicted yield of 4.27%. The experiment of APS microwave pyrolysis at optimum conditions is carried out resulting 4.69% pyrolytic oil yield which slightly higher than the predicted. Suggested model is valid to be used to predict pyrolytic oil yield from microwave pyrolysis of APS since it has value of Prob>F below than 0.05 and high value of R2 (0.9243) and F-value (36.6125). The behavior of optimized pyrolytic oil production can be represented by second-order kinetic model because it has high value of R2 and low value of RMSE as compared to first-order kinetic model regardless of application of AC. The optimized oil has the calorific value of 39.04 kJ/kg, viscosity of 4.14 cSt and density of 836 kg/m3. The physical properties lie within the range of commercialized liquid fuel. Aliphatic and monoaromatic compounds traced in pyrolytic oil obtained from this study were high. Meanwhile, polycyclic aromatic hydrocarbon (PAH) and nitrogenated compounds were reduced significantly and oxygenated compound was slightly reduced as compared to the process with the absence of AC. Therefore, this study has not only contributed to future reduction or eliminating automotive paint sludge waste, but also generates new alternative fuel. 2019 Thesis NonPeerReviewed text en https://ir.uitm.edu.my/id/eprint/83295/1/83295.pdf Pyrolytic oil from automotive paint sludge via activated carbon assisted microwave pyrolysis / Syarifah Nor Faizah Syed Abdul Rahman. (2019) PhD thesis, thesis, Universiti Teknologi MARA (UiTM).
institution Universiti Teknologi Mara
building Tun Abdul Razak Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Mara
content_source UiTM Institutional Repository
url_provider http://ir.uitm.edu.my/
language English
description Abundance of automotive paint sludge (APS), SW416 led to disposal problem due to its nature that contains high moisture content and limitation of landfill. APS contains valuable components that could be recovered. Microwave pyrolysis technique was applied to treat and convert the APS into pyrolytic oil which later can be upgraded into alternative fuel. Previously, APS was converted into pyrolytic oil using the same technique with addition of catalyst. However, APS pyrolytic oil obtained has low yield and high carcinogenic compounds of nitrogenated and polycyclic aromatic hydrocarbon (PAH). Application of activated carbon (AC) as microwave absorber in this study enhances pyrolytic oil yield. Microwave pyrolysis of APS was carried out at three microwave powers of 500, 600, and 700 W at three different radiation time of 30, 40, and 50 minutes. Response surface methodology (RSM) has been used to determine process parameters of microwave power and radiation time that gave highest pyrolytic oil yield. The behavior of pyrolytic oil yield over radiation time at optimum condition was evaluated by using first-order and second-order kinetic model. APS pyrolytic oil obtained at optimum condition also been evaluated for its fuel properties in terms of calorific value (CV), density, viscosity, chemical bonding and compounds. In the presence of AC, increment of microwave power from 500 W to 600 W led to increment of pyrolytic oil yield from 1.01% to 2.08%, 1.70% to 3.90%, and 1.83% to 4.52% for the process at 30, 40, and 50 minutes, respectively. Further increment of microwave power to 700 led to reduction of pyrolytic oil yield to 2.36%, 2.63%, and 2.93% for the process at 30, 40 and 50 minutes, respectively. Pyrolytic oil yield increased with radiation time regardless of microwave power and application of AC. It was found that process with the presence of AC at 600 W and 50 minutes gave the highest pyrolytic oil yield of 4.52%. Based on the model developed using RSM, it was suggested that the best operating condition for microwave pyrolysis of APS process was 620 W with 50 minutes with predicted yield of 4.27%. The experiment of APS microwave pyrolysis at optimum conditions is carried out resulting 4.69% pyrolytic oil yield which slightly higher than the predicted. Suggested model is valid to be used to predict pyrolytic oil yield from microwave pyrolysis of APS since it has value of Prob>F below than 0.05 and high value of R2 (0.9243) and F-value (36.6125). The behavior of optimized pyrolytic oil production can be represented by second-order kinetic model because it has high value of R2 and low value of RMSE as compared to first-order kinetic model regardless of application of AC. The optimized oil has the calorific value of 39.04 kJ/kg, viscosity of 4.14 cSt and density of 836 kg/m3. The physical properties lie within the range of commercialized liquid fuel. Aliphatic and monoaromatic compounds traced in pyrolytic oil obtained from this study were high. Meanwhile, polycyclic aromatic hydrocarbon (PAH) and nitrogenated compounds were reduced significantly and oxygenated compound was slightly reduced as compared to the process with the absence of AC. Therefore, this study has not only contributed to future reduction or eliminating automotive paint sludge waste, but also generates new alternative fuel.
format Thesis
author Syed Abdul Rahman, Syarifah Nor Faizah
spellingShingle Syed Abdul Rahman, Syarifah Nor Faizah
Pyrolytic oil from automotive paint sludge via activated carbon assisted microwave pyrolysis / Syarifah Nor Faizah Syed Abdul Rahman
author_facet Syed Abdul Rahman, Syarifah Nor Faizah
author_sort Syed Abdul Rahman, Syarifah Nor Faizah
title Pyrolytic oil from automotive paint sludge via activated carbon assisted microwave pyrolysis / Syarifah Nor Faizah Syed Abdul Rahman
title_short Pyrolytic oil from automotive paint sludge via activated carbon assisted microwave pyrolysis / Syarifah Nor Faizah Syed Abdul Rahman
title_full Pyrolytic oil from automotive paint sludge via activated carbon assisted microwave pyrolysis / Syarifah Nor Faizah Syed Abdul Rahman
title_fullStr Pyrolytic oil from automotive paint sludge via activated carbon assisted microwave pyrolysis / Syarifah Nor Faizah Syed Abdul Rahman
title_full_unstemmed Pyrolytic oil from automotive paint sludge via activated carbon assisted microwave pyrolysis / Syarifah Nor Faizah Syed Abdul Rahman
title_sort pyrolytic oil from automotive paint sludge via activated carbon assisted microwave pyrolysis / syarifah nor faizah syed abdul rahman
publishDate 2019
url https://ir.uitm.edu.my/id/eprint/83295/1/83295.pdf
https://ir.uitm.edu.my/id/eprint/83295/
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score 13.211869