{"id":6534,"date":"2019-12-14T16:43:54","date_gmt":"2019-12-14T16:43:54","guid":{"rendered":"https:\/\/www.inspirenignite.com\/vtu\/mechanics-of-materials-aero-3rd-sem-syllabus-for-vtu-be-2017-scheme\/"},"modified":"2019-12-14T16:43:54","modified_gmt":"2019-12-14T16:43:54","slug":"mechanics-of-materials-aero-3rd-sem-syllabus-for-vtu-be-2017-scheme","status":"publish","type":"post","link":"https:\/\/www.inspirenignite.com\/vtu\/mechanics-of-materials-aero-3rd-sem-syllabus-for-vtu-be-2017-scheme\/","title":{"rendered":"Mechanics of Materials Aero 3rd Sem Syllabus for VTU BE 2017 Scheme"},"content":{"rendered":"

Mechanics of Materials detail syllabus for Aeronautical Engineering (Aero), 2017 scheme is taken from VTU<\/a> official website and presented for VTU students. The course code (17AE34), 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 aero 3rd sem syllabus for be 2017 scheme vtu you can visit Aero 3rd Sem syllabus for BE 2017 Scheme VTU Subjects<\/a>. The detail syllabus for mechanics of materials is as follows.<\/p>\n

Course Objectives:<\/h4>\n

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

    \n
  1. Comprehend the basic concepts of strength of materials.<\/li>\n
  2. Acquire the knowledge of stress, strain under different loadings.<\/li>\n
  3. Understand the different failure theory.<\/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

    Euler-Bernoulli beam theory: The Euler-Bernoulli assumptions, Implications of the Euler-Bernoulli assumptions, Stress resultants Beams subjected to axial loads, Beams subjected to transverse loads, Beams subjected to combined axial and transverse loads. Three-dimensional beam theory: Kinematic description, Sectional constitutive law, Sectional equilibrium equations, governing equations, Decoupling the three-dimensional problem, The principal centroidal axes of bending. The neutral axis, Evaluation of sectional stiffness.\t\t\t\t<\/p>\n

    .\n<\/p>\n

    Module 3<\/h4>\n

    Torsion: Torsion of circular cylinders, Torsion combined with axial force and bending moments, Torsion of bars with arbitrary cross-sections, Torsion of a thin rectangular cross-section, Torsion of thinwalled open sections. Thin-walled beams: Basic equations for thin-walled beams, Bending of thin-walled beams, Shearing of thin-walled beams. The shear centre. Torsion of thin-walled beams, Coupled bending-torsion problems Warping of thin-walled beams under torsion. Equivalence of the shear and twist centres, Non-uniform torsion, Structural idealization.\t\t\t\t<\/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

    Yielding: Yielding under combined loading, Applications of yield criteria to structural, Application to bars, trusses and beams. Buckling of beams: Rigid bar with root torsion spring, buckling of beams, buckling of sandwich beams. Shearing deformations in beams, Shear deformable beams: an energy approach. Kirchhoff plate theory: Governing equations of Kirchhoff plate theory, The bending problem, Anisotropic plates, Solution techniques for rectangular plates, Circular, Energy formulation of Kirchhoff plate theory, Buckling of plates.\t<\/p>\n

    Course Outcomes:<\/h4>\n

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

      \n
    1. Apply the basic concepts of strength of materials.<\/li>\n
    2. Compute stress, strain under different loadings.<\/li>\n
    3. Distinguish the different failure theories.<\/li>\n<\/ol>\n

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