Bioenergy Production through Mono and Co-Digestion of Tomato Residues

The agro-industry of tomato generates three types of residues: ripe rotten tomato (unfit for consumption) (RT), green (unripe) tomato (GT), and tomato branches including leaves and stems (TB). These materials are commonly wasted or used as feed for livestock. Energy production through anaerobic dige...

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Bibliographic Details
Published in:Energies (Basel) 2021-09, Vol.14 (17), p.5563
Main Authors: Almeida, PatrĂ­cia V., Rodrigues, Rafaela P., Teixeira, Leonor M., Santos, Andreia F., Martins, Rui C., Quina, Margarida J.
Format: Article
Language:English
Subjects:
agro-industrial residues
Alternative energy sources
Anaerobic conditions
Anaerobic digestion
biochemical methane potential
Biodegradation
Biogas
Biomass
co-digestion
Design of experiments
Food
Fractional factorial design
Inoculum
Livestock
Livestock feeds
Methane
Microorganisms
Moisture content
Nutrients
Ratios
Renewable resources
Residues
Sludge
Substrates
Systems stability
Tomatoes
Volatile solids
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Summary:The agro-industry of tomato generates three types of residues: ripe rotten tomato (unfit for consumption) (RT), green (unripe) tomato (GT), and tomato branches including leaves and stems (TB). These materials are commonly wasted or used as feed for livestock. Energy production through anaerobic digestion is an alternative way to manage and simultaneously valorise these materials. Initially, the operating conditions of mono anaerobic digestion were investigated using RT. Thus, a design of experiments based on a two-level fractional factorial design with resolution V was performed to determine the factors that affect biochemical methane potential (BMP). The substrate to inoculum ratio (SIR), total volatile solids concentration (VSt), working volume (WV), presence of nutrients (Nu), and the pre-incubation of the inoculum (Inc) were investigated. The results showed that SIR is the most important factor. The maximum BMP for RT was 297 NmLCH4/gVS with SIR = 0.5; tVS = 20 g/L; WV = 20%; no pre-incubation and the presence of nutrients. Using these optimum operating conditions, co-digestion was investigated through a mixture design approach. The substrates RT and GT presented similar BMP values, whereas TB led to a significantly lower BMP. Indeed, when high concentrations of TB were used, a significant decrease in methane production was observed. Nonetheless, the highest BMP was achieved with a mixture of 63% RT + 20% GT + 17% TB, with a production of 324 NmLCH4/gVS, corresponding to a synergetic co-digestion performance index of about 1.20. In general, although the substrate RT generates the highest BMP, the mixture with GT did not impair the methane yield. Overall, the co-digestion of tomato residues must be conducted with SIR close to 0.5 and the content of tomato branches in the reaction mixture should be kept low (up to 20%).
ISSN:1996-1073
1996-1073
DOI:10.3390/en14175563