Theorem of three moments: Difference between revisions
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{{Short description|Theorem used in structural analysis}} |
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In |
In civil engineering and [[structural analysis]] '''Clapeyron's''' '''theorem of three moments''' (by [[Émile Clapeyron]]) is a relationship among the [[bending moment]]s at three consecutive supports of a horizontal beam. |
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Let ''A,B,C |
Let ''A,B,C-D be the three consecutive points of support, and denote by- '''''l''''' the length of ''AB'' and <math>l'</math> the length of ''BC'', by ''w'' and <math>w'</math> the weight per unit of length in these segments. Then<ref>J. B. Wheeler: An Elementary Course of Civil Engineering, 1876, Page 118 [https://books.google.com/books?id=IRhDAAAAIAAJ&pg=PA118]</ref> the bending moments <math>M_A,\, M_B,\, M_C</math> at the three points are related by:'' |
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:<math>M_A l + 2 M_B (l+l') +M_C l' = \frac{1}{4} w l^3 + \frac{1}{4} w' (l')^3.</math> |
:<math>M_A l + 2 M_B (l+l') +M_C l' = \frac{1}{4} w l^3 + \frac{1}{4} w' (l')^3.</math> |
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This equation can also be written as <ref> |
This equation can also be written as <ref>[https://books.google.com/books?id=W9ZuLZWldUoC&pg=PA73 Srivastava and Gope: Strength of Materials, page 73]</ref> |
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:<math>M_A l + 2 M_B (l+l') +M_C l' = \frac{6 a_1 x_1}{l} + \frac{6 a_2 x_2}{l'}</math> |
:<math>M_A l + 2 M_B (l+l') +M_C l' = \frac{6 a_1 x_1}{l} + \frac{6 a_2 x_2}{l'}</math> |
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where ''a''<sub>1</sub> is the area on the [[Shear and moment diagram|bending moment diagram]] due to vertical loads on AB, ''a''<sub>2</sub> is the area due to loads on BC, ''x''<sub>1</sub> is the distance from A to the |
where ''a''<sub>1</sub> is the area on the [[Shear and moment diagram|bending moment diagram]] due to vertical loads on AB, ''a''<sub>2</sub> is the area due to loads on BC, ''x''<sub>1</sub> is the distance from A to the centroid of the bending moment diagram of beam AB, ''x''<sub>2</sub> is the distance from C to the centroid of the area of the bending moment diagram of beam BC. |
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The second equation is more general as it does not require that the weight of each segment be distributed uniformly. |
The second equation is more general as it does not require that the weight of each segment be distributed uniformly. |
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[[File:Figure 01 - Sample continuous beam section.png|thumb|Figure 01-Sample continuous beam section]] |
[[File:Figure 01 - Sample continuous beam section.png|thumb|Figure 01-Sample continuous beam section]] |
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==Derivation of |
==Derivation of three moments equations == |
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[ |
[[Christian Otto Mohr|Christian Otto Mohr's]] theorem<ref>{{cite web|title=Mohr's Theorem|url=http://www.colincaprani.com/files/notes/SAIII/Mohrs%20Theorems.pdf}}</ref> can be used to derive the three moment theorem<ref>{{cite web|title=Three Moment Theorem|url=http://www.duke.edu/~hpgavin/cee201/three-moment.pdf}}</ref> (TMT). |
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===Mohr's |
===Mohr's first theorem=== |
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The change in [[slope]] of a [[deflection (physics)|deflection]] curve between two points of a beam is equal to the area of the |
The change in [[slope]] of a [[deflection (physics)|deflection]] curve between two points of a beam is equal to the area of the M/EI diagram between those two points.(Figure 02) |
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[[File:Mohr's First Theorem.png|thumb|Figure 02-Mohr's First Theorem]] |
[[File:Mohr's First Theorem.png|thumb|Figure 02-Mohr's First Theorem]] |
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===Mohr's |
===Mohr's second theorem=== |
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Consider two points k1 and k2 on a [[beam (structure)|beam]]. The [[deflection (physics)|deflection]] of k1 and k2 relative to the point of intersection between tangent at k1 and k2 and vertical through k1 is equal to the M/EI diagram between k1 and k2 about k1.(Figure 03) |
Consider two points k1 and k2 on a [[beam (structure)|beam]]. The [[deflection (physics)|deflection]] of k1 and k2 relative to the point of intersection between tangent at k1 and k2 and vertical through k1 is equal to the moment of M/EI diagram between k1 and k2 about k1.(Figure 03) |
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[[File:Mohr's Second Theorem.png|thumb|Figure03-Mohr's Second Theorem]] |
[[File:Mohr's Second Theorem.png|thumb|Figure03-Mohr's Second Theorem]] |
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The three moment equation expresses the relation between [[bending moment]]s at three successive supports of a continuous beam, subject to a loading on a two adjacent span with or without [[settlement (structural)|settlement]] of the supports. |
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===The |
===The sign convention=== |
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According to the Figure 04, |
According to the Figure 04, |
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# The moment M1, M2, and M3 be positive if they cause [[Compression (physical)|compression]] in the upper part of the beam. ( |
# The moment M1, M2, and M3 be positive if they cause [[Compression (physical)|compression]] in the upper part of the beam. ([[:wikt:sagging|sagging]] positive) |
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# The [[deflection (physics)|deflection]] downward positive. (Downward settlement positive) |
# The [[deflection (physics)|deflection]] downward positive. (Downward settlement positive) |
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# Let ABC is a [[:wikt:continuous|continuous]] beam with support at A,B, and C. Then moment at A,B, and C are M1, M2, and M3, respectively. |
# Let ABC is a [[:wikt:continuous|continuous]] beam with support at A,B, and C. Then moment at A,B, and C are M1, M2, and M3, respectively. |
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# Let A' B' and C' be the final positions of the beam ABC due to support [[settlement (structural)|settlements]]. |
# Let A' B' and C' be the final positions of the beam ABC due to support [[settlement (structural)|settlements]]. |
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[[File:Deflection Curve of a Continuous Beam.png|thumb|Figure 04-Deflection Curve of a Continuous Beam Under Settlement |
[[File:Deflection Curve of a Continuous Beam.png|thumb|Figure 04-Deflection Curve of a Continuous Beam Under Settlement]] |
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===Derivation of |
===Derivation of three moment theorem=== |
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PB'Q is a tangent drawn at B' for final [[Elasticity (physics)|Elastic]] Curve A'B'C' of the [[beam (structure)|beam]] ABC. RB'S is a horizontal line drawn through B'. |
PB'Q is a tangent drawn at B' for final [[Elasticity (physics)|Elastic]] Curve A'B'C' of the [[beam (structure)|beam]] ABC. RB'S is a horizontal line drawn through B'. |
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Consider, Triangles RB'P and QB'S. |
Consider, Triangles RB'P and QB'S. |
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{{NumBlk|:|<math>\dfrac{PR}{L1} = \dfrac{SQ}{L2}</math>|{{EquationRef|1}}}} |
{{NumBlk|:|<math>\dfrac{PR}{L1} = \dfrac{SQ}{L2}</math>|{{EquationRef|1}}}} |
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{{NumBlk|:|<math>PR = \Delta B - \Delta A + PA'</math>|{{EquationRef|2}}}} |
{{NumBlk|:|<math>PR = \Delta B - \Delta A + PA'</math>|{{EquationRef|2}}}} |
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{{NumBlk|:|<math>SQ = \Delta C - \Delta B |
{{NumBlk|:|<math>SQ = \Delta C - \Delta B - QC'</math>|{{EquationRef|3}}}} |
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From (1), (2), and (3), |
From (1), (2), and (3), |
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:<math>\dfrac{\Delta B - \Delta A + PA'}{L1} = \dfrac{\Delta C - \Delta B |
:<math>\dfrac{\Delta B - \Delta A + PA'}{L1} = \dfrac{\Delta C - \Delta B - QC'}{L2}</math> |
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{{NumBlk|:|<math>\dfrac{PA'}{L1} + \dfrac{QC'}{L2} = \dfrac{\Delta A -\Delta B}{L1} + \dfrac{\Delta C -\Delta B}{L2}</math>|{{EquationRef|a}}}} |
{{NumBlk|:|<math>\dfrac{PA'}{L1} + \dfrac{QC'}{L2} = \dfrac{\Delta A -\Delta B}{L1} + \dfrac{\Delta C -\Delta B}{L2}</math>|{{EquationRef|a}}}} |
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Draw |
Draw the M/EI diagram to find the PA' and QC'. |
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[[File:Moment Diagram.png|thumb|Figure 05 - M / EI Diagram]] |
[[File:Moment Diagram.png|thumb|Figure 05 - M / EI Diagram]] |
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:<math>QC' = \left(\frac{1}{2} \times \frac{M_3}{E_2 I_2} \times L_2\right)\times L_2\times\frac{1}{3} + \left(\frac{1}{2} \times \frac{M_2}{E_2 I_2} \times L_2\right)\times L_2\times\frac{2}{3}+ \frac{A_2 X_2}{E_2 I_2}</math> |
:<math>QC' = \left(\frac{1}{2} \times \frac{M_3}{E_2 I_2} \times L_2\right)\times L_2\times\frac{1}{3} + \left(\frac{1}{2} \times \frac{M_2}{E_2 I_2} \times L_2\right)\times L_2\times\frac{2}{3}+ \frac{A_2 X_2}{E_2 I_2}</math> |
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Substitute in PA' and QC' on equation (a), |
Substitute in PA' and QC' on equation (a), the Three Moment Theorem (TMT) can be obtained. |
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==Three |
==Three moment equation== |
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<br /> |
<br /> |
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:<math>\frac{M_1 L_1}{E_1 I_1}+ 2M_2\left(\frac{L_1}{E_1 I_1} + \frac{L_2}{E_2 I_2}\right)+\frac{M_3 L_2}{E_2 I_2} = 6 \frac{\Delta A - \Delta B}{L_1} + \frac{\Delta C - \Delta B}{L_2} - 6 \frac{A_1 X_1}{E_1 I_1 L_1} + \frac{A_2 X_2}{E_2 I_2 L_2}</math> |
:<math>\frac{M_1 L_1}{E_1 I_1}+ 2M_2\left(\frac{L_1}{E_1 I_1} + \frac{L_2}{E_2 I_2}\right)+\frac{M_3 L_2}{E_2 I_2} = 6 [\frac{\Delta A - \Delta B}{L_1} + \frac{\Delta C - \Delta B}{L_2}] - 6 [\frac{A_1 X_1}{E_1 I_1 L_1} + \frac{A_2 X_2}{E_2 I_2 L_2}]</math> |
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==Notes== |
==Notes== |
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==External links== |
==External links== |
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*[http://www.codecogs.com/ |
*[http://www.codecogs.com/library/engineering/materials/beams/multiple-continuous-beams.php CodeCogs: Continuous beams with more than one span] |
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{{DEFAULTSORT:Theorem Of Three Moments}} |
{{DEFAULTSORT:Theorem Of Three Moments}} |
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[[Category:Continuum mechanics]] |
[[Category:Continuum mechanics]] |
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[[Category:Physics theorems]] |
[[Category:Physics theorems]] |
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⚫ | |||
[[es:Teorema de los tres momentos]] |
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[[pt:Teorema dos três momentos]] |
Latest revision as of 11:49, 12 September 2024
In civil engineering and structural analysis Clapeyron's theorem of three moments (by Émile Clapeyron) is a relationship among the bending moments at three consecutive supports of a horizontal beam.
Let A,B,C-D be the three consecutive points of support, and denote by- l the length of AB and the length of BC, by w and the weight per unit of length in these segments. Then[1] the bending moments at the three points are related by:
This equation can also be written as [2]
where a1 is the area on the bending moment diagram due to vertical loads on AB, a2 is the area due to loads on BC, x1 is the distance from A to the centroid of the bending moment diagram of beam AB, x2 is the distance from C to the centroid of the area of the bending moment diagram of beam BC.
The second equation is more general as it does not require that the weight of each segment be distributed uniformly.
Derivation of three moments equations
[edit]Christian Otto Mohr's theorem[3] can be used to derive the three moment theorem[4] (TMT).
Mohr's first theorem
[edit]The change in slope of a deflection curve between two points of a beam is equal to the area of the M/EI diagram between those two points.(Figure 02)
Mohr's second theorem
[edit]Consider two points k1 and k2 on a beam. The deflection of k1 and k2 relative to the point of intersection between tangent at k1 and k2 and vertical through k1 is equal to the moment of M/EI diagram between k1 and k2 about k1.(Figure 03)
The three moment equation expresses the relation between bending moments at three successive supports of a continuous beam, subject to a loading on a two adjacent span with or without settlement of the supports.
The sign convention
[edit]According to the Figure 04,
- The moment M1, M2, and M3 be positive if they cause compression in the upper part of the beam. (sagging positive)
- The deflection downward positive. (Downward settlement positive)
- Let ABC is a continuous beam with support at A,B, and C. Then moment at A,B, and C are M1, M2, and M3, respectively.
- Let A' B' and C' be the final positions of the beam ABC due to support settlements.
Derivation of three moment theorem
[edit]PB'Q is a tangent drawn at B' for final Elastic Curve A'B'C' of the beam ABC. RB'S is a horizontal line drawn through B'. Consider, Triangles RB'P and QB'S.
(1) |
(2) |
(3) |
From (1), (2), and (3),
(a) |
Draw the M/EI diagram to find the PA' and QC'.
From Mohr's Second Theorem
PA' = First moment of area of M/EI diagram between A and B about A.
QC' = First moment of area of M/EI diagram between B and C about C.
Substitute in PA' and QC' on equation (a), the Three Moment Theorem (TMT) can be obtained.
Three moment equation
[edit]
Notes
[edit]- ^ J. B. Wheeler: An Elementary Course of Civil Engineering, 1876, Page 118 [1]
- ^ Srivastava and Gope: Strength of Materials, page 73
- ^ "Mohr's Theorem" (PDF).
- ^ "Three Moment Theorem" (PDF).