ENGINEERING APPLIED TO RENEWABLES CourseCode: 3002Degree: Master's in Solar and Renewable EnergySchool of Engineering of ElcheYear: Year 1 of Master's in Solar and Renewable EnergySemester: FallType: RequiredLanguage: SpanishECTS credits: 4.5Lecture: 4.5Laboratory: 0Hours: 112.5Directed: 112.5Shared: 0Autonomous: 0Subject matter: Energy EngineeringDepartment: Course instructors are responsible for the course content descriptions in English.DescriptionGeneral introduction to renewables. Calculations. Electrotechnics. Electrical components and apparatuses. Thermodynamics. Practical cases. A refresher course for students who have taken electrotechnics and thermodynamics during their academic training and one of leveling for those without such knowledge in order to subsequently be able to take on thermal, photovoltaic, biomass, and wind projects.FacultyNameCoordinatorLectureLaboratoryALONSO SERRANO, JOSE LUIS■■■ALCARAZ HERNÁNDEZ, ANTONIO■■Professional interestCompetencies and learning outcomesGeneral competenciesAcquire a mindset committed to the environment, the use of energy resources, and optimization of electrical generation and consumption.Ability to search for, acquire, and manage information on all levels, including scientific and technical literature, patent databases, economic indicators, and legislation.Ability to use tools related to information and communications technology.Specific competenciesAbility to evaluate the advantages and disadvantages of different energy production systems.Ability to analyze the role of energy as a key production factor in the economic system and operations of distinct energy markets.Ability to understand the operation of conventional energy generation systems.Ability to analyze and describe environmental problems arising from the use of non-renewable energy.Ability to understand and know how to apply the basic principles of electrotechnics, electronics, and mechanics in renewable energy systems.Objectives (Learning outcomes)Conocer los principios generales de Electrotecnia para poder enfrentarse a los proyectos en témica, fotovotaica, biomasa y eólica.Conocer los principios generales de Termodinámica para poder enfrentarse a los proyectos en témica, fotovotaica, biomasa y eólica.ContentsLecture topicsTeaching unitsIntroducción a las energías renovables.Generación, transporte y distribución.Instalaciones eléctricas.Sistema eléctrico y mercado eléctrico.Panorama y horizontes.Primer principio de la Termodinámica.Segundo principio de la Termodinámica.Aplicaciones conjuntas de los dos principios de la Termodinámica.Máquinas Térmicas.Course contentsBasic bibliographyFouillé, A. "Compendio de electrotecnia". Barcelona Marcombo D.L. 1979. Ruiz Vassallo, Francisco. "Electrotécnia general". Barcelona CEAC 1985. Hurtado Pérez, Elías. "Problemas de electrotecnia". Valencia Universidad Politécnica D.L. 1987. Cavallé Sesé, Francisco. "Practicas de electrotecnia aparatos de medida eléctricos". Valencia Universidad Politécnica [1988]. Holman, J. P. García Quiroga, Iván / Ospina Torres, Alejandro / Riveros Rodríguez, Humberto / Acosta, Fernando. "Termodinámica". Mexico [etc.] McGraw-Hill cop. 1975. Tejerina, A. F. "Termodinámica". Madrid Paraninfo 1983. Boxer, G. "Termodinámica técnica Teoría, ejemplos resueltos y problemas". Barcelona etc. Reverté D. L. 1979. Cañada Ribera, Javier. "Problemas resueltos de termodinámica". Valencia Universidad Politécnica, Servicio de Publicaciones D.L. 1996. Complementary bibliographyLinksSoftwareMethodology and gradingMethodologyLecture: Pass on knowledge and activate cognitive processes in students, encouraging their participation.Solving exercises and problems: Exercise, test, and apply previous knowledge through routine repetition.GradingLa nota final de la asignatura vendrá dada por un examen escrito que ponderará un 80% y una parte práctica que ponderará 20%. La asignatura está dividida en dos partes diferenciadas como son Electrotecnia y Termodinámica, cada una tendrá un peso del 50%.