HIBBING COMMUNITY COLLEGECOURSE OUTLINE COURSE TITLE & NUMBER: Thermodynamics: ENGR 2050 (Formerly ENGR 205)CREDITS: 3 (Lecture Hours 48 / Lab Hours 0 per Semester)PREREQUISITES: PHYS 2010: General Physics 1CATALOG DESCRIPTION:This course covers basic thermal energy relationships, processes and cycles,First and Second Law of Thermodynamics, entropy, and availability. This courseis intended for engineering majors and includes open-ended design.OUTLINE OF MAJOR CONTENT AREAS:I. Concepts of thermodynamicsA. Definitions1. Systems: closed, open, and isolated2. Property, equilibrium, state, and process3. Point and path functions and cyclesB. Units and dimensionsC. Pressure D. TemperatureE. Heat F. WorkII. Properties of substancesA. Definitions1. Extensive and intensive properties2. Physical and thermodynamic properties3. Homogeneous substances and phasesB. The state postulateC. The total energy1. Kinetic energy2. Potential energy3. Internal energy4. EnthalpyD. Equilibrium diagramsE. Properties of pure substances1. The superheated-vapor region2. The compressed- or subcooled-liquid region3. The liquid vapor saturation regionF. Specific heatsHibbing Community College, a technical & community collegean equal opportunity educator & employerG. Ideal gases1. Ideal gases with linearly varying specific heats2. Ideal gases with constant specific heats3. Polytropic processes for ideal gasesH. Incompressible substancesI. Approximation of properties for compressed-liquid statesIII. Conservation of massA. General conservation of mass equationB. Conservation of mass for closed systemsC. Conservation of mass for open systems1. Uniform flow2. Steady state3. Transient analysisIV. Conservation of energyA. General conservation of energy equationB. Problem organization for analysis of thermodynamic systemsC. Conservation of energy for closed systemsD. Conservation of energy for open systems1. Uniform flow2. Steady state3. Transient analysisE. Introduction to simple thermodynamic cyclesV. Entropy and the Second Law of ThermodynamicsA. Reversible and irreversible processesB. Thermal-energy reservoirsC. The Clausius Statement of the Second Law of Thermodynamics:heat enginesD. Carnot's Principle and the thermodynamic temperature scaleE. The Clausius inequality and entropyF. The T ds equationsG. The entropy change for ideal gases1. Arbitrary processes for ideal gases2. Isentropic processes for ideal gasesH. The entropy change for incompressible substancesI. The entropy change for pure substancesJ. The increase-in-entropy principleK. The Carnot CycleVI. Second-law analysis of thermodynamic systemsA. A general expression for the total rate of entropy changeB. Reversible work and irreversibilityC. Maximum work and availabilityD. Second-law analysis of closed systemsE. Second-law analysis of open systems1. Steady state2. Transient systemsVII. Gas cyclesA. Basic considerationsHibbing Community College, a technical & community collegean equal opportunity educator & employerB. Ideal and actual cyclesC. Air-standard assumptionsD. Gas Carnot CycleE. Stirling and Ericsson CyclesF. Ideal Otto CycleG. Ideal Diesel CycleH. Ideal Brayton CycleI. Ideal Brayton Cycle with regenerationK. Ideal jet-propulsion cyclesL. Ideal Brayton Cycle with intercooling and reheatingM. Ideal gas refrigeration cycleN. Actual gas cyclesVIII. Vapor cyclesA. Ideal Rankine CycleB. Ideal Rankine Cycle modified with reheatC. Ideal Rankine Cycle modified with regenerationD. Ideal vapor-compression refrigeration cycleE. Actual vapor cyclesIX. Thermodynamic relationshipsA. Mathematical preliminariesB. The Gibbs Equations and the Maxwell RelationsC. General equations for du , dh, and ds1. Internal energy2. Enthalpy3. EntropyCOURSE GOALS/OBJECTIVES/OUTCOMES:The students will1. identify, define, and apply substance properties including symbols, units,and physical sense.2. utilize conservation of mass in analysis problems.3. use the general energy equation to derive equations for several open andclosed transient and steady state systems.4. utilize the Second Law of Thermodynamics for in-depth thermodynamicssystem analysis.5. explain the operation of all covered gas and vapor cycles.6. use general equations for thermodynamics.7. explain availability.8. complete an extensive capstone design project in a team environmentand submit a professional report.Hibbing Community College, a technical & community collegean equal opportunity educator & employerHCC COMPETENCIES MET:STUDENTS CONTRIBUTIONS:The student will attend class regularly, participate in class discussion, completeassignments, team design projects, and take a comprehensive final examination.The student will spend sufficient time to complete all assignments.To request disability accommodations, please contact Bonnie Olson, Central campus, 218-262-7246.Students are encouraged to discuss their individual needs with the instructor.METHODS FOR EVALUATING STUDENT LEARNING:The final grade is determined by grades earned on homework problems, periodicexaminations, a comprehensive design project, and a comprehensive final examination.SPECIAL INFORMATION: (SPECIAL FEES, DIRECTIVES ON HAZARDOUS MATERIALS, TEXTBOOK USED, ETC.)All homework must be done on engineer's paper. A scientific calculator with exponential and logarithmic capabilities is required for this course.___________________________Date