A novel approach for nutrients recovery from municipal waste as biofertilizers by combining electrodialytic and gas permeable membrane technologies

Oliveira, V.; Dias-Ferreira, Célia; González-Garcı́a, Isabel; Labrincha, J.A.; Horta, Carmo; García-González, María Cruz

doi:10.1016/j.wasman.2021.02.055

Cited by 25 publications

(13 citation statements)

References 27 publications

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“…Most of the common nitrogen recovery approaches mentioned above have already been applied to recover nutrients from the liquid fraction of digestate. Typical, and most recent, attempts include stripping [92], chemical precipitation [110], adsorption [111], membrane separation [112], evaporation [113], and electrodialysis [114,115]. The comparison among these approaches is summarized in Table 2.…”

Section: Ad Digestate As a Nutrient-rich Sourcementioning

confidence: 99%

From renewable energy to sustainable protein sources: Advancement, challenges, and future roadmaps

Khoshnevisan

et al. 2022

Renewable and Sustainable Energy Reviews

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Section: Ad Digestate As a Nutrient-rich Sourcementioning

confidence: 99%

From renewable energy to sustainable protein sources: Advancement, challenges, and future roadmaps

Khoshnevisan

et al. 2022

Renewable and Sustainable Energy Reviews

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“…It should be noted that ED is the only membrane method that makes it possible to simultaneously obtain high-purity P V and recover N III [ 176 ] from dilute liquid media, as well as to concentrate these substances to the maximum [ 170 , 177 ]. For example, Wang et al [ 178 ] achieved an 18 fold increase in the concentration of NH 4 + recovering it from the liquid component of pig manure by ED.…”

Section: Modern Trends In Nutrients Recoverymentioning

confidence: 99%

“…The energy consumption for this combined process was 111.26 kJ/mol NH4+ , which is much lower than in the case of single HFMC process for ammonia capture. A similar system has also been tested for the processing of urine [ 186 ] and municipal solid waste digestate [ 176 ].…”

Section: Modern Trends In Nutrients Recoverymentioning

confidence: 99%

Recovery of Nutrients from Residual Streams Using Ion-Exchange Membranes: Current State, Bottlenecks, Fundamentals and Innovations

2022

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The review describes the place of membrane methods in solving the problem of the recovery and re-use of biogenic elements (nutrients), primarily trivalent nitrogen NIII and pentavalent phosphorus PV, to provide the sustainable development of mankind. Methods for the recovery of NH4+ − NH3 and phosphates from natural sources and waste products of humans and animals, as well as industrial streams, are classified. Particular attention is paid to the possibilities of using membrane processes for the transition to a circular economy in the field of nutrients. The possibilities of different methods, already developed or under development, are evaluated, primarily those that use ion-exchange membranes. Electromembrane methods take a special place including capacitive deionization and electrodialysis applied for recovery, separation, concentration, and reagent-free pH shift of solutions. This review is distinguished by the fact that it summarizes not only the successes, but also the “bottlenecks” of ion-exchange membrane-based processes. Modern views on the mechanisms of NH4+ − NH3 and phosphate transport in ion-exchange membranes in the presence and in the absence of an electric field are discussed. The innovations to enhance the performance of electromembrane separation processes for phosphate and ammonium recovery are considered.

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“…The micronutrients (Fe, Cu, Zn, Al, Co and Mn) of the biofertilizer were significantly improved with higher nitrogen (1685 mgN/L) and phosphorous (235 mgP/L) content with potassium content unchanged at a 180 °C of thermal treatments [ 123 ]. High purity phosphorous (81%) from waste were recovered by electrodialysis and 74% of nitrogen in the form of nitrate was recovered from waste by gas permeable membrane for production of biofertilization [ 124 ]. The sequential digestion of the two-stage anaerobic process followed by the aerobic process of fruit and vegetable waste mixed with slaughterhouse waste significantly enhanced biofertilizer formations [ 125 ].…”

Section: Food Waste Biorefinery Productsmentioning

confidence: 99%

Food Waste Biorefinery: Pathway towards Circular Bioeconomy

Tsegaye

Jaiswal

2021

Foods

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Food waste biorefineries for the production of biofuels, platform chemicals and other bio-based materials can significantly reduce a huge environmental burden and provide sustainable resources for the production of chemicals and materials. This will significantly contribute to the transition of the linear based economy to a more circular economy. A variety of chemicals, biofuels and materials can be produced from food waste by the integrated biorefinery approach. This enhances the bioeconomy and helps toward the design of more green, ecofriendly, and sustainable methods of material productions that contribute to sustainable development goals. The waste biorefinery is a tool to achieve a value-added product that can provide a better utilization of materials and resources while minimizing and/or eliminating environmental impacts. Recently, food waste biorefineries have gained momentum for the production of biofuels, chemicals, and bio-based materials due to the shifting of regulations and policies towards sustainable development. This review attempts to explore the state of the art of food waste biorefinery and the products associated with it.

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A novel approach for nutrients recovery from municipal waste as biofertilizers by combining electrodialytic and gas permeable membrane technologies

Cited by 25 publications

References 27 publications

From renewable energy to sustainable protein sources: Advancement, challenges, and future roadmaps

From renewable energy to sustainable protein sources: Advancement, challenges, and future roadmaps

Recovery of Nutrients from Residual Streams Using Ion-Exchange Membranes: Current State, Bottlenecks, Fundamentals and Innovations

Food Waste Biorefinery: Pathway towards Circular Bioeconomy

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