{"id":7297,"date":"2019-12-14T16:53:10","date_gmt":"2019-12-14T16:53:10","guid":{"rendered":"https:\/\/www.inspirenignite.com\/vtu\/momentum-transfer-petro-3rd-sem-syllabus-for-vtu-be-2017-scheme\/"},"modified":"2019-12-14T16:53:10","modified_gmt":"2019-12-14T16:53:10","slug":"momentum-transfer-petro-3rd-sem-syllabus-for-vtu-be-2017-scheme","status":"publish","type":"post","link":"https:\/\/www.inspirenignite.com\/vtu\/momentum-transfer-petro-3rd-sem-syllabus-for-vtu-be-2017-scheme\/","title":{"rendered":"Momentum Transfer Petro 3rd Sem Syllabus for VTU BE 2017 Scheme"},"content":{"rendered":"

Momentum Transfer detail syllabus for Petroleum Engineering (Petro), 2017 scheme is taken from VTU<\/a> official website and presented for VTU students. The course code (17CH32), and for exam duration, Teaching Hr\/week, Practical Hr\/week, Total Marks, internal marks, theory marks, duration and credits do visit complete sem subjects post given below.<\/p>\n

For all other petro 3rd sem syllabus for be 2017 scheme vtu you can visit Petro 3rd Sem syllabus for BE 2017 Scheme VTU Subjects<\/a>. The detail syllabus for momentum transfer is as follows.<\/p>\n

Course Objectives:<\/h4>\n

The students will<\/p>\n

    \n
  1. Understand concepts on nature of fluids, pressure concepts and measurement of pressure by various experimental methods and by mathematical relations and enhancement of problem solving skills.<\/li>\n
  2. Learn detailed explanation on types of fluids, stress and velocity relations, type of fluid flow and boundary layer relations.<\/li>\n
  3. Understand relationship between kinetic energy, potential energy, internal energy and work complex flow systems using Bernoulli’s equation with application to industrial problems.<\/li>\n
  4. Understand clear concepts on Flow of incompressible fluids in conduits and thin layers and friction factor variations with velocity and friction losses using Bernoulli’s Equations and they will be demonstrated experimentally.<\/li>\n
  5. Study Flow of compressible fluids, Dimensional analysis, Dimensional homogeneity and various dimensionless numbers and their applications.<\/li>\n
  6. Understand principles and working of various types of pumps, transportation and metering of fluids using various experimental techniques and applications to industry.<\/li>\n<\/ol>\n

    Module 1
    \nFor complete syllabus and results, class timetable and more pls     download iStudy<\/a>. Its a light weight, easy to use, no images, no pdfs platform to make students life easier.<\/p>\n

    Module 2
    \n<\/h4>\n

    BASIC EQI Average vel Bernoulli eq factors, Pum equation.\tUATIONS OF FLUID FLOW: ocity, Mass velocity, Continuity equation, Euler and uations Modified equations for real fluids with correction p work in Bernoulli equation, Angular momentum
    \nFLOW OF INCOMPRESSIBLE FLUIDS IN CONDUITS AND THIN LAYERS: Laminar flow through circular and non-circular conduits, Hagen, Poiseuille equation, Laminar flow of non-Newtonian liquids. Turbulent flow\n<\/p>\n

    Module 3
    \n<\/h4>\n

    FLOW OF INCOMPRESSIBLE FLUIDS IN CONDUITS AND THIN LAYERS \ud83d\ude41 Contd…) Friction factor chart, friction from changes in velocity or direction, Form friction losses in Bernoulli equation, Flow of fluids in thin layers.
    \nFLOW OF COMPRESSEBLE FLUIDS: Continuity equation, Concept of Mach number, Total energy balance, Velocity of sound, Ideal gas equations, Flow through variable-area conduits, Adiabatic frictional flow, Isothermal frictional flow (elementary treatment only).\n<\/p>\n

    Module 4
    \nFor complete syllabus and results, class timetable and more pls     download iStudy<\/a>. Its a light weight, easy to use, no images, no pdfs platform to make students life easier.<\/p>\n

    Module 5
    \n<\/h4>\n

    PUMPS: Performance and Characteristics of pumps-positive displacement and centrifugal pumps, Fans, compressors, and blowers.
    \nDIMENSIONAL ANALYSIS: Dimensional homogeneity, Rayleigh’s and Buckingham’ s n- methods, Significance of different dimensionless numbers, Elementary treatment of similitude between model and prototype.\n<\/p>\n

    Course Outcomes:<\/h4>\n

    On completion of this course the students will be able to<\/p>\n

      \n
    1. Analyze different types of fluids and they will be able to measure pressure difference for flow of fluids.<\/li>\n
    2. Understand and analyze the relationship between kinetic and potential energy, internal energy, work, and heat in complex flow systems using Bernoulli’s equation, perform macroscopic energy balances.<\/li>\n
    3. Analyze and calculate friction factor for different types of flow in various types of constructions.<\/li>\n
    4. Develop mathematical relations using Dimensional analysis by Rayleigh and Buckingham – n method.<\/li>\n<\/ol>\n

      Graduate Attributes (as per NBA):<\/h4>\n
        \n
      1. Design and Development of Solutions.<\/li>\n
      2. Problem Analysis<\/li>\n<\/ol>\n

        Question paper pattern:<\/h4>\n