Structural Analysis, Si Edition (mindtap Course List)
Structural Analysis, Si Edition (mindtap Course List)
6th Edition
ISBN: 9781337630948
Author: KASSIMALI, Aslam
Publisher: Cengage Learning
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Chapter 6, Problem 6P
To determine

Find the equations for slope and deflection of the beam using direct integration method.

Expert Solution & Answer
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Answer to Problem 6P

For segment AB:

The equation for slope is PaL6EI(13x2L2)_.

The equation for deflection is PaxL6EI(1x2L2)_.

For segment BC:

The equation for slope is PLEI(x22Lx(1+aL)+L2+2a3)_.

The equation for deflection is PLEI[x36Lx22(1+aL)+x(L2+2a3)L6(L+a)]_.

Explanation of Solution

Calculation:

Consider flexural rigidity EI of the beam is constant.

Draw the free body diagram of the beam as in Figure (1).

Structural Analysis, Si Edition (mindtap Course List), Chapter 6, Problem 6P , additional homework tip  1

Refer Figure (1),

Consider upward force is positive and downward force is negative.

Consider clockwise  is negative and counterclowise is positive.

Determine the support reaction at A using the relation;

MB=0RA×L(P×a)=0RA=PaLRA=PaL()

Determine the support reaction at B using the relation;

V=0RA+RBP=0RB=P(PaL)RB=PL+PaLRB=P(1+aL)

Show the reaction values as in Figure (2).

Structural Analysis, Si Edition (mindtap Course List), Chapter 6, Problem 6P , additional homework tip  2

Take a section at a distance of x.

Show the section as in Figure (2).

Structural Analysis, Si Edition (mindtap Course List), Chapter 6, Problem 6P , additional homework tip  3

Consider the segment AB:

Refer Figure (2),

Write the equation for bending moment at x distance.

Mx=RA(x)=PaL(x)=PaxL

Write the equation for MEI as follows:

d2ydx2=1EI(PaxL)        (1)

Write the equation for slope as follows:

Integrate Equation (1) with respect to x.

dydx=θ=1EI(PaL)(xdx)=PaEIL(x22)+C1        (2)

Write the equation for deflection as follows:

Integrate Equation (2) with respect to x.

y=[PaEIL((x22))+C1]dx=Pa2EIL(x33)+C1x+C2        (3)

Find the integration constants C1andC2:

Write the boundary conditions as follows:

Atx=0;y=0:

Apply the above boundary conditions in Equation (3):

0=Pa2EIL((03)3)+C1(0)+C2C2=0

Write the boundary conditions as follows:

Atx=L;y=0:

Apply the above boundary conditions in Equation (3):

0=Pa2EIL(L33)+C1(L)+0C1(L)=PaL26EIC1=PaL6EI

Find the equation for slope.

Substitute PaL6EI for C1 in Equation (2).

θ=PaEIL(x22)+PaL6EI=PaL6EI(13x2L2)

Thus, the equation for slope is PaL6EI(13x2L2)_.

Find the equation for deflection.

Substitute PaL6EI for C1 and 0 for C2 in Equation (3).

y=Pa2EIL(x33)+(PaL6EI)x+0=Pa2EIL(x33)+(PaxL6EI)=PaxL6EI(1x2L2)

Thus, the equation for deflection is PaxL6EI(1x2L2)_.

Consider segment BC;

Show the distance at a distance of x as in Figure (4).

Structural Analysis, Si Edition (mindtap Course List), Chapter 6, Problem 6P , additional homework tip  4

Refer Figure (2),

For segment BC the limit should be Lx(L+a).

Write the equation for bending moment at x distance.

Mx=P(L+ax)

Write the equation for MEI as follows:

d2ydx2=1EI(P(L+ax))=PEI(L+ax)        (4)

Write the equation for slope as follows:

Integrate Equation (4) with respect to x.

dydx=θ=PEI(L+ax)dx=PEI(Lx+axx22)+C3        (5)

Write the equation for deflection as follows:

Integrate Equation (5) with respect to x.

y=[PEI(Lx+axx22)+C3]dx=PEI(Lx22+ax22x36)+C3x+C4        (6)

Write the boundary conditions as follows:

Atx=L

The slope at left and right of support B is equal.

θAB=θBC

Substitute PaL6EI(13x2x2) for θAB and PEI(Lx+axx22)+C3 for θBC.

[PaL6EI(13x2x2)]x=L=[PEI(Lx+axx22)+C3]x=L

Apply the above boundary conditions in the above Equation

PaL6EI(13L2L2)=PEI(L×L+aLL22)+C3PaL6EI(2)=PEI(L22+aL)+C3C3=PaL3EI+PL22EIPaLEIC3=PLEI(a3+L2a)

C3=PLEI(2a3+L2)

Substitute PLEI(2a3+L2) for C3 in Equation (5).

θ=PEI(Lx+axx22)+PLEI(2a3+L2)=PLEI(2a3+L2xaxL+x22L)=PLEI(2a3+L2x(1+aL)+x22L)=PLEI(x22Lx(1+aL)+L2+2a3)

Hence, the Equation for slope is PLEI(x22Lx(1+aL)+L2+2a3)_.

Write the boundary conditions as follows:

Atx=L;y=0:

Apply the above boundary conditions in Equation (6):

PEI(L×L22+aL22L36)+(PLEI(2a3+L2))L+C4=0PEI(L33+aL22)+PL2EI(2a3+L2)+C4=0PL2EI(L3+a22a3L2)+C4=0PL2EI(L6a6)+C4=0

PL2EI(L6+a6)+C4=0C4=PL26EI(L+a)

Substitute PLEI(2a3+L2) for C3 and PL26EI(L+a) for C4 in Equation (6).

y=PEI(Lx22+ax22x36)+PLEI(2a3+L2)xPL26EI(L+a)=PLEI(Lx22+ax22x36)+PLEI(2a3+L2)xPL26EI(L+a)=PLEI[x36Lx22(1+aL)+x(L2+2a3)L6(L+a)]

Hence, the Equation for deflection is PLEI[x36Lx22(1+aL)+x(L2+2a3)L6(L+a)]_.

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