Methane recovery from water hyacinth through whole‐cell immobilization technology

The concepts of feed pretreatment, phase separation, and whole‐cell immobilization technology have been incorporated in this investigation for the development of rational and cost‐effective two‐ and three‐stage methane recovery systems from water hyacinth (WH) Analyses of laboratory data reveal that a three‐stage system could be designed with an alkali pretreatment stage [3.6% Na 2 CO 3 + 2.5% Ca(OH) 2 W/W, 24 h HRT] followed by an open acid reactor (2.1 days HRT) and closed immobilized methane reactor (12 h HRT), providing steady‐state COD conversion of 62–65%, TVA conversion of 91–95%, and gas productivity of 4.08–5.36 L/L reactor volume/day with 82% methane. A gas yield of 50 L/kg WH/day (dry wt basis) at 35–37°C is possible with this system. Insulation bricks, with particle size distribution of 500–3000 μm, were used as support material in the reactors at organic loading rate of 20 kg COD/m 3 day. The reactors matured in 15–18 weeks Substantial reduction in retention time for the conversion of volatile acids in immobilized methane reactors prompted further research on the combined immobilized reactor to make possible an additional reduction in the cost of a WH‐based biogas system. Evaluation of laboratory data reveals that a two‐stage system could be designed with an open alkali pretreatment stage and a combined immobilized reactor (12 h HRT), providing steady‐state COD conversion of 53% and gas productivity of 3.1 L/L reactor volume/day with 86% methane. A gas yield of 44 L/kg WH/day (dry wt basis) at 35–37°C could be obtained from this system. Insulation bricks, with 500–1000 μm particle size distribution, was used as support material at an organic loading rate of 15 kg COD/m 3 day. Notwithstanding the fact that the technology in this study has been developed with water hyacinth as substrate, the implicit principles could be extended to any other organic substrate.