2. Unit 2- Stresses in Beams
Topics Covered
 Lecture -1 – Review of shear force and bending
moment diagram
 Lecture -2 – Bending stresses in beams
 Lecture -3 – Shear stresses in beams
 Lecture -4- Deflection in beams
 Lecture -5 – Torsion in solid and hollow shafts.

3. Beam Deflection
Recall: THE ENGINEERING BEAM THEORY
σ M E
= =
y I R
Moment-Curvature Equation
v (Deflection)
y
€ NA
A B
x
A’ B’
If deformation is small (i.e. slope is “flat”):

4. 1 dθ
∴ ≈
R dx
R
δy
and δθ ≈ (slope is “flat”)
δx
B’
δy 1 d2y €
A’ ⇒ ≈ 2
R dx
€
€
Alternatively: from Newton’s Curvature Equation
y € ⎛ d 2 y ⎞ ⎛ dy ⎞ 2
R ⎜ 2 ⎟ if ⎜ ⎟ <<<< 1
1 ⎝ dx ⎠ ⎝ dx ⎠
= 3
y = f (x) R ⎛ 2 ⎞ 2
⎛ dy ⎞
⎜1+ ⎜ ⎟ ⎟ 1 d2y
x ⎝ ⎝ dx ⎠ ⎠ ⇒ ≈ 2
€ R dx
€
€

5. From the Engineering Beam Theory:
M E 1 M d2y
= = = 2
I R R EI dx
d2y
⇒ ( EI ) 2 = M
dx
€Flexural € € Bending
Stiffness Moment
Curvature
€

6. Relationship
A C B Deflection = y
dy
Slope =
dx
d2y
A C B Bending moment = EI 2
y dx
d3y
Shearing force = EI 3
dx
d4 y
Rate of loading = EI 4
dx
€

7. Methods to find slope
and deflection
 Double integration method
 Moment area method
 Macaulay’s method

8. Double integration method
d 2 y ⎛ 1 ⎞
⎟ M Curvature
Since, 2 = ⎜
dx ⎝ EI ⎠
dy ⎛ 1 ⎞
⇒ = ⎜ ⎟ ∫ M ⋅ dx + C1 Slope
dx ⎝ EI ⎠
€
⎛ 1 ⎞
⇒ y = ⎜ ⎟ ∫ ∫ M ⋅ dx⋅ dx + ∫ C ⋅ dx + C
1 2 Deflection
⎝ EI ⎠
€
Where C1 and C2 are found using the boundary conditions.
€ Curvature Slope Deflection
y
R dy
dx

9. Double integration method
Simple supported
W
Slope Deflection
L/2 L/2 dy
A C B Slope = Deflection = y c
dx
yc 2 WL3
WL =−
= θA = θB = − 48EI
16EI
L
Uniform distributed load
x
€ Slope
€
Deflection
w/Unit length
A C dy
B Slope = Deflection = y c
dx
yc 2 5 WL3
WL =−
= θA = θB = − 384 EI
24 EI
L
€
€

10. Macaulay’s method
 The procedure of finding slope and deflection for
simply supported beam with an eccentric load is very
laborious.
 Macaulay’s method helps to simplify the calculations
to find the deflection of beams subjected to point
loads.

11. Moment-Area Theorems
• Consider a beam subjected to arbitrary
loading,
dθ d 2 y M
= =
dx dx 2 EI
θD xD
M
∫ dθ = ∫ EI dx
θC xC
xD
M
θ D − θC = ∫ EI
dx
xC
dx
CD = Rdθ = dx
€
€ R dθ
• First Moment-Area Theorem:
€
area under BM diagram between
€ C and D.
9 - 11

12. Moment-Area Theorems
• Tangents to the elastic curve at P and P’
intercept a segment of length dt on the vertical
through C.
M
dt = xdθ = x dx
EI
xD x
M 1 D 1 −
tC D = ∫ x
EI
dx = ∫ xMdx = EI A x
EI xC
xC
− A= total area of BM diagram between C & D
€ x = Distance of CG of BM diagram from C
• Second Moment-Area Theorem:
The tangential deviation of C with respect to
€ D is equal to the first moment with respect to
a vertical axis through C of the area under
the BM diagram between C and D.
9 - 12

13. Moment Area Method

14. Moment Area Method

15. An Exercise- Moment of Inertia – Comparison
1
Load
Maximum distance of
4 inch to the centroid I2
2 x 8 beam
Load 2
I1
Maximum distance of 1 inch to 2 x 8 beam
the centroid
I2 > I1 , orientation 2 deflects less
Ken Youssefi Engineering 10, SJSU 15