Transcript Document

FME461
Engineering Design II
Dr.Hussein Jama
[email protected]
Office 414
Lecture: Mon 8am -10am
Tutorial Tue 3pm - 5pm
7/21/2015
1
Spring design




Types
Factors in spring design
Materials
Torsional
7/21/2015
2
Types of Springs
7/21/2015
3
Types of spring cont.
7/21/2015
4
Types of springs cont.
7/21/2015
5
Types of springs cont.
7/21/2015
6
Spring Design
F  ky
k  F /y
1
k series

1
k1

1
k2

1
k3
k parallel  k 1  k 2  k 3
7/21/2015
7
Factors in spring design





High strength
High yield
Modulus may be low for energy storage
Cost
Environmental factors


7/21/2015
Temperature resistance (e.g. valve springs)
Corrosion resistance
8
Common materials for springs
7/21/2015
9
Influence of diameter on
ultimate stress
7/21/2015
10
Influence of diameter on
ultimate stress cont.
S ut  Ad
b
S us  0 . 67 S ut
7/21/2015
11
Design of helical compression
springs
 Length nomenclature




7/21/2015
Free
Assembled
Solid or shut height
Working deflection
12
Stresses in Helical Spring
7/21/2015
13
Stresses in Helical springs
cont.
At the inside of the spring
Substituting for
Gives
4<C<12
Defining the spring index
Therefore the stress is
7/21/2015
Equation(1)
14
Effect of curvature on Stress




Equation (1) is based on the wire being
straight
However the curvature increases the stress
on the inside of the wire
For static stress the effect of curvature can
be neglected
For fatigue the effect of curvature is important
7/21/2015
15
Effect of curvature cont.
Wahl factor
Bergstrasser
factor
The results of the two equations differ by less than 1%.
Bergstrasser factor is preferred due to simplicity
7/21/2015
16
Deflection

The external work done on an elastic member
in deforming it is transformed into strain, or
potential, energy. If the member is deformed a
distance y, and if the force-deflection
relationship is linear, this energy is equal to
the product of the average force and the
deflection, or

This equation is general in the sense that the
force F can also mean torque, or moment,
provided, that consistent units are used for k.
7/21/2015
17
Deflection cont..

By substituting appropriate expressions for k,
strain-energy formulas for various simple
loadings may be obtained. For tension and
compression and for torsion,
7/21/2015
18
Deflection of a helical spring

Using Castigliano’s theorem, strain energy is
equal to

Substituting
7/21/2015
19
Deflection cont.

Using the spring index

Spring scale is
7/21/2015
20
Spring design – end treatment

End details affect active coils




7/21/2015
Plain ends
Squared ends
Squared
Ground
21
Number of active coils
7/21/2015
22
Stability of a column
Euler Formula
7/21/2015
23
Stability of a spring



We know a column will buckle when the load
is too large
A compression coil spring will also buckle
ycr is the deflection corresponding to onset of
instability
7/21/2015
24
Deflection cont.
Is called the effective slenderness ratio
Alpha = end condition constant
Lo is the spring length
D is the Coil diameter
7/21/2015
25
Instability cont.

End constraint alpha given by
7/21/2015
26
Instability cont.

For absolute stability

For steels it turns out

For square and ground ends
7/21/2015
27
Static design flow chart
7/21/2015
28
Flow chart cont.
7/21/2015
29
Recommended design
conditions
Figure of merit (fom)
7/21/2015
30
Materials for springs

Yield strength for static loading



7/21/2015
Depends on set
Before set removed use Wahl factor
After set removed no stress concentration used
31
Properties for fatigue

Fatigue Strength



7/21/2015
Torsion is relevant loading- could use von Mises
stress
Materials testing specific to helical compression
springs is available, however
Correct for temp., reliability, environment
32
Properties - endurance

Endurance Strength (steels) unlimited cycles



For high ultimate strengths, endurance limits max
out at 45 kpsi (unpeened) and 67.5 kpsi (peened)
Small wires have high ultimate strength
Tests have been done specific to spring wire



7/21/2015
Temperature may require compensation
Corrosion
Reliability
33
S-N and Modified Goodman
7/21/2015
34
Designing springs
Requirements

Functionality

Stiffness
Lengths
Diameter
Forces






Reliable operation




7/21/2015
Design Choices
Static factor of safety
Fatigue factor of safety
Buckling and surge
Manufacturability




Index C
Material
Wire and coil
diameter
Number of turns
End treatment and
constraint
Set and shot peen
Constraints (other)
• Bend radius
35
Helical extension spring






Similar in most ways to
compression springs
Usually wound to be closed
coil at zero force
Thus a preload is required
to stretch any, i.e. y=k(F-Fi )
Spring hook is a source of
failure in bending and
torsion
No set is used
One coil not considered
active
7/21/2015
36
End stresses
Bending stress:

A
 Kb
16 DF
d
3

4F
d
4C1  C1  1
2
2
Kb 
4 C 1 ( C 1  1)
;
C1 
2 R1
d
Torsional stress:
 B  K w2
K w2 
7/21/2015
8 DF
d
3
4C 2  1
4C 2  4
;
C2 
2 R2
d
37
Design for fatigue






Data available for springs with loading from
zero to some compresion value
Application often has preload… how to use?
First construct (or find) S-N curve
Next construct Mod-Goodman chart
Apply load line for given preload and design
stress
Find factor of safety to failure point
7/21/2015
38
Goodman curve
7/21/2015
39
A word about torsional springs




The wire in a torsional spring is primarily in
bending
Spring constant is rotary M=k
Loading should act to wind up coil
Design process resembles compression
springs
7/21/2015
40
Torsional
7/21/2015
41
Homework

Read chapter 10 of Shigley
7/21/2015
42