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Introduction Lecture Prepared by Dr. Riham Hazzaa

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Introduction Lecture. Prepared by Dr. Riham Hazzaa. PETROCHEMICAL DEPARTMENT PE327 chemical process principals. Instructor: Dr. Riham Hazzaa Room:136 e-mail: [email protected] Assistant: Eng Amira el Gendy Lecture: E ……….. –Sunday from 11:30 to 12:30 - PowerPoint PPT Presentation

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  • Introduction LecturePrepared byDr. Riham Hazzaa

  • Instructor: Dr. Riham HazzaaRoom:136e-mail: [email protected]: Eng Amira el GendyLecture: E.. Sunday from 11:30 to 12:30 Tuesday from 10:30 to 12:30Tutorial: E.. from .. to Office hours: Monday from to Tuesday from Thursday from .. to

    Prerequisites: BE103 Math 3, BE111 General chemistry

    PETROCHEMICAL DEPARTMENTPE327 chemical process principals

  • Overall aims of course The main objective of the course is to teach the students the following:-The fundamentals of material balance calculations,Batch and continuous,steady flow and unsteady process,reactive and non reactive systems for single unit and multi unit process,process with recycle and by-pass with or without purge material balance for combustion reactions. the fundamentals of the energy balances and their role in chemical processes. the concepts used in Energy balance calculations with and without chemical reactions

  • Intended learning outcomes of course (ILOs(a- Knowledge and understanding:a1. Recognize units and dimensions-Conversion of units- systems of units-force and Weight.a2. Identify dimensional Homogeneity and dimensionless quantities.a3. Define Mass and volume Flow rate, Concentration, pressure and Temperaturea4. Identify Process Classification, Balances, Material balance calculations, recycle, bypass-Balances on reactive processes and Combustion.a5. Identify the different forms of Energy.a6.define the Law of Kinetic Energy.a7.define the Law of Potential Energy.a8.define the First Law of Thermodynamics for Closed Systems.a9.Define Adiabatic Systems.a10.recognize Steam Tables.a11.Define Sensible Heat and Heat Capacities.a12.State the relation between Heat Capacities at constant pressure and Heat Capacities at constant volume in liquid, solids and ideal gas.a13.Define the Heat of Reaction.a14.Define Endothermic and Exothermic Reactions.a15.Define the Internal Energy of reactiona16.Define Hess law.a17.Define the Heat of formation and the Standard Heat of formation.a18.Define Heat of Combustion and Standard heat of Combustion.

  • b- Intellectual skillsb1. Categorize different units.b2. Examine the applicability of balancing the equation to be homogenous. b3. Apply the relation between Mass and Volume to convert them to each others.b4. Calculate the concentration of different substancesb5. Analyze any system by applying material balance equationb6. Analyze different systems containing bypass.b7. Apply material balance equation to reactive systems.b8.Calculate the Kinetic Energy of a body of mass (m) moving with a velocity.b9.Calculate the Potential Energy of a moving stream at elevation (z). b10.Calculate the amount of heat transferred (Q) in appropriate units.b11.analyze Shaft Work.and Flow Work. b12.Categorize vapor pressure, specific internal energy, specific enthalpy and specific volumes of a saturated steam from saturated steam tables at different temperatures and pressures and at the triple point.b13.Apply both Material and Energy Balances.b14.Calculate the required heat removal rate using heat capacity formulas and specific enthalpies. b15.Calculate the Heat Capacity of a mixtureb16.Calculate the Heat of reaction.b17.Calculate the Internal Energy of reaction.b18.Calculate the Heat of reaction by Hess law.b19.Calculation of Heat of reaction from Heat of combustion.

  • c- Professional and practical skillsc1. Perform a dimensionally homogenous equation. c2. Distinguish between mass and weight.c3. Explain the force with the aid of units.c4. Use the data of mass and volume flow rate.c5. Estimate how to prepare solutions with different concentrations.c6. Select the appropriate material balance equation for different non reactive system.c7. Apply the appropriate material balance equation for reactive system.c8. Determine the data required for combustion processes.c9.examine closed system sand open system, isothermal process and adiabatic process.c10.Distinguish the conditions at which each of the five terms in the balanced equation can be neglected. c11. Apply the energy balance equation for a closed system and open system c12.Use the saturated and superheated steam tablesc13.Estimate the heat capacity of a liquid or solid using Kopp, s Rule.c14.Calculate Latent Heat of Vaporization.c15.Calculate the Heat of reaction by Hess law.c16.Calculation of Heat of reaction from Heat of formation.c17.Calculation of Heat of reaction from Heat of combustion.

  • d- General and transferable skillsd1-Developing both Communication and Management skills.d2- Developing engineers capability to use of general information technology,d3- work as a team and work independently

  • WeekDateLectures123/9/2012Introduction conversion table230/9/2012units and dimensions37/10/2012process and process variables414/10/2012fundamentals of material balances521/10/2012multiple unit process material balances/ recycle and by-pass628/10/2012stoichiometric chemical reaction74/11/2012balances on reactive process811/11/2012Product Separation/ combustion reaction918/11/2012Midterm Exam1025/11/2012Energy and Energy Balances -Forms of Energy112/12/2012Tables of thermodynamic data129/12/2012Balances on Nonreactive Processes -Sensible Heat and Heat Capacities1316/12/2012Procedure for energy balance calculations1423/12/2012Balance on reactive processes- Heats of reaction Heats of combustion1530/12/2012Balance on reactive processes- adiabatic reactors

  • 4 Teaching and learning methods4.1-Lectures.4.2-Assignments.4.3-Case study

    5- Student assessment methods5.1-Assignments : to assess student skills.5.2-Mid-term Exams(9th week): to assess student achievements.5.3-case study to assess student understanding and skills.5.4-Final-exam to assess student understanding.

  • Assessment: Mid-term20 marks quizzes 15 markscase study 5 marksHome works and attedance10 marksFinal Exam. 50 marks --------- 100

  • 6- List of references 6.1- Course notesBased on selected chapters collected from text books.6.2- Textbook: R.M. Felder and R.W. Rousseau Elementary Principles of Chemical Processes, John Wiley & Sons, 3rd Edition 2005.6.3- Periodicals, Web sites, etc