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Analysis of Frames Without Sidesway - Slope Deflection Equation - Displacement Method, | Strength of Material Notes - Agricultural Engg - Agricultural Engineering PDF Download

Analysis of Frames Without Sidesway

The general procedure for analysis of frames without sidesway is same as for continous beams (lesson 12). This is illustrated in the following two examples.

Example 1

Draw the bending moment diagram for the follwing frame. EI is constant for all members.

Fig. 13.2.

Step 1: Fixed end Moments

\[M{}_{FAB} =-{{5 \times 4} \over 8}=-2.5{\rm{kNm}}\]  ;   \[M{}_{FCB} = {{7.5 \times {{10}^2}} \over {12}} = 62.5{\rm{kNm}}\]

\[M{}_{FAB} = M{}_{FBA} = M{}_{FCD} = M{}_{FDC}=0\]

Step 2: Slope-Deflection Equaitons

Since A and D are fixed ends, θA = θD = 0

Since there is no support settlement, δ = 0

For span AB,

\[{M_{AB}} = {M_{FAB}} + {{2EI} \over {{L_{AB}}}}\left( {2{\theta _A} + {\theta _B} - {{3\delta } \over {{L_{AB}}}}} \right) = 0.4EI{\theta _B}\]               (13.1)

\[{M_{BA}} = {M_{FBA}} + {{2EI} \over {{L_{AB}}}}\left( {{\theta _A} + 2{\theta _B} - {{3\delta } \over {{L_{AB}}}}} \right) = 0.8EI{\theta _B}\]               (13.2)


For span BC,

\[{M_{BC}} = {M_{FBC}} + {{2EI} \over {{L_{BC}}}}\left( {2{\theta _B} + {\theta _C} - {{3\delta } \over {{L_{BC}}}}} \right)=-62.5 + 0.2EI\left( {2{\theta _B} + {\theta _C}} \right)\]               (13.3)

\[{M_{CB}} = {M_{FCB}} + {{2EI} \over {{L_{BC}}}}\left( {2{\theta _C} + {\theta _B} - {{3\delta } \over {{L_{BC}}}}} \right) = 62.5 + 0.2EI\left( {{\theta _B} + 2{\theta _C}} \right)\]               (13.4)

For span CD,

\[{M_{CD}} = {M_{FCD}} + {{2EI} \over {{L_{CD}}}}\left( {2{\theta _C} + {\theta _D} - {{3\delta } \over {{L_{CD}}}}} \right) = 0.8EI{\theta _C}\]              (13.5)

\[{M_{DC}} = {M_{FDC}} + {{2EI} \over {{L_{CD}}}}\left( {{\theta _C} + 2{\theta _D} - {{3\delta } \over {{L_{CD}}}}} \right) = 0.4EI{\theta _C}\]              (13.6)

Step 3: Equilibrium Equaitons

At B,

\[{M_{BA}} + {M_{BC}} = 0 \Rightarrow 0.8EI{\theta _B} - 62.5 + 0.2EI\left( {2{\theta _B} + {\theta _C}} \right)=0\]

\[\Rightarrow 1.2EI{\theta _B} + 0.2EI{\theta _C} - 62.5 = 0\]             (13.7)

At C,

\[{M_{CB}} + {M_{CD}} = 0 \Rightarrow 62.5 + 0.2EI\left( {{\theta _B} + 2{\theta _C}} \right) + 0.8EI{\theta _C}=0\]

\[\Rightarrow 0.2EI{\theta _B} + 1.2EI{\theta _C} + 62.5 = 0\]            (13.8)

Solving equations (7) and (8),

\[{\theta _B} = {{62.5} \over {EI}}\]  and  \[{\theta _C}=-{{62.5} \over {EI}}\]

Step 4: End Moment calculation

Substituting,  θB and θC into equations (1) – (6), we have,

\[{M_{AB}} = 0.4EI{\theta _B} = 25{\rm{ kNm}}\]

\[{M_{BA}} = 0.8EI{\theta _B} = 50{\rm{ kNm}}\]

\[{M_{BC}}=-62.5 + 0.2EI\left( {2{\theta _B} + {\theta _C}} \right) =-50{\rm{ kNm}}\]

\[{M_{CB}} = 62.5 + 0.2EI\left( {{\theta _B} + 2{\theta _C}} \right) = 50{\rm{ kNm}}{M_{CB}} = 62.5 + 0.2EI\left( {{\theta _B} + 2{\theta _C}} \right) = 50{\rm{ kNm}}\]

\[{M_{CD}} = 0.8EI{\theta _C} =-50{\rm{ kNm}}\]

\[{M_{DC}} = 0.4EI{\theta _C} =-25{\rm{ kNm}}\]

Fig. 13.3. Bending Moment Diagram.

Example 2

Draw the bending moment diagram for the follwing frame. EI is constant for all members.

Fig.13.4.

Step 1: Fixed end Moments

\[M{}_{FAB}=-{{5 \times 4} \over 8}=-2.5{\rm{kNm}}\]  ;               \[M{}_{FBA} = {{5 \times 4} \over 8} = 2.5{\rm{kNm}}\]

\[M{}_{FBC}=-{{4 \times 4} \over 8}=-2{\rm{kNm}}\] ;                   \[M{}_{FCD}=-{{4 \times 4} \over 8}=-2{\rm{kNm}}\] 

Step 2: Slope-Deflection Equaitons

Since A and C are fixed ends, θA = θC = 0

Since there is no support settlement, δ = 0

For span AB,

\[{M_{AB}} = {M_{FAB}} + {{2EI} \over {{L_{AB}}}}\left( {2{\theta _A} + {\theta _B} - {{3\delta } \over {{L_{AB}}}}} \right) =-2.5 + 0.5EI{\theta _B}\]                 (13.9)

\[{M_{BA}} = {M_{FBA}} + {{2EI} \over {{L_{AB}}}}\left( {{\theta _A} + 2{\theta _B} - {{3\delta } \over {{L_{AB}}}}} \right) = 2.5 + EI{\theta _B}\]                       (13.10)

For span BC,

\[{M_{BC}} = {M_{FBC}} + {{2EI} \over {{L_{BC}}}}\left( {2{\theta _B} + {\theta _C} - {{3\delta } \over {{L_{BC}}}}} \right) =-2 + EI{\theta _B}\]                          (13.11)

\[{M_{CB}} = {M_{FCB}} + {{2EI} \over {{L_{BC}}}}\left( {2{\theta _C} + {\theta _B} - {{3\delta } \over {{L_{BC}}}}} \right) = 2 + 0.5EI{\theta _B}\]                     (13.12)


For span BD,

\[{M_{BD}} =-{{1.5 \times {2^2}} \over 2} =  - 3{\rm{ kNm}}\]                         (13.3)

Step 3: Equilibrium Equaitons

At B,

\[{M_{BA}} + {M_{BC}} + {M_{BD}} = 0 \Rightarrow 2.5 + EI{\theta _B} - 2 + EI{\theta _B} - 3 = 0\]

\[\Rightarrow 2EI{\theta _B} - 19.5 = 0 \Rightarrow {\theta _B} = {{1.25} \over {EI}}\]

Step 4: End Moment calculation

Substituting, θB into equations (9) – (12), we have,

\[{M_{AB}} =-2.5 + 0.5EI{\theta _B} =-1.875{\rm{ kNm}}\]

\[{M_{BA}} = 2.5 + EI{\theta _B} = 3.75{\rm{ kNm}}\]

\[{M_{BC}} =-2 + EI{\theta _B} =-0.75{\rm{kNm}}\]

\[{M_{CB}} = 2 + 0.5EI{\theta _B} = 2.265{\rm{ kNm}}\]

Fig.13.5. Bending Moment Diagram.

The document Analysis of Frames Without Sidesway - Slope Deflection Equation - Displacement Method, | Strength of Material Notes - Agricultural Engg - Agricultural Engineering is a part of the Agricultural Engineering Course Strength of Material Notes - Agricultural Engg.
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FAQs on Analysis of Frames Without Sidesway - Slope Deflection Equation - Displacement Method, - Strength of Material Notes - Agricultural Engg - Agricultural Engineering

1. What is the slope deflection equation in frame analysis?
Ans. The slope deflection equation is a method used in structural frame analysis to determine the displacements and rotations at various points within a frame structure. It is based on the assumption that the frame members do not undergo any sidesway or lateral deflection. The equation relates the bending moment at a particular point to the rotation and slope of the adjacent members.
2. How is the displacement method used in frame analysis?
Ans. The displacement method is a technique used in frame analysis to determine the displacements and rotations at various points within a frame structure. It involves solving a system of equations based on the equilibrium conditions and compatibility of displacements. By applying the slope deflection equation and considering the boundary conditions, the method allows for the determination of member forces and reactions in the frame.
3. What are the advantages of using the displacement method in frame analysis?
Ans. The displacement method offers several advantages in frame analysis. Firstly, it provides a more accurate representation of the behavior of the frame structure compared to other methods. Secondly, it allows for the analysis of complex frame systems with multiple degrees of freedom. Thirdly, it can handle frames with varying member properties and boundary conditions. Lastly, it provides a systematic approach for determining member forces and reactions, making it suitable for both hand calculations and computer analysis.
4. What are the limitations of the slope deflection equation in frame analysis?
Ans. While the slope deflection equation is a useful tool in frame analysis, it has certain limitations. Firstly, it assumes that the frame members do not undergo any sidesway or lateral deflection, which may not be the case in real-world scenarios. Secondly, the method becomes more complex as the frame structure becomes more intricate, making it time-consuming for manual calculations. Lastly, the slope deflection equation may not be applicable to frames with non-linear member behavior or significant axial loads.
5. How can the displacement method be applied in agricultural engineering?
Ans. The displacement method can be applied in agricultural engineering to analyze and design various structures such as agricultural buildings, grain bins, and equipment supports. By using the slope deflection equation and considering the specific loading and boundary conditions relevant to agricultural applications, engineers can determine the displacements, member forces, and reactions within these structures. This analysis helps ensure the structural integrity and safety of agricultural infrastructure.
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