Your search keyword '"Luiz, Thiago"' showing total 3 results

1. Influence study of cationic surfactant, temperature, and current on the electrocoagulation process for removal of Remazol Red RB 133 by central composite design and response surface methodology

Author

da Silva, Luiz Thiago Vasconcelos, Crisóstomo, João Victor Cardoso, da Silva, Leonardo Paes, Monteiro, Noberto de Kássio Vieira, Oliveira, Juliene Tomé, do Nascimento, Hélio Oliveira, Longhinotti, Elisane, Romero, Franscico Belmino, de Oliveira, André Gadelha, and do Nascimento, Ronaldo Ferreira

Published

2024

2. Electrocoagulation cell for the production of hydrogen without carbon emission and simultaneous treatment of textile wastewater.

Author

da Silva, Luiz Thiago Vasconcelos, de Oliveira, André Gadelha, Ribeiro, Jefferson Pereira, Lopes, Amanda Fonseca, da Silva Costa, Rouse, Neto, Eliezer Fares Abdala, Carvalhod, Tecia Vieira, Romero, Francisco Belmino, Santos Sales, João Victor, de Souza, Francisco Thiago Correia, and Nascimento, Ronaldo Ferreira do

Subjects

*HYDROGEN production, *DISSOLVED organic matter, *CARBON emissions, *WATER purification, *WASTEWATER treatment

Abstract

This study aimed to verify the efficiency of an electrocoagulation reactor to generate low carbon hydrogen and treat textile effluent simultaneously. The electrolytic cell comprised a hermetically sealed polypropylene container containing 800 mL of effluent and a pair of immersed stainless steel 304 L electrodes powered by a photovoltaic solar panel (540 W). A gas chromatograph with a dielectric-barrier discharge ionization detector (GC-BID) measured the hydrogen gas produced. The efficiency of the textile effluent treatment was evaluated using the parameters of dissolved organic carbon, turbidity, pH, conductivity, and color. The electrical energy consumed by hydrogen generation and effluent treatment was also measured. The maximum concentration of hydrogen produced was 89.87% (v/v) with 898676.9 ppm. The process removed 100% of color, 92% of dissolved organic carbon, and 99.53% of turbidity. The electrical energy consumed for hydrogen generation ranged from 19.02 to 55.74 KW h/m3H 2. • Simultaneous electrolytic process of low carbon hydrogen generation and textile effluent treatment. • Hydrogen concentration values were obtained in the 475773.3 ppm (47.57 %) to 898676.9 ppm (89.87 %) range. • The process removed 100%, 99.53%, and 92% of color, turbidity, and dissolved organic carbon, respectively. • The energy per volume of hydrogen produced was 19.02–55.74 KW h/m3H 2. [ABSTRACT FROM AUTHOR]

Published

2024

3. Removal of natural organic matter from aqueous solutions using electrocoagulation pulsed current: optimization using response surface methodology

Author

Ari Clecius Alves de Lima, Luiz Thiago Vasconcelos da Silva, Eliezer Fares Abdala Neto, Ronaldo Ferreira do Nascimento, Álvaro Amanajás Amazonas, Jefferson Pereira Ribeiro, and André Gadelha de Oliveira

Subjects

chemistry.chemical_classification, Environmental Engineering, Aqueous solution, Materials science, Supporting electrolyte, medicine.medical_treatment, Analytical chemistry, Water, Factorial experiment, Electrocoagulation, Water Purification, chemistry, Electrode, medicine, Humic acid, Response surface methodology, Current density, Electrodes, Water Pollutants, Chemical, Water Science and Technology

Abstract

The use of the pulsed current can be an alternative to decrease the electrode polarization, as well as achieving lower energy consumption. This study investigated the electrocoagulation through pulsed current for the removal of natural organic matter from water. The experiments were carried out using Box–Behnken factorial design with the response surface methodology for the design of experiments, modeling and interpreting of the results. The electrocoagulation cell consisted of an acrylic reactor with 4 L capacity with four electrodes of aluminum, in parallel connection mode. The experimental independent variables studied were: current density (5.5 to 44.5 A m−2), electrodes spacing (2 to 7.6 mm), stirring rate (200 to 1,000 rpm), frequency (500 to 5,000 Hz), humic acid concentration (5 to 20 mg L−1) and NaCl (100 to 300 mg L−1) as supporting electrolyte, evaluating the residual apparent color (RAC) and electric energy consumption (EEC). The pH of the solution increased during the experiments, reaching basic values. The response surface regression procedure was employed to fit the second-order polynomial, and the model fitted well to the obtained values, reaching R2 0.9995 (RAC) and R2 0.9989 (EEC). The lowest RAC was 11.8 Hazen units (96.2% color removal), where the EEC was 0.393 kWh m−3.

Published

2020