High-rate biological hydrogen and methane production from pome in a two-stage anaerobic hybrid reactor / Bidattul Syirat Zainal

This study was divided into three phases, viz. i) batch study, ii) start-up study using upflow anaerobic sludge fixed film (UASFF) bioreactor, and iii) optimization study. UASFF bioreactor is a type of bioreactor configuration similar to the type used by industries for the treatment of wastewaters....

Full description

Saved in:
Bibliographic Details
Main Author: Bidattul Syirat , Zainal
Format: Thesis
Published: 2019
Subjects:
Online Access:http://studentsrepo.um.edu.my/11971/1/Bidattul.pdf
http://studentsrepo.um.edu.my/11971/2/Bidattul_Syirat.pdf
http://studentsrepo.um.edu.my/11971/
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Universiti Malaya
id my.um.stud.11971
record_format eprints
spelling my.um.stud.119712022-01-05T19:43:00Z High-rate biological hydrogen and methane production from pome in a two-stage anaerobic hybrid reactor / Bidattul Syirat Zainal Bidattul Syirat , Zainal TA Engineering (General). Civil engineering (General) TD Environmental technology. Sanitary engineering This study was divided into three phases, viz. i) batch study, ii) start-up study using upflow anaerobic sludge fixed film (UASFF) bioreactor, and iii) optimization study. UASFF bioreactor is a type of bioreactor configuration similar to the type used by industries for the treatment of wastewaters. It is a hybrid system that combines two compartments for providing granular and fixed biomasses in a single bioreactor. In this study, a 2.5 L and 3.5 L of H2-UASFF and CH4-UASFF bioreactor units, respectively, were successfully operated for palm oil mill effluent (POME) treatment. An initial experiment was done to evaluate the nature of POME wastewater by conducting a batch study using a 160-mL serum bottle, under anaerobic condition. A batch study for biohydrogen production was conducted using raw POME and POME sludge as a feed and inoculum respectively. Response Surface Methodology (RSM) was used to design the experiments. Experiments were conducted at different reaction temperatures (30-50°C), inoculum size to substrate ratios (I:S) and reaction times (HRT) (8-24 h). Although the highest COD removal efficiency was 49.09% at 24 h, 50°C and 10:90 (I:S), however, based on the optimization study using RSM, the optimum condition of biohydrogen production was achieved with COD removal efficiency of 21.95% with hydrogen yield of 28.47 mL H2 g-1 COD removed (2.22 mg H2 g-1 COD removed). The I:S ratio was 40:60, with a reaction temperature of 50°C at 8 h of reaction time. The next experiment was done in a two-stage UASFF bioreactor in order to study its performance. A start-up study was conducted to produce biohydrogen and biomethane from POME. During this period of continuous operation, the HRT and temperature were adjusted in order to optimize the condition for biogas production. After 59 days of operation, using 100% raw POME led to a total COD removal of 83.70%, average gas production rates of 5.29 L H2 d-1 (57.11% H2) and 9.60 L CH4 d-1 (94.08% CH4), in H2-UASFF unit and CH4-UASFF unit, respectively. This work concludes that the two-stage UASFF bioreactor operating at a final HRT of 4 h and temperature of 43°C in H2-UASFF unit and 24 h HRT, 43°C in CH4-UASFF unit has taken a period of two months for start-up. The third phase was done in order to find the optimum conditions for two-stage UASFF bioreactor in treating POME. Two variables, i.e. temperature (37-70°C) and HRT (3-9 h) was examined in H2-UASFF unit and the same temperature and dark fermentation effluent was used as a substrate (12 – 20 g CODL-1) in CH4-UASFF unit. At optimum temperature and HRT of 57°C and 7 h, respectively, maximum hydrogen production rate of 10.39 L H2 d-1, hydrogen yield of 0.95 L H2 g-1 CODremoved and 35.88% of COD removal were observed. In CH4-UASFF unit, at 24 h HRT, 76% of total COD removal efficiency was achieved with methane production rate of 15.63 L CH4 d-1, methane yield of 0.803 L CH4 g-1 CODremoved, COD removal efficiency of 66.28%, and 93.31% of CH4 content at optimum temperature and substrate concentration of 54°C and 12 g COD L-1, respectively. These findings proved that the integrated system can enhance biogas production rate, yield and efficiently treating POME wastewater under a short period of time with low substrate concentration and thermophilic condition. 2019-08 Thesis NonPeerReviewed application/pdf http://studentsrepo.um.edu.my/11971/1/Bidattul.pdf application/pdf http://studentsrepo.um.edu.my/11971/2/Bidattul_Syirat.pdf Bidattul Syirat , Zainal (2019) High-rate biological hydrogen and methane production from pome in a two-stage anaerobic hybrid reactor / Bidattul Syirat Zainal. PhD thesis, Universiti Malaya. http://studentsrepo.um.edu.my/11971/
institution Universiti Malaya
building UM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Malaya
content_source UM Student Repository
url_provider http://studentsrepo.um.edu.my/
topic TA Engineering (General). Civil engineering (General)
TD Environmental technology. Sanitary engineering
spellingShingle TA Engineering (General). Civil engineering (General)
TD Environmental technology. Sanitary engineering
Bidattul Syirat , Zainal
High-rate biological hydrogen and methane production from pome in a two-stage anaerobic hybrid reactor / Bidattul Syirat Zainal
description This study was divided into three phases, viz. i) batch study, ii) start-up study using upflow anaerobic sludge fixed film (UASFF) bioreactor, and iii) optimization study. UASFF bioreactor is a type of bioreactor configuration similar to the type used by industries for the treatment of wastewaters. It is a hybrid system that combines two compartments for providing granular and fixed biomasses in a single bioreactor. In this study, a 2.5 L and 3.5 L of H2-UASFF and CH4-UASFF bioreactor units, respectively, were successfully operated for palm oil mill effluent (POME) treatment. An initial experiment was done to evaluate the nature of POME wastewater by conducting a batch study using a 160-mL serum bottle, under anaerobic condition. A batch study for biohydrogen production was conducted using raw POME and POME sludge as a feed and inoculum respectively. Response Surface Methodology (RSM) was used to design the experiments. Experiments were conducted at different reaction temperatures (30-50°C), inoculum size to substrate ratios (I:S) and reaction times (HRT) (8-24 h). Although the highest COD removal efficiency was 49.09% at 24 h, 50°C and 10:90 (I:S), however, based on the optimization study using RSM, the optimum condition of biohydrogen production was achieved with COD removal efficiency of 21.95% with hydrogen yield of 28.47 mL H2 g-1 COD removed (2.22 mg H2 g-1 COD removed). The I:S ratio was 40:60, with a reaction temperature of 50°C at 8 h of reaction time. The next experiment was done in a two-stage UASFF bioreactor in order to study its performance. A start-up study was conducted to produce biohydrogen and biomethane from POME. During this period of continuous operation, the HRT and temperature were adjusted in order to optimize the condition for biogas production. After 59 days of operation, using 100% raw POME led to a total COD removal of 83.70%, average gas production rates of 5.29 L H2 d-1 (57.11% H2) and 9.60 L CH4 d-1 (94.08% CH4), in H2-UASFF unit and CH4-UASFF unit, respectively. This work concludes that the two-stage UASFF bioreactor operating at a final HRT of 4 h and temperature of 43°C in H2-UASFF unit and 24 h HRT, 43°C in CH4-UASFF unit has taken a period of two months for start-up. The third phase was done in order to find the optimum conditions for two-stage UASFF bioreactor in treating POME. Two variables, i.e. temperature (37-70°C) and HRT (3-9 h) was examined in H2-UASFF unit and the same temperature and dark fermentation effluent was used as a substrate (12 – 20 g CODL-1) in CH4-UASFF unit. At optimum temperature and HRT of 57°C and 7 h, respectively, maximum hydrogen production rate of 10.39 L H2 d-1, hydrogen yield of 0.95 L H2 g-1 CODremoved and 35.88% of COD removal were observed. In CH4-UASFF unit, at 24 h HRT, 76% of total COD removal efficiency was achieved with methane production rate of 15.63 L CH4 d-1, methane yield of 0.803 L CH4 g-1 CODremoved, COD removal efficiency of 66.28%, and 93.31% of CH4 content at optimum temperature and substrate concentration of 54°C and 12 g COD L-1, respectively. These findings proved that the integrated system can enhance biogas production rate, yield and efficiently treating POME wastewater under a short period of time with low substrate concentration and thermophilic condition.
format Thesis
author Bidattul Syirat , Zainal
author_facet Bidattul Syirat , Zainal
author_sort Bidattul Syirat , Zainal
title High-rate biological hydrogen and methane production from pome in a two-stage anaerobic hybrid reactor / Bidattul Syirat Zainal
title_short High-rate biological hydrogen and methane production from pome in a two-stage anaerobic hybrid reactor / Bidattul Syirat Zainal
title_full High-rate biological hydrogen and methane production from pome in a two-stage anaerobic hybrid reactor / Bidattul Syirat Zainal
title_fullStr High-rate biological hydrogen and methane production from pome in a two-stage anaerobic hybrid reactor / Bidattul Syirat Zainal
title_full_unstemmed High-rate biological hydrogen and methane production from pome in a two-stage anaerobic hybrid reactor / Bidattul Syirat Zainal
title_sort high-rate biological hydrogen and methane production from pome in a two-stage anaerobic hybrid reactor / bidattul syirat zainal
publishDate 2019
url http://studentsrepo.um.edu.my/11971/1/Bidattul.pdf
http://studentsrepo.um.edu.my/11971/2/Bidattul_Syirat.pdf
http://studentsrepo.um.edu.my/11971/
_version_ 1738506551205822464