Question:

Answer:

Beam deflection 01

Linearly distributed load, w₀ = 3 kN/m

E = 270 GPa, b = 200 mm and h = 400 mm

Moment of inertia, I =  = 1.0667 x 10⁹ mm^{4 (The Engineering ToolBox, (n.d.))}

EI = 270 GPa x 1.0667 x 10⁹ mm⁴ = 270 x 10³ N/mm² x 1.0667 x 10⁹ mm⁴ = 2.88 x 10¹⁴ Nmm²

Taking moments at B to the left hand side:

→ -R_AL + ( = 0

R_AL =  → R_A = ; and R_B =

Taking moment at a point x from support A to the left hand side:

 

( → M =

But M =  (Selvam & Bindhu, 2014)

Therefore

…………………………………………………………… (1)

Integrating equation 1 with respect to x gives

………………………………………………… (2)

Integrating equation 2 with respect to x gives

………………………………………. (3)

When x = 0, y = 0; substituting this in equation 3 gives:

0 = 0 – 0 + 0 + C2 → C2 = 0

When x = L, y = 0; substituting this in equation 3 gives:

→ ; C1 =

Substituting the value of C1 in equation 3 and making y the subject gives:

 

………………………………………………. (4)

Equation 4 is the equation of the elastic curve

Slope of the curve is determined by differentiating equation 4 with respect to x, which gives:

……………………….…………………….. (5)

At maximum deflection, slope,  (substituting this in equation 5)

0 = 30L²x² – 15x⁴ – 7L⁴ (where x is the point at maximum deflection)

15x⁴ – 30L²x² + 7L⁴ = 0

Solving this equation gives x² = 0.2697L² → x = 0.5193L

Thus maximum deflection is:

 

 

 

 

 

(ignore the negative sign) …………………………………….. (6)

Equation 6 is the maximum deflection of the beam

Substituting the values of E, I, w₀ and L in equation 6

EI = 2.88 x 10¹⁴ Nmm²; w₀ = 3 kN/m = 3 N/mm; L = L mm

 

y = 6.796 x 10^-17L⁴ mm (where L is the length of the beam in mm).

 

Beam deflection 02

E = 15 GPa, b = 200 mm and h = 400 mm

Moment of inertia, I =  = 1.0667 x 10⁹ mm⁴

EI = 15 GPa x 1.0667 x 10⁹ mm⁴ = 15 x 10³ N/mm² x 1.0667 x 10⁹ mm⁴ = 1.6 x 10¹³ Nmm²

→ R_A – (2 x 3) – 4 – 6 = 0; R_A = 16 kN

→ -M_A + (2 x 3 x 1.5) + (4 x 4.5) + (6 x 6) = 0; M_A = 63 kNm

Taking moments, M, at a point x from the left hand side

; R_Ax – M_A – ( = 0; 16x – 63 – x² = 0

M = -x² + 16x – 63 = 0

But M =  (Sigurdardottir, et al., 2017)

Therefore

=

Integrating the above equation gives

……………………………….…. (7)

Integrating the above equation gives

…………. (8)

Boundary conditions:

When x = 0, y = 0, and when x = 0, dy/dx = 0

Substituting dy/dx = 0 when x = 0 in equation 7 gives

0 =

C₁ = 0

Substituting y = 0 when x = 0 in equation 8 gives

→ C₂ = 0

Therefore equation of elastic curve is given as:

 

 

Substituting the value of EI = 1.6 x 10¹³ Nmm² = 16,000 kNm²

 

Beam deflection 03

Calculating support reactions:

Taking moments at B,

3R_A + 20(1.5) – (6 x 1.5 x 3.75) = 0; 3R_A = 3.75; R_A = 1.25 kN

R_B = [(6 x 1.5) + 20] = 1.25 = 27.75 kN

Taking moment at a point x along the beam

 

M =

M = -3x² + 3(x – 1.5)² + 1.25(x – 1.5) + 27.75(x – 4.5)

But M =

Therefore

= -3x² + 3(x – 1.5)² + 1.25(x – 1.5) + 27.75(x – 4.5)

Integrating the above equation gives

…………….. (9)

Integrating equation 7 above gives

…. (10)

Equation 9 and 10 above represents equation of slope and elastic curve of the beam respectively (Sulaiman, et al., 2015).

C₁ and C₂ are constants and are solved using boundary conditions.

The first boundary condition is that deflection is zero at support A, i.e. when x = 1.5m, y = 0

The second boundary equation is that deflection is zero at support B, i.e. when x = 4.5, y = 0

Substituting y = 0 when x = 1.5 m in equation 10 gives:

0 = -1.266 + 0 + 0 – 124.875 + 1.5C₁ + C₂

0 = -126.141 + 1.5C₁ + C₂ → 1.5C₁ + C₂ = 126.141 ……………………………….. (11)

Substituting y = 0 when x = 4.5 m in equation 10 gives:

0 = -102.516 + 20.25 + 5.625 + 0 + 4.5C₁ + C₂

0 = -76.641 + 4.5C₁ + C₂ → 4.5C₁ + C₂ = 76.641 …………………………………. (12)

Solving equations 9 and 10 gives:

C₁ = -16.59 and C₂ = 151.30

Therefore

Equation of the slope is:

 

 

Equation of the elastic curve is:

 

Beam deflection 04

Finding support reactions:

Taking moments at B

→ 6R_A – 4.5(20) – ( = 0; 6R_A = 105; R_A = 22.5 kN

R_B = (20 + ( – 22.5 = 20 kN

Taking moments at a point x from point A near point B to the left hand side

M = R_Ax – 20(x – 1.5) – {

M = R_Ax – 20(x – 1.5) – {7.5(x² – 6x + 9) + 5(x² – 6x + 9)}

M = R_Ax – 20(x – 1.5) – {12.5(x² – 6x + 9)

M = 22.5x – 20x + 30 – 12.5x² + 75x – 112.5

M = -12.5x² + 77.5x – 82.5

But M =

Therefore

= =

Integrating the above equation gives

…………………………… (13)

Integrating the above equation gives

………………… (14)

Equation 13 and 14 above represents equation of slope and deflection curve of the beam respectively, where C₁ and C₂ are constants and are solved using boundary conditions (Ramasamy, 2012).

The first boundary condition is that deflection is zero at support A, i.e. when x = 0 m, y = 0

The second boundary equation is that deflection is zero at support B, i.e. when x = L = 6, y = 0

Substituting y = 0 when x = 0 in equation 14 gives:

0 = 0 + 0 – 0 + 0 + C₂; C₂ = 0

Substituting y = 0 when x = 6 m in equation 14 gives:

0 = -1.0417(6)⁴ + 12.83(6)³ – 41.25(6)² + 6C₁ + 0

0 = -1350.04 + 2771.28 – 1485 + 6C₁; 6C₁ = 63.76 → C₁ = 10.63

Therefore,

Equation of slope is:

Equation of deflection is:

But at maximum deflection, slope is zero, i.e.

 

 

 

Solving this equation gives: x₁ = 6.02, x₂ = 0.14 and x₃ = 3.08 (University of Cambridge, (n.d.))

Since the span of the beam is 6m, it means that x cannot be 6.02, hence we remain with x = 0.14m or x = 3.08 m.

This means that maximum deflection can occur at a point x = 0.14m or x = 3.08m from support A

EI = (180 GPa) x (85 x 10⁶ mm⁴) = 180 x 10³ N/mm² x 85 x 10⁶ mm⁴ = 1.53 x 10¹³ Nmm² = 15,300 kNm²

Substituting the values of x and EI in the deflection equation gives:

When x = 0.14m:

=

= -0.000215m = 0.215 mm

When x = 3.08m:

 

= -0.00506m = 5.06 mm

Thus maximum deflection will occur at x = 3.08 and its value is 5.06 mm.

Beam deflection 05

Taking moments at B so as to determine support reactions

 

10R_A – (7 x 50) – (10 x 10 x 5) = 0 → 10R_A = 850 → R_A = 85 kN

R_B = 50 + (10 x 10) – 85 = 65 kN

Taking moments at a point x between C and B to the left hand side

M = R_Ax – 50(x – 3) –

M =

But M =

Therefore

= =

Integrating the above equation gives

…………………………… (15)

Integrating the above equation gives

………………… (16)

Equation 15 and 16 above represents equation of slope and displacement curve of the beam respectively.

C₁ and C₂ are constants and are solved using boundary conditions.

The first boundary condition is that deflection is zero at support A, i.e. when x = 0 m, y = 0

The second boundary equation is that deflection is zero at support B, i.e. when x = L = 10, y = 0

Substituting y = 0 when x = 0 in equation 16 gives:

→ C₂ = -225

Substituting y = 0 when x = 10 m in equation 16 gives:

Remember w = 10 kN/m

 

0 = -4166.67 + 14167 – 2858.22 + 10C₁ – 225

C₁ =-691.71

Therefore

Equation for slope,

Equation for displacement,

EI = 200 GPa x 65 x 10⁶ mm⁴

EI = 200 GPa x 65 x 10⁶ mm⁴ = 200 x 10³ N/mm² x 65 x 10⁶ mm⁴ = 1.3 x 10¹³ Nmm² = 13,000 kNm²

Slope at A:

At A, x = 0, w = 10 kN/m and EI = 13,000 kNm²; substituting these values in slope equation gives:

Δ_A =  =  = -0.917 radians = 0.917 radians

Slope at B:

At B, x = 10, w = 10 kN/m and EI = 13,000 kNm²; substituting these values in slope equation gives:

Δ_B =  =

= 0.0492 radians

Displacement at C:

At C, x = 3, w = 10 kN/m and EI = 13,000 kNm²; substituting these values in displacement equation gives

 

= -0.15 m = 0.00015 mm

References

Ramasamy, V. R. P., 2012. Strength of materials. New delhi: Perason India.

Selvam, V. & Bindhu, K., 2014. Computation of deflection and slope in beams by using Maxwell-Betti theorem. Journal of Structural Engineering, 41(3), pp. 279-286.

Sigurdardottir, D., Stearns, J. & Glisic, B., 2017. Error in the determination of the deformed shape of prismatic beam using double integration of curvature. Smart Materials and Structures, 26(7).

Sulaiman, H., Othman, M., Aziz, M. & M.M.F.A., 2015. Theory and applications of applied electromagnetics: APPEIC 2014. Cham, Switzerland: Springer International Publishing.

The Engineering ToolBox, (n.d.). Area moment of inertia – typical cross sections I. [Online]
Available at: http://www.engineeringtoolbox.com/area-moment-inertia-d_1328.html
[Accessed 25 September 2017].

University of Cambridge, (n.d.). How to discover for yourself the solution of the cubic. [Online]
Available at: https://www.dpmms.cam.ac.uk/~wtg10/cubic.html
[Accessed 25 September 2017].