Conjugate Beam METHOD

Structural Analysis   (II)

Chapter Chapter 5: Deflectio Deflection  n 

Method (2) Conjugate beam Method ....

Slope( θ) Deflection ( y)  Conjugate beam:

Deflection ( y) (M)

-M ) (  EI 

(Elastic load )

Slope( θ) (Conjugate beam)

 Rotation or Slope( θ)or (y')= Shear force of elastic load = Qelastic Deflection ( δ  )or (y)= Moment of elastic load =  Melastic δ )or  Real(Original) beam  Load =  d²M(x)  = w  dx² Shear =  dM(x)  = Q dx

Moment = M(x) wt/m'

 Conjugate beam: M  Elastic load =  d²(y)  = EI  dx²

 Rotation =  d(y)  = Qelastic dx Deflection = y = Melastic

- M/EI 

 Rotation)

Deflection)

Structural Analysis   (II)

Chapter 5: Deflection 

(Conjugate beam)  Real Support 

(Original beam) Conjugate Support 

Fixed support 

Free end

M≠0,Q≠0

δ≠0,θ≠0

M

Q

Free end

Fixed support 

M=0,Q=0

δ=0,θ=0 End support (Roller or Hinge) δ=0,θ≠0

End support (Roller or Hinge) Q M=0,Q≠0

θ Interior support (Roller or Hinge)

Internal hinge

θR δ=0,θ≠0

M=0,Q≠0 θL

 (QL=QR )

(θR = θL )

Interior support (Roller or Hinge)

Internal hinge θL

δ ≠ 0 , θL ≠ θR ≠ 0

θR

M ≠ 0 , QL ≠ QR

 Examples  Real Beam

Conjugate Beam

(???) Indetreminate Beam

Structural Analysis   (II)

Chapter 5: Deflection 

Steps of Solution :

( y)

( θ)

.Conjugate beam method 

 FOR Real beam  Reactions Bending Moment Diagram

( B.M.D)

 Examples 6t 

(1)

12t.m

3t/m`

12t.m

B.M.D

= WL²  8

WL²  8

= 24m.t 

= 24m.t 

(2) 4 t/m`

6t 

2 t/m` C

15 t 

14 t 

21 t  WL²/8=32m.t 

8 m.t 

WL²/8=9m.t 

12 m.t 

B.M.D

8 m.t 

12 m.t 

B.M.D WL²/8=32m.t 

WL²/8=9m.t 

Structural Analysis   (II)

( 

Chapter 5: Deflection 

)

( 

) 8t 

8t  2 C

8t  12mt  6mt 

B.M.D 12mt   

12mt  6mt 

3mt 

12mt 

6mt 

Or 

2

6mt  12mt 

12mt 

Modified B.M.D

24mt 

 FOR Conjugate beam (Conjugate Beam) .(Modified B.M.D)

(Given)

(Elastic loads) (Conjugate Beam)

.(Conjugate Beam)

(Elastic loads)

 R .( B.M.D)

 R

(C.g) .( B.M.D) ( Elastic loads) 1 ML 2

( B.M.D) ML

Datum

Datum 4 

Structural Analysis   (II)

Chapter 5: Deflection  1 M L 2 1

M1

Datum

1 M L 2 2

M2 Datum 2 3ML

M1

1 M L 2 1

M1

Datum

Datum

=

M2

M2

1 M L 2 2

Datum

M1 Datum

M1

1 M L 2 1

=

1 M L 2 2

M2

+

M2 Datum

2 ML 3 1 M L 2 1

M1 Datum

M1 Datum

=

+

1 M L 2 2

M2

M2

Datum

2 3ML

Structural Analysis   (II)

Chapter 5: Deflection 

(Rotation) (Deflection ) Qelastic

 Rotation (  θ )=

Deflection (y) =

Melastic

Qelastic Melastic

Moment 

 Shear force Negtive )

 Positive ) Q

M

Q

Q

M

- v e

Q

( θ )= + ve

Negtive )

 Positive )

+v e

M

 + v e

(  θ )= - ve

- v e

M

( y )= - ve

( y )= + ve -

θ

θ

+

Solved Examples  Ex(1)

Using the Conjugate beam method, determine the rotation at points (a,b,c and d) and deflection at points(c,d and e).

10t

2t/m' a

c

10t  

 3t 

b

d

e

Solution

 EI = Constant 

 Reactions and Bending moment diagram (Original beam) 10t

2t/m'

10t  

18.8t  a

 3t  16.2t  6.0t.m

c

d b

 2*3²=2.25 t.m 8 

47.4t.m

46.8t.m  2*3²=2.25 t.m 8 

e

Structural Analysis   (II)

Chapter 5: Deflection 

 Elastic loads( Area of bending moment)

12

6.0 6.0

a

c

d e

b

71.1 

 2.25 t.m

47.4

46.8  71.1  70.2

M) Modified B.M.D(  EI  93.6

4.5 

4.5 

Conjugate beam b

a

e

b

a

e

 Elastic loads on Conjugate beam a

     6  .      3      9

     2      1  .  .     5  .      0      1      7     4     7

     1      5  .  .      1      7      4

b

c

e

d

     0  .      6

     2      1

 Elastic Reactions a

     6  .      3      9

     2      1  .  .     5  .      0      1      7     4     7

     1      5  .  .      1      4     7

M) (  EI 

b

c d

164.3 

     2      1

138.7  b

 269.4 e

     0  .      6

132.7  7 

Structural Analysis   (II)

Chapter 5: Deflection 

 Required rotation and deflection  Rotation ( θ )=

Qelastic

Deflection (y) =  Left

Melastic

Right 

+ve Sign summary

+ ve

 Point (a)

a

1 [164.3] = + 164.3 θa = EI EI

164.3   Point (b) 1 [-138.7] = - 138.7 θb = EI EI

138.7  b      1      5  .  .      1      4     7

 Point (c) 1 [164.3-4.5-71.1] = + 88.7 θc = EI EI 1 [164.3(3)-4.5(1.5)-71.1(1)] = + 415.05  yc = EI EI

c

164.3       6  .      3      9

 Point (d) 1 [ -138.7 -12 +93.6] = - 57.1 θd = EI EI

b d      2      1

 Point (e) 1 [ -132.7] = - 132.7 θe = EI EI 1 [ -268.8] = - 269.4 ye = EI EI

 269.4 e

132.7 

     7  .      8      3      1

Structural Analysis   (II)

 Ex(2)

Chapter 5: Deflection 

Using the Conjugate beam method, determine the rotation at points (a,b,c and d ) and deflection at points(c and d ).

4t 

a

4t/m'

I

d

b

I

2I

c

 

Solution 12t.m 6t.m d

 Required rotation and deflection

I 

1 [+7.88] = + 7.88 θa = EI EI

 2I 

c

B.M.D

 Point (a)

9 

18 

18 

12

1 [-14.62] = - 14.62 θb = EI EI

a

     8      1

c

d

     5  .      4

1 [18 - 14.62 - 4.5] θc = EI = - 1.12 EI

6  3 

c

I

I 

9t.m

Conj.beam

b

14.62

      6      3

d

     8      1

1 [-10.12] = - 10.12 θd = EI EI 1 [+ 12.36] = + 12.36 yd = EI EI

10.12

d

I 

     8      1

b      5  .      4

      9     8 1       6      3

a

12.36

b

a

 Elastic loads

 Point (d)

4.5 

18  18t.m

 36

1 [14.62(3) + 4.5(1.0) -18(1.125)] yc = EI = + 28.11 EI

b

4*6²=18.0 t.m 8 

 Point (b)

 Point (c)

I 

a

     8      1

b

c

7.88 

      9     8 1

     5  .      4

a      8      1

 Elastic Reactions

14.6

Structural Analysis   (II)

 Ex(3)

Chapter 5: Deflection 

Using the Conjugate beam method, determine : * the rotation at points (a ,b,d and e ), * the relative (change in) rotation at point( f ), * the deflection at points(d ,e ,f and j).

2t/m' a

6t 

f   j

e

b

d

c

Solution

6t 

f 

 EI = Constant  c

e

a

4t   3t 

16t 

2t/m'  j

b

d

6.75t 

16.25t  40

10 10t.m

 5t.m b

d

a

f 

1t.m

16t.m

e

c

9t.m

1.33   27  85.33  85.33 

1.33 

 27 

b

a

e

d

85.33  a

40

10 b

d

 29.33 

c

f 

40

16

16

1.33 

 27 

f 

c

e

10

 24.13 

10.2

Structural Analysis   (II)

Chapter 5: Deflection 

 Required rotations and deflections  Point (a)

 Point (b) a

1 [+29.33] θa = EI = + 29.33 EI

 29.33   Point (f)(Internal Hinge )

16

1 [-16+10-1.33] = - 7.33 θf/L = EI EI 1 [-16+10-1.33+24.13 ] = + 16.8 θf/R = EI EI -7.33 24.13 Rf  θf/rel = [θf/R - θf/L ]= + 16.8 EI - EI  = + EI  = EI 1 [-16(2)+10(1.33)-1.33(1)] = - 20 yf  = EI EI

16

      3       3   .       1

f 

 24.13 

       0       1

10

 Point (d) 1 [29.33+10-42.7] = - 3.37 θd = EI EI

 5t.m d

a

 29.33 

1 [+29.33(4)+10(1.33)-42.7(1.5)] yd=EI =+66.6 EI

16t.m

 Point (e)

42.7 

1 [13.5-10.2 ] = + 3.3 θe = EI EI 1 [+10.2(3)-13.5(1)] = + 17.1 ye=EI EI

e

c

9t.m

10.2 13.5 

 Point (j)  Real beam 6t  2

Conj. beam 16.88 

t/m'

a

b

1 [-16] =-16 θb =EI EI

 j

6.75t 

 29.33 

 2.25 t.m

11.25t.m 4.5 

M = 6.75(3) - 6(1.5) = 11.25t.m  j

1 [+29.33(3)-16.88(1) -4.5(1.5)] = + 64.36 y  = EI EI  j

11 

Structural Analysis   (II)

 Ex(4)

Chapter 5: Deflection 

Using the Conjugate beam method, determine : * the rotation at points (c and e ), * the relative (change in) rotation at point( d ), * the deflection at points(c ,e and d ).

[take EI = 6000 t/cm²]

4t 

2t/m' b

a

I 

Solution

I 

d

2

I 

 2I 

 2I 

e

7t 

c

13t 

a

I 

d

7t  7t.m

8t.m

4t.m e

a

b

d

B.M.D(Original beam)

4.0

8.0

7t.m a

8.0 4t.m

4t.m  2t.m

d

e

42.67 

4.0 c

b

16t.m  21.33   21.33 

42.67  a

c

16t.m

 3.5 

 Elastic Reactions

4t 

b

 Reactions(Original beam)

Conjugate beam

c

16t 

t/m'

7.0t.m

 2I 

 2I 

e

d e

 3.5 

 24.2

8.0

4.0

8.0

16.29 

 27.25  c

4.0

12.29 

Structural Analysis   (II)

Chapter 5: Deflection 

 Required rotations and deflections  Point (c)

c

 27.25 

12.29  1 [-12.29] = - 0.002rad θc = 6000 1 [-27.25] = - 0.454 cm yc = 6000

 Point (d)(Internal Hinge )

d

a       5   .       3

 24.2

1 [+ 3.5] = 5.833*10 -4 rad θd/L = 6000 1 [+ 3.5 + 24.2 ] = + 4.6167*10 -3 θd/R = 6000 24.2   = 4.033*10-3 rad θd/rel = │θd/R - θd/L│= Rd  = EI 6000 1 [3.5(0.67)] = + 0.039 cm yd = 6000

 21.33 

 Point (e) e

4.0

8.0

16.29 

1 [-16.29-8-4+21.33] = - 0.00116 rad θe = 6000 1 [16.29*4 + 8*2.67+ 4*1.33-21.33*1.5] = + 0.997 cm ye = 6000