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Instructional Objectives 
After reading this chapter the student will be able to 
1. Solve continuous beam with support settlements by the moment-
distribution method. 
2. Compute reactions at the supports. 
3. Draw bending moment and shear force diagrams. 
4. Draw the deflected shape of the continuous beam. 
 
19.1 Introduction 
 
In the previous lesson, moment-distribution method was discussed in the context 
of statically indeterminate beams with unyielding supports. It is very well known 
that support may settle by unequal amount during the lifetime of the structure. 
Such support settlements induce fixed end moments in the beams so as to hold 
the end slopes of the members as zero (see Fig. 19.1). 
 
 
In lesson 15, an expression (equation 15.5) for beam end moments were derived 
by superposing the end moments developed due to 
 
1. Externally applied loads on beams 
2. Due to displacements 
B A
? ? , and ? (settlements). 
 
The required equations are, 
 
?
?
?
?
?
? ?
- + + =
AB
B A
AB
AB F
AB AB
L L
EI
M M
3
2
2
? ?      (19.1a) 
 
 
Page 2


Instructional Objectives 
After reading this chapter the student will be able to 
1. Solve continuous beam with support settlements by the moment-
distribution method. 
2. Compute reactions at the supports. 
3. Draw bending moment and shear force diagrams. 
4. Draw the deflected shape of the continuous beam. 
 
19.1 Introduction 
 
In the previous lesson, moment-distribution method was discussed in the context 
of statically indeterminate beams with unyielding supports. It is very well known 
that support may settle by unequal amount during the lifetime of the structure. 
Such support settlements induce fixed end moments in the beams so as to hold 
the end slopes of the members as zero (see Fig. 19.1). 
 
 
In lesson 15, an expression (equation 15.5) for beam end moments were derived 
by superposing the end moments developed due to 
 
1. Externally applied loads on beams 
2. Due to displacements 
B A
? ? , and ? (settlements). 
 
The required equations are, 
 
?
?
?
?
?
? ?
- + + =
AB
B A
AB
AB F
AB AB
L L
EI
M M
3
2
2
? ?      (19.1a) 
 
 
?
?
?
?
?
? ?
- + + =
AB
A B
AB
AB F
BA BA
L L
EI
M M
3
2
2
? ?     (19.1b) 
 
 
This may be written as, 
 
       (19.2a) []
S
AB B A AB
F
AB AB
M K M M + + + = ? ? 2 2
 
[ ] 22
F
BA BA AB B A BA
S
M MK M ?? =+ + +       (19.2b) 
 
where 
AB
AB
AB
L
EI
K =  is the stiffness factor for the beam AB. The coefficient 4 has 
been dropped since only relative values are required in calculating distribution 
factors. 
 
Note that 
2
6
AB
AB S
BA
S
AB
L
EI
M M
?
- = =       (19.3)  
 
S
AB
M is the beam end moments due to support settlement and is negative 
(clockwise) for positive support settlements (upwards). In the moment-distribution 
method, the support moments  and  due to uneven support settlements 
are distributed in a similar manner as the fixed end moments, which were 
described in details in lesson 18. 
S
AB
M
S
BA
M
 
It is important to follow consistent sign convention. Here counterclockwise beam 
end moments are taken as positive and counterclockwise chord rotation 
?
?
?
?
?
? ?
L
 is 
taken as positive. The moment-distribution method as applied to statically 
indeterminate beams undergoing uneven support settlements is illustrated with a  
few examples. 
 
 
 
 
 
 
 
Page 3


Instructional Objectives 
After reading this chapter the student will be able to 
1. Solve continuous beam with support settlements by the moment-
distribution method. 
2. Compute reactions at the supports. 
3. Draw bending moment and shear force diagrams. 
4. Draw the deflected shape of the continuous beam. 
 
19.1 Introduction 
 
In the previous lesson, moment-distribution method was discussed in the context 
of statically indeterminate beams with unyielding supports. It is very well known 
that support may settle by unequal amount during the lifetime of the structure. 
Such support settlements induce fixed end moments in the beams so as to hold 
the end slopes of the members as zero (see Fig. 19.1). 
 
 
In lesson 15, an expression (equation 15.5) for beam end moments were derived 
by superposing the end moments developed due to 
 
1. Externally applied loads on beams 
2. Due to displacements 
B A
? ? , and ? (settlements). 
 
The required equations are, 
 
?
?
?
?
?
? ?
- + + =
AB
B A
AB
AB F
AB AB
L L
EI
M M
3
2
2
? ?      (19.1a) 
 
 
?
?
?
?
?
? ?
- + + =
AB
A B
AB
AB F
BA BA
L L
EI
M M
3
2
2
? ?     (19.1b) 
 
 
This may be written as, 
 
       (19.2a) []
S
AB B A AB
F
AB AB
M K M M + + + = ? ? 2 2
 
[ ] 22
F
BA BA AB B A BA
S
M MK M ?? =+ + +       (19.2b) 
 
where 
AB
AB
AB
L
EI
K =  is the stiffness factor for the beam AB. The coefficient 4 has 
been dropped since only relative values are required in calculating distribution 
factors. 
 
Note that 
2
6
AB
AB S
BA
S
AB
L
EI
M M
?
- = =       (19.3)  
 
S
AB
M is the beam end moments due to support settlement and is negative 
(clockwise) for positive support settlements (upwards). In the moment-distribution 
method, the support moments  and  due to uneven support settlements 
are distributed in a similar manner as the fixed end moments, which were 
described in details in lesson 18. 
S
AB
M
S
BA
M
 
It is important to follow consistent sign convention. Here counterclockwise beam 
end moments are taken as positive and counterclockwise chord rotation 
?
?
?
?
?
? ?
L
 is 
taken as positive. The moment-distribution method as applied to statically 
indeterminate beams undergoing uneven support settlements is illustrated with a  
few examples. 
 
 
 
 
 
 
 
Example 19.1 
 
Calculate the support moments of the continuous beam  (Fig. 19.2a) having 
constant flexural rigidity 
ABC
EI throughout, due to vertical settlement of support B 
by 5mm. Assume ; and . 200 GPa E =
44
410 m I
-
=×
 
 
Solution 
 
There is no load on the beam and hence fixed end moments are zero. However, 
fixed end moments are developed due to support settlement of B by 5mm. In the 
spanAB , the chord rotates by 
AB
? in clockwise direction. Thus,  
5
10 5
3 -
×
- =
AB
? 
?
?
?
?
?
?
?
? ×
-
× × × ×
- = - = =
- -
5
10 5
5
10 4 10 200 6 6
3 4 9
AB
AB
AB S
BA
S
AB
L
EI
M M ? 
 
 
96000 Nm 96 kNm. ==                 (1)  
 
In the span , the chord rotates by BC
BC
? in the counterclockwise direction and 
hence taken as positive. 
5
10 5
3 -
×
=
BC
? 
 
 
Page 4


Instructional Objectives 
After reading this chapter the student will be able to 
1. Solve continuous beam with support settlements by the moment-
distribution method. 
2. Compute reactions at the supports. 
3. Draw bending moment and shear force diagrams. 
4. Draw the deflected shape of the continuous beam. 
 
19.1 Introduction 
 
In the previous lesson, moment-distribution method was discussed in the context 
of statically indeterminate beams with unyielding supports. It is very well known 
that support may settle by unequal amount during the lifetime of the structure. 
Such support settlements induce fixed end moments in the beams so as to hold 
the end slopes of the members as zero (see Fig. 19.1). 
 
 
In lesson 15, an expression (equation 15.5) for beam end moments were derived 
by superposing the end moments developed due to 
 
1. Externally applied loads on beams 
2. Due to displacements 
B A
? ? , and ? (settlements). 
 
The required equations are, 
 
?
?
?
?
?
? ?
- + + =
AB
B A
AB
AB F
AB AB
L L
EI
M M
3
2
2
? ?      (19.1a) 
 
 
?
?
?
?
?
? ?
- + + =
AB
A B
AB
AB F
BA BA
L L
EI
M M
3
2
2
? ?     (19.1b) 
 
 
This may be written as, 
 
       (19.2a) []
S
AB B A AB
F
AB AB
M K M M + + + = ? ? 2 2
 
[ ] 22
F
BA BA AB B A BA
S
M MK M ?? =+ + +       (19.2b) 
 
where 
AB
AB
AB
L
EI
K =  is the stiffness factor for the beam AB. The coefficient 4 has 
been dropped since only relative values are required in calculating distribution 
factors. 
 
Note that 
2
6
AB
AB S
BA
S
AB
L
EI
M M
?
- = =       (19.3)  
 
S
AB
M is the beam end moments due to support settlement and is negative 
(clockwise) for positive support settlements (upwards). In the moment-distribution 
method, the support moments  and  due to uneven support settlements 
are distributed in a similar manner as the fixed end moments, which were 
described in details in lesson 18. 
S
AB
M
S
BA
M
 
It is important to follow consistent sign convention. Here counterclockwise beam 
end moments are taken as positive and counterclockwise chord rotation 
?
?
?
?
?
? ?
L
 is 
taken as positive. The moment-distribution method as applied to statically 
indeterminate beams undergoing uneven support settlements is illustrated with a  
few examples. 
 
 
 
 
 
 
 
Example 19.1 
 
Calculate the support moments of the continuous beam  (Fig. 19.2a) having 
constant flexural rigidity 
ABC
EI throughout, due to vertical settlement of support B 
by 5mm. Assume ; and . 200 GPa E =
44
410 m I
-
=×
 
 
Solution 
 
There is no load on the beam and hence fixed end moments are zero. However, 
fixed end moments are developed due to support settlement of B by 5mm. In the 
spanAB , the chord rotates by 
AB
? in clockwise direction. Thus,  
5
10 5
3 -
×
- =
AB
? 
?
?
?
?
?
?
?
? ×
-
× × × ×
- = - = =
- -
5
10 5
5
10 4 10 200 6 6
3 4 9
AB
AB
AB S
BA
S
AB
L
EI
M M ? 
 
 
96000 Nm 96 kNm. ==                 (1)  
 
In the span , the chord rotates by BC
BC
? in the counterclockwise direction and 
hence taken as positive. 
5
10 5
3 -
×
=
BC
? 
 
 
?
?
?
?
?
?
?
? × × × × ×
- = - = =
- -
5
10 5
5
10 4 10 200 6 6
3 4 9
BC
BC
BC S
CB
S
BC
L
EI
M M ? 
 
 
. 96 96000 kNm Nm - = - =      (2)  
 
Now calculate stiffness and distribution factors. 
 
EI
L
EI
K
AB
AB
BA
2 . 0 = =   and  EI
L
EI
K
BC
BC
BC
15 . 0
4
3
= =    (3) 
 
  
 Note that, while calculating stiffness factor, the coefficient 4 has been dropped 
since only relative values are required in calculating the distribution factors. For 
span , reduced stiffness factor has been taken as support C is hinged.  BC
AtB : 
 
EI K 35 . 0 =
?
 
 
571 . 0
35 . 0
2 . 0
= =
EI
EI
DF
BA
 
429 . 0
35 . 0
15 . 0
= =
EI
EI
DF
BC
        (4) 
 
 
At support C : 
 
EI K 15 . 0 =
?
; . 0 . 1 =
CB
DF
 
Now joint moments are balanced as discussed previously by unlocking and 
locking each joint in succession and distributing the unbalanced moments till the 
joints have rotated to their final positions. The complete procedure is shown in 
Fig. 19.2b   and also in Table 19.1. 
 
Page 5


Instructional Objectives 
After reading this chapter the student will be able to 
1. Solve continuous beam with support settlements by the moment-
distribution method. 
2. Compute reactions at the supports. 
3. Draw bending moment and shear force diagrams. 
4. Draw the deflected shape of the continuous beam. 
 
19.1 Introduction 
 
In the previous lesson, moment-distribution method was discussed in the context 
of statically indeterminate beams with unyielding supports. It is very well known 
that support may settle by unequal amount during the lifetime of the structure. 
Such support settlements induce fixed end moments in the beams so as to hold 
the end slopes of the members as zero (see Fig. 19.1). 
 
 
In lesson 15, an expression (equation 15.5) for beam end moments were derived 
by superposing the end moments developed due to 
 
1. Externally applied loads on beams 
2. Due to displacements 
B A
? ? , and ? (settlements). 
 
The required equations are, 
 
?
?
?
?
?
? ?
- + + =
AB
B A
AB
AB F
AB AB
L L
EI
M M
3
2
2
? ?      (19.1a) 
 
 
?
?
?
?
?
? ?
- + + =
AB
A B
AB
AB F
BA BA
L L
EI
M M
3
2
2
? ?     (19.1b) 
 
 
This may be written as, 
 
       (19.2a) []
S
AB B A AB
F
AB AB
M K M M + + + = ? ? 2 2
 
[ ] 22
F
BA BA AB B A BA
S
M MK M ?? =+ + +       (19.2b) 
 
where 
AB
AB
AB
L
EI
K =  is the stiffness factor for the beam AB. The coefficient 4 has 
been dropped since only relative values are required in calculating distribution 
factors. 
 
Note that 
2
6
AB
AB S
BA
S
AB
L
EI
M M
?
- = =       (19.3)  
 
S
AB
M is the beam end moments due to support settlement and is negative 
(clockwise) for positive support settlements (upwards). In the moment-distribution 
method, the support moments  and  due to uneven support settlements 
are distributed in a similar manner as the fixed end moments, which were 
described in details in lesson 18. 
S
AB
M
S
BA
M
 
It is important to follow consistent sign convention. Here counterclockwise beam 
end moments are taken as positive and counterclockwise chord rotation 
?
?
?
?
?
? ?
L
 is 
taken as positive. The moment-distribution method as applied to statically 
indeterminate beams undergoing uneven support settlements is illustrated with a  
few examples. 
 
 
 
 
 
 
 
Example 19.1 
 
Calculate the support moments of the continuous beam  (Fig. 19.2a) having 
constant flexural rigidity 
ABC
EI throughout, due to vertical settlement of support B 
by 5mm. Assume ; and . 200 GPa E =
44
410 m I
-
=×
 
 
Solution 
 
There is no load on the beam and hence fixed end moments are zero. However, 
fixed end moments are developed due to support settlement of B by 5mm. In the 
spanAB , the chord rotates by 
AB
? in clockwise direction. Thus,  
5
10 5
3 -
×
- =
AB
? 
?
?
?
?
?
?
?
? ×
-
× × × ×
- = - = =
- -
5
10 5
5
10 4 10 200 6 6
3 4 9
AB
AB
AB S
BA
S
AB
L
EI
M M ? 
 
 
96000 Nm 96 kNm. ==                 (1)  
 
In the span , the chord rotates by BC
BC
? in the counterclockwise direction and 
hence taken as positive. 
5
10 5
3 -
×
=
BC
? 
 
 
?
?
?
?
?
?
?
? × × × × ×
- = - = =
- -
5
10 5
5
10 4 10 200 6 6
3 4 9
BC
BC
BC S
CB
S
BC
L
EI
M M ? 
 
 
. 96 96000 kNm Nm - = - =      (2)  
 
Now calculate stiffness and distribution factors. 
 
EI
L
EI
K
AB
AB
BA
2 . 0 = =   and  EI
L
EI
K
BC
BC
BC
15 . 0
4
3
= =    (3) 
 
  
 Note that, while calculating stiffness factor, the coefficient 4 has been dropped 
since only relative values are required in calculating the distribution factors. For 
span , reduced stiffness factor has been taken as support C is hinged.  BC
AtB : 
 
EI K 35 . 0 =
?
 
 
571 . 0
35 . 0
2 . 0
= =
EI
EI
DF
BA
 
429 . 0
35 . 0
15 . 0
= =
EI
EI
DF
BC
        (4) 
 
 
At support C : 
 
EI K 15 . 0 =
?
; . 0 . 1 =
CB
DF
 
Now joint moments are balanced as discussed previously by unlocking and 
locking each joint in succession and distributing the unbalanced moments till the 
joints have rotated to their final positions. The complete procedure is shown in 
Fig. 19.2b   and also in Table 19.1. 
 
 
 
Table 19.1 Moment-distribution for continuous beam ABC 
 
Joint A B C 
Member  BA BC CB 
Stiffness factor  0.2EI 0.15EI 0.15EI 
Distribution Factor  0.571 0.429 1.000 
Fixd End Moments 
(kN.m) 96.000 96.000 -96.000 -96.000 
 Balance joint C and 
C.O. to B   48.00 96.000 
Balance joint B and 
C.O. to A  -13,704 -27.408 -20.592  
      
Final Moments 
(kN.m) 82.296 68.592 -68.592 0.000 
 
  
Note that there is no carry over to joint as it was left unlocked. C
 
 
Example 19.2 
 
A continuous beam  is carrying uniformly distributed load  as 
shown in Fig. 19.3a. Compute reactions and draw shear force and bending 
moment diagram due to following support settlements. 
ABCD m kN / 5
 
,    0.005m vertically downwards. Support B
 
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FAQs on The Moment Distribution Method: Statically Indeterminate Beams With Support Settlements - 1 - Structural Analysis - Civil Engineering (CE)

1. What is the Moment Distribution Method?
Ans. The Moment Distribution Method is a structural analysis technique used to analyze statically indeterminate beams with support settlements. It allows engineers to determine the distribution of moments and shears along the length of the beam, taking into account the effects of settlement at the supports.
2. How does the Moment Distribution Method handle support settlements?
Ans. The Moment Distribution Method considers support settlements by adjusting the stiffness of the supports. The settlements are incorporated into the analysis by modifying the stiffness coefficients used in the moment distribution calculations. This ensures that the effects of settlement on the beam's behavior are accurately accounted for in the analysis.
3. Why is the Moment Distribution Method useful for analyzing statically indeterminate beams with support settlements?
Ans. The Moment Distribution Method is particularly useful for analyzing statically indeterminate beams with support settlements because it provides a simplified and efficient approach to determine the distribution of moments and shears. It allows engineers to quickly and accurately determine the internal forces and deformations in the beam, taking into account the effects of both the support settlements and the beam's structural indeterminacy.
4. What are the limitations of the Moment Distribution Method when analyzing beams with support settlements?
Ans. While the Moment Distribution Method is a powerful tool for analyzing statically indeterminate beams with support settlements, it does have some limitations. One limitation is that it assumes linear-elastic behavior of the materials and neglects any nonlinear effects that may occur due to large displacements or material nonlinearity. Additionally, the method may become less accurate for beams with highly non-uniform stiffness distributions or complex support settlement patterns.
5. Are there alternative methods to analyze statically indeterminate beams with support settlements?
Ans. Yes, there are alternative methods to analyze statically indeterminate beams with support settlements. Some common alternatives include the flexibility matrix method, slope-deflection method, and the direct stiffness method. These methods may provide more accurate results in certain cases or may be preferred for their ease of implementation. However, the Moment Distribution Method remains a popular choice due to its simplicity and efficiency.
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