Storage of Food Waste: Variations of Physical–Chemical Characteristics and Consequences on Biomethane Potential

Degueurce, Axelle; Picard, S.; Peu, Pascal; Trémier, Anne

doi:10.1007/s12649-018-00570-0

Cited by 21 publications

(11 citation statements)

References 29 publications

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“…During storage at the restaurant or supermarket site, the food waste undergoes rapid hydrolysis and acidification due to microbial activity as a batch-fermentation system under anaerobic conditions. 13 This will have a positive effect on subsequent anaerobic digester treatment. 14 The storage tank is periodically filled with food-waste slurry during the one-to two-week storage period.…”

Section: ■ Introductionmentioning

confidence: 99%

Systematic Analysis of Factors That Affect Food-Waste Storage: Toward Maximizing Lactate Accumulation for Resource Recovery

Daly

Usack

Harroff

et al. 2020

ACS Sustainable Chem. Eng.

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In the U.S., several states have attempted to mitigate greenhouse-gas emissions by banning food wastes from landfills. As a result, U.S.-based companies are now providing decentralized food-waste management systems for supermarkets and restaurants, which include storage as a slurry. It is unclear, however, which storage conditions (factors) would affect the spontaneous microbial activity, resulting in a different fermentation product spectra, and how this would further affect post-treatment. Here, we performed two experiments to mimic: (1) storage and (2) subsequent anaerobic digestion. For the food-waste storage system, we designed a mixed-level fractional factorial analysis with 12 experimental combinations, including separating food waste into: carbohydrate-rich, lipid-rich, and protein-rich food waste. We found that all factors that we tested affected the fermentation outcome. We observed that relatively low pH levels of 3–4, which were achieved due to rapid lactate accumulation by microbial activity during storage, coincided with greater lactate production and a maximum chemical oxygen demand (COD) selectivity of 90%. Food-waste storage followed classical ensilage dynamics with homofermentation to lactate in combination with low pH preventing the subsequent breakdown of lacate into other carboxylic acids and hydrogen gas. The mechanistic understanding provides an opportunity to optimize lactate production, which is ideal for subsequent methane or chemical production.

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Section: ■ Introductionmentioning

confidence: 99%

Systematic Analysis of Factors That Affect Food-Waste Storage: Toward Maximizing Lactate Accumulation for Resource Recovery

Daly

Usack

Harroff

et al. 2020

ACS Sustainable Chem. Eng.

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“…performed a storage pretreatment under anoxic conditions, concluding that the best results in terms of stability were found with pretreatement periods of 5 and 7 days, with the methane yield ranging from 397 to 484 NmL CH 4 g −1 TVS added . This fact indicated that a storage time of around 1 week is an appropriate pretreatment before AD 33 …”

Section: Resultsmentioning

confidence: 97%

“…Additionally, at the end of the 7 days, an amount of leachate of 89 ± 9 mL was obtained, representing 22.4%, of the average mass sample of 394 ± 3 g. The generation of leachate for 4 and 7 days was similar, although there was an increase of around 15% from 4 days to 7 days. Degueurce et al 33 evaluated a storage pretreatment for OFMSW and observed that the conversion from solid to leachate ranged from 15 to 27% for different substrates after 2 weeks of storage, and the largest degraded portion (about 15%) occurred in the first 3 days. In addition, during a period of 5-8 days of storage and considering substrates of different compositions, the percentage of solid matter converted to leachate was 17.5%, 34 corroborating the present study.…”

Section: Resultsmentioning

confidence: 99%

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Determination of the biochemical methane potential of food waste after aerobic storage and aeration pretreatment

Oliveira

Léo

Forster‐Carneiro³

et al. 2022

Biofuels Bioprod Bioref

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Food waste represents a relevant fraction of municipal solid organic waste, and anaerobic digestion can be an eco-friendly alternative for sustainable management in a circular economy framework. One of the challenges to the implementation of anaerobic digestion is the availability of easily degradable compounds in the substrate, which can be solved by the application of pretreatment to increase methane production. In this study, the influence of aerobic storage time and forced continuous aeration pretreatment on the biochemical methane potential of food waste was evaluated. The results demonstrate an increase in the methane production concerning the total volatile solids (TVS) of food waste stored for 7 days (425 NmL CH 4 g −1 TVS) compared with fresh samples without pretreatment (375 NmL CH 4 g −1 TVS). The adoption of forced and continuous aeration pretreatment on food waste for 4 days produced 456 NmL CH 4 g −1 TVS for the leachate, 1.22-fold higher than that for the food waste without storage. In conclusion, the application of aeration pretreatment previous to anaerobic digestion can be an alternative to increase the methane potential from food waste.

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“…A pre-digester tank to store the feedstock collected and to feed the AD is required to buffer the irregularly collected volume of biowaste; however, the storage duration that may affect the AD performance and odor should be controlled [113]. Gonzalez et al [112] reported that a temperature increase of the feed to process conditions requires a significant amount of thermal energy, which strongly affects the efficiency of the process when operated at a low organic load.…”

Section: Observed Co-benefits and Limitationsmentioning

confidence: 99%

Nature-Based Units as Building Blocks for Resource Recovery Systems in Cities

Hullebusch

Bani

Carvalho³

et al. 2021

Water

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Cities are producers of high quantities of secondary liquid and solid streams that are still poorly utilized within urban systems. In order to tackle this issue, there has been an ever-growing push for more efficient resource management and waste prevention in urban areas, following the concept of a circular economy. This review paper provides a characterization of urban solid and liquid resource flows (including water, nutrients, metals, potential energy, and organics), which pass through selected nature-based solutions (NBS) and supporting units (SU), expanding on that characterization through the study of existing cases. In particular, this paper presents the currently implemented NBS units for resource recovery, the applicable solid and liquid urban waste streams and the SU dedicated to increasing the quality and minimizing hazards of specific streams at the source level (e.g., concentrated fertilizers, disinfected recovered products). The recovery efficiency of systems, where NBS and SU are combined, operated at a micro- or meso-scale and applied at technology readiness levels higher than 5, is reviewed. The importance of collection and transport infrastructure, treatment and recovery technology, and (urban) agricultural or urban green reuse on the quantity and quality of input and output materials are discussed, also regarding the current main circularity and application challenges.

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Storage of Food Waste: Variations of Physical–Chemical Characteristics and Consequences on Biomethane Potential

Cited by 21 publications

References 29 publications

Systematic Analysis of Factors That Affect Food-Waste Storage: Toward Maximizing Lactate Accumulation for Resource Recovery

Systematic Analysis of Factors That Affect Food-Waste Storage: Toward Maximizing Lactate Accumulation for Resource Recovery

Determination of the biochemical methane potential of food waste after aerobic storage and aeration pretreatment

Nature-Based Units as Building Blocks for Resource Recovery Systems in Cities

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