Abstract
Man-made organic waste leads to the rapid proliferation of pollution around the globe. Effective bio-waste management can help to reduce the adverse effects of organic waste while contributing to the circular economy at the same time. The toxic oily-biological sludge generated from oil refineries’ wastewater treatment plants is a potential source for biogas energy recovery via anaerobic digestion. However, the oily-biological sludge’s carbon/nitrogen (C/N) ratio is lower than the ideal 20–30 ratio required by anaerobic digestion technology for biogas production. Sugarcane bagasse can be digested as a high C/N co-substrate while the oily-biological sludge acts as a substrate and inoculum to improve biogas production. In this study, the best C/N with co-substrate volatile solids (VS)/inoculum VS ratios for the co-digestion process of mixtures were determined empirically through batch experiments at temperatures of 35–37 °C, pH (6–8) and 60 rpm mixing. The raw materials were pre-treated mechanically and thermo-chemically to further enhance the digestibility. The best condition for the sugarcane bagasse delignification process was 1% (w/v) sodium hydroxide, 1:10 solid-liquid ratio, at 100 °C, and 150 rpm for 1 h. The results from a 33-day batch anaerobic digestion experiment indicate that the production of biogas and methane yield were concurrent with the increasing C/N and co-substrate VS/inoculum VS ratios. The total biogas yields from C/N 20.0 with co-substrate VS/inoculum VS 0.06 and C/N 30.0 with co-substrate VS/inoculum VS 0.18 ratios were 2777.0 and 9268.0 mL, respectively, including a methane yield of 980.0 and 3009.3 mL, respectively. The biogas and methane yield from C/N 30.0 were higher than the biogas and methane yields from C/N 20.0 by 70.04 and 67.44%, respectively. The highest biogas and methane yields corresponded with the highest C/N with co-substrate VS/inoculum VS ratios (30.0 and 0.18), being 200.6 mL/g VSremoved and 65.1 mL CH4/g VSremoved, respectively.
Highlights
Environmental pollution due to rapid waste generation and energy insecurity has become a global challenge in recent years
Non-sustainable organic waste generated from industrial activities, such as biological sludge generated from industrial wastewater effluent treatment systems, can contribute together with sustainable organic waste generated from biomass to energy recovery to reduce environmental pollution and contribute to a gradual transition from non-renewable to renewable energy
The results indicate that the cumulative methane yield from the reactor with 21.1 C/N is higher than cumulative biogas yield from the reactor with 20 C/N by 6.78%
Summary
Environmental pollution due to rapid waste generation and energy insecurity has become a global challenge in recent years. It is estimated that globally, around one billion tonnes of agricultural waste are generated annually, and 80% of this waste is organic [5,6]. This organic waste is composed of biodegradable and non-biodegradable portions. Non-sustainable organic waste generated from industrial activities, such as biological sludge generated from industrial wastewater effluent treatment systems, can contribute together with sustainable organic waste generated from biomass to energy recovery to reduce environmental pollution and contribute to a gradual transition from non-renewable to renewable energy
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