Microwave Activated Carbonized Coconut Shell (MACCS) was used to recover urea from human urine. Batch adsorption studies were conducted to evaluate the effect of initial adsorbate concentration (25%-100%), contact time, carbon loading (1-3 g) and shaking speed (150-200 rpm) on the removal of urea at 30 C. Microwave activation was performed at 180 W (microwave output power) for 10 min. The sorption data were fitted to Langmuir, Freundlich, Tempkin, Flory-Huggins and Dubinin-Radushkevich isotherm models. Results showed that the maximum monolayer adsorption capacity of the MACCS powder was 256.41 mg g-1. The Flory-Huggins model was found to best describe the urea uptake process since it demonstrated the minimum deviations from the experimental data. The kinetic data was fitted to pseudo-first-order, pseudo-second-order and intra-particle diffusion models, and was found to follow closely the pseudo-first order kinetic model. Based on the Central Composite Rotary Design, a five factor interaction model and a quadratic model were respectively developed to correlate the adsorption variables to the adsorption capacity. Field studies were conducted to determine the percentage biomass increase and relative agronomic effectiveness for soil treated with the urea adsorbed MACCS powder. Microwave activated carbonized coconut shell was shown to be a promising adsorbent for recovery and removal of urea from human urine solutions. © 2013 Elsevier Ltd.

Mahesh Ganesapillai

Department of Chemical Engineering

School of Chemical Engineering

Vellore Campus

Simha P

Gugalia A.

Vellore Institute of Technology (VIT) is a private university located in&nbsp;Tamil Nadu, India. Founded in 1984, as Vellore Engineering College, the institution offers 20 undergraduate, 34 postgraduate, four integrated and four research programs. It has campuses in Vellore, Amravati, Bhopal and Chennai.

VIT is one of the top ranked private universities in India according to NIRF, THE and QS Rankings.&nbsp;Govt. of India has recognized&nbsp;VIT, Vellore as an&nbsp;Institution of Eminence. This has allowed VIT to take independent quality initiatives and move up in world ranking.

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VIT University

Journal of Environmental Chemical Engineering

The use of coal fly ash for nutrient recovery in wastewater treatment offers a potential win–win scenario as it simultaneously utilizes and re-channels two wastes – coal fly ash and wastewater. This study investigated the adsorptive recovery of urea from synthetic urine using fly ash. Equilibrium experiments revealed that 1.5 g ash loading, initial urea concentration of 13.5 g L−1, urine pH = 6.0, sorption temperature = 30 °C and 150 rpm shaker speed were the optimal process parameters and maximum adsorption capacity was 410 mg g−1. Proof of concept to the use of synthetic urine was conducted by performing adsorption with real human urine which validated the experimental findings. Comparative analysis and non–linear optimization of nine isotherm models through comprehensive error analysis revealed that Flory–Huggins and Redlich–Peterson equations best described the adsorption. Process thermodynamics suggested that Van der Waal's and electrostatic interactions occur between urea molecules and the surface of fly ash particles; besides, the sorption was found to be exothermic, spontaneous and physical in nature. Kinetic studies pointed toward a pseudo–second–order kinetic fit with contributions from intra–particle diffusion. Further, the rate of mass transfer was seen to be controlled and limited by film diffusion of urea which featured stronger than its pore diffusion. To design a multistage batch adsorber, a mathematical model unique to the sorption system was derived that minimized the total amount of fly ash required for 90% removal of urea from different volumes of influent synthetic urine solutions. © 2016 The Authors

Fulltext

Arabian Journal of Chemistry

Coal fly ash for the recovery of nitrogenous compounds from wastewater: Parametric considerations and system design

Preliminary studies were performed to demonstrate a 'value from waste' concept for recovering polyphenols from waste Tamarindus indica L. by solvent extraction assisted by microwaves and/or ultrasound. To aid formulation of process guidelines, the influence of precursor size, microwave power, ultrasonication intensity and time were investigated. It was found that extract from tamarind shells contained (-)-epicatechin although the seed coat allowed for higher extraction. An optimum extract yield of 62.35 mg and 60.45 mg (per 100 g of dry solid) were obtained for microwave (180 W) and ultrasonication (intensity: 40%) pre-treatment of tamarind seeds of 0.2 mm size using ethanol. © 2017 Elsevier Ltd.

Materials Today: Proceedings

Preliminary isolation, recovery and characterization of polyphenols from waste Tamarindus indica L.

Microwave pretreatment is a promising and unsophisticated technique for energy recovery in solid waste management. The present investigation was focused on microwave activated carbonization of mixed solid waste (MSW). The effect of process parameters such as size of particles, temperature and duration of carbonization, microwave output power for pretreatment, irradiation time and amount of additives added during microwave heating were studied. The most important factors that influenced MW drying (pre-treatment) were found to be the sample mass and the Microwave output power. Microwave induced carbonization not only overcomes the disadvantages of conventional heating method such as low heat transfer rate but also improves the quality of final carbonization products. © 2017 Elsevier Ltd.

Preparation of Activated Carbon from Municipal Organic Solid Wastes

Resource-Efficient Technologies

Deep-desulfurization of the petroleum diesel using the heterogeneous carboxyl functionalized poly-ionic liquid

In order to sustain food production in a resource-scarce scenario it is vital that maximum utility is derived from available reserves while simultaneously promoting their recycling. Further, substantial value can be sourced if approaches are devised that utilize resources that were erstwhile considered wastes. To look towards alternative fertilization techniques, this study suggests a novel fertilizer combination of two waste products: low-grade Rock Phosphate (RP) tailing and human urine. It is demonstrated that the combined use of urine (nitrogen) and low-grade RP (phosphorous) can indeed act as a substitute to synthetic inorganic fertilizers. Crop trials were carried out for Cicer arietinum using RP enriched urine at various application rates on a red loamy soil (pH of 8.11). Observations made from plant growth response indicated that direct application of this fertilizer combination resulted in performance equivalent to mineral fertilizer Di-Ammonium Phosphate added in the same ratio. The use of RP enriched urine thus holds a lot of promise for simultaneous waste minimization, waste utilization, and improved resource-use efficiency. © 2016 The Institution of Chemical Engineers.

Sustainable Production and Consumption

Low-grade rock phosphate enriched human urine as novel fertilizer for sustaining and improving agricultural productivity of Cicer arietinum

Applied Energy

Operating condition optimization of corncob hydrothermal conversion for bio-oil production

Desalination

Application of modified zeolite for ammonium removal from drinking water

Microporous and Mesoporous Materials

Adsorption of ammonium from an aqueous solution by fly ash and sepiolite: Isotherm, kinetic and thermodynamic analysis

Resources, Conservation and Recycling

Human urine as a source of alternative natural fertilizer in agriculture: A flight of fancy or an achievable reality

Bioresource Technology

Preparation of high surface area activated carbon from coconut shells using microwave heating

Recovering urea from human urine by bio-sorption onto Microwave Activated Carbonized Coconut Shells: Equilibrium, kinetics, optimization and field studies

Journal	Data powered by TypesetJournal of Environmental Chemical Engineering
Publisher	Data powered by TypesetElsevier BV
ISSN	2213-3437
Open Access	0