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Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering PDF Download

1. Eccentrically loaded screwed joint: 

Consider a bracket fixed to the wall by means of three rows of screws having two in each row as shown in figure 11.1.1. An eccentric load F is applied to the extreme end of the bracket. The horizontal component, Fh, causes direct tension in the screws but the vertical component, Fv, is responsible for turning the bracket about the lowermost point in left (say point O), which in an indirect way introduces tension in the screws.

 

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

It is easy to note that the tension in the screws cannot be obtained by equations of statics alone. Hence, additional equations must be formed to solve for the unknowns for this statically indeterminate problem. Since there is a tendency for the bracket to rotate about point O then, assuming the bracket to be rigid, the following equations are easily obtained.

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

where yi =elongation of the i-th bolt

li=distance of the axis of the i-th bolt from point O.

 If the bolts are made of same material and have same dimension, then

 fi = kyi

where fi =force in the i-th bolt

k =stiffness of the bolts

Thus Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

 

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

Using the moment balance equations about O, the lowermost point in the left side, the following equation is obtained.

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineeringin a row.

Thus the force in the i-th screw is

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

For safe design of the joint it is therefore required that

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

where St =allowable tensile stress of the bolt.

Note that Fvcauses also direct shear in the bolt. Its effect may be ignored for a preliminary design calculation.

 

2. Eccentrically loaded riveted joint: 

Consider, now, a bracket, which carries a vertical load F . The bracket, in this case, is connected to the wall by four rivets as shown in figure 11.1.2. The force,

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

in addition to inducing direct shear of magnitude  F/4 in each rivet, causes the whole assembly to rotate. Hence additional shear forces appear in the rivets. F Centroid Rivet L Figure 11.1.3: Eccentrically loaded rivet joint

Once again, the problem is a statically indeterminate one and additional assumptions are required. These are as following:

(i) magnitude of additional shear force is proportional to the distance between the rivet center and the centroid of the rivet assembly, whose coordinates are defined as

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

(ii) directions of the force is perpendicular to the line joining centroid of the rivet group and the rivet center and the sense is governed by the rotation of the bracket.

Noting that for identical rivets the centroid is the geometric center of the rectangle, the force in the i-th rivet is

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

where α =proportional constant

li=distance of the i-th rivet from centroid.

Taking moment about the centroid

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

Thus, the additional force is  Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

The net force in the i-th rivet is obtained by parallelogram law of vector addition as

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

where θ i =angle between the lines of action of the forces shown in the figure.

For safe designing we must have

Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering

where ss  =allowable shear stress of the rivet.

The document Design of Eccentrically Loaded Bolted/Riveted Joints | Design of Machine Elements - Mechanical Engineering is a part of the Mechanical Engineering Course Design of Machine Elements.
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FAQs on Design of Eccentrically Loaded Bolted/Riveted Joints - Design of Machine Elements - Mechanical Engineering

1. What is an eccentrically loaded bolted/riveted joint?
Ans. An eccentrically loaded bolted/riveted joint is a type of joint where the applied load does not act through the centroid of the joint. This results in a moment being generated, causing additional stresses and potentially leading to failure of the joint.
2. How is the design of eccentrically loaded bolted/riveted joints different from centrally loaded joints?
Ans. The design of eccentrically loaded bolted/riveted joints is different from centrally loaded joints because the eccentric loading introduces additional bending stresses. These bending stresses need to be considered along with the shear and tension stresses that are typically analyzed in centrally loaded joints.
3. What factors should be considered in the design of eccentrically loaded bolted/riveted joints?
Ans. Several factors should be considered in the design of eccentrically loaded bolted/riveted joints, including the magnitude and direction of the eccentric load, the location of the load with respect to the joint, the material properties of the joint components, and the type and size of the fasteners used in the joint.
4. How can the strength of an eccentrically loaded bolted/riveted joint be assessed?
Ans. The strength of an eccentrically loaded bolted/riveted joint can be assessed by analyzing the stresses in the joint components and comparing them to the allowable stresses for the material. This can be done using analytical methods or finite element analysis (FEA) techniques.
5. What are some common failure modes in eccentrically loaded bolted/riveted joints?
Ans. Some common failure modes in eccentrically loaded bolted/riveted joints include bolt or rivet shear, bearing failure, and joint separation. These failure modes can occur due to excessive shear, tension, or bending stresses in the joint components. Proper design and analysis can help prevent these failures.
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