unsymmetricalbending 141021064752 conversion gate01

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UNSYMMETRICAL BENDING OF BEAMS Under the guidance of Dr. M. V. RENUKA DEVI Associate Professor Department of Civil Engineering, RVCE, Bangalore By VENKATESHA A (1RV13CSE15)

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Page 1: Unsymmetricalbending 141021064752 Conversion Gate01

UNSYMMETRICAL BENDING OF BEAMS

Under the guidance

of

Dr. M. V. RENUKA DEVI

Associate Professor

Department of Civil Engineering,

RVCE, Bangalore

By

VENKATESHA A

(1RV13CSE15)

Page 2: Unsymmetricalbending 141021064752 Conversion Gate01

PURE BENDING Bending is a very severe form of stressing a structure The simple bending theory applies when bending takes place about an axis

which is perpendicular to a plane of symmetry. Bending moments acts along the axis of the member.

Assumptions made in pure bending

1. The normal planes remain normal even after bending.

2. There is no net internal axial force.

3. Stress varies linearly over cross section.

4. Zero stress exists at the centroid and the line of centroid is the Neutral Axis (N.A)

Page 3: Unsymmetricalbending 141021064752 Conversion Gate01

•Bending stress and strain at any point may be computed as

Page 4: Unsymmetricalbending 141021064752 Conversion Gate01

Symmetrical bending : The plane of loading or the plane of bending is co-incident with or parallel to, a plane containing principal centroidal axes of inertia of the cross-section of the beam.

Bending stress is given by

Bending stress along N.A is = 0

Page 5: Unsymmetricalbending 141021064752 Conversion Gate01

UNSYMMETRICAL BENDING

Assumptions

1. The plane sections of the beam remain plane after bending

2. The material of the beam is homogeneous and linearly elastic.

3. There is no net internal axial force.

Sign conventions and notation

u, v and w are the displacement components of any point within beam parallel to x, y, z axes. P = axial load and T = torque (z) and (z)are distributed loadsand are applied bending moments

Page 6: Unsymmetricalbending 141021064752 Conversion Gate01

Fig. Representation of positive internal and external force systems

•We assume and as positive when they each induce tensile stresses in the positive xy quadrant of the beam section.

Page 7: Unsymmetricalbending 141021064752 Conversion Gate01

PRODUCT SECOND MOMENT OF AREA

The second moments of area of the surface about the X and Y axes are defined as

Similarly, the product second moment of area of the section is defined as follows

Page 8: Unsymmetricalbending 141021064752 Conversion Gate01

Since the cross-section of most structural members used in bending applications consists of a combination of rectangles the value of the product second moment of area for such sections is determined by the addition of the Ixx value for each rectangle.

Where h and k are the distances of the centroid of each rectangle from the X and Y axes respectively (taking account of the normal sign convention for x and y) and A is the area of the rectangle.

Page 9: Unsymmetricalbending 141021064752 Conversion Gate01

DETERMINATION OF PRINCIPAL AXIS OF SECTION

Let, U-U, V-V be the Principal Centroidal Axes, X-X, Y-Y be the pair of orthogonal axes, α be the angle between both the axes system, 𝜕𝑎 Be the elementary area with co-ordinates (u, v) referred to the principal axes i.e.,

U-V axes and (x, y) referred to the X-Y axes, Since, U-V axes are principal axes the product of inertia = 0

Page 10: Unsymmetricalbending 141021064752 Conversion Gate01

The relationship between (x, y) and (u, v) co-ordinates are given by

Now substituting for u and v in the above equations we get,

By definition ;;;

;;;

u = AB+DP = v = GP-HG =GP-EF =

+ - 2

+ -

Page 11: Unsymmetricalbending 141021064752 Conversion Gate01

Similarly, + + - - - we have, therefore we can write

=

and

= + - = - +

Page 12: Unsymmetricalbending 141021064752 Conversion Gate01

we can write for and as follows

Thus knowing the values of , and , the principal moments of inertia and can be calculated from the above analytical expression. Note: moment of inertia of a section about its principal axes have maximum and minimum values.

=

=

Substituting the values of and

= +

= -

Page 13: Unsymmetricalbending 141021064752 Conversion Gate01

DIRECT STRESS DISTRIBUTION

We know that a beam bends about the neutral axis of its cross section so that the radius of curvature, R, of the beam is perpendicular to the neutral axis.

Fig. bending of an unsymmetrical beam section

= E

Page 14: Unsymmetricalbending 141021064752 Conversion Gate01

The beam section is subjected to a pure bending moment so that the resultant direct load on the section is zero. Hence

For a beam of a given material subjected to a given bending moment

Above equation states that the first moment of area of the beam section about the neutral axis is zero. It follows pure bending of beams in which the neutral axis always passes through the centroid of the beam section.

) The moment resultants of the direct stress distribution are

= , =

Page 15: Unsymmetricalbending 141021064752 Conversion Gate01

Substituting for

= +

= +

= + ; = + Bending stress is written as

Where,

;

In the case where the beam section has either Ox or Oy (or both) as an axis of symmetry, then is zero and Ox, Oy are principal axes, ,

Page 16: Unsymmetricalbending 141021064752 Conversion Gate01

Position of the neutral axis

The direct stress at all points on the neutral axis of the beam section is zero. Thus,

O = Where and are the coordinates of any point on the neutral

axis. Thus

= Since is positive when is negative and is positive

Page 17: Unsymmetricalbending 141021064752 Conversion Gate01

DEFLECTION OF BEAM UNDER UNSYMMETRICAL BENDING

Let the bending moment “M” inclined at an angle “θ” with one of principal planes (Say VV-axis)Along UU-axis M component will be = M Along VV-axis M component will be = M

Page 18: Unsymmetricalbending 141021064752 Conversion Gate01

From the application of principal of virtual work (unit load method) the deflection (δ) of the beam in any direction, due to a bending moment M is given by

=

Where,

M = moment due to applied moment (say M)

m = moment due to unit load applied at the point in the direction of the desired deflections,

dx = elementary length of beam, measured along the span of the beam

Hence the deflection of the beam in the direction of VV- axis is given by

=

Hence the deflection of the beam in direction of UU-axis is given by

=

The resultant deflection is given by

=

Page 19: Unsymmetricalbending 141021064752 Conversion Gate01

Since , are the moments developed due to unit load applied, it can be taken both equal to m i.e. (= = m)

If β is the inclination of neutral axis (NN-axis) with respect to UU-axis we can write as

=

Let γ be the inclination of resultant deflection in the direction -axis makes with UU-axis

= - = -

= - = - =

Therefore we can write as

=

Page 20: Unsymmetricalbending 141021064752 Conversion Gate01

Hence the resultant deflection occurs in the direction exactly perpendicular to the neutral axis (- axis perpendicular to NN-axis)

Let us consider the case of simply supported beam (SSB) subjected to UDL, then,

= ; = =

= Multiplying and dividing by

=

Thus from the above expression for a simply supported beam (SSB) we can conclude that the term w cos(β−θ) is the resultant udl acting along - axis which is perpendicular to neutral axis.

Page 21: Unsymmetricalbending 141021064752 Conversion Gate01

PROBLEMS ON UNSYMMETRICAL BENDING A Cantilever Problem

1.A horizontal cantilever 2 m long is constructed from the Z-section shown below. A load of 10 KN is applied to the end of the cantilever at an angle of 60°to the horizontal as shown. Assuming that no twisting moment is applied to the section, determine the stresses at points A and B.

2.Determine the principal second moments of area of the section and hence, by applying the simple bending theory about each principal axis, check the answers obtained in part1.

3. What will be the deflection of the end of the cantilever? E = 200 GPa.

( = 48.3 x , = 4.4 x )

Page 22: Unsymmetricalbending 141021064752 Conversion Gate01

In the given section for the web is zero since its centroid lies on both axes and hence h and k are both zero. The contributions to of the other two portions will be negative since in both cases either h or k is negative.

Therefore, = -2(80 x 18) (40 - 9) (120 - 9)

= -9.91 x

= +10000 sin x 2 = +17320 Nm

= -10000 cos x 2 = -10000 Nm

But we have,

Let = P, = Q

= P + Q ; = -P - Q

17320 = P (-9.91) x + Q 48.3x

-10000 = P (-4.4x) + Q 9.91x

Solving the above two equations for P and Q,

P = 5725x; Q = 1533x

Page 23: Unsymmetricalbending 141021064752 Conversion Gate01

The inclination of the N.A relative to the X axis is then given by

= = - = - = - 3.735

=

Now

= P x + Q y

Stress at A = 5725xx 9x+ 1533xx 120x

= 235 N/

Similarly stress at B = 235 MN/

The points A and B are on both side of neutral axis and equidistant from it. Stresses at A and B are therefore of equal magnitude but with opposite sign.

Page 24: Unsymmetricalbending 141021064752 Conversion Gate01

2. The principal second moments of area may be found from the following equations

= +

= +

= 50.43

= -

= -

= 2.27

= = = 0.451

= , =

Page 25: Unsymmetricalbending 141021064752 Conversion Gate01

The required stresses can now obtained from the above equation

= 10000 -) x 2

= 10000)

= 14828 Nm and

= 10000) x 2

= 13422 Nm

And, for A,

u = x+ y

u = (9 x 0.9776) + (120 x 0.2105) = 34.05 mm

v = y- x

v = (120 x 0.9776) - (9 x 0.2105) = 115.5 mm

= 235 MN/ as obtained before

Page 26: Unsymmetricalbending 141021064752 Conversion Gate01

3. The deflection at free end of a cantilever is given by

Therefore the component of deflection perpendicular to the V axis

= = 39.4 mm

And component of deflection perpendicular to the U axis

= = 1.96 mm

The total deflection is then given by

= = = 39.45 mm

Its direction is normal to the N.A.

Page 27: Unsymmetricalbending 141021064752 Conversion Gate01

UNSYMMETRICAL CANTILEVER UNIT [11] To demonstrate unsymmetrical bending of

beams Determines deflections along u and v

directions Consist of 1. Main column (cantilever specimen

clamped at its bottom)2. Loading head at upper end – can rotate

with intervals about vertical axis3. Set of pulley, located at the loading head,

to apply a horizontal load.4. 2 Dial gauges of 0-25 mm and 0.01

mm accuracy, to measure and deflections. Poligona industrial san jose de valderas,

spain demonstrated this model. Limitations-Dimensions: 400 x 300 x 400 mm approx. -Weight: 14 Kg. approx.

Page 28: Unsymmetricalbending 141021064752 Conversion Gate01

IMPORTANCE OF UNSYMMETRICAL BENDING If the plane of bending or plane of loading does not lie in or parallel to the

plane that contains the principal centroidal axes of cross-section, the bending is called as unsymmetrical bending.

Members that are not symmetrical about the vertical axes and which are typically composed of thin unsymmetrical sections (e.g. ISA, Channel) undergo phenomenon of twisting under the transverse loads.

A channel section carrying the transverse load would twist because the line of action of the load does not pass through shear centre of the member.

whereas rectangular beam would not twist because the loading would pass through the centre of gravity of the section and for such two axis symmetrical section the shear centre would coincide with the cg of the section.

If one is desired to use unsymmetrical sections to carry transverse loads without twisting, it is possible to do so by locating the load so that it passes through the shear centre of the beam.

Page 29: Unsymmetricalbending 141021064752 Conversion Gate01

CONCLUSION The axis of about which the product moment of inertia is zero is called as

principal axis. Hence we can conclude by saying that the simple bending theory is applicable for bending about principal axes only.

It should be noted that moment of inertia of a section about its principal axes have maximum and minimum values respectively.

The resultant deflection for simply supported beam subjected unsymmetrical bending is

= The resultant deflection for cantilever beam is

Taking =

In order to overcome the effect of twisting when the beam subjected to unsymmetrical loading, the study of unsymmetrical bending is useful.

Page 30: Unsymmetricalbending 141021064752 Conversion Gate01

REFERENCES

1. Arthur P. Boresi, Richard J.Schindt, “Advanced Mechanics of materials”, Sixth edition John Wiley &Sons. Inc., New Delhi, 2005

2. Thimoshenko & J N Goodier, “Mechanics Of Solids”, Tata McGraw-Hill publishing Co.Ltd, New Delhi, 1997

3. Seely Fred B. and Smith James O., “ Advanced Mechanics of Materials”, 2nd edition, John Wiley & Sons Inc, New York, 1952

4. Srinath L.S., “Advanced Mechanics of Solids”, Tata McGraw-Hill publishing Co.Ltd, New Delhi, 1980

5. Thimoshenko S., “Strength of Materials”, Part-1, Elementary Theory and Problems, 3 rd Edition, D. Van Nostrand company Inc., New York, 1955

6. Boresi A.P and Chong K.P(2000), “Elasticity In Engineering Mechanics” 2nd edition New York ; Wiley – Interscience.

7. N Krishna Raju & D R Gururaja, “Advance Mechanics Of Solids & Structures”, 1997

8. B C Punmia & A K Jain. “Strength of Materials and Theory of Structures”, Vol.2 Lakshmi publications (P) Ltd.2002

9. Jiang Furu, “Unsymmetrical Bending Of Cantilever Beams”, Appl. Math. & Mech. (English Ed.), 1982

10. G. D. Williams, D. R. Bohnhoff, R. C. Moody, “Bending Properties of Four-Layer Nail- Laminated Posts”, United States Department of Agriculture, Forest Service (Forest Products Laboratory), Research Paper FPL–RP–528, 1994

11. Poligona industrial san jose de valderas, spain, “Unsymmetrical Cantilever Unit”, ED01/12, 2012