Valorisation of the organic fraction of municipal solid waste

Medina-Salas, Lorena De; Castillo-González, Eduardo; Giraldi-Díaz, Mario Rafael; Jamed-Boza, Luis Omar

doi:10.1177/0734242x18812651

Cited by 26 publications

(15 citation statements)

References 39 publications

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“…Begum et al (2018) facilitated high-rate co-digestion of mixed organic wastes and reported positive ramification on the biogas yield. A techno-economic evaluation of pilot AD in continuous mode would be interesting in order to assess other factors than the mixing ratio for full-scale applications (Achinas and Euverink, 2019; Baccioli et al, 2019; Benato and Macor, 2019; Carlini et al, 2017; De Medina-Salas et al, 2019). In addition, we recommend an in-depth analysis of microbiome heterogeneity to assess the activity discrepancies between microbial communities.…”

Section: Resultsmentioning

confidence: 99%

Elevated biogas production from the anaerobic co-digestion of farmhouse waste: Insight into the process performance and kinetics

Achinas

Euverink

2019

Waste Manag Res

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The biodegradable portion of solid waste generated in farmhouses can be treated for energy recovery with small portable biogas plants. This action can be done across the Netherlands and all around the planet. This study aims to appraise the performance of anaerobic digestion of different wastes (cow manure, food waste and garden waste) obtained from a regional farmhouse. Batch reactors were established under mesophilic conditions in order to investigate the impact of ternary mixtures on the anaerobic digestion process performance. Different mixing ratios were set in the batch tests. The upshots from the experiments connoted that ternary digestion with cow manure:food waste:garden waste mixing ratio of 40:50:10 yielded higher biogas amount. The kinetics’ results showed quite good congruence with the experimental study. The results from the kinetic analysis appeared to be in line with the experimental one.

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Section: Resultsmentioning

confidence: 99%

Elevated biogas production from the anaerobic co-digestion of farmhouse waste: Insight into the process performance and kinetics

Achinas

Euverink

2019

Waste Manag Res

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“…A tiny portion of bio-waste is burned without recovering the abundance of valuable nutrients, and the remainder is landfilled [ 24 ]. The amount of municipal solid trash generated worldwide is estimated to be 1.3 billion Mg/year, and it is anticipated to grow in the coming years [ 25 ]. A significant portion of municipal waste, which includes food waste and green & garden waste (leaves, grass), is organic waste.…”

Section: Complexity Of the Soil Systemmentioning

confidence: 99%

Production of a Rich Fertilizer Base for Plants from Waste Organic Residues by Microbial Formulation Technology

Vurukonda,

Fotopoulos,

Saeid

2024

Microorganisms

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This review explores different methods of sustainably introducing nutrients from agro-industrial waste into the soil. The focus is on sustainable agriculture and how the soil system can be modified by introducing secondary raw materials and beneficial microorganisms. Soil is a nexus between plants and microorganisms that must be balanced. The article emphasizes the importance of maintaining the microbiological balance when supplying nutrients. This review is focused on the possible techniques involved in the production of biofertilizers and their mode of application into the soil system and on plants. We addressed several advantages concerning the use of beneficial microorganisms in waste management by microbial formulation techniques. Not only the advantages but several limitations and challenges were also discussed in regard to the large scale production of microbial products. Therefore, the proper treatment of industrial waste is essential so that we can preserve the environment and human safety and also achieve sustainable agriculture.

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“…Organic solid waste heat treatment technology mainly includes incineration technology and pyrolysis technology. Incineration is an organic solid waste heat treatment technology that burns organic solid waste directly as fuel in the boiler or is mixed with coal/biomass and then sent to the boiler for combustion, so that the combustible components in the organic solid waste undergo rapid oxidation reaction and release energy [10][11]. Although incineration technology can quickly reduce and recycle domestic waste, the inorganic components in organic solid waste are converted into incineration bottom slag and fly ash after incineration, forming environmentally hazardous waste.…”

Section: Thermal Treatment Technology Of Organic Solid Wastementioning

confidence: 99%

Clean Utilization of Organic Solid Waste Based on Pyrolysis Technology

2022

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Pyrolysis technology can convert organic solid waste into gas, liquid and solid three-state products, providing a variety of high-value utilization methods. High oxygen content and component complexity limit the high-value utilization of organic solid waste pyrolysis oil, and conventional catalysts will be deactivated due to carbon deposition during the catalytic upgrading of pyrolysis oil. The good fluidity and heat and mass transfer properties of the alkali metal molten salt can increase the effective contact area between the alkali metal cation and the reactant, and improve the reaction rate. At the same time, the alkali metal cation has a catalytic effect and can alleviate carbon deposition. The purpose of this paper is to analyze the potential of organic solid waste energy and clean utilization based on pyrolysis technology. In the experiment, salt catalytic heat treatment technology is used to convert organic solid waste pyrolysis oil model compound molten salt heat. The experimental results show that the introduction of molten salt reduces gas production and realizes clean energy.

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Valorisation of the organic fraction of municipal solid waste

Cited by 26 publications

References 39 publications

Elevated biogas production from the anaerobic co-digestion of farmhouse waste: Insight into the process performance and kinetics

Elevated biogas production from the anaerobic co-digestion of farmhouse waste: Insight into the process performance and kinetics

Production of a Rich Fertilizer Base for Plants from Waste Organic Residues by Microbial Formulation Technology

Clean Utilization of Organic Solid Waste Based on Pyrolysis Technology

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