leaf spring design and engineering strength of materials - engineers edge

8/12/2019 Leaf Spring Design and Engineering Strength of Materials - Engineers Edge

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Leaf Spring Design and Engineering

Mechanics of Materials

Simple Supported Leaf Spring:

Uniform Width Leaf Spring

EquationNon-Uniform Width Leaf Spring

Equation

Simply supported leaf of Lozenge shape for which the maximum stress and maximum deflection are known.

From the stress and deflection equations the thickness of the spring plate, h, can be obtained as,

The maxis replaced by design stress des . Similarly, maxis replaced by des .

E = The Modulus of Elasticity material property and depends on the type of spring material chosen.

L = The characteristic length of the spring. Therefore, once the design parameters, given on the left side of the

above equation, are fixed the value of plate thickness, h can be calculated.Substitution of h in the stress equation

above will yield the value of plate width b.

F = Force applied to leaf spring.

b = Width of leaf spring

h = Height or thickness of leaf spring

In the similar manner h and b can be calculated for leaf springs of different support conditions and beam types.

Laminated Leaf Springs

One of the challenges of the uniform strength beam, say Lozenge shape, is that the value of width b sometimes is

too large to accommodate in a machine assembly. One practice is that instead of keeping this large width one

can make several slices and put the pieces together as a laminate. This is the concept of laminated spring. The

illustration below shows the concept of formation of a laminated spring.

Laminated Leaf Spring

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The Lozenge shaped plate is cut into several longitudinal strips, as indicated above. The central strip, marked 1

is the master leaf which is placed at the top. Then two pieces, marked 2 are put together, side by side to form

another leaf and placed below the top leaf. In the similar manner other pairs of strips, marked 3 and 4

respectively are placed in the decreasing order of strip length to form a laminated spring. Here width of each

strip, bNis given as,

Where:

N = The number of spring strips or layers.


In practice, strips of width, bNand lengths, stay equal to layer1, layer2 etc., as shown in the example, are cut

and put in the laminated form. The stress and deflection equations for a laminated spring is,

Where p and q are:

Simply supported beam: p = 3 and q = 3

Cantilever beam: p = 6 and q = 6

L = The characteristic length of the spring. Therefore, once the design parameters, given on the left side of the

above equation, are fixed the value of plate thickness, h can be calculated. Substitution of h in the stress equation

above will yield the value of plate width b.

F = Force applied to leaf spring.


h = Height or thickness of leaf spring

N = Number of spring strips or leafs

It should be noted that the ends of the leaves are not sharp and pointed, as shown below. In fact they are made

blunt or even made straight to increase the load bearing capacity. This change from ideal situation does not havemuch effect on the stress equation. However, small effect is there on the deflection equation.

The Illustration above shows a laminated semi- elliptic spring. The top leaf is known as the master leaf. The eye

is provided for attaching the spring with another machine member. The amount of bend that is given to the spring

from the central line, passing through the eyes, is known as camber. The camber is provided so that even at the

maximum load the deflected spring should not touch the machine member to which it is attached. The camber

shown in the figure is known as positive camber. The central clamp is required to hold the leaves of the spring.

However, the bolt holes required to engage the bolts to clamp the leaves weaken the spring to some extent.

Rebound clips help to share the load from the master leaf to the graduated leaf.

Heavy loads - Leaf Spring Design


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In order to carry heavy loads a few more additional full length leaves are placed below the master leaf for heavy

loads. Such alteration from the standard laminated leaf spring, does not change the stress value, but deflection

equation requires some correction.

Where, correction in deflection, c is given as,

Where:

m= Nf/ N

Nf= Number of full length leaf layers

N = Total number or leaf layers in spring

F = Force applied to Leaf Spring

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leaf spring design and engineering strength of materials - engineers edge

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