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22HPI32 - Chemical Engineering Calculations

Course specification
Course titleChemical Engineering Calculations
Acronym22HPI32
Study programme
Module
Lecturer (for classes)
    Lecturer/Associate (for practice)
      Lecturer/Associate (for OTC)
        ESPB5.0Status
        ConditionComputer programmingОблик условљености
        The goalCourse objective is to enable student to to define calculation input data based only on substance structural formula; to establish analytical dependence of chemical engineering experimental data on temperature, pressure and mole fraction; to archive required experimental chemical engineering data and develop an efficient and rational chemical engineering software.
        The outcomeAbility to formulate chemical engineering problems in algorithmic manner, to solve them using computers and to provide required chemical engineering data for calculation and archiving.
        Contents
        Contents of lectures• Correlation: heat of vaporization, vapor pressure, density, dynamic viscosity coefficients, heat capacity and thermal conductivity coefficient • Prediction: parahor, normal freezing and boiling temperature, critical parameters, accentric factor, heat of vaporization, critical compressibility factor, vapor pressure, density, dynamic viscosity coefficient, heat capacity and thermal conductivity coefficient • Data bases of chemical engineering data
        Contents of exercisesNumerical methods and computer software in solving chemical engineering problems and data acquisition
        Literature
        1. Grozdanić,D.K., Hemijsko-inženjersko računanje, Tehnološko-metalurški fakultet, Beograd 2015.
        2. Nagar S., Introduction to Python for Engineers and Scientists, Apress 2018.
        3. Jovanović, J.D., Grozdanić, D.K., Programiranje sa numeričkim metodama, TМF, Beograd 2017.
        4. Chopey,N.P.,Hicks,T.G.(eds.), Handbook of Chemical Engineering Calculations, McGraw.Hill, New York 1984.
        5. 2. Poling,B.E.,Prausnitz,J.M.,O’Connell,J.P., The Properties of Gases and Liquids, McGraw-Hill, New York 2001.
        Number of hours per week during the semester/trimester/year
        LecturesExercisesOTCStudy and ResearchOther classes
        22
        Methods of teachingLectures (2h weakly) Computer exercises (2h weakly)
        Knowledge score (maximum points 100)
        Pre obligationsPointsFinal examPoints
        Activites during lecturesTest paper
        Practical lessons60Oral examination30
        Projects
        Colloquia
        Seminars