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22MEIP - Heat integration

Course specification
Course titleHeat integration
Acronym22MEIP
Study programmeBiochemical Engineering and Biotechnology
Module
Lecturer (for classes)
Lecturer/Associate (for practice)
    Lecturer/Associate (for OTC)
      ESPB4.0Status
      Condition-Облик условљености
      The goalThe aim of the course is to provide fundamental understanding of the methods of process and energy integration, as well as capital and operating cost minimisation, based on the increase of the energy efficiency of the chemical and process plants, as well as with cleaner production concept implementation.
      The outcomeStudents gain knowledge necessary for the: developing of the methodology for the identification of the strategies for using renewable and other energy sources, energy analyses of the existing process equipment and the whole process, particularly in terms of increasing energy efficiency compared to existing solutions in the process industries (processes energy conservation) and the reduction of thermal environmental pollution.
      Contents
      Contents of lecturesI THERMODYNAMIC PROCESS ANALYSIS (THERMODYNAMIC MODEL SELECTION AND DETERMINATION OF APPROPRIATE PARAMETERS) II ANALYSIS OF PROCESS HEAT AND MATERIAL BALANCES - COMPARISON WITH REAL PROCESS PARAMETERS. III ENERGY ANALYSIS OF PROCESS EQUIPMENT APPLICATION OF DIRECT AND INDIRECT HEAT PUMP IN DISTILLATION. IV PROCESS MODEL VERIFICATION, SENSITIVITY ANALYSIS AND OPTIMIZATION V ENERGY AND PROCESS NETWORK SYNTHESIS-ENERGY CONSERVATION AND THERMAL ENERGY MANAGEMENT VI THE INTRODUCTION AND IMPLEMENTATION OF CLEANER PRODUCTION PRINCIPLES (INCREASE OF THE ENERGY EFFICIENCY OF EQUIPMENTS AND PROCESSES, CONSUMPTION OF RAW AND AUXILIARY FLUIDS REDUCTION, ETC.).
      Contents of exercisesComputer simulations that follow the theoretical classes (determination of appropriate process parameters; simulation of process and heat integration) and seminars.
      Literature
      1. B. Đorđević, M. Kijevčanin: Energetika procesne industrije, internal material, Faculty of Technology and Metallurgy, Beograd, 2012.
      2. Reference literature:
      3. 1) R. Smith, Chemical Process Design and Integration, Wiley, New York, 2014.
      4. 2) B. Linnhoff, D.W. Townsend, D. Boland, G. F. Hewitt, B.E.A. Thomas, A. R. Guy and R. H. Marsland, User Guide on Process Integration for the Efficient Use of Energy, IChemE, UK, 1994.
      5. 3) M.M. El-Halwagi, Sustainable Design through Process Integration: Fundamentals and Applications to Industrial Pollution Prevention, Resource Conservation, and Profitability Enhancement,Elsevier, 2017.
      Number of hours per week during the semester/trimester/year
      LecturesExercisesOTCStudy and ResearchOther classes
      21
      Methods of teachingTheoretical and practical lectures.
      Knowledge score (maximum points 100)
      Pre obligationsPointsFinal examPoints
      Activites during lecturesTest paper30
      Practical lessonsOral examination
      Projects
      Colloquia
      Seminars70