{"id":6579,"date":"2019-12-14T16:44:19","date_gmt":"2019-12-14T16:44:19","guid":{"rendered":"https:\/\/www.inspirenignite.com\/vtu\/aero-thermodynamics-as-3rd-sem-syllabus-for-vtu-be-2017-scheme\/"},"modified":"2019-12-14T16:44:19","modified_gmt":"2019-12-14T16:44:19","slug":"aero-thermodynamics-as-3rd-sem-syllabus-for-vtu-be-2017-scheme","status":"publish","type":"post","link":"https:\/\/www.inspirenignite.com\/vtu\/aero-thermodynamics-as-3rd-sem-syllabus-for-vtu-be-2017-scheme\/","title":{"rendered":"Aero-Thermodynamics AS 3rd Sem Syllabus for VTU BE 2017 Scheme"},"content":{"rendered":"

Aero-Thermodynamics detail syllabus for Aerospace Engineering (As), 2017 scheme is taken from VTU<\/a> official website and presented for VTU students. The course code (17AS33\/ 17AE33), 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 as 3rd sem syllabus for be 2017 scheme vtu you can visit AS 3rd Sem syllabus for BE 2017 Scheme VTU Subjects<\/a>. The detail syllabus for aero-thermodynamics is as follows.<\/p>\n

Course Objectives:<\/h4>\n

This course will enable students to<\/p>\n

    \n
  1. Understand various concepts and definitions of thermodynamics.<\/li>\n
  2. Comprehend the I law and II law of thermodynamics.<\/li>\n
  3. Acquire the knowledge of various types of gas cycles<\/li>\n<\/ol>\n

    Module 1 <\/h4>\n

    For 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<\/h4>\n

    First Law of Thermodynamics: Joules experiments, equivalence of heat and work. Statement of the First law of thermodynamics, extension of the First law to non – cyclic processes, energy, energy as a property, modes of energy, pure substance; definition, two-property rule, Specific heat at constant volume, enthalpy, specific heat at constant pressure. Extension of the First law to control volume; steady state-steady flow energy equation, important applications, analysis of unsteady processes such as film and evacuation of vessels with and without heat transfer.\n<\/p>\n

    Module 3 <\/h4>\n

    Second Law of Thermodynamics: Devices converting heat to work; <\/p>\n

      \n
    1. in a thermodynamic cycle,<\/li>\n
    2. in a mechanical cycle.<\/li>\n<\/ol>\n

      Thermal reservoir. Direct heat engine; schematic representation and efficiency. Devices converting work to heat in a thermodynamic cycle; reversed heat engine, schematic representation, coefficients of performance. Kelvin – Planck statement of the Second law of Thermodynamics; PMM I and PMM II, Clausius statement of Second law of Thermodynamics, Equivalence of the two statements; Reversible and Irreversible processes; factors that make a process irreversible, reversible heat engine, Carnot cycle, Carnot principles. Entropy: Clasius inequality; Statement, proof, application to a reversible cycle. Entropy; definition, a property, change of entropy, principle of increase in entropy, entropy as a quantitative test for irreversibility, calculation of entropy using Tds relations, entropy as a coordinate. Available and unavailable energy.\n<\/p>\n

      Module 4 <\/h4>\n

      For 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 <\/h4>\n

      Gas Cycles: Efficiency of air standard cycles, Carnot, Otto,
      \nDiesel cycles, P-V & T-S diagram, calculation of efficiency; Carnot vapour power cycle, simple Rankine cycle, Analysis and performance of Rankine Cycle, Ideal and practical regenerative Rankine cycles – Reheat and Regenerative Cycles, Binary vapour cycle.\n<\/p>\n

      Course Outcomes:<\/h4>\n

      After studying this course, students will be able to:<\/p>\n

        \n
      1. Apply the concepts and definitions of thermodynamics.<\/li>\n
      2. Differentiate thermodynamic work and heat and apply I law and II law of thermodynamics to different process.<\/li>\n
      3. Apply the principles of various gas cycles.<\/li>\n<\/ol>\n

        Graduate Attributes (as per NBA):<\/h4>\n