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The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE) PDF Download

Alternate derivation

The above three moment equations may also be derived by direct application of force method as follows. Now choose ML, MC and MR , the three support moments at left, centre and right supports respectively as the redundant moments. The primary determinate structure is obtained by releasing the constraint corresponding to redundant moments. In this particular case, inserting hinges at L, C and R , the primary structure is obtained as below (see Fig. 12.2)

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

Let displacement (in the primary case rotations) corresponding to rotation MC be ΔL, which is the sum of rotations θCL and θCR. Thus,

ΔL = θCL + θCR                               (12.6)

It is observed that the rotations θCL and θCR are caused due to only applied loading as shown in Fig.12.2.This can be easily evaluated by moment area method as shown previously.

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

In the next step, apply unit value of redundant moments at L ,C and R and calculate rotation at C (i.e. flexibility coefficients).
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

In the actual structure the relative rotation of both sides is zero. In other words the compatibility equation is written as,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
Substituting the values of flexibility coefficients and ΔL in the above equation,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

Or,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

when moment of inertia remains constant i.e. IR = IL = I ,the above equation simplifies to,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

Example 12.1
A continuous beam ABCD is carrying a uniformly distributed load of 1 kN/m over span ABC in addition to concentrated loads as shown in Fig.12.4a. Calculate support reactions. Also, draw bending moment and shear force diagram. Assume EI to be constant for all members.

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

From inspection, it is assumed that the support moments at A is zero and support moment at C ,
MC =15 kN.m (negative because it causes compression at bottom at C) Hence, only one redundant moment MB   needs to be evaluated. Applying three moment equation to span ABC ,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

The bending moment diagrams for each span due to applied uniformly distributed and concentrated load are shown in Fig.12.4b.

Equation (1) may be written as,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

Thus,

MB = −18.125 kN.m

After determining the redundant moment, the reactions are evaluated by equations of static equilibrium. The reactions are shown in Fig.12.4c along with the external load and support bending moment.

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

In span AB,  RA, can be calculated by the condition that  The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

Similarly from span BC ,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

The shear force and bending moment diagrams are shown in Fig.12.4d.

Example 12.2
A continuous beam ABC is carrying uniformly distributed load of 2 kN/m as shown in Fig.12.5a.The moment of inertia of span AB is twice that of span . Evaluate reactions and draw bending moment and shear force diagrams.

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

By inspection it is seen that the moment at support C is zero. The support moment at A and B needs to be evaluated .For moment at B , the compatibility equation is written by noting that the tangent to the elastic curve at B is horizontal .The compatibility condition corresponding to redundant moment at A is written as follows. Consider span AB as shown in Fig.12.5b.

The slope at A , θA may be calculated from moment-area method. Thus,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

Now, compatibility equation is,

= θA = 0                        (2)

It is observed that the tangent to elastic curve at A remains horizontal. This can also be achieved as follows. Assume an imaginary span The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE) left of support A having a very high moment of inertia (see Fig. 12.5c). As the imaginary span has very high moment of inertia, it does not yield any imaginary span has very high moment of inertia it does not yield any M/EI diagram and hence no elastic curve. Hence, the tangent at A to elastic curve remains horizontal.
Now, consider the span  The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE) applying three-moment equation to support A,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

The above equation is the same as the equation (2). The simply supported bending moment diagram is shown in Fig.12.5d.

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
Thus, equation (3) may be written as

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

20MA  + 10MB = −500                             (4)

Now, consider span ABC, writing three moment equation for support B ,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

5MA + 20MB = -250-62.5

= -312.5                          (5)

Solving equation (4) and (5),

MB = -6.25 kN.m
MA = -37.5 kN. m

The remaining reactions are calculated by equilibrium equations (see Fig.12.5e)

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

In span AB, ∑MB = 0

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

Similarly from span BC ,

The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE)

The shear force and bending moment diagrams are shown in Fig. 12.5f.

Summary

In this lesson the continuous beam with unyielding supports is analysed by threemoment equations. The three-moment equations are derived for the case of a continuous beam having different moment of inertia in different spans. The threemoment equations also belong to force method of analysis and in this case, redundants are always taken as support moments. Hence, compatibility equations are derived in terms of three support moments. Few problems are solved to illustrate the procedure.

The document The Three Moment Equations-I (Part - 2) | Structural Analysis - Civil Engineering (CE) is a part of the Civil Engineering (CE) Course Structural Analysis.
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FAQs on The Three Moment Equations-I (Part - 2) - Structural Analysis - Civil Engineering (CE)

1. What are the three moment equations in civil engineering?
Ans. The three moment equations in civil engineering are mathematical equations used to calculate the reactions and moments at supports of a beam or frame structure. These equations are derived from the equilibrium conditions and are based on the principles of statics. The three moment equations are used to solve for the unknown forces, moments, and reactions in a structure.
2. How are the three moment equations derived?
Ans. The three moment equations are derived by considering the equilibrium conditions of a beam or frame structure. These equations are based on the principle of statics, which states that a structure is in equilibrium when the sum of all the forces and moments acting on it is zero. By applying this principle to different sections of a beam or frame structure, the three moment equations can be derived.
3. What are the applications of the three moment equations in civil engineering?
Ans. The three moment equations have various applications in civil engineering. They are used to analyze and design structures such as bridges, buildings, and other load-bearing structures. These equations help in determining the reactions and moments at supports, which are crucial for ensuring the safety and stability of the structure. The three moment equations are also used to calculate the internal forces and stresses in different sections of a structure.
4. Can the three moment equations be used for all types of structures?
Ans. The three moment equations are commonly used for analyzing statically determinate structures, which are structures that can be completely analyzed using the equilibrium equations alone. However, for statically indeterminate structures, additional equations and methods, such as the method of virtual work or the flexibility method, may be required to determine the unknown forces and moments. Therefore, while the three moment equations are a valuable tool in civil engineering, they may not be applicable to all types of structures.
5. Are there any limitations or assumptions associated with the three moment equations?
Ans. Yes, there are certain limitations and assumptions associated with the three moment equations. These equations assume that the structure is in a state of static equilibrium and that the material used is linearly elastic. They also assume that the structure behaves in a linear-elastic manner and that the applied loads are static and can be represented by concentrated forces or moments. Additionally, the three moment equations may not accurately account for certain factors such as dynamic loads, non-linear material behavior, and geometric imperfections, which may require more advanced analysis techniques.
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