1
A Mini project
report
on
Design,
Manufacturing
and
Failure Analysis
of
Leaf Spring
submitted by :
CH.RAKESH KUMAR 08471A0311
K.SAI KIRAN 08471A0320
K.SESHI REDDY 08471A0321
K.NAGA LAKSHMI 08471A0356
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ACKNOWLEDGEMENT
We express our sincere thanks to Mr. K.VARA PRASAD RAO, Professor & HOD of
Mechanical Engineering, Narasaraopeta Engineering College, for his encouragement and
valuable suggestions through out the miniproject.
We profoundly thank Mr.Dr B.V.RAMA MOHANA RAO, principle of Narasaraopeta
Engineering College for having given us permission to carry out the miniproject.
We express our sincere thanks and deep sense of gratitude for the inspiring guidance
and kind encouragemet with unfailing rendered by Mr.M.VENKAIAH, Asst Prof. Dept of
Mechanical Engineering, Narasaraopeta Engineering College.
We are also thankful to the Staff of our Mechanical Engineering Department for there
valuable support, comments during the course of the miniproject.
We are also thankful to all others who have directly or indirectly contributed to the
success of the miniproject.
We would like to express my heart-felt gratitude to my parents without whom we would
not have been privileged to achieve and fulfill our dreams.
We owe our gratitude to our Narasaraopeta Engineering College for providing an
opportunity to do our project.
Our sincere thank‟s to Mr.T.VINOD BABU, Managing Partner of TRAILOR SPRINGS &
the Working staff of TRAILOR SPRINGS for supporting us to complete our miniproject in
their presence.
CH.RAKESH KUMAR 08471A0311
K.SAI KIRAN 08471A0320
K.SESHI REDDY 08471A0321
K.NAGA LAKSHMI 08471A0356
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CONTENTS
ABSTRACT
LIST OF FIGURES
SYMBOLS
1. INTRODUCTION TO LEAF SPRING ……………………………….….9
2. HISTORY OF LEAF SPRING …………………………………………….…….10
3. DESGN OF LEAF SPRING …………………………………………………..12
3.1. Materials for leaf spring.......................................………………………………13
3.2. Steel……………………………………………………………………………..13
3.2.1. Introduction……………………………………………………………...13
3.2.2. Types of steel…………………………………………………………….14
3.2.3. Spring steel………………………………………………………………16
3.2.4. Role of carbon in steel…………………………………………………...18
3.3. Types of leaf springs…………………………………………………………….18
3.4. Design of leaf spring…………………………………………………………….19
3.5. Length of leaf spring leaves……………………………………………………..28
3.6. Standard sizes of automobile suspension springs………………………………29
3.7. Dimensions for center bolts……………………………………………………..30
3.8. Dimensions of clip,rivet and bolts………………………………………………30
4. MANUFACTURING OF LEAF SPRING ………………………………………..31
4.1. Raw material……………………………………………………………………..33
4.2. Shearing or cutting process……………………………………………………...33
4.3. Drilling operation………………………………………………………………..34
4.4. Eye rolling of main blade………………………………………………………..35
4.5. Hardening (Quenching)……………………………………………………….…36
4.6. Tempering………………………………………………………………………..38
4.7. Hardness testing………………………………………………………………....40
4.8. Fitting…………………………………………………………………………....42
4.8.1. Clamps…………………………………………………………………......42
4.8.2. Bolts and nuts………………………………………………………….......44
4.8.3. Rivets……………………………………………………………………....45
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4.8.4. MS pipe……………………………………………………………………..45
4.8.5. Bushes……………………………………………………………………....45
4.9. Painting…………………………………………………………………………...45
4.10. Labeling………………………………………………………………………….46
4.11. Inspection………………………………………………………………….……..47
4.12. Stock ready to supply…………………………………………………………….47
5. FAILURE ANALYSIS OF LEAF SPRING……………………………………….48
5.1. Failure analysis……………………………………………………………………49
5.2. Quench cracks…………………………………………………………………….49
5.3. Optical Metallurgical Microscope………………………………………………...50
5.4. Scanning Electron Microscope………………………………………………........51
5.5. Tensile test of leaf spring……………………………………………………........53
5.6. Fatigue test of leaf spring…………………………………………………….…..54
5.7. Increasing the fatigue strength of leaf spring………………………………….....56
5.8. When to repair…………………………………………………………………….58
5.9. When to replace…………………………………………………………………...59
6. CONCLUSION
BIBLOGRAPHY
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ABSTRACT
Although leaf springs are one of the oldest suspension components they
are still frequently used, especially in commercial vehicles. Being able to capture the
leafspring characteristics is of significant importance for vehicle handling dynamics studies.
This report describes the theoretical design considerations that are used during the design of
leaf springs including the design of various accessories such as rivets,bolts,nuts,clips and
main spring. It also decribes the manufacturing process of leaf springs and the failures that
are caused in the leaf springs and there remedies. Various tests such as fatigue test, tensile
test are carried out to determine the failure analysis of leaf springs and necessary
modifications are described in order to increase the fatigue strength of leaf springs. This
report also describes when to repair and when to replace a deformed leaf spring.
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LIST OF FIGURES
CHAPTER 1
Figure 1(a): Leaf Springs
CHAPTER 2
Figure 2(a): Leaf spring suspension
CHAPTER 3
Figure 3(a): Types of leaf springs
Figure 3(b): Flat spring (cantilever type)
Figure 3(c): Stress diagram
Figure 3(d): Flat spring (simply supported beam type)
Figure 3(e): Traingular plate
Figure 3(f): Laminated leaf spring
Figure 3(g): Construction of leaf spring
Figure 3(h): Nipping
Figure 3(i): Spring clip
CHAPTER 4
Figure 4(a) : Steel alloy
Figure 4(b): 100 ton press cutting machine
Figure 4(c): Vertical drilling machine
Figure 4(d): Eye rolling of main spring
Figure 4(e): Hardening
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Figure 4(f): Hydraulic bending machine
Figure 4(g): Tempering process
Figure 4(h): Tempering furnace
Figure 4(i): Rockwell hardness tester
Figure 4(j): Clamps of different sizes
Figure 4(k): Circular cutting die of clamp
Figure 4(l): Bolts and rivets
Figure 4(m): Bush
Figure 4(n): Painting
Figure 4(o): Labeling
Figure 4(p): Stock ready to supply
CHAPTER 5
Figure 5(a): Metallurgical Microscope
Figure 5(b): Scanning Electron Microscope
Figure 5(c): Failure Material Leaf Spring and Received Material Leaf Spring
Figure 5(d): Universal Tensile Testing Machine
Figure 5(e): Fatigue test
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SYMBOLS
t = Thickness of plate
b = Width of plate
L = Length of plate or distancenof the load W from the cantilever end.
M = Maximum bending moment
Z = Section modulus
σ = Bending stress
δ = Maximum deflection
E = Young‟s modulus
W = Total load on the spring
n = Number of leaves
nG = Number of graduated leaves
nF = Number of full length leaves
C = Initial gap between the leaves
Wb = The load on the clip bolts
WG = Load taken up by graduated leaves
WF = Load taken up by full length leaves
σG = Stress in the graduated leaves
σF = Stress in the full length leaves
d = Inside diameter of eye
R = Radius of curvature
y = Camber of the spring
L1 = Half span of the spring
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1. INTRODUCTION TO LEAF SPRING
Originally Leaf spring called laminated or carriage spring, a leaf spring is a simple
form of spring, commonly used for the suspension in wheeled vehicles. It is also one of the
oldest forms of springing, dating back to medieval times.
Sometimes referred to as a semi-elliptical spring or cart spring, it takes the form of a slender
arc-shaped length of spring steel of rectangular cross-section. The center of the arc provides
location for the axle, while tie holes are provided at either end for attaching to the vehicle
body. For very heavy vehicles, a leaf spring can be made from several leaves stacked on top
of each other in several layers, often with progressively shorter leaves. Leaf springs can serve
locating and to some extent damping as well as springing functions.
A leaf spring can either be attached directly to the frame at both ends or attached directly at
one end, usually the front, with the other end attached through a shackle, a short swinging
arm. The shackle takes up the tendency of the leaf spring to elongate when compressed and
thus makes for softer springiness.
Figure 1(a): Leaf Springs
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2. History of Leaf Spring
There were a variety of leaf springs, usually employing the word
"elliptical". "Elliptical" or "full elliptical" leaf springs referred to two circular arcs linked at
their tips. This was joined to the frame at the top center of the upper arc, the bottom center
was joined to the "live" suspension components, such as a solid front axle. Additional
suspension components, such as trailing arms, would be needed for this design, but not for
"semi-elliptical" leaf springs as used in the Hotchkiss drive. That employed the lower arc,
hence its name. "Quarter-elliptic" springs often had the thickest part of the stack of leaves
stuck into the rear end of the side pieces of a short ladder frame, with the free end attached to
the differential, as in the Austin Seven of the 1920s. As an example of non-elliptic leaf
springs, the Ford Model T had multiple leaf springs over its differential that were curved in
the shape of a yoke. As a substitute for dampers (shock absorbers), some manufacturers laid
non-metallic sheets in between the metal leaves, such as wood.
Leaf springs were very common on automobiles, right up to the 1970s, when the move to
front wheel drive, and more sophisticated suspension designs saw automobile manufacturers
use coil springs instead. U.S. passenger cars used leaf springs until 1989 where the Chrysler
M platform was the final production vehicle marketed. However, leaf springs are still used in
heavy commercial vehicles such as vans and trucks, and railway carriages. For heavy
vehicles, they have the advantage of spreading the load more widely over the vehicle's
chassis, whereas coil springs transfer it to a single point. Unlike coil springs, leaf springs also
locate the rear axle, eliminating the need for trailing arms and a Panhard rod, thereby saving
cost and weight in a simple live axle rear suspension.
A more modern implementation is the parabolic leaf spring. This design is characterized by
fewer leaves whose thickness varies from centre to ends following a parabolic curve. In this
design, inter-leaf friction is unwanted, and therefore there is only contact between the springs
at the ends and at the centre where the axle is connected. Spacers prevent contact at other
points. Aside from a weight saving, the main advantage of parabolic springs is their greater
flexibility, which translates into vehicle ride quality that approaches that of coil springs.
There is a trade-off in the form of reduced load carrying capability.
Like most other fundamental mechanisms, metal springs have existed since the Bronze Age.
Even before metals, wood was used as a flexible structural member in archery bows and
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military catapults. Precision springs first became a necessity during the Renaissance with the
advent of accurate timepieces. The fourteenth century saw the development of precise clocks
which revolutionized celestial navigation. World exploration and conquest by the European
colonial powers continued to provide an impetus to the clockmakers' science and art.
Firearms were another area that pushed spring development.
The eighteenth century dawn of the industrial revolution raised the need for large, accurate,
and inexpensive springs. Whereas clockmakers' springs were often hand-made, now springs
needed to be mass-produced from music wire and the like. Manufacturing methodologies
were developed so that today springs are ubiquitous. Computer-controlled wire and sheet
metal bending machines now allow custom springs to be tooled within weeks, although the
throughput is not as high as that for dedicated machinery.
Figure 2(a): Leaf spring suspension
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DESIGN
OF LEAF SPRING
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3. DESIGN OF LEAF SPRING
3.1 Materials for leaf spring:
The material used for leaf springs is usually a plain carbon steel having 0.90 to
1.0% carbon. The leaves are heat treated after the forming process. The heat treatment of
spring steel produces greater strength and therefore greater load capacity, greater range of
deflection and better fatigue properties.
According to Indian standards, the recommended materials are :
1. For automobiles : 50 Cr 1, 50 Cr 1 V 23, and 55 Si 2 Mn 90 all used in hardened and
tempered state.
2. For rail road springs : C 55 (water-hardened), C 75 (oil-hardened), 40 Si 2 Mn 90
(waterhardened) and 55 Si 2 Mn 90 (oil-hardened).
3. The physical properties of some of these materials are given in the following table. All
values are for oil quenched condition and for single heat only.
Physical properties of materials commonly used for leaf springs :
3.2 STEEL
3.2.1 Introduction
Steel is an alloy of iron that contains the element iron as the major component
and small amounts of carbon as the major alloying element.
The carbon contents in steel ranges from 0.02% to 2.0% by weight. Small amounts, generally
on the order of few percent, of other alloying elements such as manganese, silicon,
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chromium, nickel and molybdenum may also be present, but it is the carbon content that turns
iron into steel. Also the properties like toughness and ductility are obtained by the addition of
elements like manganese, chromium, nickel, molybdenum, tungsten, vanadium, silicon etc.
Steel is the most common and widely used metallic material in today‟s society. It can be cast
or wrought into numerous forms and can be produced with tensile strength exceeding 5GPa.
3.2.2 Types of steel
Steel can be classified in many ways, such as method of manufacturing, its
final use and AISI standards, but mostly steel can be classified into following two categories:
1. Carbon Steel
2. Alloy Steel
Carbon Steel
Carbon steel is steel that receives its distinctive properties, mainly form carbon it
contains. Other elements, such as manganese, silicon, phosphorus and sulfur may be present
in relatively small amounts and their purpose is not to modify the mechanical properties of
steel. The carbon content of this grade may ranges from a trace to 1.7%.
The plain carbon steels are usually divided into three grades on the basis of their carbon
content. These are give as under.
a) Low Carbon Steel
The plain carbon steel in which carbon content ranges from 0.08 to below
0.3% are known as low carbon steel or mild steel.
Mild steel are not much affected by heat treatment processes specially hardening process. A
decrease in carbon improves the ductility of mild steels. These steels posses good machine
ability and weld ability. They are used for making wires, rivets, nuts and bolts, screws,
sheets, plates, tubes, rods, shafts, structural steel sections and form general work shop
purposes.
b) Medium Carbon Steel
The plain carbon steel in which carbon content ranges from 0.3 to 0.8% are
called medium carbon steel.
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These steels are stronger than mild steel but are less ductile. Their mechanical properties can
be much improved by proper heat treatment. They have lesser machine ability than mild steel.
However, they can easily be welded and forged. They are used for making stronger nuts and
bolts, shafts, various steel sections, high tensile tubes, springs, locomotive, large forging dies,
hammer and agricultural tools etc.
c) High Carbon steel
The plain carbon steel in which carbon content range from 0.8 to 1.8% are
known as high carbon steel.
The structure and hardness of steel increases with the increase of carbon content and the
strength is almost maximum at about 0.8% carbon, there after hardness continuously
increases while strength decreases. Ductility and machine ability of steel decrease with
increase of carbon content from mild steel onwards. Their mechanical properties can be
altered by proper heat treatment. They are mainly used for making springs, wood working
tools, press work dies and punches.
Alloy Steel:
Alloy steels are the type of steels in which elements other than iron and carbon are
present in sufficient quantities to modify the properties. The utility of alloy steels lies in the
fact that they permit a much wider range of physical and mechanical properties than is
possible in plain carbon steel.
Alloy steels may be classified in many ways but for the purpose of convenience we may
divide it as follows:
a) Micro alloy steel:
Micro alloy steels are those steels in which the total alloying elements
present in steel other than iron and carbon are below one percent.
Micro alloy steels are widely used in many engineering industries such as manufacturing of
pipe lines, automobiles and in aircraft industries. Micro alloy steel is used in these industries
because of its good strength, light weight and good weld ability. Some common micro alloy
steels contain small amounts of vanadium m, columbium, copper, manganese. Micro alloy
steels are only slightly heavier than pure iron but are as strong as some steels.
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b) Low alloy steel:
Low alloy steels are those steels in which the total alloying elements present in steel other
than that of iron and carbon are above one percent and below 5%. Low alloy steels have
superior mechanical properties than plain carbon steels. Superior properties usually mean
higher strength, hardness, hot hardness, wear resistance and toughness.
3.2.3 Spring Steel
Spring steel is a low alloy, medium carbon steel with a very high yield
strength. This allows objects made of spring steel to return to their original shape despite
significant bending or twisting. Spring steel chemical composition which is given as under:
ELEMENTS IN LEAF
SPRING
% OF ELEMENTS
CARBON 0.5 ~0.65
SILICON 0.15 ~0.35
MANGANESE 0.65 ~0.95
PHOPHOROUS 0.035
SILICON 0.035
CHROMIUM 0.65 ~0.95
Depending on the type of application, springs are made of carbon steels, silicon and
manganese containing steels, silicon-manganese steels, alloyed steels, stainless steels.
Springs must be capable of storing and releasing the energy. After repeated applications of
load, they must retain their original shape and dimensions. This property may be attained by
the use of a highly elastic material and by proper design because the allowable stress values
determine the choice of material and design.
Major requirements of spring steels are:
1. Should have a highly yield strength (of the order of 21000kg/mm2) or more
accurately, a high proportional limit, so that it will not show any appreciable
permanent set
2. High fatigue strength under alternating and fluctuating stresses with a reserve for
occasional or more frequent overloads (e.g. Vehicle springs when stressed in their
resonance range)
3. Should have an adequate plastic range for the forming (winding) of the springs.
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These desirable properties of springs can be achieved firstly by a higher carbon
content or with suitable alloying elements, and secondly by heat treatment. The actual
springiness of steel is determined by its modulus of elasticity which is about 21000kg/mm2,
the modulus 0f rigidity being about 8000kg/mm2. It is possible to influence the modulus of
elasticity and shear by severe cold working treatments. Spring failure is almost invariably
from fatigue, with some stress raisers are nucleus.
Spring steels are used in hard, high strength condition. To attain these properties
springs are hardened and tempered. In the hardened condition, the steel should have 100%
martensite to attain the maximum yield strength to avoid excessive set in service. The
presence of retained austenite in the hardened condition lowers the yield strength and
produces excessive set.
Use of carbon steel for smaller sections in martensite as against sections in which
hardness will be less when carbon steel is used. However, harden ability of the steel may be
increased by the addition of alloying elements. To get high yield strength on tempering
martensite needs to be high in carbon. The combination of high carbon along with alloying
elements will posses the desired hardenability in different sections. Hence the desired
properties of spring can be achieved firstly by higher carbon content or by addition may
occur if the hardening temperature is too low.
For many applications, where the working stresses are low, carbon spring steels are
quite satisfactory for smaller cross- sections. But, for higher duty springs, steels of higher
harden ability are used. In addition to carbon steels, mainly alloy steels having principle
alloying elements such as manganese- silicon, chromium, vanadium, molybdenum, etc., are
used for production of springs. Spring steels that are commercially available are carbon
spring steel, silico-manganese steel, manganese alloyed steel, silicon alloyed steel, chrome-
vanadium steel, etc.
Drawn spring steels used for highly duty valve spring in the automotive and aircraft
industries are coiled in the annealed condition, and finally hardened and oil-tempered, as this
treatment imparts to them improved fatigue strength.
Springs of small dimensions are also made from patented drawn spring wires coiled in
the cold state. They posses a very high tensile strength and elastic properties compare to the
normally drawn wire. They also posses good ductility and toughness. Springs made out of
patented wire do not require hardening. They are only subjected to tempering at 200 to
250OC.
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3.2.4 Role of Carbon in Steel
Generally, carbon is the most important commercial steel alloy.
Increasing carbon content increases hardness and strength and improves hardenability. But
carbon also increases brittleness and reduces weldability because of its tendency to form
martensite. This means carbon content can be both a blessing and a curse when it comes to
commercial steel. And while there are steels that have up to 2 percent carbon content, they
are the exception. Most steel contains less than 0.35 percent carbon. To put this in
perspective, keep in mind that‟s 35/100 of 1 percent. Now, any steel in the 0.35 to 1.86
percent carbon content range can be hardened using a heat-quench-temper cycle
Carbon is the most important element in steel as slight variations in percentage cause
very marked changes in physical and mechanical properties. When a small amount of carbon
is added to iron, the properties which give steel its great value begin to appear. In plain
carbon steels manganese, phosphorus and sulfur are present in amounts which do not
interfere in any way with the effect that carbon variation has on the properties of the steel.
Thus, steels may be considered binary alloys of iron and carbon. In alloy steels, the effects of
the alloying elements must be considered.
The plain carbon steels represent the most important group of engineering materials
known. They represent by far the major percentage of steel production and the widest
diversity of application of any of the engineering materials. These applications are so
diversified that anything like a complete listing or even a classification on the basis of
application is not feasible.
3.3 Types of leaf springs
Figure 3(a) Types of leaf springs
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3.4 Design of leaf spring
Leaf springs (also known as flat springs) are made out of flat plates. The
advantage of leaf spring over helical spring is that the ends of the spring may be guided along
a definite path as it deflects to act as a structural member in addition to energy absorbing
device. Thus the leaf springs may carry lateral loads, brake torque, driving torque etc., in
addition to shocks.
Consider a single plate fixed at one end and loaded at the other end as shown in Fig. 23.25.
This plate may be used as a flat spring.
Let t = Thickness of plate,
b = Width of plate, and
L = Length of plate or distancenof the load W from the cantilever end.
Figure 3(b): Flat spring (cantilever type).
We know that the maximum bending moment at the cantilever end A,
M = W.L
and section modulus,
∴ Bending stress in such a spring,
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……… (I)
We know that the maximum deflection for a cantilever with concentrated load at the free end
is given by
………(II)
∴
It may be noted that due to bending moment, top fibres will be in tension and
the bottom fibres are in compression, but the shear stress is zero at the extreme fibres and
maximum at the centre, as shown in Fig. Hence for analysis, both stresses need not to be
taken into account simultaneously.
We shall consider the bending stress only.
Figure 3(c): Stress diagram
If the spring is not of cantilever type but it is like a simply supported beam,
with length 2L and load 2W in the centre, as shown in Fig., then Maximum bending moment
in the centre,as shown in fig, then
Maximum bending moment in the center,
M=W.L
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Sectionmodulus,
Figure 3(d): Flat spring (simply supported beam type)
∴
We know that maximum deflection of a simply supported beam loaded
in the centre is given by
(Since in this case, W1=2W,and L1=2L)
From above we see that a spring such as automobile spring
(semi-elliptical spring) with length 2L and loaded in the centre by a load 2W, may be treated
as a double cantilever.
If the plate of cantilever is cut into a series of n strips of width b and these are
placed as shown in Fig then equations (i) and (ii) may be written as
…… (III)
and
….. (IV)
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Figure 3(e): Traingular plate
The above relations give the stress and deflection of a leaf spring
of uniform cross-sectionThe stress at such a spring is maximum at the support.
If a triangular plate is used as shown in Fig 3(e), the stress will be uniform throughout. If this
triangular plate is cut into strips of uniform width and placed one below the other, as shown
in Fig to form a graduated or laminated leaf spring, then
Figure 3(f): Laminated leaf spring
and ………..(V)
…………(VI)
Where n=number of graduated leaves.
A little consideration will show that by the above arrangement, the
spring becomes compact so that the space occupied by the spring is considerably reduced.
When bending stress alone is considered, the graduated leaves
may have zero width at the loaded end. But sufficient metal must be provided to support the
shear. Therefore, it becomes necessary to have one or more leaves of uniform cross-section
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extending clear to the end. We see from equations (iv) and (vi) that for the same deflection,
the stress in the uniform cross-section leaves (i.e. full length leaves) is 50% greater than in
the graduated leaves, assuming that each spring element deflects according to its own elastic
curve. If the suffixes F and G are used to indicate the full length (or uniform cross section)
and graduated leaves, then
or
∴
………..(VII)
Adding 1 to both sides we have
(
) (
)
……….. (VIII)
where W= total load on the spring=WG+WF.
WG=load taken up by graduated leaves, and
WF= load taken up by full length leaves.
From equation (VIII), we may write
or
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∴ (
) (
)
therefore bending stress for full length leaves,
(
)
since
,therefore
The deflection in full length and graduated leaves is given by equation (VI), i.e.
[
]
Construction of Leaf Spring
A leaf spring commonly used in automobiles is of semi-elliptical form as shown in Fig.
Figure 3(g): Construction of leaf spring
It is built up of a number of plates (known as leaves). The leaves are usually given an
initial curvature or cambered so that they will tend to straighten under the load. The leaves
are held together by means of a band shrunk around them at the centre or by a bolt passing
25
through the centre. Since the band exerts a stiffening and strengthening effect, therefore the
effective length of the spring for bending will be overall length of the spring minus width of
band. In case of a centre bolt, two-third distance between centres of U-bolt should be
subtracted from the overall length of the spring in order to find effective length. The spring is
clamped to the axle housing by means of U-bolts.
The longest leaf known as main leaf or master leaf has its ends formed
in the shape of an eye through which the bolts are passed to secure the spring to its supports.
Usually the eyes, through which the spring is attached to the hanger or shackle, are provided
with bushings of some antifriction material such as bronze or rubber. The other leaves of the
spring are known as graduated leaves. In order to prevent digging in the adjacent leaves, the
ends of the graduated leaves are trimmed in various forms as shown in Fig. 23.30. Since the
master leaf has to with stand vertical bending loads as well as loads due to sideways of the
vehicle and twisting, therefore due to the presence of stresses caused by these loads, it is
usual to provide two full length leaves and the rest graduated leaves as shown in Fig. .
Rebound clips are located at intermediate positions in the length of the spring, so that the
graduated leaves also share the stresses induced in the full length leaves when the spring
rebounds.
Equalised Stress in Spring Leaves (Nipping)
We have already discussed that the stress in the full length leaves is 50% greater
than the stress in the graduated leaves. In order to utilise the material to the best advantage,
all the leaves should be equally stressed.
This condition may be obtained in the following two ways :
1. By making the full length leaves of smaller thickness than the graduated leaves. In
this way, the full length leaves will induce smaller bending stress due to small
distance from the neutral axis to the edge of the leaf.
Figure 3(h): Nipping
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2. By giving a greater radius of curvature to the full length leaves than graduated leaves,
as shown in Fig. 23.31, before the leaves are assembled to form a spring. By doing so,
a gap or clearance will be left between the leaves. This initial gap, as shown by C in
Fig. 23.31, is called nip. When the central bolt, holding the various leaves together, is
tightened, the full length leaf will bend back as shown dotted in Fig. and have an
initial stress in a direction opposite to that of the normal load. The graduated leaves
will have an initial stress in the same direction as that of the normal load. When the
load is gradually applied to the spring, the full length leaf is first relieved of this initial
stress and then stressed in opposite direction. Consequently, the full length leaf will
be stressed less than the graduated leaf. The initial gap between the leaves may be
adjusted so that under maximum load condition the stress in all the leaves is equal, or
if desired, the full length leaves may have the lower stress. This is desirable in
automobile springs in which full length leaves are designed for lower stress because
the full length leaves carry additional loads caused by the swaying of the car, twisting
and in some cases due to driving the car through the rear springs. Let us now find the
value of initial gap or nip C.
Consider that under maximum load conditions, the stress in all
the leaves is equal. Then at maximum load, the total deflection of the graduated leaves will
exceed the deflection of the full length leaves by an amount equal to the initial gap C. In
other words,
…………(I)
Since the stresses are equal,therefore
And
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Substituting the values of WG and WF in equation (I), we have
………….(II)
The load on the clip bolts (Wb) required to close the gap is determined
by the fact that the gap is equal to the initial deflections of full length and graduated leaves.
∴
…………… (III)
The final stress in spring leaves will be the stress in the full
length leaves due to the applied load minus the initial stress.
∴ Final stress
[
]
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…….(substituting n =nF+nG ) ……… . (IV)
Notes :
1. The final stress in the leaves is also equal to the stress in graduated leaves due to the
applied load plusthe initial stress.
2. The deflection in the spring due to the applied load is same as without initial stress.
Design considerations of Main spring
The master leaf of a laminated spring is hinged to the supports. The
support forces induce, stresses due to longitudinal forces and stresses arising due to possible
twist. Hence, the master leaf is more stressed compared to other the graduated leaves.
Methods to reduce additional stresses could be,
1.) Master leaf is made of stronger material than the other leaves.
2.) Master leaf is made thinner than the other leaves. This will reduce the bending stress
as evident from stress equation.
3.) Another common practice is to increase the radius of curvature of the master leaf than
the next leaf.
3.5 Length of Leaf Spring Leaves
The length of the leaf spring leaves may be obtained as discussed below :
Let 2L1 = Length of span or overall length of the spring,
= Width of band or distance between centres of U-bolts. It is the
ineffective length of the spring,
nF = Number of full length leaves,
nG = Number of graduated leaves, and
n = Total number of leaves = nF + nG.
We have already discussed that the effective length of the spring,
…….. ...(When band is used)
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=
………..... (When U-bolts are used)
It may be noted that when there is only one full length leaf (i.e. master leaf only), then the
number of leaves to be cut will be n and when there are two full length leaves (including one
master leaf), then the number of leaves to be cut will be (n – 1). If a leaf spring has two full
length leaves, then the length of leaves is obtained as follows :
Similarly,
The nth leaf will be the master leaf and it is of full length. Since the master leaf has
eyes on both sides, therefore
Length of master leaf = 2 L1 + π (d + t) × 2
Where d = Inside diameter of eye, and
t = Thickness of master leaf.
The approximate relation between the radius of curvature (R) and the camber (y) of the spring
is given by
The exact relation is given by
y (2R + y) = (L1)2
where L1 = Half span of the spring.Note : The maximum deflection ( δ ) of the spring is equal
to camber (y) of the spring.
3.6 Standard Sizes of Automobile Suspension Springs
Standard nominal widths are : 32, 40*, 45, 50*, 55, 60*, 65, 70*, 75, 80, 90, 100 and
125 mm. (Dimensions marked* are the preferred widths)
Standard nominal thicknesses are : 3.2, 4.5, 5, 6, 6.5, 7, 7.5, 8, 9, 10, 11, 12, 14 and 16
mm.
At the eye, the following bore diameters are recommended : 19, 20, 22, 23, 25, 27, 28,
30, 32, 35, 38, 50 and 55 mm.
30
Dimensions for the centre bolts, if employed, shall be as given in the following table.
Minimum clip sections and the corresponding sizes of rivets and bolts used with the
clips shall be as given in the following table (See Fig. 23.32).
3.7 Dimensions for centre bolts
3.8 Dimensions of clip, rivet and bolts.
Notes :
For springs of width below 65 mm, one rivet of 6, 8 or 10 mm may be used. For springs of
width above 65 mm, two rivets of 6 or 8 mm or one rivet of 10 mm may be used.
1. For further details, the following Indian Standards may be referred :
(a) IS : 9484 – 1980 (Reaffirmed 1990) on „Specification for centre bolts for leaf
springs‟.
(b) IS : 9574 – 1989 (Reaffirmed 1994) on „Leaf springs assembly-Clips-
Specification‟.
Figure 3(i): Spring clip
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MANUFACTURING
OF
LEAF SPRING
32
4. Manufacturing of leaf spring
Raw material
Shearing or cutting process
Drilling
Eye rolling of main blade
Hardening
Tempering
Hardness testing
Fitting Painting labeling inspection stock ready for supply
33
4.1 Raw material
Generally leaf springs are made of various fine grade alloy steel. The most
commonly used grades of steel are 55 Si 7,60 Si Cr7,50 Cr V4. The others are En 45 A, 65 Si
7,55 Si Cr 7,65 Si cr7,En 42 60 s 87.
In our project we are going to use En 42 60 S87 grade of steel alloy.
Generally the width of the raw material varies from 40-100 mm and thickness varies from 4
to 20mm.
Figure 4(a) : Steel alloy
4.2 Shearing or cutting process
Shearing is a process for cutting sheet metal to size out of a larger stock such
as roll stock. The raw material is cut into different sizes with the help of the 100 ton cutting
press machine.
1) At first the raw material is placed on the roller bed so that it will be easy to move the
material towards the machine.
2) Required length of the material to be cut is measured with a tape and marking is done
on the raw material.
3) Now move the material in to the cutting area of the machine so that the mark is placed
exactly at the cutting edge of the blade.
4) Now lock the material with the help of the lock nut provided.
34
5) Allow the lubricant to flow for free action of cutting and for reducing friction.
6) Now apply the load on the material by pressing the brake provided.
7) Now the required length of the material piece can be obtained.
Figure 4(b): 100 ton press cutting machine
4.3 Drilling operation
Necessary holes are provided on the strips of leaf springs to hold all the plates
together. So drilling operation is performed. Generally vertical drilling machine is used for
this operation.
1.) The given material piece is placed on the table of the drilling machine.
35
2.) The diameter of the required hole is choosen and the required drill bit is connected to
the spindle.
3.) The workpiece is placed in the required position for drilling and the coolent oil is
sprayed over the work piece.
4.) Now by applying the hand lever the required hole diameter is drilled. Required number
of holes are drilled.
Figure 4(c): Vertical drilling machine
4.4 Eye rolling of main blade
The master blade is heated at its two ends for eye formation, these
are done to attach with the frame of the vehicle. The heating is done in a end heating furnace
36
at a temperature of 1000 degree centigrade. The heating is done only at the ends so that it will
be easy to bend at the ends.
Furnace oil and the air are used for heating the furnace. The furnace is
first allowed to heat freely for 45 mins. Now the master blades are placed in the furnace such
that only ends are heated.
After heating is done for one end it is bend to form the eye and again it
is placed in the furnace to heat the other end. After heating the main blade is bent slightly to
form curve at the end with the help of 50 ton punching machine so that it will be easy to roll
to form eye formation.
In the eye rolling machine the master blade end is placed between the circular wheel and the
die. after placing the hand lever is moved so that the end of the master blade rolls over the die
thus forming eye shape.
Figure 4(d): Eye rolling of main spring
37
4.5 Hardening (Quenching)
Hardening is carried out to achieve the maximum hardness.
The main blades after the eye formation are heated to a temperature of 800-1000
degree centigrade in a furnace to increase the hardness of the material.
The other blades along with main blades are heated in the furnace. The furnace is
heated by using air and furnace oil through conventional air flow system. The conventional
air flow system is used to mix both air and furnace oil for heating purpose. A pump is
provided for the air to go out.
After heating the blades in the furnace for 45 minutes they are taken out and bent to
the required angle on the hydraulic bending machine. The required angle can be obtained by
using required angle dies.
The blades after making the required angle they are immersed in the Quenchngon
oil to increase the hardness. The hardness at the end of this stage is about 50 to 60.
Figure 4(e): Hardening
38
Figure 4(f): Hydraulic bending machine
Following are the factors of affecting the hardening process.
Chemical composition of steel.
Size and shape of steel part.
Hardening cycle, i.e. heating rate, hardening temperature, holding time and
cooling rate.
Homogeneity and grain size of austenite.
Quenching media.
Surface condition of steel part.
4.6 Tempering
Quenched steel, while very hard and strong, is too brittle to be useful for most
applications. A method for alleviating this problem is called tempering. For most steels,
tempering involves heating to between 250 and 500 °C, holding that temperature (soaking)
for an appropriate amount of time (on the order of seconds or hours), then cooling slowly
over an appropriate length of time (minutes or hours). This heat treatment results in higher
39
toughness and ductility, without sacrificing all of the hardness and tensile strength gained
from rapid quenching. Tempering balances the amount of hard martensite with ductile ferrite
and pearlite.
In some applications, different areas of a single object are given different heat treatments.
This is called differential hardening. It is common in high quality knives and swords.
Figure 4(g): Tempering process
Figure 4(h): Tempering furnace
40
Purpose of tempering
Improve ductility
Improve toughness
Reduce hardness
Increase% elongation
Relieve residual; stresses
After the hardening process the blades are dried and again heated in the furnace for tempering
process. In the tempering process the blades are heated to nearly 6oo degree centigrade for
nearly 80 minutes to decrease the hardness up to 30 to 40. Here also air along with furnace oil
is used for heating process.
After tempering is done the blades are removed from the furnace and they are dried in air.
4.7 Hardness testing
Hardness is usually defined as resistance of a material to penetration. It also refers to
stiffness or resistance to scratching, abrasion or cutting.
In the most general accepted tests, an indenter is pressed into the surface of the
material by a slowly applied known load, and the extent of the resulting impression is
measured mechanically or optically. A large impression for a given load and indenter
indicates a soft material, and the opposite is true for a small impression.
Following are the testing methods used to determine hardness.
The scratch hardness test (one material scratches another or not)
The Brinnell hardness tester (ball indenter)
The Rockwell hardness tester (diamond cone or steel ball indenter)
The Vicker hardness tester ( diamond pyramid indenter)
The shore Scleroscope ( the height of bounce of diamond tipped hammer)
We generally use Rockwell hardness tester for testing the hardness of the steel.
41
Rockwell Hardness Test
This test determines the hardness of metals by measuring the depth of impression,
which can be made by a hard test point under a known load. The penetrator may be either a
steel ball or diamond sphero-conical. Soft metals will be indicated by low hardness numbers.
Hard metals will be indicated by high hardness numbers. Harder metals permit less of an
impression to be made, resulting in higher hardness numbers.
s.no Indenter load dial application
A diamond 60 black Carbides,thin
steel,shallow case
hardenedsteel,case
carburized surfaces.
B diamond 150 black Hard cast
iron,pearlitic
malleable iron,
steel,deep
casehardened
steel,titanium.
C diamond 150 Blackpearlitic
malleable iron,
Pearlitic malleable
iron,thin steel and
medium case
hardened
steel,titanium
42
Figure 4(i): Rockwell hardness tester
4.8 Fitting
In this section the leaf springs along with the main spring are fitted together with
the help of clamps,bolts,nuts and rivets.
4.8.1 Clamps
Clamps are the devices which are used for holding the leaf springs together. Clamps are made
of Mild Steel.
Procedure for making clamps
At first the material is cut into the required length on the 50 ton cutting machine by
using blades. Next the cutted material is punched on the 5o ton punching machine to obtain
required circular shape at the edge by using suitable die.
Now after measuring the correct size the other end is also punched on 50 ton
punching machine to obtain circular shape by using the same die. This circular shape at the
ends is provided for clamps of width greater than 20 mm.
43
After making the reqired size the clamp materials are heated in the end heating furnace at
1000 degree centigrade by using furnace oil and air. The clamps are heated for 15 minutes in
the furnace.
After heating they are taken out and placed on the 50 ton punching machine to make the
clamp of „U‟ shape by using clamp dies. Different dies are used for making clamps of
different widths.
Generally 4 clamps are used for 12 plates and 2 clamps are used for 7 leaf plates.the clamps
are arranged at equal distance from the centre.
Figure 4(j): Clamps of different sizes
44
Figure 4(k): circular cutting die of clamp
4.8.2 Bolts and nuts
Bolts and nuts of different sizes are used in the holes provided on the leaf springs to
hold them tightly.
Figure 4(l): Bolts and rivets
45
4.8.3 Rivets
Rivets are used for holding the clamps and leaf springs together.
4.8.4 MS pipe
Ms pipes are provided for the bolts that are attached to the clamps to reduce the wear
of the bolts.
4.8.5 Bushes
Bushes made of MS with gold coating are inserted in to the eye rolling end of the main
spring in order to the wear.
Figure 4(m): Bush
4.9 Painting
After fitting operation the leaf springs are allowed for painting operation.
Figure 4(n): Painting
46
Two types of paints are generally used for leaf springs
(1) Black
(2) Green.
Black paint is generally used for high quality leaf springs and Green is used for low quality
leaf springs.
The leaf springs are placed on the painting table and now the required paint is sprayed over it
with the help of Spray gun.
4.10 Labelling
After drying the painted leaf springs, labelling is done on the leaf springs.
Generally the name of the manufactured company and the dimensions are used as labelling.
Figure 4(o): labeling
47
4.11 Inspection
Inspection is carried out by authorities regularly to check the quality, performance
of the leaf springs. The leaf springs with bad quality or with low performance are rejected
and once again allowed for manufacturing.
4.12 Stock ready to supply
After inspection the leaf springs with good quality and performance are allowed to
stock storage. Now the stock is are ready to supply.
Figure 4(p): Stock ready to supply
48
FAILURE
ANALYSIS
OF
LEAF SPRING
49
5. Failure analysis of leafspring
5.1 Failure analysis
Spring failures may be categorized into three types :
Early Life Failures
• These type of failures occur generally due to a spring defect, installation problem or
overload. This may be due to the material used, the manufacturing processes or improper
installation techniques. This type of failure may also be caused by a short-term
overloadcondition.
Midlife Failures
• Once the spring has passed the time in service which would expose early life failures, a very
low failure rate should be observed, assuming the spring is subjected to normal service.
Late Life Failures
• At this point, the frequency of spring failures will tend to increase rapidly as the useful life
of the spring has been reached. By this time the spring steel has been fatigued and corroded to
a point where its useful life is over.
Failures occurring in early and midlife of the spring are usually most economically handled
by repairing the broken leaf rather than replacing the spring. Failures in older springs occur at
a point when all leaves have reached their fatigue life the spring should now be replaced. The
difficulty, of course, is determining what type of failure the spring has experienced.
Basically, the condition of the spring, as well as its service history, will indicate if the spring
should be repaired or replaced.
5.2 Quench cracks:
Quench cracks, which are aligned normal to the length of the leaf, have been identified in
shot peened and polished surfaces. These cracks have been attributed to an improper
quenching process. It is established by theoretical analysis that the leaf thickness is smaller
than the critical plate thickness required for this composition of steel, and that leads to an
increase in quench severity. It appears that some of these quench cracks have propagated by a
50
fatigue mode which is confirmed by the presence of beach marks on the fractures surface.
Observation of intergranular cracking and the presence of FeS inclusions at the prior
austenite rain boundaries implies that some sort of grain boundary embrittlement might have
facilitated crack growth and led to failure. It has been suggested that quenching should be
carried out by recommended procedures guided by the thickness of the component and
chemical composition of the steel. Careful inspection of the surface after quenching must also
be carried out to maintain quality assurance in order to avoid premature failure.
The failure analysis of a leaf spring which failed prematurely during
service was carried out using
1.) Optical and scanning electron microscopy
2.) hardness and tensile testing,
3.) residual stress evaluation by X-ray diffraction.
5.3 Optical Metallurgical Microscope
Microstructures were visualized and photographed by using optical metallurgical
microscope shown in fig6. Metallurgical microscope is a value able apparatus for
metallurgist which is used to investigate the microstructure of metal or alloys usually at
magnification ranging from 40X to 600X. Since a metallographic sample is opaque to light,
the sample is illuminated by reflected light. A properly polished and etched specimen is
placed under the objective lens and when a particular combination of objective lens and eye
piece is used at the proper tube length, the total magnification is equal to the product of the
objective and the eyepiece.
51
Figure 5(a): Metallurgical Microscope
5.4 Scanning Electron Microscope
The scanning electron microscope (SEM) is a type of electron
microscope that creates various images by focusing a high energy beam of electrons onto the
surface of a sample and detecting signals from the interaction of the incident electrons with
the sample's surface. The type of signals gathered in a SEM varies and can include secondary
electrons, characteristic x-rays, and back scattered electrons. The sample for SEM do not
require any special preparation, except for cutting to appropriate size that can fit into the
specimen chamber. Non-conductive solid specimen are coated with a layer of conducting
material. A very thin coating of electrically conducting material is deposited over the
specimen by vacuum evaporation. Such coatings include gold, platinium, tungsten, graphite
etc. As these elements are quite expensive therefore, while preparing the sample for SEM, we
inserted a thin copper wire inside the sample during mounting, thus making an electrical
contact between the metal piece and base of specimen holder.
52
Figure 5(b): Scanning Electron Microscope
Microstructure of Failure & Received Material
As we know that the microstructures have a significant influence on the
mechanical and physical properties of the materials. Therefore, we examined the
microstructures of samples in different conditions, viz. As rolled, hardened tempered shot
penned. The changes in microstructure with respect to the treatment given to the material are
very clear in the figures given below. For the best fatigue resistance, tempered martensite
structure is obtained, because it is an ideal structure with low mean free path available that is
extremely small, uniformly dispersed cementite in uniform ferrite (similar to spheroid, but
much smaller).
Figure 5(c): Failure Material Leaf Spring and Received Material Leaf Spring
53
5.5 Tensile Test of Leaf Spring
Tensile test is most frequently performed to determine the certain mechanical
properties. Tensile strength can give an idea of fatigue strength, as fatigue strength is almost
half of tensile strength in most cases.
The standard tensile strength of in tempered condition according to JIS G 4801
is 125 kgf/mm2 (126N/ mm
2) minimum.
We performed the tensile test of material in two conditions, i.e.: as rolled, and tempered.
The results obtained are tabulated below:
S.No Condition Tensile Strength
1 Failure Material 156 kg/mm2
2 Received Material 126.75 kg/mm2
This test can be performed on following type of Machine
Figure 5(d): Universal Tensile Testing Machine
54
5.6 Fatigue Test of Leaf Spring
The fatigue testing machine in Landhi Engineering Works is imported
from Japan and is specially designed for the fatigue test of the Leaf Spring. The picture of
this machine has been shown below:
Figure Leaf Spring Sup-9 during Fatigue Test LEW Karachi
The Leaf spring shown in above diagram is the rare leaf spring of IMV;
an upcoming model by Toyota Motors. This vehicle would be type of a heavy load carriage.
The fatigue testing machine at the Landhi engineering works was installed by the Toyota
motors for the tasting of the leaf spring to be used in IMV; their new product. Machine was
set at the speed of 60 cycles per minute.
The test was conducted by applying load of 1545Kg and it took 153761 numbers of cycles to
break the Leaf on which the test was carried out.
Standard Mechanical Test results of Leaf Spring Give by People Steel Mills (PSM)
Karachi
Yield Strength
N/mm2
Tensile Strength
N/mm2
Elongation
%
Hardness
HB
1079 1226 9 % 363-429
Test Results of Prepared Specimen
But we have received following results during the experimental work
Yield Strength
N/mm2
Tensile Strength
N/mm2
Elongation
%
Hardness
HB
1181 1305 12 % 388
55
Figure 5(e): fatigue test
Springs are a limited life component.
Regardless of how well a spring is maintained or how favorable the operating conditions are,
all springs will eventually fail from fatigue caused by the repeated flexing of the spring. Once
the spring life limit is reached a fatigue failure will or has occurred.
Factors influencing fatigue life :
Overloading
• The higher the loads or deflections seen by a spring, the lower its fatigue life.
Shock Absorbers
• A properly functioning shock absorber will tend to reduce the spring deflection as the
vehicle hits a bump. Lower spring deflections mean lower operating stresses on the spring
which in turn gives longer fatigue life. This is especially true for full taper springs which do
not have the high interleaf friction to help dampen spring deflections. Worn or missing shock
absorbers must be replaced to maximize spring life.
Brake Adjustments
• Improperly adjusted brakes can also reduce spring life. Under braking, springs are expected
to absorb some of the braking forces. If the brakes on an axle are unevenly adjusted one
spring will have to absorb more than its share of braking force which can reduce its fatigue
life.
56
Protective Coatings
• Corrosion is one of the major factors in reducing spring life. Proper paints and care during
handling and installation can help to slow the spread of spring corrosion. On full taper springs
the only acceptable coating is the individual painting of each leaf with zinc-rich paint. This
paint may be recognized by its characteristic gray color.
Surface Condition
• The condition of the spring surface also has an effect on fatigue life. Generally, a fatigue
crack will start at some sort of surface defect on the spring leaf. Therefore, care needs to be
used when manufacturing and installing springs to reduce these defects to a minimum.
Shot Peening
• Extensive testing indicates that shot peening can increase the life of springs by a factor of
three or more. It is not enough, however, to simply shot peen the first one or two leaves in an
assembly-all leaves must be shot peened. All major vehicle manufacturers specify that their
OEM springs have each leaf shot peened.
Decarburization and Steel Quality
• Improper manufacturing methods can also reduce fatigue life. For example, poorly
controlled heat-treat furnaces can excessively decarburize the leaf surface.
Decarburization is the loss of carbon from the steel surface which will result in a soft leaf
surface once heat-treating is complete. This soft layer will not be able to handle the spring
stresses and will lead to early failure. Poor steel quality can also influence spring life. If the
steel has excessive impurities in it, the fatigue life will be reduced.
Maintenance
• Finally, improper maintenance will affect spring life.
• Spring eyes and other suspension components should be regularly greased to prevent
binding.
• U-bolts should never be reused.
• Axle seats, top plates and other components should be periodically inspected and replaced
as required.
5.7 Increasing the fatigue strength of leaf spring:
In order to increase the fatigue strength of leaf spring you have to do the following:
Carefully polish the surfaces of the springs to remove any surface defects or
machining marks that will be the location for crack initiation.
57
Shot- Peen the steel. Bombard the surfaces of the spring with steel shot, which cold
works the steel, which hardens the surface and puts it into a state of compression, which
impedes crack propagation.
Temper the steel. When initially forming the piece, cool the outer surface quickly to
put the surface into a state of compression, which will also impede crack propagation.
(Theres another definition for Tempering steel, which is heating it to stabilize and de-stress
the crystal structure.)
Quench the steel, when forming the piece the faster you cool it down, the more steel
gets locked into a Martensite phase, which has better fatigue properties. However, if you
quench it too quickly, you develop thermal stresses and cracks, which will obviously weaken
the steel. (Another method for increasing the Martensite percentage is to heat treat the steel
before tempering it.)
Case is thus expended more than the core because,
(Austenite Martensite) volume increase by 4% and
(Austenite Ferrite + pearlite) volume increase by 3%,
This is lesser than that.
During fabrication, prevent air pockets or contaminates (non-metallic inclusion) from
getting into the steel. These contaminates will provide starting points for cracks to form.
Increase the carbon content from 0.5% to about 0.95%. This will harden your steel
and improve the fatigue properties.
Finally, you could just decrease the applied load on your leaf spring steel has the nifty
property of a “Fatigue Limit”, which means that if your loads are less than a certain value,
then you can cycle the part as many times as you want without ever seeing fatigue fractures.
Most non-ferrous alloys such as aluminum or copper will not have a fatigue limit.
58
Fatigue cracks that have begun to propagate can sometimes be stopped by drilling
holes, called drill stops, in the path of fatigue crack. However, it is not recommended because
a hole represents a stress concentration factor of about 2. There is thus the possibility of a
new crack starting in the side of the hole. It is always for better to replace the cracked part
entirely. Several disasters have been caused by botched repairs to cracked structures.
In the end we are able to conclude that fatigue life of leaf spring can be increased if:
The vehicle is loaded not greater than load for which it has been manufactured.
Proper cleanliness of leaf spring is done and also it should be avoided from water and
mud etc. as much as possible to minimize the corrosion of leaf springs.
The government takes appreciable steps to improve the smoothness of the road
network in the country.
Shot-peening must be done to create residual compressive stresses as fatigue failure
always occurs in the tensile stresses.
5.8 When To Repair
• If the spring has not been repaired or repaired only once. Stamping a 1 in the clip for the
first repair and a 2 for a second repair will help identify the number of previous repairs.
• If the spring mileage is less than half of normal life.
• If the repair cost is less than 1/2 the cost of a new spring.
• If no more than two or three leaves are broken.
• If the failure is not of a fatigue type. For example, a leaf broken through the center hole is
caused by improper spring clamping brought on by loose U-bolts or worn axle seats, not
fatigue. This spring should be repaired, if possible, and the cause of failure corrected. Even
when it appears to make sense to repair, the following should be kept in mind :
1. Repair leaves are usually not shot peened and must often be heavily hand-fit to match the
old spring. Therefore, the repair leaf will not be as durable as a leaf in a new spring would be.
2. Since the remaining leaves have lost some of their strength, the replaced leaves will be
carrying more of the load than they were originally designed for.
59
3. When the leaves first broke the remaining leaves in the spring had to carry more load and
were probably overstressed.
4. Replacing the broken leaves does nothing to restore the fatigue life of the reused leaves.
These leaves will continue to fail since their fatigue life is essentially over.
5.9 When To Replace
• The spring has already been repaired once or, at most, twice.
• The spring service mileage has exceeded 1/2 its normal life.
• The repair cost exceeds 1/2 the cost of a new spring.
• More than two or three leaves are broken.
• If small fatigue cracks can be seen running across the leaf width near the U-bolts on the
unbroken leaves.
• If the leaf tips have separated away from the leaf above.
• Never attempt to repair a full taper spring.
60
CONCLUSION:
This project work has provided us an excellent opportunity and experience to use
our limited knowledge. We gained a lot of practical knowledge regarding the “DESIGN,
MANUFACTURING AND FAILURE ANALYSIS OF LEAF SPRING”.
In “TRAILOR SPRINGS” our intensions were to observe the process deeply and to
point out any deficiency that is taking place in the process. We have found that the process
and steps are followed by them with many safety measurements and they manufacture leaf
springs with all necessary, viz. Heating, Quenching, Tempering and Shot peening. Since the
manufacturing process is difficult skilled workers are generally employed.
Finally we conclude that we clearly observed the design,manufacturing and failures of leaf
spring and completed our mini project successfully.
working staff of TRAILOR SPRINGS
61
BIBLIOGRAPHY/REFERENCES/WEBSITES
Books:
1. “A Textbook of Machine Design” by R.S.KHURMI_AND_J.K.GUPTA.
2. William D Callister. “Fundamentals of Material Science and Engineering”. Fifth
Edition. John Wiley & Sons, Inc 1985
3. Mikell P. Groover, “Fundamentals of Modern Manufacturing” Second Edition. John
Wiley & Sons.Inc.
4. Metals Handbook. Volume 1 Microsturcture
5. Heat Treatment Principle and Technique by T.V Rajan, C.P Sharma, Ashok Sharma
6. Steel and Its Heat Treatmentby K.E Theling
Websites:
1. http://www.wikipedia.org
2. http://www.howstuffworks.com
3. http://www.tpub.com
4. http://www.google.com
5. http://www.answer.com
6. http://www. freepatentsonline.com
7. http://www. procarcare.com