Área de Concentração: 3137
Concentration area: 3137
Criação: 10/10/2022
Creation: 10/10/2022
Ativação: 10/10/2022
Activation: 10/10/2022
Nr. de Créditos: 8
Credits: 8
Carga Horária:
Workload:
Teórica (por semana) |
Theory (weekly) |
Prática (por semana) |
Practice (weekly) |
Estudos (por semana) |
Study (weekly) |
Duração | Duration | Total | Total |
---|---|---|---|---|---|---|---|---|---|
3 | 0 | 7 | 12 semanas | 12 weeks | 120 horas | 120 hours |
Docentes Responsáveis:
Professors:
Jorge Alberto Soares Tenório
Amilton Barbosa Botelho Junior
Objetivos:
Apresentar os problemas e as tecnologias para recuperação de compostos químicos em soluções aquosas usando membranas.
Objectives:
To present the problems and technologies for the recovery of chemical compounds in aqueous solutions using membranes.
Justificativa:
Nos últimos anos, é crescente a preocupação com o tratamento de efluentes industriais e tecnologias para recuperação de compostos químicos em solução mais eficientes e sustentáveis. Isso torna necessário o conhecimento de tecnologias e variáveis de processo para aplicação. Será apresentado aos alunos os processos usando membranas para recuperação de compostos químicos presentes em solução. Serão feitas aulas expositivas e atividades com base na metodologia ativa, que é um processo de ensino-aprendizagem no qual o aluno é colocado como protagonista.
Rationale:
In recent years, there has been a growing concern about the treatment of industrial effluents and technologies for the recovery of chemical compounds in more efficient and sustainable solutions. This makes knowledge of technologies and process variables necessary for application. Students will be introduced to processes using membranes to recover chemical compounds present in solution. Lectures and activities will be held based on the active methodology, which is a teaching-learning process in which the student is placed as the protagonist.
Conteúdo:
Nos tópicos de cada aula, serão apresentados os conceitos fundamentais sobre processos industriais usando membranas. A partir de exemplos reais, serão apresentados e discutidos as tecnologias aplicadas; balanços de massa e energia; exemplos de sistemas contínuos, bateladas e semicontínuos; parâmetros de processo, controle e otimização; e termodinâmica. 1. Introdução teórica: Apresentação do curso, apresentação e classificação dos processos de separação por membranas para efluentes industriais 2. Materiais utilizados para fabricação de membranas 3. Osmose reversa 4. Microfiltração, nanofiltração e ultrafiltração 5. Eletrodiálise e Eletrodiálise Reversa 6. Pervaporação 7. Sistema MBR 8. Equações, balanços de massas e energia, especificação de sistemas, custos de sistemas de separação por membranas e exemplos de processos industriais 9. Aplicações de membranas para tratamento de efluentes industriais
Content:
In the topics of each class, fundamental concepts about industrial processes using membranes will be presented. Based on real examples, the applied technologies will be presented and discussed; mass and energy balances; examples of continuous, batch and semi-continuous systems; process parameters, control and optimization; and thermodynamics. 1. Theoretical introduction: Course presentation, presentation, and classification of membrane separation processes for industrial effluents 2. Materials used to manufacture membranes 3. Reverse Osmosis 4. Microfiltration, nanofiltration and ultrafiltration 5. Electrodialysis and Reverse Electrodialysis 6. Pervaporation 7. MBR System 8. Equations, mass and energy balances, systems specification, costs of membrane separation systems and examples of industrial processes 9. Applications of membranes for industrial effluent treatment
Forma de Avaliação:
Monografia, seminário, e atividades abordando os resíduos e técnicas de tratamento conforme discutidos em sala de aula.
Type of Assessment:
Monograph, seminar, and activities addressing waste and treatment techniques as discussed in the classroom.
Bibliografia:
1. Tadashi Uragami. Science and Technology of Separation Membranes. John Wiley & Sons Ltd. 2017. 2. Enrico Drioli, Lidietta Giorno and Francesca Macedonio. Membrane Engineering. De Gruyter. 2019. 3. Xin Li, Jiuyang Lin, Shuaifei Zhao. Advances in Functional Separation Membranes. Royal Society of Chemistry. 2021. 4. Ahmad Ismail, Takeshi Matsuura. Membrane Separation Processes: Theories, Problems, and Solutions. Elsevier. 2021. 5. Simon Judd, Claire Judd (Editors). The MBR book: principles and applications of membrane bioreactors for water and wastewater treatment. Oxford: Elsevier/Butterworth-Heinemann, 2011, Burlington, MA. 519 p. 6. Andréa Moura Bernardes, Marco Antônio Siqueira Rodrigues, Jane Zoppas Ferreira. Electrodialysis and Water Reuse: Novel Approaches. Springer. 2014. 144p. 7. Kai Zhang, Huan-Huan Wu, Hui-Qian Huo, Yan-Li Ji, Yong Zhou, Cong-Jie Gao. Recent advances in nanofiltration, reverse osmosis membranes and their applications in biomedical separation field. Chinese Journal of Chemical Engineering Volume 49, September 2022, Pages 76-99 8. Song Liu, Guangyuan Zhou, Gongbi Cheng, Xiaokang Wang, Gongping Liu, Wanqin Jin. Emerging membranes for separation of organic solvent mixtures by pervaporation or vapor permeation. Separation and Purification Technology, Volume 299, 15 October 2022, 121729 9. Haoze Zeng, Shanshan He, Seyed Saeid Hosseini, Bin Zhu, Lu Shao. Emerging nanomaterial incorporated membranes for gas separation and pervaporation towards energetic-efficient applications. Advanced Membranes, Volume 2, 2022, 100015 10.Victor Rezende Moreira, Yuri Abner Rocha Lebron, Míriam Cristina Santos Amaral. Enhancing industries exploitation: Integrated and hybrid membrane separation processes applied to industrial effluents beyond the treatment for disposal. Chemical Engineering Journal, Volume 430, Part 3, 15 February 2022, 133006 11.Asfak Patel, Ambika Arkatkar, Monali Chhatbar, Alka A. Mungray, Arvind Kumar Mungray. Advances in membrane technologies for industrial effluents for resource recovery. Novel Approaches Towards Wastewater Treatment and Resource Recovery Technologies 2022, Pages 167-184 12.Dennis Deemtera, Isabel Oller, Ana M. Amat, Sixto Malato. Advances in membrane separation of urban wastewater effluents for (pre)concentration of microcontaminants and nutrient recovery: A mini review. Chemical Engineering Journal Advances Volume 11, 15 August 2022, 100298
Bibliography:
1. Tadashi Uragami. Science and Technology of Separation Membranes. John Wiley & Sons Ltd. 2017. 2. Enrico Drioli, Lidietta Giorno and Francesca Macedonio. Membrane Engineering. De Gruyter. 2019. 3. Xin Li, Jiuyang Lin, Shuaifei Zhao. Advances in Functional Separation Membranes. Royal Society of Chemistry. 2021. 4. Ahmad Ismail, Takeshi Matsuura. Membrane Separation Processes: Theories, Problems, and Solutions. Elsevier. 2021. 5. Simon Judd, Claire Judd (Editors). The MBR book: principles and applications of membrane bioreactors for water and wastewater treatment. Oxford: Elsevier/Butterworth-Heinemann, 2011, Burlington, MA. 519 p. 6. Andréa Moura Bernardes, Marco Antônio Siqueira Rodrigues, Jane Zoppas Ferreira. Electrodialysis and Water Reuse: Novel Approaches. Springer. 2014. 144p. 7. Kai Zhang, Huan-Huan Wu, Hui-Qian Huo, Yan-Li Ji, Yong Zhou, Cong-Jie Gao. Recent advances in nanofiltration, reverse osmosis membranes and their applications in biomedical separation field. Chinese Journal of Chemical Engineering Volume 49, September 2022, Pages 76-99 8. Song Liu, Guangyuan Zhou, Gongbi Cheng, Xiaokang Wang, Gongping Liu, Wanqin Jin. Emerging membranes for separation of organic solvent mixtures by pervaporation or vapor permeation. Separation and Purification Technology, Volume 299, 15 October 2022, 121729 9. Haoze Zeng, Shanshan He, Seyed Saeid Hosseini, Bin Zhu, Lu Shao. Emerging nanomaterial incorporated membranes for gas separation and pervaporation towards energetic-efficient applications. Advanced Membranes, Volume 2, 2022, 100015 10.Victor Rezende Moreira, Yuri Abner Rocha Lebron, Míriam Cristina Santos Amaral. Enhancing industries exploitation: Integrated and hybrid membrane separation processes applied to industrial effluents beyond the treatment for disposal. Chemical Engineering Journal, Volume 430, Part 3, 15 February 2022, 133006 11.Asfak Patel, Ambika Arkatkar, Monali Chhatbar, Alka A. Mungray, Arvind Kumar Mungray. Advances in membrane technologies for industrial effluents for resource recovery. Novel Approaches Towards Wastewater Treatment and Resource Recovery Technologies 2022, Pages 167-184 12.Dennis Deemtera, Isabel Oller, Ana M. Amat, Sixto Malato. Advances in membrane separation of urban wastewater effluents for (pre)concentration of microcontaminants and nutrient recovery: A mini review. Chemical Engineering Journal Advances Volume 11, 15 August 2022, 100298
Tipo de oferecimento da disciplina:
Presencial
Class type:
Presencial