Abstract
Optimization of factors affecting biohydrogen production from the codigestion of crude glycerol and microalgal biomass by anaerobic sludge consortium was conducted. The experiments were designed by a response surface methodology with central composite design. The factors affecting the production of hydrogen were the concentrations of crude glycerol, microalgal biomass, and inoculum. The maximum hydrogen production (655.1 mL-H2/L) was achieved with 13.83 g/L crude glycerol, 23.1 g-VS/L microalgal biomass, and 10.3% (v/v) inoculum. The hydrogenic effluents obtained under low, high, and optimal conditions were further used as substrates for methane production. Methane production rates and methane yield of 868.7 mL-CH4/L and 2.95 mL-CH4/L-h were attained with the effluent produced under optimum conditions. The use of crude glycerol and microalgal biomass as cosubstrates had an antagonistic effect on biohydrogen production and a synergistic effect on methane fermentation. The two-stage process provided a more attractive solution, with a total energy of 1.27 kJ/g-VSadded, than the one-stage process.
Highlights
Increasing energy insecurity and environmental pollution caused by the overconsumption of fossil fuels is an emerging problem that is predicted to become very serious in the future [1]
The lowest hydrogen production was found at crude glycerol, inoculum, and algal biomass concentrations of 40 glycerol concentration (g/L), 25% (v/v), and 4.62 g-volatile solid (VS)/L, respectively (Run 1)
The results suggested that appropriate levels of crude glycerol, inoculum, and algal biomass could improve the microbial community, which enhanced hydrogen production and hydrogen production rate (HPR)
Summary
Increasing energy insecurity and environmental pollution caused by the overconsumption of fossil fuels is an emerging problem that is predicted to become very serious in the future [1]. Renewable energy sources such as wind, bioenergy (hydrogen and methane), and solar energy can be used to substitute fossil fuels, at least partially [1,2,3,4]. The biohydrogen can be produced via dark fermentation and photo fermentation. Owing to its lower energy consumption and a greater number of available feedstocks, dark fermentation has advantages over photo fermentation [7]
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