Your search keyword '"Andrés Ferrer Gisbert"' showing total 3 results

1. Evaluation of methane production from the anaerobic co-digestion of manure of guinea pig with lignocellulosic Andean residues

Author

Andrés Ferrer Gisbert, Zulay Niño Ruiz, Borja Velázquez-Martí, Juan Gaibor Chávez, and Washington Orlando Meneses Quelal

Subjects

Health, Toxicology and Mutagenesis, Guinea Pigs, Biogas, Amaranth, Co-substrate, Lignin, Methane, chemistry.chemical_compound, Bioreactors, Lignocellulosic waste, Animal science, Anaerobic digestion, Animals, Environmental Chemistry, Anaerobiosis, Sewage, Chemistry, General Medicine, Kinetic model, Biodegradation, Pollution, Manure, Synergy, Biofuels, Digestion, Inoculum, Sewage treatment, Mesophile

Abstract

The objective of this research was to evaluate the anaerobic co-digestion of guinea pig manure (CY) with Andean agricultural residues such as amaranth (AM), quinoa (QU) and wheat (TR) in batch biodigesters under mesophilic conditions (37⁰C) for 40 days. As microbial inoculum, sewage treatment sludge was used in two inoculum/substrate ratios (ISR of 1 and 2). In terms of methane production, the best results occurred in the treatments that contained AM and QU as co-substrate and an ISR of 2. Thus, the highest methane production occurred in the CY:AM biodigesters (25:75) and CY:QU (25:75) with 341.86 mlCH4/g VS and 341.05 mlCH4/g VS, respectively. On the other hand, the results showed that methane production with an ISR of 2 was more feasible for guinea pig waste, where the methane fraction of the biogas generated was in a range of 57 and 69%. The kinetics of methane production from these raw materials was studied using five kinetic models: modified Gompertz, logistic equation, transfer, cone, and Richards. The cone model was the one that best adjusted the experimental values ​​with those observed with an r2 of 0.999 and an RMSE of 1.16 mlCH4/g VS. Finally, the highest biodegradability was obtained in the CY-AM biodigesters (25:75) with 67.92%.

Published

2021

2. Separation of virgin plastic polymers and post-consumer mixed plastic waste by sinking-flotation technique

Author

Washington Orlando Meneses Quelal, Andrés Ferrer Gisbert, and Borja Velázquez-Martí

Subjects

Concentration, Municipal solid waste, Materials science, Polymers, Health, Toxicology and Mutagenesis, Sodium, chemistry.chemical_element, Density, Processing, Solid Waste, chemistry.chemical_compound, Tap water, Environmental Chemistry, Recycling, chemistry.chemical_classification, Ethanol, General Medicine, Polymer, Polyolefins, Pollution, Refuse Disposal, Treatment, chemistry, Volume (thermodynamics), Chemical engineering, Plastic waste, High-density polyethylene, Plastics, Research Article

Abstract

The main objective of this research is to separate virgin polymers (PA, PC, PP, HDPE; PS and ABS) and post-consumer plastic waste from municipal solid waste (MSW) using the sinking-flotation technique. The separation was carried out on a pilot scale in a container of 800 l of useful volume with agitation of 160 rpm for one hour. Tap water, ethanol solutions and sodium chloride at different concentrations were used as the densification medium. The virgin polymers were separated into two groups, that is, a group of low-density polymers (HDPE and PP) and a group of high-density polymers (PS, ABS, PA, and PC). Polymers whose density was less than that of the medium solution floated to the surface, while those whose density was greater than that of the medium solution sank to the bottom. The experimental results showed that the complete separation of HDPE from PP was achieved at 23% v/v of ethanol. For the separation of the high-density polymers, up to 40% w / v sodium chloride was used. The recoveries of the polymers ranged from 70 to 99.70%. In post-consumer recycled plastic waste, fractions of 29.6% polyolefins, 37.54% PS, 11% ABS, 8% PA and 12% PC, PET and PVC were obtained. Finally, cast plates were made of the post-consumer waste to improve the identification of the type of polymer present in the separated fractions.

Published

2021

3. Anaerobic Codigestion of Slaughter Residues with Agricultural Waste of Amaranth Quinoa and Wheat

Author

Juan Gaibor-Chávez, Zulay Niño-Ruiz, Borja Velázquez-Martí, Orlando Washinton Meneses-Quelal, and Andrés Ferrer Gisbert

Subjects

chemistry.chemical_compound, Agricultural waste, chemistry, Agronomy, Environmental science, Amaranth, Anaerobic exercise

Abstract

The objective of this research is to experimentally evaluate the anaerobic co-digestion of slaughterhouse residues in the city of Guaranda with straw residues from agriculture, such as: amaranth, quinoa and wheat. The study was carried out on a laboratory scale using 311 ml biodigesters under mesophilic conditions of 37 °C. Anaerobic co-digestion resulted in methane yields of 407 ml CH4/g VS, with a methane content in the biogas of 77% for the mixture of slaughterhouse waste and quinoa (RM-QU (25:75)). The increase in inoculum in the mixtures composed of slaughterhouse residues and quinoa increased the biodegradability between 17 and 22%. However, in the mixtures of slaughterhouse waste and amaranth (RM-AM (0:100)), a further increase in inoculum decreased biodegradability by 5%. To predict and simulate methane production, 5 kinetic models were used: modified Gompertz, logistic equation, transfer, cone and Richards. The cone model was the one that best adjusted the experimental values ​​with those predicted with an R2 of 0.982 to 0.999 and RMSE of 0.61 to 6.92 ml CH4/g VS. The calculation of the theoretical yield was carried out by stoichiometry and elemental analysis of the samples. Theoretical yields ranged between 480-564 ml CH4/g VS for all mixtures of RM with agricultural residues.

Published

2021