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REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
UNIT 4
DESIGN OF RECTANGULAR BEAM SECTIONS
GENERAL OBJECTIVE
To be able to provide steel reinforcement required in reinforced concrete beams.
At the end of this unit, you should be able to: -
1. calculate the area and total number of reinforcement required in given
beam sections with known bending moments.
2. calculate the bending moment that can be carried by the beam section
when the grade of steel is already provided.
1
OBJECTIVES
SPECIFIC OBJECTIVES
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
4.1 Simply Reinforced Rectangular Section
What does it mean?
Simply reinforced section is the steel reinforcement that is provided only at the
tension zone. The form of section, stress distribution and forces on a section are as
shown in Figure 4.1:
2
Z=d-0.45x
Fcc=0.405fcubx
INPUT 1
As
Section
0.87 fy
Stress
Fst=0.87fyAs
Forces
0.45x
0.9x
0.45fcu
x
b
d
Figure 4.1: The form of section, stress distribution and forces on a section
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
The meaning of symbols used are given in clause 3.4.4.3
For the section to be in balance, the sum of the forces must be equal to zero, i.e.
Fst = Fcc
0.87fyAs = 0.405fcubx
x =
Taking moments about Fcc or Fst, the moment of resistance of the section can be
calculated as follows,
M = Fst. Z
= (0.87fyAs) (d - 0.45x)
or,
M = Fcc. Z
= (0.405fcubx) (d – 0.45 x)
= (0.405 ) ( ) (fcubd2)
= K. fcu bd2
A section whereby the reinforcement is already known, the above equation can be
used to calculate the moment of resistance or the bending moment. Equation 4.1
shows that, x will increase if the area of reinforcement, As increases. The moment
of resistance of the section will also increase. It is clear that a section provided
with more reinforcement will be able to with stand reinforcement load i.e. greater
bending moment.
3
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
In order to make sure that concrete will not crush or fail when in compression or
when yielding of the steel occurs, BS 8110 limits the value of x to be not greater
than 0.5d.
Therefore, the maximum resistance moment of resistance of the section can be
obtained by equating x = 0.5d. This is shown as follows: -
M = Mu = ) (1- ) (fcubd2)
= 0.156fcubd2
= K’fcubd2
Where Mu is known as the ultimate moment of resistance for singly
reinforced section.
The equation above may be used to calculate the area of reinforcement
required if the bending moment is known.
One important conclusion is that if the bending moment, M applied is less
than Mu, the section requires tension reinforcement in the tension zone.
This is called singly reinforced section.
4.2 Example Simply Reinforced Rectangular Section
A rectangular beam section is required to carry a design moment of 300kNm. The
dimension of the area, b = 250 mm and d = 700 mm. Determine the area and total
number of reinforcement needed if the characteristic strength of reinforcement
used, fy=460N/mm2 and that of concrete, fcu = 40 N/mm2.
4
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Solution:
Calculate the ultimate moment of resistance for singly reinforced section as
follows: -
Mu = 0.156fcubd2
= 0.156 (40) (250) (700)2
= 764.4kNm
This shows that Mu > M (=300kNm). Therefore this is a singly reinforced section
Calculate the depth to neutral axis as follows: -
M = 0.405fcubx (d - 0.45x)
300 x 106 = 0.405 (4) (250) (x) (700 - 0.45x)
x2 – 1560x + 16500 = 0
x = 114 mm @ 1441 mm
x is taken as 114mm (the reasonable value).
Calculate Lever arm, Z = d – 0.45x
= 700 – 0.45(114)
= 649 mm
Calculate the area of reinforcement required as follows: -
As =
=
= 1155mm 2
Use 4T20 (As = 1260mm2)
5
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
4.2.1Example
Calculate the moment of resistance for a beam section shown in Figure 4.1 below:
-
The section is already provided with 4T20 reinforcement whereby fcu and fy are
given as 40N/mm2 and 460 N/mm2 respectively.
Solution:
6
xd = 700Fcc = 0.405fcubx
Z = d – 0.45x
Fst = 0.87fyAs
Figure 4.2: Simply Reinforced Rectangular Section
b=250mm
d= 700 mm
250 mm
4T20
Figure 4.1: Beam Section
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Calculate the depth to neutral axis as follows: -
Fcc = Fst
0.405fcubx = 0.87fyAs
x =
=
= 124 mm
Check,
Therefore concrete will not be crushed during compression.
Calculate the moment of resistance as shown below: -
M = Fst. Z
= 0.87 fy As (d - 0.45x)
= 0.87 (460) (1260) (700 – 0.45 (124))
= 325 kNm
Therefore, the moment of resistance of the beam section, provided with 4T20, is
325 kNm.
7
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
4.3 Doubly Reinforced Rectangular Section
For singly reinforced section, steel reinforcement is only used for resisting tensile
force. Compressive force is taken by concrete in the compressive zone. BS 8110
allows the maximum value of x to be not greater than 0.5d for the concrete stress
block taking the compressive force.
Based on this maximum limit x = 0.5d, the maximum moment that can be carried
by concrete is given by,
Mu = 0.156fcubd2
If the bending moment, M to be carried by the section is greater than Mu, steel
reinforcement is to be provided in the compression zone to resist the resultant
moment. The stress-strain distribution and the forces acting in a doubly reinforced
rectangular section is shown in Figure 4.3 below: -
8
INPUT 2
As
Fst
Fsc
Fcc
Z Z1
As’
x
d’
Section Strain Stress & Forces
Figure 4.3: The stress-strain distribution and the forces acting in a doubly reinforced rectangular section
d
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
The condition for equilibrium which must be obtained at any point in the section
is that horizontal forces must equate to zero; i.e.:
Fst = Fcc + Fsc
0.87fyAs = 0.405fcubx + 0.87fyAs’
x = ……..(4.2)
Taking moment (moment of resistance) about the tension steel, we have;
M = Fcc . Z + Fsc . Z1
= (0.405fcubx) (d - 0.45x) + (0.87 fyAs’). (d - d’)
= 0.156fcubd2 + 0.87fyAs’ (d - d’)
= Mu + 0.87fyAs’ (d - d’)
Therefore, area of compression reinforcement is:
As’ =
=
From equation 4.2, it can be shown that:
0.87fyAs = 0.405fcubx + 0.87fyAs’
0.87fyAs.Z = 0.405fcubx. Z + 0.87fyAs’ Z
When x = 0.5d, therefore z = 0.775d
Then,
0.87fyAs. Z = 0.405fcub (0.5d - 0.775d) + 0.87fyAs’. Z
0.87fyAs.Z = 0.156 fcubd2 + 0.87fyAs’. Z
9
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Therefore the area of tension reinforcement is given by,
As =
Or As =
4.4 Stress in the compression reinforcement.
In deriving equation 4.3 above, it is assumed that the compression reinforcement
has yielded, i.e. it has achieved its design strength of 0.87fy.
From the strain design diagram, it can be shown that:
For the design strength to achieve the value 0.87fy, therefore;
And
For fy = 460 N/mm2,
= 0.43
10
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
This implies that for compression reinforcement to achieve its yield point, the
ratio must not exceed 0.43. If > 0.43, the compressive stress, fsc < 0.87 fy
and the value fsc can be obtained from Figure 2.2 BS 8110.
It can be shown that,
fsc = Es . εsc where εsc =
fsc = 200 x 103 x 0.0035 (
= 700
Now do activity 1
11
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Answer the following questions.
4.1 What is the limit for depth to neutral axis, x as specified by BS 8110?
__________________________________________________________________
4.2 Write down the formula that is used to calculate the maximum moment that
can be carried by concrete.
__________________________________________________________________
__________________________________________________________________
4.3 What should be done if the applied moment is greater than the ultimate
moment, Mu?
__________________________________________________________________
__________________________________________________________________
4.4 Write down the formula that is used to calculate the area of compression
reinforcement.
__________________________________________________________________
__________________________________________________________________
12
ACTIVITY 4a
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
4.5 Write down the formula that is used to calculate the area of tension
reinforcement.
__________________________________________________________________
__________________________________________________________________
4.6 Write down the formula used to that is calculate fsc when is greater
than 0.43.
__________________________________________________________________
__________________________________________________________________
13
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Check your answers below: -
4.1 ≠ 0.5d
4.2 Mu = 0.156fcubd2
4.3 Compression reinforcement should be provided.
4.4 As’ = or
As’ =
4.5 As = or As =
4.6 fsc = 700
14
FEEDBACK 4a
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
4.3 Design Example (Rectangular Section )
A rectangular section of reinforced concrete beam is to be designed to carry a
design moment of 880kNm. The width of this beam, b=250 mm and the depth,
d=700 mm. Calculate the area and the total number of bars needed if
fcu=40N/mm2 and fy = 460 N/mm2.
Solution:
Ultimate moment of singly reinforced section,
Mu = 0156fcubd2
= 0.156 x 40 x 250 x (700)2
= 764.4 kNm
Mu < M (= 880kNm). This shows that compression reinforcement is needed and
is calculated as follows: -
As’ =
Assuming that d’ = 60 mm,
As’ =
= 451 mm 2 .
15
INPUT 3
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Now, we have to check the ratio. This is done as follows: -
x = 0.5d
= 0.5 x 700
= 350 mm
=
= 0.17 < 0.43
This shows that the assumed compression steel achieved its design strength
0.87fy.
The area of tension steel is then calculated as shown below: -
As =
=
= 3972 mm 2
16
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Now we have to check from the table below to determine the total number of bars
and then the size.
Provided: 3T16 for compression reinforcement (As’ = 603 mm2)
5T32 for tension reinforcement (As = 4023 mm2)
17
Table 4.1: The Allowable Size and Numbers of Bars
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
4.7 Given the following information, calculate the area of reinforcement required
for a bending moment of 650 kNm
fcu = 30 N/mm2
fy = 460 N/mm2
b = 300 mm
d = 618 mm
d’ = 60 mm.
18
ACTIVITY 4b
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
4.7 Solution: -
Step 1
Mu = 0.156fcubd2
= 0.156 x 30 x 300 x (618)2
= 536.2 kNm < M (= 650 kNm)
Compression reinforcement is required.
Step 2
As’ =
=
=509.6 mm 2
Step 3
Check ratio: -
x = 0.5d = 0.5 (618) = 309 mm
= = 0.19 < 0.43
Compression steel has yielded.
19
FEEDBACK 4b
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Step 4
As =
=
= 2797 mm 2
Step 5
Provide: 5T12 (As’ = 565 mm2) for compression reinforced
9T20 (As = 2828 mm2) for tension reinforced
20
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
4.4 Design example (Determine moment capacity of a section)
Calculate the moment of resistance of a rectangular section beam which has been
provided with 5T32 (tension steel) and 3T16 (compression steel). The
characteristic strengths are and .
The section is as shown in Figure 4.4 below:
21
INPUT 3
700 mm
250 mm
3T16
5T32
Figure 4.4: Rectangular Section Beam
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Solution:
The stress and forces in the stress block is given below: -
Step:
1. For equilibrium of forces;
2. The depth to neutral axis is given by,
= 338.5 mm
3. Check the steel stress.
22
Figure 4.5: The Stress and Forces in the Stress Block
Fsc
Fcc
Fst
Z Z1=d-d’
x d
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
This shows that both the compression and tension steel have yielded at
0.87fy
4. Moment of resistance is calculated as shown below;
= 904 kNm.
Therefore the resistance moment of the section is 904 kNm.
Now, do activity 3
23
ACTIVITY 4c
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
1.8 Determine the moment of resistance for the given section: -
b = 400 mm2
As’ = 800 mm2
d’ = 40 mm
d = 800 mm
As = 5050mm2
fcu = 30N/mm2
fy = 460 N/mm2
24
FEEDBACK 3
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
4.2 Refer to the answer as shown below: -
Step 1: Equilibrium of forces
= 350 mm
Step 2: Check whether the steel has yielded.
Compression and tension steel have yielded.
Step 3: Calculate the moment of resistance.
25
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
= 15.87 + 1092.9 kNm
= 1108.77 kNm
26
SUMMARYSUMMARY
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
To calculate the area of reinforcement of a beam (having a size of b x d), with a
bending moment of M, using concrete strength of fcu and steel strength fy , you
should use the following steps: -
1. Calculate
2. Calculate
3. If K< K’, compression reinforcement is not required.
i) Calculate but z < 0.95d
ii) Calculate As =
4. If K > K’, compression reinforcement is required.
i) Calculate
ii) Calculate
iii) Check ratio.
iv) Calculate
if
27
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
or if
v) Calculate
28
SELF-ASSESSMENT
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Test your understanding by solving the given problem.
1. Calculate the area, size and total number of bars required by the given
section shown in Figure 4.6. The section is to carry a design moment of
90kNm. Use concrete of grade 30 and high yield steel.
2. Calculate the area, size and total number of bars required for the given
section. The bending moment, fcu and fy to be used are the same as in
question 1. Use d’ = 50 mm.
29
200 mm
400 mm
(4 Marks)
350 mm
150 mm(7 Marks)
Figure 4.6: Rectangular Bar
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
3. The figure below shows a rectangular beam section which is to be designed
using concrete of grade 25 and high yield steel reinforcement. Calculate the
moment of resistance of the section.
4. Calculate the moment of resistance of the given section using concrete of
grade 25 and high yield steel reinforcement.
30
600 mm
300 mm
4T25
d=450mm
250mm
2T12
3T20 (4 Marks)
(3 Marks)
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
Check your answers below and then total up your marks. The marks allocated are
shown at every step:
(TOTAL 100 MARKS)
1.
31
FEEDBACK ON SELF-ASSESSMENT
1
1
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
= 0.094 ……………………. 1
Since, K < K’
Therefore compression reinforcement is not required.
= ……………………..
= 380 mm
…………………………..
Use 6T12 (As = 679 mm2)
2.
32
1
1
1
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
= 0.163 ………………………..
K > K’
Compression reinforcement is required.
=272 mm ………………………….
0.95d = 0.95(350)
=332.5 mm
Z < 0.95d
45.0
Zdx
45.0
272350
=173.3 mm
33
1
1
1
1
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
………………………….
……………………………
= 822 mm 2 ………………………………
Use : 2T8 (As’=101 mm2) as compression reinforcement . ………………
8T12 (As=905 mm2) as tension reinforcement ………………..
3. For equilibrium of forces ;
Fcc = Fst
0.405 fcu b x = 0.87 fy As
x =
=
34
1
1
1
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
= 258.8 mm
= 0.43 < 0.5
Moment of resistance,
M = Fst Z
= 0.87 x 460 x 1964 (600 – 0.45 x 258.8)
= 380.06 kNm
4. Fst = Fcc + Fsc
0.87 fy As = 0.405 fcu b x + 0.87 fy As’
x =
=
= 113.4 mm ……………………………
…………………………
35
1
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/
…………...………………
Moment of resistance is,
M =
= {0.87 x 460 x 226 x (450 - 40)} + {0.405 x 25 x 250 x 113.4 x [(450-
(0.45x113.4)]}
151.6 kNm ……………………………….
Total = 18 marks
NOW TOTAL UP YOUR MARKS. FULL MARKS = 18 MARKS
Calculate your score as shown below:
Score = total marks obtained x 100% 18
36
You should score 80% or more to pass this unit.
If you have scored 80% or more, you may
proceed to unit 5.
If you have scored less than 80%, you should
go through unit 4 again until you pass this unit.See you in UNIT 5.
REINFORCED CONCRETE STRUCTURAL DESIGN C4301/UNIT4/37
END OF UNIT 4
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