Transport Phenomena I
| Áreas Científicas |
| Classificação |
Área Científica |
| OFICIAL |
Processos em Engenharia Química e Biológica |
Ocorrência: 2019/2020 - 1S
Ciclos de Estudo/Cursos
| Sigla |
Nº de Estudantes |
Plano de Estudos |
Anos Curriculares |
Créditos UCN |
Créditos ECTS |
Horas de Contacto |
Horas Totais |
| TPD |
22 |
Study Plan |
2 |
- |
6 |
75 |
162 |
Docência - Responsabilidades
Língua de trabalho
Portuguese
Objetivos
In the end of the semester students should: acquire basic knowledge about transport of momentum and heat; apply the knowledge acquired in solving problems involving fluid flow and heat transfer; know how to establishing balance sheets of thermal energy and boundary conditions.
After approval students should have the ability to: design transport systems of a fluid; understand the fundamentals of energy transfer, being able to apply it for solving practical problems. Identify the processes involved in heat transfer to calculate the amount of heat transferred in one-dimensional systems; determine the temperature profile and the amount of heat transferred in one-dimensional systems involving heat generation; analysis of heat transfer equipment, in order to select and design heat exchangers. Select and design isolation equipment
Resultados de aprendizagem e competências
Not applicable.
Modo de trabalho
Presencial
Pré-requisitos (conhecimentos prévios) e co-requisitos (conhecimentos simultâneos)
Not applicable.
Programa
Chapter I: 1. Introduction; 2. Dimensional Analysis; 3. Momentum Transfer and General Balances: Molecular Transport Equation, Velocity Profiles in Laminar Flow; 4. Mass Transfer: Molecular Transport Equation; 5. Energy transfer: Molecular Transport Equation. Bernoulli's equation; 6. Viscosity; Classification of Fluids, Rheology of fluids. Reynolds number, fluid flow under laminar and turbulent regime; 7. Pressure loss. Friction factor; pressure loss in pipes and in pipe fittings, flow meters. Pumps: centrifugal pump sizing Chapter II: 1. Mechanisms of heat transfer; 2. Fourier's law, Newton's Law of cooling; Stefan-Boltzmann law; 3. Thermal Conduction: Conduction at steady state, one-dimensional conduction in plans and radial systems; with convection and with energy production. Thermal resistances in series, overall coefficient of heat transfer. Thermal insulation; 4. Heat transfer in transient state: finite thickness plate, cylinder and sphere. Analytical method and graphical method.
Bibliografia Obrigatória
Geankoplis, C.J ; Transport Processes and Separation Process Principles , Prentice-Hall, 2009
Welty, J.R.; Wicks, C.E. ; & Wilson, R.E. ; Fundamentals of momentum, heat and mass transfer , John Wiley &Sons, 1984
Bird, R. B. ; Stewart, W. E. ; Lightfoot, E. N; Transport Phenomena , John Wiley & Sons, 1980
Métodos de ensino e atividades de aprendizagem
Theoretical material will be presented to promote the involvement and participation of all students, by developing their reasoning skills and stimulating their critical thinking. Materials about the subjects lectured will be available for consultations on Moodle. Online mini-tests will be weekly proposed to evaluate the subjects taught in the previous week. At any time students can contact the teacher using the Moodle platform. The assessment consists of 20% for the practical component (Minitest) and 80% of the theoretical component (final exam).
Tipo de avaliação
Distributed evaluation without final exam
Componentes de Avaliação
| Designation |
Peso (%) |
| Participação presencial |
20,00 |
| Teste |
80,00 |
| Total: |
100,00 |
Componentes de Ocupação
| Designation |
Tempo (Horas) |
| Estudo autónomo |
87,00 |
| Frequência das aulas |
75,00 |
| Total: |
162,00 |
Obtenção de frequência
Not applicable.
Fórmula de cálculo da classificação final
100% Exam
or
40% Test 1+40%Test 2 +10% Participation +10% Activities