Fundamental Concepts of Stress PDF

Summary

This document presents the fundamental concepts of stress, covering normal stress, shear stress, and bearing stress. It includes examples of problem-solving and explains how to calculate different types of stress.

Full Transcript

Fundamen
tal
Concept of
stress
 LEARNING OUTCOMES:
By the end of this lecture, students should be able to:
 Define stress and classify load/force
 Solve problems involving normal stress
 Solve problems involving shearing stress
 Solve problems involving bearing stress
 Solve problems involving tangential & longitudinal
stress in thin-walled vessel
What is
Stress?
Stress is the a measure of what the
material feels from externally
applied forces. It is simply a ratio of
the external forces to the cross
sectional area of the material.
Watch this!
(8) An Introduction to Stress and Strain - YouTube
 stress
𝑭
𝝈=
𝑨
Where: = average normal stress
F = Normal force
A = cross section area
 NORMAL
TYPES STRESS
is the stress developed when
force applied is acting normally
to the surface.
OF SHEARIN
SIMPL G STRESS
the stress developed due to a
shear force that tends to slide
one section pass the other
E section of a body.
BEARING
STRES STRESS
the contact pressure
S between two surfaces of
bodies.
 NORMAL
TYPES STRESS
is the stress developed when
force applied is acting normally

OF to the surface.

Compressiv tensile
SIMPLe STRESS
the stress developed due to the STRESS
E compressive force that
compress or shorten the
tends to
the stress developed due
to the tensile force that
tends to elongate the body
STRESmember

S
 Problem 1
 The bar has a constant width of 35 mm and a
thickness of 10 mm. Determine the maximum average
normal stress in the bar when it is subjected to the
loading shown.
 solution
 The bar has a constant width of 35 mm and a thickness of 10 mm.
Determine the maximum average normal stress in the bar when it is
subjected to the loading shown.
a b
c

a b
c
solution
Section a-a

𝑷 𝑨𝑩 (T)

Section b-b
𝑃 𝐵𝐶 =12 𝑘𝑁 +9 𝑘𝑁 + 9 𝑘𝑁
𝑷 𝑩𝑪
(T)
solution
Section c-c

𝑷 𝑪𝑫

𝑃 𝐶𝐷 =12 𝑘𝑁 + 9 𝑘𝑁 +9 𝑘𝑁 − 4 𝑘𝑁 − 4 𝑘𝑁
(T)
Solve for the maximum average normal stress
𝑃 𝐵𝐶 30 ( 10 3 ) 𝑁
𝜎= ¿ Ans
𝐴 (0.035 𝑚)(0.010 𝑚)
 Problem 2
 Member AC shown is subjected to a
vertical force of 3 kN. Determine the
position x of this force so that the
average compressive stress at the
smooth support C is equal to the
average tensile stress in the tie rod
AB. The rod has a cross-sectional
area of 400 mm2 and the contact
area at C is 650 mm2.
 
solution
Member AC shown is subjected to a vertical force
of 3 kN. Determine the position x of this force so
that the average compressive stress at the smooth
support C is equal to the average tensile stress in
the tie rod AB. The rod has a cross-sectional area
of 400 mm2 and the contact area at C is 650 mm2.

Consider FBD 1,

Eq. 1
+

↺+
FBD
1
 
solution
Member AC shown is subjected to a vertical force of 3 kN. Determine the position x of this force
so that the average compressive stress at the smooth support C is equal to the average tensile
stress in the tie rod AB. The rod has a cross-sectional area of 400 mm 2 and the contact area at
C is 650 mm2.

For average normal stress, By Substitution with
Eq. 1
Eq. 1,

𝐹 𝐶 =1.625 𝐹 Solve
𝐴𝐵 for x from Eq.2,

Ans
 Shear
𝑽
𝝉= stress
𝑨
Where: = average shear stress
V = shear force
A = sheared area
 Shear
STRESS
Shear stress is tangent or parallel to the plane

TYPES on which it acts. Shear stress arises whenever
the applied loads cause one section of a body to
slide past its adjacent section. Shearing stress is
OF PUNCHI
also known as tangential stress.
Single Double
NG
SIMPLshear shear
shear
E
STRES
S
 Problem 3
 Determine the average shear stress in the 20-mm-diameter pin at A
and the 30-mm-diameter pin at B that support the beam in the figure
shown.
  Determine the average shear stress in the 20-mm-
diameter pin at A and the 30-mm-diameter pin at B that

solution support the beam in the figure shown.

Determine the reaction at A and the
↺+
tension FB
= 12.5 kN
+

= 7.50 kN
+

= 20 kN

𝐹 𝐴= √ 𝐴𝑥+ 𝐴𝑦 =√(7.50𝑘𝑁) +(20𝑘𝑁) =21.36𝑘𝑁
2 2 2 2
  Determine the average shear stress in the 20-mm-
diameter pin at A and the 30-mm-diameter pin at B that

solution support the beam in the figure shown.

Determine values of shear

Double Shear @ A

= Ans

Single Shear @ B
= =12.50 kN

= Ans
 Problem 4
 The inclined member shown
is subjected to a compressive
force of 600 lb. Determine the
average compressive stress
along the smooth areas of
contact defined by AB and
BC, and the average shear
stress along the horizontal
plane defined by DB.
  The inclined member shown is subjected to a

Solution
compressive force of 600 lb. Determine the
average compressive stress along the smooth
areas of contact defined by AB and BC, and the
average shear stress along the horizontal plane
defined by DB.
Consider FBD 1 and solve for the compressive
forces
+

= 360 lb
+

= 480 lb

Consider FBD 2 and solve for shear
+

= 360 lb
FBD
2
FBD
1
  The inclined member shown is subjected to a compressive force of
600 lb. Determine the average compressive stress along the smooth

Solution areas of contact defined by AB and BC, and the average shear
stress along the horizontal plane defined by DB.

The average compressive stresses

=
=
Ans
Ans

The average shear stress
Ans

FBD
2
FBD
1
 𝑷𝒃
Bearing
If two bodies are pressed against each

𝝈 𝒃= Stress
other, compressive forces are developed on
the area of contact. The pressure caused by

𝑨𝒃
these surface loads is called bearing
stress.

Where: = bearing stress
Pb = bearing force
Ab = bearing area
 Problem 5
 The lap joint shown is fastened
by four rivets of 3/4-in. diameter.
Find the maximum load P that
can be applied if the working
stresses are 14 ksi for shear in
the rivet and 18 ksi for bearing in
the plate. Assume that the
applied load is distributed evenly
among the four rivets, and
neglect friction between the
plates.
  The lap joint shown is fastened by four rivets of 3/4-in. diameter. Find

Solution the maximum load P that can be applied if the working stresses are 14
ksi for shear in the rivet and 18 ksi for bearing in the plate. Assume
that the applied load is distributed evenly among the four rivets, and
neglect friction between the plates.
From shearing stress of rivet

From bearing stress of plate

The safe load P as governed by shearing in rivet is P = 24
700 lb Ans
Thin-
walled
cylinders
 A tank or pipe carrying a fluid or gas under
a pressure is subjected to tensile forces, which
resist bursting, developed across longitudinal and
transverse sections.

Two stresses developed:
1. Tangential stress,
σt (Circumferential Stress)
2. Longitudinal stress, σL
 The forces acting are the total pressures
TANGENTIAL STRESS, caused by the internal pressure p and the
σt (Circumferential Stress) total tension in the walls T.
Consider the tank shown being subjected to
an internal pressure p. The length of the tank F=pA=pDL
is L and the wall thickness is t. Isolating the T=σtAwall=σttL
right half of the tank:
ΣFH=0
F=2T
pDL=2(σttL)
σt=pD/2t

If there exist an external pressure p o and an internal
pressure pi, the formula may be expressed as:

Where:
=tangential stress
P=internal pressure
D=internal diameter
T=thickness
LONGITUDINAL STRESS, σL The total force acting at the rear of the tank F must equal to
the total longitudinal stress on the wall PT = σLAwall. Since t is
Consider the free body diagram in the transverse so small compared to D, the area of the wall is close to πDt
section of the tank:

ΣFH=0
PT=F
=

If there exist an external pressure po and an internal pressure
pi, the formula may be expressed as:

It can be observed that the tangential stress is twice that of
the longitudinal stress. σt=2σL
 Problem 6
 A cylindrical steel pressure vessel 400 mm in diameter with a wall thickness of
20 mm, is subjected to an internal pressure of 4.5 MN/m 2. (a) Calculate the
tangential and longitudinal stresses in the steel.

 (b) To what value may the internal pressure be increased if the stress in the
steel is limited to 120 MN/m2?

 (c) If the internal pressure were increased until the vessel burst, sketch the
type of fracture that would occur.
 Solution b) Since tangential stress is the crit

σt=pD/2t
a) Tangential stress (longitudinal section): 120=p(400)/2(20)
p=12MPa answer
F=2T
pDL=2(σt tL)
σt=pD/2t=4.5(400)/2(20)
σt=45MPa answer

Longitudinal Stress (transverse section): c) Since tangential stress
governs, fracture is expected
F=P as shown.
¼ πD2p=σl(πDt) fracture
σl=pD/4t=4.5(400)/4(20)
σl=22.5MPa answer
 Solution
Total internal pressure:
P=p(1/4 πD2)

Resisting wall:
F=P
σA=p(1/4 πD2)
σ(πDt)=p(1/4 πD2)
σ=pD/4t
8000=p(4×12)4(516)
p=208.33psi answer
 Problem 7
The wall thickness of a 4-ft-diameter
spherical tank is 5/16 inch. Calculate the
allowable internal pressure if the stress is
limited to 8000 psi.
 Problem 8
A water tank, 22 ft in diameter, is made from
steel plates that are 1/2 in. thick. Find the
maximum height to which the tank may be filled
if the circumferential stress is limited to 6000
psi. The specific weight of water is 62.4 lb/ft3.
Solution
Solution
Given a free surface of water, the actual
pressure distribution on the vessel is not
uniform. It varies linearly from zero at the free
surface to γh at the bottom (see figure below).
Using this actual pressure distribution, the total
hydrostatic pressure is reduced by 50%. This
reduction of force will take our design into
critical situation; giving us a maximum height of
200% more than the h above.
EXERCIS
ES
solution
2.0
solution
REFERENCES/
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