COURSE GENERAL OBJECTIVESUpon completion of this course, students will be able to analyze energy transformation processes; calculatethe thermodynamic properties of pure substances; evaluate process performance, and; define theperformance limits of systems. STUDENT OUTCOMESe. An ability to identify, formulate, and solve engineering problemsk. An ability to use the techniques, skills, and modern engineering tools necessary for engineeringpractice.SYNTHETIC PROGRAMFor details visithttp://micampus.ccm.itesm.mx/web/division-de-diseno-ingenieria-y-arquitectura/ingeniero-en-desarrollo-sustentable# COURSE METHODOLOGYThe main course of this teaching strategy is focused on Problem Based Learning.series of challengingproblems will be posed to the students. COURSE ThermodynamcisCODE IQ2001SCHEDULE MaVi 7:00-8:30 hrsCLASSROOM Cie 002COURSE MODALITY ClassroomPROFESSOR:Dr. icardo !"nem Cor#erae-Mail:r$anem%i&esm.m' LOCATION (di)icio de *)icinas 1+ )irs&)loorTUTORIAL TIME AND PLACEMonday-Th,rsday: 13:00 1-:00 hrs. ./lace:0*)icinas 11irs& 1loor2or 0/la3a del 4cad5mico2 Campus Ciudad de MxicoEscuela de Diseo, Ingeniera y ArquitecturaDepartamento de Ingeniera MecatrnicaThermodynamicsGRADING !valuation " #Traditional !$am%&'(!valuation & #Traditional !$am%&'(!valuation ) #Teams%"'( *inal#Traditional !$am% )+(,nnovation -ee. ' (IMPORTANT DATES!nd of classes/0ovember &'th i1 -ee.2eptembre&" to &' th*irst partial e$am/ 2eptember "' th

2econd partial e$am/3ctober &4th*inal e$am/ *riday, 0ovember &4th, 5/++ hrs.GENERAL POLICIESh&&6:77micam6,s.ccm.i&esm.m'7re$lamen&osCODE OF ETHICSAll students recognize a commitment by being enrolled in the course and must adhere to the code of ethicspresentedinthis sectionandtheir acts as students will begovernedbytheRespect, Responsibility,Academic Honesty, and Commitment to the Community. Also, their activities within the course must bedone with honesty and in a personal way, reflecting students knowledge and students must assume thegrade.In particular, all students agree to:Respect Always speak the truth and respecting their peers, teachers and campus staff. Be tolerant with peers, respect diversity and free expression of ideas, religious beliefs, traditions,cultures and points of view. Show consideration and appreciation for campus staff and for their work, create an environmentconducive to learning.Academic Honesty Do not copy on academic tasks: reports, essays, papers, tests, etc. Donot plagiarize, submit original workandrespect thecopyright onacademictasks: reports,essays, papers, tests, etc..2Responsibility Participate actively andresponsiblyinthe assignedteamworkandfoster anenvironment ofcooperation and solidarity. Know and follow the rules of the institution, in particular the Academic Regulations and GeneralRules of students and assume responsibility for the consequences of their actions.Commitment to the Community Use of campus facilities carefully and adopt an attitude of austerity in relation to the use of materialresources in general.1. BibliographyTEXTBOOK Thermodynamics. An Engineering Approach. 7th Ed.Cengel & Boles.Ed. Mc Graw-HillREFERENCES Biological Thermodynamics. Hayne, Donald T. Cambridge University Press 2008Introduction to Chemical Engineering Thermodynamics Smith & Van Ness,Mc. Graw HillPerrys Chemical Engineers Handbook. Perry, Mc Graw Hill Internal Combustion Engines. Ferguson, Colin R.John Wiley & Sons 2001Fundamentals of Engineering Thermodynamics Michael J. Moran.Howard N. Shapiro Ed:Wiley.5th ed.Classical ThermodynamicsSonntage andVan Wylen Ed. Mc Graw-HillThe Refrigerator and the Universe Martin Goldstein,Inge F. Goldstein. Ed.Harvard. Clouds in a glass of Beer. Simple experiments in Athmospheric Pysics. Craig. F. Bohren.Ed. WileyReflexiones sobre la Potencia Motriz del Fuego. Sadi Carnot. Instituto Politcnico Nacional.Generalized Thermodynamics: The Thermodynamics of Irreversible Processes Eu.B.C. WEB SOURCES & eBookshttp://www.thermofluids.net (Tutoriales y Software)http://www.keveney.com/Engines.html( Simulacin de Mquinas de Vapor, Combustin Interna)http://www.redrok.com/engine.htm( Proyectos de Termodinmica)http://www.theaircar.com/howitworks.html( Carro que funciona con Aire Comprimido)http://www.autospeed.com/cms/A_0948/printArticle.html ( Carro que funciona con un mecanismo de Scoth Yoke )http://www.corbyrefrigeration.co.uk/refrigeration.htm(Simulacin de un Sistema de Refrigeracin)http://www.bchp.org/status-4-1finance.html( Descripcin de Ciclos de refrigeracin)http://www.educar.org/inventos/heladera.asp( Historia de la refrigeracin)http://eosweb.larc.nasa.gov/sse/( Meteorologa y Energa Solar. Pgina de la NASA)http://www.lhup.edu/~dsimanek/museum/unwork.htm(Museo de Mquinas de Movimiento Perpetuo )http://www.physics.ohio-state.edu/~farrell/616/heat/vortex.html ( El Tubo del Hilsh)http://www.nd.edu/~msen/Teaching/IntHT/ControlNotes.pdf ( Termodinmica y Control)http://entropy.sdsu.edu/testcenter/ (buenas animaciones de Ciclos entre otras cosas)2. Technological ResourcesSOFTWARE, APPS, etc.Mathlab, Excell or Similar Software.Week Topic31Week.(Agost 10th to Agost 14th)INTRODUCTION: WHAT IS THERMODYNAMICS?- The Science of Energy (but what is energy?- Why is it important?- Difference between energy and energy velocity.- Energy in Mexico.- A Brief History of Thermodynamics. 22FUNDAMENTAL CONCEPTS- System, Boundaries and Environment- Open and Closed Systems- Properties (State Functions) and Non-Properties (Path Functions)- Intensive and Extensive Properties.3Week, (Agost 24th to Agost 28th)HEAT AND WORK- Concept of Heat- Concept of Work- Expansion Work4 Week (Agost 31th to September 4th)FIRST LAW OF THERMODYNAMICS FOR CLOSED SYSTEMS- Specific Heat:Cv and Cp- Internal Energy and Enthalpy for Ideal Gasses- Problems5 Week (September 7th to September 11th)PROPERTIES OF PURE SUBSTANCES- Gibbs phase rule- Phase Diagram- P vs V and T vs V diagrams for pure substancess- The concept of quality (X) and the use of tables.6 Week (September 7th to September 11th)Compressibility and the Generalized Compresibility Diagram7 Week (September 14th to September 18th)FIRST PARTIAL EXAM.8 Week(September 28th to October 2th)FIRST LAW FOR OPEN SYSTEMS- Mass conservation for open systems- Flow Work- Energy Conservation for Open Systems: Steady State9 Week(October 5th to October 9th) - Energy Conservation for Open Systems: Unsteady state.10 Week(October 12th to October 16th )HEAT ENGINES- Fundamentals and Efficiency- The Carnot Engine11 Week(October 26th to October 30th )SECOND PARTIAL EXAM12 Week(November 2th to November 6th )- Refrigerators and Heat Pumps- The Coefficient of Performance13 Week(November 9th to November 13thENTROPY- Reversible and Irreversible Processes- The Definition of Entropy and its Physical Meaning814 Week(November 16th to November 20th- How to calculate entropy changes?- Entropy Generation and the Second Law of Thermodynamics15 Week(November 23th to November 25th- Isentropic Efficiency: Turbines, Compressors, Nozzles and Diffusors.9