Liquid fertilizer products from anaerobic digestion of food waste: mass, nutrient and energy balance of four digestate liquid treatment systems

Tampio, Elina; Marttinen, Sanna; Rintala, Jukka

doi:10.1016/j.jclepro.2016.03.127

Cited by 165 publications

(77 citation statements)

References 46 publications

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“…This trend was recorded for elements such as nitrogen, phosphorus, potassium, magnesium, manganese, iron, zinc, aluminium and copper. Therefore, these digestates can be said to be rich in nutrient and has great potentials to increase both the microbial and nutrient status of soil when applied through the rhizosphere as fertilizers especially in nutrient-depleted soils (Tampio et al, 2016a). Plant growth and general wellbeing could also be enhanced via the use of such digestate as biofertiliser especially in Sub-Saharan Africa and other regions faced with soil nutrient depletion and erosion of top soil.…”

Section: Discussionmentioning

confidence: 99%

“…Anaerobic digestion is a biochemical process that is widely used for the treatment and energy recovery from many kinds of biomasses, especially agricultural products and agro-industrial wastes (He et al, 2016;Othman et al, 2017). It is an efficient method which employs diverse microbial groups for the conversion of biomasses and wastes into biogas (which serves to mitigate the energy challenges currently faced in several parts of the world) (Ismail and Talib, 2016;Chuichulcherm et al, 2017) and digestate biofertilizer which can be used to improve soil nutrients and plant growth when applied either in solid or liquid form (Shane and Gheewala, 2017;Tampio et al, 2016a).…”

Section: Introductionmentioning

confidence: 99%

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Cleaner energy for cleaner production: Modeling and optimization of biogas generation from Carica papayas (Pawpaw) fruit peels

Dahunsi

Oranusi

Efeovbokhan

2017

Journal of Cleaner Production

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In this study, the potentials of pretreated and untreated Carica papayas fruit peels for biogas generation was evaluated alongside its process optimization after employing the combination of mechanical and thermo-alkaline pretreatment methods. The peel was anaerobically digested using a consortium of microorganisms from cattle rumen content as inoculum. A batch system designed by the Central Composite Design (CCD) was employed. The physicochemical and microbial characteristics of the substrates and inoculum as well as the constituent of the generated biogas were evaluated using standard methods and results showed elevated levels of most elements after anaerobic digestion. The most feasible experimental biogas yields were 0.1839 m 3 /kg VS and 0.1361 m 3 /kg VS for the pretreated and untreated experiments respectively. Microbiologically, members of the genus Clostridium dominated the microbial flora and their succession patterns were affected by temperature and pH. The methane and carbon dioxide content of biogas from both experiments were 61.5± 2.5%; 24± 1% and 52 ± 2%; 25± 1.5% respectively. The Response Surface Methodology (RSM) and the Artificial Neural Networks (ANNs) were employed in data optimization. Based on the optimized values, the predicted biogas yield for RSM was 0.1895 m 3 /kg VS and 0.1839 m 3 /kg VS for ANNs in the pretreated experiment. For the experiment without pretreatment, the RSM predicted yield was 0.1361 m 3 /kg VS while that of ANNs was 0.1392 m 3 / kg VS. In all, there was a 26.5% increase in predicted biogas yield in the pretreated experiment over the untreated. Further usage of pawpaw peels for biofuels generation is advocated.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Cleaner energy for cleaner production: Modeling and optimization of biogas generation from Carica papayas (Pawpaw) fruit peels

Dahunsi

Oranusi

Efeovbokhan

2017

Journal of Cleaner Production

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“…Therefore, a feasible utilization method ought to be adopted to enrich nutrient concentrations and reduce the volume of digested slurry so that the pre-treated digested slurry could be easily transported and applied as a fertilizer in regions of high demand [9]. This nutrient enrichment and mitigation strategy might also help reduce the environmental pollution risk of nutrient run-off and leaching by the surplus application of digested slurry [10].…”

Section: Introductionmentioning

confidence: 99%

Effect of flocculation pre-treatment on membrane nutrient recovery of digested chicken slurry: Mitigating suspended solids and retaining nutrients

Luo

Lyu

Muhmood

et al. 2018

Chemical Engineering Journal

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Use of membrane filtration is attracting increasing attention for nutrient recovery from anaerobically digested slurry. However, the challenge is to reduce membrane fouling by effective solids mitigation, while maintaining valuable nutrients. In this study, the effects of several flocculation pre-treatments using polyaluminium chloride, iron chloride, and flocculant aid at various dosages were investigated. The results showed significant improvement in membrane flux from 0.8 to 27.6 mL/m 2 /s due to solid 2 migration (up to 75% removal). Significant loss of PO4 3− -P (99%) and humic acids (40-80 %) was observed. However, the content of NH4 + -N and indoleacetic acids was largely maintained in the treated slurry. Moreover, toxic metals were significantly removed through flocculation, making the final product risk-free of heavy metals for agricultural application.

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“…The physical‐chemical methods include struvite formation , ammonia stripping , evaporation , membrane separation , adsorption processes with activated carbons, ion exchange resins, zeolites , and biochar , as well as various combination of these processes. In particular, Tampio et al have shown that the system based on evaporation combined with reverse osmosis is an efficient nutrient technology for the production of transportable fertilizer products for agricultural application due to the highest concentration of nutrients, nutrient availability, the low mass of the product and low energy consumption of the treatment. Stripping is an efficient technology for nitrogen recovery; however, the high mass of the residue containing the remaining K and P should be further managed sustainably.…”

Section: Introductionmentioning

confidence: 99%

Synergy between anaerobic digestion and a post‐treatment based on Thermophilic Aerobic Membrane Reactor (TAMR)

Collivignarelli

Bertanza

Abbà

et al. 2017

Env Prog and Sustain Energy

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Wet Oxidation (WO) of sewage sludge is a chemical\ud oxidation of sludge at high temperatures and pressures by\ud means of an oxygen-containing gas. The liquid stream originated\ud byWO is easily biodegradable, and therefore, the recirculation\ud to the biological Waste Water Treatment Plant\ud (WWTP) may be a feasible solution. However, the WO effluent\ud has a residual organic and nitrogen content so that its\ud treatment may be required when the receiving WWTP has\ud no surplus treatment capacity left. The aim of this research\ud was the assessment of the anaerobic treatability of the WO\ud liquid residue, in order to reduce the organic load to be\ud recirculated to the WWTP, simultaneously promoting energy\ud recovery. For this purpose, the liquid residue obtained during\ud full scale WO tests on two different types of sludge was\ud submitted to anaerobic digestion in a continuous flow pilot\ud reactor (V=5 L). Furthermore, batch tests were carried out in\ud order to evaluate possible inhibition factors. Experimental\ud results showed that, after the start-up/acclimation period\ud (~130 days), Chemical Oxygen Demand (COD) removal\ud efficiency was stably around 60% for about 120 days, despite\ud the change in operating conditions. In the last phase of the\ud experimental activity, COD removal reached 70 % under the\ud following treatment conditions: Hydraulic Retention Time\ud (HRT)=20 days, Volumetric Organic Loading Rate\ud (VOLR)=0.868 kg COD/m3/day, Organic Loading Rate per\ud Volatile Suspended Solids (OLRvss)=0.078 kg COD/kg VSS/\ud day, temperature (T)=36.5 °C, pH=8. Energy balance calculation\ud demonstrated anaerobic treatment sustainability

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Liquid fertilizer products from anaerobic digestion of food waste: mass, nutrient and energy balance of four digestate liquid treatment systems

Cited by 165 publications

References 46 publications

Cleaner energy for cleaner production: Modeling and optimization of biogas generation from Carica papayas (Pawpaw) fruit peels

Cleaner energy for cleaner production: Modeling and optimization of biogas generation from Carica papayas (Pawpaw) fruit peels

Effect of flocculation pre-treatment on membrane nutrient recovery of digested chicken slurry: Mitigating suspended solids and retaining nutrients

Synergy between anaerobic digestion and a post‐treatment based on Thermophilic Aerobic Membrane Reactor (TAMR)

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