Theory of Simple Bending: Assumptions and Neutral Axis - C-16-C-302

1. e LESSON MODULE FOR C-16 CURRICULUM, SBTET& ANDHRA PRADESH Year/Semester : III semester Branch : Civil Engineering Subject : Strength of Materials& Theory of Structures Subject code : C-302 Topic : Theory of Simple Bending Sub topic : Assumptions of Theory of Simple Bending Duration : 100 min Revised By : Dr.K.Lakshmi Pathi D.Haseena N.Srujana M.Yerri Swamy H.O.D : Dr.K.Lakshmi Pathi Venue : G.P.W, Hindupur C-16-C-302.1.3&1.4

2. Objectives • On completion of this period, you would be able to understand • The basic assumptions in theory of simple bending • The concept of Neutral Axis • Finding stresses in un – symmetrical sections C-16-C-302.1.3&1.4

3. Recap • In the previous session we have discussed about • Definition of beam, Bending moment, Shear force • Sign convention ,Relation between S.F., B.M & intensity of loading (w) • Neutral layer, Neutral axis, Modulus of section, Moment of resistance • Concept of theory of simple bending/pure bending C-16-C-302.1.3&1.4

4. R Assumptions in theory of pure bending/simple bending • The beam is initially straight before the application of loads on it • The material of the beam is homogeneous and isotropic – same elastic properties in all directions and at all points C-16-C-302.1.3&1.4

5. R Assumptions in theory of pure bending/simple bending • Elastic limit is not exceeded • Transverse sections which are plane before bending remain plane after bending C-16-C-302.1.3&1.4

6. R Assumptions in theory of pure bending/simple bending • Each layer of the beam is free to expand or contract independently of the layers above or below it • Young’s modulus of elasticity ‘E’ of the material is same in tension and compression C-16-C-302.1.3&1.4

7. R Assumptions in theory of pure bending/simple bending • Beam section is symmetrical about the plane of bending • There is no resultant pull or push on the cross section of the beam C-16-C-302.1.3&1.4

8. R Assumptions in theory of pure bending/simple bending • The loads are applied in the plane of bending • The transverse section of the beam is symmetrical about a line passing through the centre of gravity in the plane of bending C-16-C-302.1.3&1.4

9. R Assumptions in theory of pure bending/simple bending • The radius of curvature of the beam before bending is very large in comparison to the transverse dimension • As a result of a bending moment or couple, length of beam will take up a curved shape C-16-C-302.1.3&1.4

10. R Assumptions in theory of pure bending/simple bending • A very short length may be treated as a part of the arc of a circle • It follows that at the outer radii the material will be subjected to tension and at the inner radii is subjected to compression. C-16-C-302.1.3&1.4

11. R Assumptions in theory of pure bending/simple bending • At some radius there will be no stress • This layer of the material is the neutral layer or neutral axis C-16-C-302.1.3&1.4

12. ASSUMPTIONS OF THEORY OF PURE BENDING C-16-C-302.1.3&1.4

13. ASSUMPTIONS OF THEORY OF PURE BENDING • Click Here C-16-C-302.1.3&1.4

14. Bending stresses in a beam • Above the neutral axis bending stresses are compressive • Below the neutral axis bending stresses are tensile C-16-C-302.1.3&1.4

15. Bending Stress in a Beam • Click Here C-16-C-302.1.3&1.4

16. Neutral axis for symmetrical sections For symmetrical beams, NA lies exactly at the center of the depth yc = yt = D/2 Extreme fibre stresses are equal Fig.2 C-16-C-302.1.3&1.4 16

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19. Neutral axis for unsymmetrical sections If the NA does not lie exactly at the centre of the depth, the beam is known as unsymmetrical beam   yc≠ yt Extreme fibre stresses are not equal Fig.3 C-16-C-302.1.3&1.4 19

20. Problems • An unsymmetrical simply supported beam of depth 480mm is subjected to compressive stress of 20N/mm2 and tension stress of 80N/mm2. Find the position of NA from the top? σc=20N/mm2 A N 480 - X σt=80N/mm2 C-16-C-302.1.3&1.4

21. σc=40N/mm2 σt=? 2)A triangular beam of depth 300 mm is subjected to a max comp stress of 40N/mm2 at the top. Find the tensile stress at the bottom of the beam? N A C-16-C-302.1.3&1.4

22. σc=? σt=30N/mm2 3)A triangular beam of depth 240 mm is subjected to a tensile stress 30 N/mm2 find the corresponding comp. stress? C-16-C-302.1.3&1.4

23. 4)An unsymmetrical beam of depth 500mm is subjected to tensile stress of 120N/mm2 and comp. stress of 80N/mm2. Locate the position of NA from the top? σc=80N/mm2 x N A 500-x σt=120N/mm2 C-16-C-302.1.3&1.4

24. 5) An unsymmetrical beam of depth 300mm is subjected to a comp stress of 40N/mm2 and tension stress of 160 N/mm2 at the bottom. Find the position of NA from the top? σc=40N/mm2 x N A 300-x σt=160 N/mm2 C-16-C-302.1.3&1.4

25. Calculation of Section Modulusfor Standard Sections C-16-C-302.1.3&1.4 25

26. Rectangular Section y N A C-16-C-302.1.3&1.4 26

27. Section modulus (Z)(or) modulus of section It is the ratio of moment of inertia and distance of the most extreme fibre from the NA It is denoted by ‘Z’ Z = Moment of Inertia / Centroidal distance of extreme fibre Z= I / Ymax C-16-C-302.1.3&1.4 27

28. Square Section C-16-C-302.1.3&1.4 28

29. Circular Section C-16-C-302.1.3&1.4 29

30. Hollow Circular Section C-16-C-302.1.3&1.4 30

31. Hollow Rectangular Section C-16-C-302.1.3&1.4 31

32. Section modulus (z) for Unsymmetrical section Y c N A Y t Z = I / Ymax C-16-C-302.1.3&1.4

33. Triangular Section Yc N A Yt C-16-C-302.1.3&1.4 33

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