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The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE) PDF Download

Instructional Objectives

After reading this chapter the student will be able to

1. Derive three-moment equations for a continuous beam with yielding supports.
2. Write compatibility equations of a continuous beam in terms of three moments.
3. Compute reactions in statically indeterminate beams using three-moment equations.
4. Analyse continuous beams having different moments of inertia in different spans and undergoing support settlements using three-moment equations.

Introduction

In the last lesson, three-moment equations were developed for continuous beams with unyielding supports. As discussed earlier, the support may settle by unequal amount during the lifetime of the structure. Such future unequal settlement induces extra stresses in statically indeterminate beams. Hence, one needs to consider these settlements in the analysis. The three-moment equations developed in the pervious lesson could be easily extended to account for the support yielding. In the next section three-moment equations are derived considering the support settlements. In the end, few problems are solved to illustrate the method.

Derivation of Three-Moment Equation

Consider a two span of a continuous beam loaded as shown in Fig.13.1. Let ML, MC and MR be the support moments at left, center and right supports respectively. As stated in the previous lesson, the moments are taken to be positive when they cause tension at the bottom fibers. IL and IR denote moment of inertia of left and right span respectively and lL and lR denote left and right spans respectively. Let δLC and δR be the support settlements of left, centre and right supports respectively. δLC and δR are taken as negative if the settlement is downwards. The tangent to the elastic curve at support C makes an angle θCL at left support and θCR at the right support as shown in Fig. 13.1. From the figure it is observed that,

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

Fig. 13.1 Continuous beam with support settlement

θCL = θCR                              (13.1)

The rotations βCL and βCR due to external loads and support moments are calculated from the M/EI diagram .They are (see lesson 12)

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

The rotations of the chord L' C'' and C'' R' from the original position is given by

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

From Fig. 13.1, one could write,

θCL = αCL - βCL                          (13.4a)

θCR = βCR - αCR                      (13.4b)

Thus, from equations (13.1) and (13.4), one could write,

αCL − βCL = βCR −αCR                (13.5)

Substituting the values of αCL, αCR, βCL and βCR in the above equation,

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
This may be written as

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)                           (13.6)

The above equation relates the redundant support moments at three successive spans with the applied loading on the adjacent spans and the support settlements.

Example 13.1
Draw the bending moment diagram of a continuous beam BC shown in Fig.13.2a by three moment equations. The support B settles by 5mm below A and C . Also evaluate reactions at A , B and C .Assume EI to be constant for all members and E = 200 GPa , I = 8x106 mm4

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

Assume an imaginary span having infinitely large moment of inertia and arbitrary span L′ left of A as shown in Fig.13.2b .Also it is observed that moment at C is zero.

The given problem is statically indeterminate to the second degree. The moments MA and MB, the redundants need to be evaluated. Applying three moment equation to the span A’AB,

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
Note that,  The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

Again applying three moment equation to span ABC the other equations is obtained. For this case,  The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE) (negative as the settlement is  downwards) and δR = 0.

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

Solving equations (2) and (3),

MB = −1.0 kN.m
MA = −4.0 kN.m                          (4)

Now, reactions are calculated from equations of static equilibrium (see Fig.13.2c)

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
Thus,

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

The reactions at B,

RB = RBR + RBL = 5.5kN                                  (5)

The area of each segment of the shear force diagram for the given continuous beam is also indicated in the above diagram. This could be used to verify the previously computed moments. For example, the area of the shear force diagram between A and B is 5.5 kN.m. This must be equal to the change in the bending moment between A and D, which is indeed the case (−4-1.5 = 5.5 kN.m). Thus, moments previously calculated are correct.

Example 13.2

A continuous beam ABCD is supported on springs at supports B and C as shown in Fig.13.3a. The loading is also shown in the figure. The stiffness of springs is kB = EI/20 and kC = EI/30. Evaluate support reactions and draw bending moment diagram. Assume EI to be constant.

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

In the given problem it is required to evaluate bending moments at supports B and C. By inspection it is observed that the support moments at A and D are zero. Since the continuous beam is supported on springs at B and C, the support settles. Let RB and RC be the reactions at B and C respectively. Then the support settlement at B and C are  The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE) respectively. Both the settlements are negative and in other words they move downwards. Thus,

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

Now applying three moment equations to span ABC(see Fig.13.2b)

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
Simplifying,

16MB + 4MC = -124 + 60RB - 45RC                             (2)

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

4MB + 16MC = -90 + 90RC - 30RB                   (3)

In equation (2) and (3) express RB and RC in terms of MB and MC (see Fig.13.2c)

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

Note that initially all reactions are assumed to act in the positive direction (i.e. upwards) .Now, 

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

Now substituting the values of RB and RC in equations (2) and (3), 

16MB + 4MC =-124 + 60(13 - 0.5MB + 0.25MC)- 45(7 + 0.25MB - 0.5MC)

Or,

57.25MB - 33.5MC = 341                                        (6)

Ana from equation 3,

4MB + 16MC = -90 + 90(7 + 0.25MB - 0.5MC)-30(13 - 0.5MB + 0.25MC)

Simplifying,

- 33.5MB + 68.5MC = 150                                       (7)

Solving equations (6) and (7)

MC = 7.147 kN.m

MB = 10.138 kN.m                   (8) 

Substituting the values of MB and MC in (4),reactions are obtained.

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

The shear force and bending moment diagram are shown in Fig. 13.2d.

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

Example 13.3
Sketch the deflected shape of the continuous beam ABC of example 13.1. The redundant moments MA and MB for this problem have already been computed in problem 13.1.They are,

MB =-1.0 kN.m

MA = -4.0 kN.m

The computed reactions are also shown in Fig.13.2c.Now to sketch the deformed shape of the beam it is required to compute rotations at B and C. These joints rotations are computed from equations (13.2) and (13.3).
For calculating θA, consider span A’AB

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

For calculating θBL , consider span ABC

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

For θBR consider span ABC

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)                              (3)

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)                              (4)

The deflected shape of the beam is shown in Fig. 13.4.

The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)
The Three Moment Equations-II | Structural Analysis - Civil Engineering (CE)

Summary

The continuous beams with unyielding supports are analysed using threemoment equations in the last lesson. In this lesson, the three-moment-equations developed in the previous lesson are extended to account for the support settlements. The three-moment equations are derived for the case of a continuous beam having different moment of inertia in different spans. Few examples are derived to illustrate the procedure of analysing continuous beams undergoing support settlements using three-moment equations.

The document The Three Moment Equations-II | 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-II - 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 expressions used to analyze and determine the bending moment at any section of a beam. These equations are derived from the equilibrium equations and are based on the concept of equilibrium of forces and moments.
2. How do you apply the three moment equations to solve beam problems?
Ans. To apply the three moment equations, you need to first determine the reactions at the supports of the beam. Then, for each section of the beam, you can write the moment equilibrium equation by considering the forces and moments acting on that section. By solving these equations simultaneously, you can find the unknown bending moments at different sections of the beam.
3. What are the limitations of using the three moment equations?
Ans. While the three moment equations are widely used in civil engineering for beam analysis, they do have some limitations. These equations assume that the beam is elastic, the material is homogeneous and isotropic, and there are no axial forces or shear forces present. Additionally, these equations are only applicable to beams with simple loading conditions and uniform cross-sections.
4. Can the three moment equations be used for curved beams or beams with varying cross-sections?
Ans. No, the three moment equations are not suitable for curved beams or beams with varying cross-sections. These equations are based on the assumption of straight beams with constant cross-sections. For curved beams or beams with varying cross-sections, more advanced methods, such as the moment-area method or numerical analysis techniques, need to be employed.
5. Are there any software programs available for solving beam problems using the three moment equations?
Ans. Yes, there are several software programs available that can solve beam problems using the three moment equations. These programs allow engineers to input the beam's geometry, loading conditions, and support conditions, and then calculate the bending moments at various sections of the beam. Some commonly used software programs for beam analysis include SAP2000, STAAD.Pro, and ETABS.
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