## Syllabus 2015-16 - 13412012 - Thermal Engineering (Ingeniería térmica)

Caption
• Level 1: Tutorial support sessions, materials and exams in this language
• Level 2: Tutorial support sessions, materials, exams and seminars in this language
• Level 3: Tutorial support sessions, materials, exams, seminars and regular lectures in this language
 DEGREE: Grado en Ingeniería mecánica (13412012) FACULTY: SCHOOL OF ENGINEERING OF JAÉN DEGREE: Grado en Ingeniería eléctrica (13512013) FACULTY: SCHOOL OF ENGINEERING OF JAÉN DEGREE: Grado en Ingeniería de organización industrial (13012014) FACULTY: SCHOOL OF ENGINEERING OF JAÉN DEGREE: Grado en Ingeniería electrónica industrial (13112017) FACULTY: SCHOOL OF ENGINEERING OF JAÉN ACADEMIC YEAR: 2015-16 COURSE: Thermal Engineering
SYLLABUS
1. COURSE BASIC INFORMATION
 NAME: Thermal Engineering CODE: 13412012 (*) ACADEMIC YEAR: 2015-16 LANGUAGE: English LEVEL: 1 ECTS CREDITS: 6.0 YEAR: 2 SEMESTER: PC
2. LECTURER BASIC INFORMATION
 NAME: TORRES JIMÉNEZ, ELOISA DEPARTMENT: U121 - INGENIERÍA MECÁNICA Y MINERA FIELD OF STUDY: 590 - MÁQUINAS Y MOTORES TÉRMICOS OFFICE NO.: A3 - 013 E-MAIL: etorres@ujaen.es P: 953212867 WEBSITE: http://www10.ujaen.es/conocenos/departamentos/ingmec/4809 ORCID: https://orcid.org/0000-0002-9689-1746 LANGUAGE: English LEVEL: 1
3. CONTENT DESCRIPTION

Chapter 1. Concepts, definitions, and basic principles : Introduction. Thermodynamic systems and control Volumes. Macroscopic description. Properties and state of a system. Thermodynamic equilibrium; processes. Units. Density, specific volume, specific weight. Pressure. Temperature. Energy.

Chapter 2. Properties of pure substances. Introduction. The P-v-T surface. The liquid-vapor region. Steam tables. The ideal-gas equation of state. Equations of state for nonideal gas.

Chapter 3. Work and Heat. Introduction. Definition of work. Quasiequilibrium work due to a moving boundary. Nonequilibrium work. Other work modes. Heat.

Chapter 4. The first law of Thermodynamic. Introduction. The fisrt Law of Thermodynamic applied to a cycle. The first Law applied to a process. Enthalpy. Latent heat. Specific Heat. The first Law applied to various proocesses. General formulation for control volumes. Applications of the Energy Equation.

Chapter 5. The second law of Thermodynamic. Introduction. Heat engines, heat pumps, and refrigerators. Statements of the second Law of Themodynamics. Reversibility. The Carnot engine. Carnot Efficiency.

Chapter 6. Entropy. Introduction. Definition. Entropy for an ideal gas with constant specific heats. Entropy for an ideal gas with variable specific heats. Entropy for substances such as steam, solid, and liquids. The inequality of Clausius. Entropy change for and irreversible process. The second Law applied to a control volume.

Chapter 7. Reversible work, irreversibility, and availability. Basic concepts. Reversible work and irreversibility. Availability and exergy. Second-Law analysis of a cycle.

Chapter 8. Power and refrigeration vapor cycles. Introduction. The Rankine cycle. Rankine cycle efficiency. The vapor refrigeration cycle. The heat pump. Effect of losses on power cycle efficiency.

Chapter 9. Power and refrigeration gas cycles. Introduction. Gas compressors. The air-standard cycle. The Carnot cycle. The Otto cycle. The Diesel cycle. The Dual cycle. The Stirling and Ericson cycles. The Bryton cycles. The combined Bryton-Rankine Cycle.

Chapter 10. Thermodynamic relations. Three Differential Relationships. The Maxwell Relations. The Clapeyron Equation. Further Consequences of the Maxwell Relations. Relationships involving specific heats. The Juole-Thomson coeficient. Enthalpy, internal energy, and entropy changes of real gases.

Chapter 12. Mixtures and solutions. Basic definitions. Ideal Gas-Law for mixtures. Properties of a mixture of ideal gases. Gas-Vapor mixtures.

Chapter 13. Heat transfer: introduction. Conduction, convection, and radiation. Material properties. Units.

Chapter 14. One dimensional steady-state Conduction. Conduction, convection, and radiation. Material properties. Units.

Chapter 15. Fluid mechanics. Fluid statics. Fluid dynamics. Conservation of mass. Equation of motion along a streamline. Conservation of energy.

Chapter 16. Forced convection: laminar flow. Hydrodynamic (Isothermal) boundary layer: flat plate. Thermal boundary layer: flat plate. Isothermal pipe flow. Heat transfer in pipe flow. Summary of temperatures for property evaluations.

Chapter 17. Natural convection. Vertical flat plate. Empirical correlations: isithermal surfaces. Free convection in enclosed espaces. Mixed free and forced convection. Newer correlations.

Chapter 18.  Radiation. Introduction. Properties and definitions. Blackbody radiation. Real surfaces and the gray body.

4. COURSE DESCRIPTION AND TEACHING METHODOLOGY

Lecture (Theory): exposition of the subject by formal discourse in Spanish is open for international students. Tutorial support, bibliography, and multimedia resources are available in English. (3 h per week)

Lecture (Practice): laboratory sessions with multimedia support in English. (10 h).

Students with special educational needs should contact the Student Attention Service (Servicio de Atención y Ayudas al Estudiante) in order to receive the appropriate academic support

5. ASSESSMENT METHODOLOGY

Exam (40% theory and 50% problems). Maximum 9 points.

Practical lessons: written work. Maximum 1 point.

6. BOOKLIST
MAIN BOOKLIST:
• Schaum's outline of heat transfer. Edition: 2ª ed.. Author: Pitts, Donald R.. Publisher: New York : Schaum ; London : McGraw-Hill [distributor], 2011  (Library)
• Schaum's outline of thermodynamics for engineers. Edition: 2ª ed.. Author: Potter, Merle C.. Publisher: New York ; London : McGraw-Hill, 2006  (Library)