Reinforced Concrete Design

4

Reinforced Concrete Design

Strength of Rectangular Section in Bending Location of Reinforcement Behavior of Beam under Load Beam Design Requirements Working Stress Design (WSD) Practical Design of RC Beam Asst.Prof.Dr.Mongkol JIRAVACHARADET

SURANAREE UNIVERSITY OF TECHNOLOGY

INSTITUTE OF ENGINEERING SCHOOL OF CIVIL ENGINEERING

Location of Reinforcement Concrete cracks due to tension, and as a result, reinforcement is required where flexure, axial loads, or shrinkage effects cause tensile stresses.

• Simply supported beam

tensile stresses and cracks are developed along bottom of the beam Positive Moment

BMD

longitudinal reinforcement is placed closed to the bottom side of the beam

Location of Reinforcement • Cantilever beam - Top bars - Ties and anchorage to support

Location of Reinforcement • Continuous beam

Location of Reinforcement • Continuous beam with 2 spans

Figure B-13 : Reinforcement Arrangement for Suspended Beams

Figure B-14 : Reinforcement Arrangement for Suspended Cantilever Beams

Behavior of Beam under Load w

L εc

Elastic Bending (Plain Concrete)

εc

εc

Working Stress Condition

f < f c′

f < f r = 2.0 f c′

f < f c′

C

T = As fs εs

Brittle failure mode

εcu= 0.003 C

Crushing

T = As fs

εs 4,000 ksc:

As = 0.0018 4,000 bt fy

b t As

3) Minimum Steel (for beam) As min = 14 / fy

As

To ensure that steel not fail before first crack 4) Concrete Covering stirrup

Durability and Fire protection

> 4/3 max. aggregate size 5) Bar Spacing

WSD of Beam for Moment Assumptions: 1) Section remains plane 2) Stress proportioned to Strain 3) Concrete not take tension 4) No concrete-steel slip Modular ratio (n): Es 2.04 × 106 134 n= = ≈ Ec 15,100 f c′ f c′

Effective Depth (d) : Distance from compression face to centroid of steel d

Cracked transformed section strain condition

εc

compression face kd

force equilibrium f c = Ecε c C N.A.

d

εs b

T = As f s f s = Es ε s

jd

Compression in concrete:

1 C = f c b kd 2

kd

N.A.

T = As f s

Tension in steel:

T = As f s f s = Es ε s

Equilibrium ΣFx= 0 : Compression = Tension

1 f c b kd = As f s 2 Reinforcement ratio: fc 2 ρ = fs k

f c = Ecε c C

ρ = As / bd 1

jd

Strain compatibility: εc

εc kd k = = ε s d − kd 1 − k

kd

f c / Ec k = f s / Es 1 − k

d

fc k n = fs 1 − k

εs Analysis: know ρ find k

Design: know fc , fs find k

1

2

2

2

k = 2n ρ + ( n ρ ) − n ρ 2

k=

n fc 1 = n fc + fs 1 + fs n fc

Allowable Stresses Steel:

Plain concrete:

f c = 0.33 f c′ ≤ 60 kg/cm 2 Reinforced concrete:

f c = 0.375 f c′ ≤ 65 kg/cm 2

SR24: fs = 0.5(2,400)

= 1,200 ksc

SD30: fs = 0.5(3,000)

= 1,500 ksc

SD40, SD50: fs

= 1,700 ksc

Example 3.1: f c′ = 150 ksc , fs = 1,500 ksc n=

134 = 10.94 ⇒ 10 (nearest integer) 150

f c = 0.375(150) = 56 ksc k=

1 = 0.2515 1,500 1+ 9(56)

Resisting Moment Moment arm distance : j d

kd/3

C=

M

1 fc k b d 2

jd T = As fs

kd jd = d − 3 k j = 1− 3

Steel:

M = T × jd = As f s jd

Concrete:

1 M = C × jd = f c k j b d 2 = R b d 2 2 1 R = fc k j 2

Design Step: known M, fc, fs, n 1) Compute parameters

k=

1 1 + fs n fc

j = 1− k / 3

R=

1 fc k j 2

R (kg/cm2)

fc (kg/cm2)

n

45

fs=1,200 (kg/cm2)

fs=1,500 (kg/cm2)

fs=1,700 (kg/cm2)

12

6.260

5.430

4.988

50

12

7.407

6.463

5.955

55

11

8.188

7.147

6.587

60

11

9.386

8.233

7.608

65

10

10.082

8.835

8.161

Design Parameter k and j fc (kg/cm2)

n

fs=1,200 (kg/cm2)

fs=1,500 (kg/cm2)

fs=1,700 (kg/cm2)

k

j

k

j

k

j

45

12

0.310

0.897

0.265

0.912

0.241

0.920

50

12

0.333

0.889

0.286

0.905

0.261

0.913

55

11

0.335

0.888

0.287

0.904

0.262

0.913

60

11

0.355

0.882

0.306

0.898

0.280

0.907

65

10

0.351

0.883

0.302

0.899

0.277

0.908

1) For greater fs , k becomes smaller → smaller compression area 2) j ≈ 0.9 → moment arm j d ≈ 0.9d can be used in approximation design.

2) Determine size of section bd2 Such that resisting moment of concrete Mc = R b d 2 ≥ Required M Usually b ≈ d / 2 : b = 10 cm, 20 cm, 30 cm, 40 cm, . . . d = 20 cm, 30 cm, 40 cm, 50 cm, . . . 3) Determine steel area From

M = As f s jd

→

M As = fs j d

4) Select steel bars and Detailing

.1 , .2 Number of Bars Bar Dia.

1

2

3

RB6

0.283

0.565

0.848

RB9

0.636

1.27

DB10

0.785

DB12

4

5

6

1.13

1.41

1.70

1.91

2.54

3.18

3.82

1.57

2.36

3.14

3.93

4.71

1.13

2.26

3.53

4.52

5.65

6.79

DB16

2.01

4.02

6.03

8.04

10.05

12.06

DB20

3.14

6.28

9.42

12.57

15.71

18.85

DB25

4.91

9.82

14.73

19.63

24.54

29.45

.3 !" #$%! & ACI Member

Simple One-end Both-ends supported continuous continuous

Cantilever

One-way slab

L/20

L/24

L/28

L/10

Beam

L/16

L/18.5

L/21

L/8

L = span length For steel with fy not equal 4,000 kg/cm2 multiply with 0.4 + fy/7,000

Example 3.2: Working Stress Design of Beam w = 4 t/m

Concrete: fc = 65 kg/cm2 Steel: fs = 1,700 kg/cm2

5.0 m

From table: n = 10, R = 8.161 kg/cm2

Required moment strength

M = (4) (5)2 / 8 = 12.5 t-m

Recommended depth for simple supported beam: d = L/16 = 500/16 = 31.25 cm USE section 30 x 50 cm with steel bar DB20 d = 50 - 4(covering) - 2.0/2(bar) = 45 cm

Moment strength of concrete: Mc = R b d2 = 8.161 (30) (45)2 = 495,781 kg-cm = 4.96 t-m < 12.5 t-m

NG

TRY section 40 x 80 cm d = 75 cm Mc = R b d2 = 8.161 (40) (75)2 = 1,836,225 kg-cm = 18.36 t-m > 12.5 t-m Steel area:

OK

M 12 . 5 × 10 5 As = = = 10 . 8 cm 2 f s jd 1,700 × 0 . 908 × 75

Select steel bar 4DB20 (As = 12.57 cm2)

Alternative Solution: From Mc = R b d2 = required moment M

bd

2

=

M R

⇒

d =

M Rb

For example M = 12.5 t-m, R = 8.161 ksc, b = 40 cm d =

12 . 5 × 10 5 = 61 . 88 cm 8 . 161 × 40

USE section 40 x 80 cm d = 75 cm

Revised Design due to Self Weight From selected section 40 x 80 cm Beam weight wbm = 0.4 × 0.8 × 2.4(t/m3) = 0.768 t/m Required moment M = (4 + 0.768) (5)2 / 8 = 14.90 < 18.36 t-m OK Revised Design due to Support width 30 cm

Column width 30 cm

30 cm

Required moment: M = (4.768) (4.7)2 / 8 = 13.17 t-m

4.7 m clear span 5.0 m span

Practical Design of RC Beam B1 30x60 Mc = 8.02 t-m, Vc = 6.29 t. w = 2.30 t/m

5.00

Load dl wall slab w

0.43 0.63 1.24 2.30

fc = 65 ksc, fs = 1,500 ksc, n = 10 k = 0.302, j = 0.899, R = 8.835 ksc b = 30 cm, d = 60 - 5 = 55 cm Mc = 8.835(30)(55)2/105 = 8.02 t-m

M± = (1/9)(2.3)(5.0)2 = 6.39 t-m Vc = 0.29(173)1/2(30)(55)/103 As± = 8.62 cm2 (2DB25) V = 5.75 t ([email protected] St.)

= 6.29 t As± = 6.39×105/(1,500×0.899×55) = 8.62 cm2

B2 40x80 Mc = 19.88 t-m, Vc = 11.44 t.

SFD BMD As

w = 2.64 t/m

w = 2.64 t/m

8.00

5.00

8.54

9.83 12.58 +13.81

3.37 +2.15

-16.17 13.65

15.99

2.13

3DB25

4DB25

2DB25

GRASP Version 1.02 B11-B12

Membe r

Mz.i [T-m]

Mz.pos [T-m]

Mz.j [T-m]

Fy.i [Ton]

Fy.j [Ton]

1

0

39.03

-53.42

33.04

-50.84

2

-53.42

17.36

-37.97

44.52

-39.36

3

-37.97

20.75

-46.35

40.54

-43.34

4

-46.35

25.88

-28.26

44.96

-38.92

5

-28.26

6.59

-92.25

31.27

-52.61

6

-92.25

81.47

0.00

69.70

-47.73

Analysis of RC Beam Given: Section As , b, d

Materials fc , fs

Find: Mallow = Moment capacity of section STEP 1 : Locate Neutral Axis (kd)

k = 2 ρn + (ρn ) − ρn 2

j =1−k / 3 As = Reinforcem ent ratio bd Es 2.04 ×106 134 n= = ≈ Ec 15,100 f c′ f c′

where ρ =

STEP 2 : Resisting Moment Concrete:

1 Mc = f c k j b d 2

Steel:

M s = As f s j d

2

If Mc > Ms , Over reinforcement

Mallow = Ms

If Mc < Ms , Under reinforcement

Mallow = Mc

Under reinforcement is preferable because steel is weaker than concrete. The RC beam would fail in ductile mode.

Example 3.3 Determine the moment strength of beam 40 cm

fc = 65 ksc, fs = 1,700 ksc, n = 10, d = 75 cm

As 12 . 57 ρ= = = 0 . 00419 , ρ n = 0 . 0419 bd 40 × 75

80 cm

k = 2 × 0 . 0419 + ( 0 . 0419 ) 2 − 0 . 0419 4 DB 20 As = 12.57 cm2

= 0 . 251 → j = 1 − 0 . 251 / 3 = 0 . 916

Mc = 0.5(65)(0.251)(0.916)(40)(75)2/105 = 16.81 t-m Ms = (12.57)(1,700)(0.916)(75)/105 = 14.68 t-m (control)

Double Reinforcement - Increase steel area - Enlarge section

When Mreq’d > Mallow

- Double RC only when no choice εc

A’s d’ M

As

εs

ε’s

T’ = A’s f’s 1

C = 2 fc k b d

T = As fs

As1 fs As2 fs

T’ = A’s f’s C=

1

C = 2 fckbd

1 f kbd 2 c

d-d’

jd T = As fs

T1 = As1 fs

Moment strength M = M1 + M2

Steel area

As =

T’ = A’s f’s

T2 = As2 fs

1 M 1 = M c = f c kjbd 2 2 = As1 f s jd Mc As1 = f s jd

+

M2 = M − Mc = As 2 f s (d − d ′) = As′ f s′(d − d ′) M − Mc As 2 = f s (d − d ′)

Compatibility Condition d’ kd

εc

εs d − kd = ε s′ kd − d ′

ε’s

From Hook’s law: εs = Es fs, ε’s = Es f’s

d

εs

.. .

Es f s fs d − kd = = Es f s′ f s′ kd − d ′ k − d′ d f s′ = f s 1− k k − d′ d f s′ = 2 f s 1− k

( A’s ) T’ = A’s f’s

Force equilibrium [ ΣFx=0 ] T’ = T2

d-d’

A’s f’s = As2 fs T2 = As2 fs

Substitute

k − d′ d f s′ = 2 f s 1− k

1 1− k As′ = As 2 2 k − d′ d

( k ) d’ kd d

εc

Compression = Tension

Cc + Cs′ = T

ε’ s Substitute

1 f c b kd + As′ f s′ = As f s 2 k − d′ d As′ f s′ = 2 f s , ρ′ = 1− k bd

εs

As 1− k f s = n fc , ρ= k bd

k =

d′  2 2  ′ ′ 2n  ρ + 2 ρ  + n ( ρ + 2 ρ ) − n ( ρ + 2 ρ ′) d 

Example 3.4 Design 40x80 cm beam using double RC w = 6 t/m

fc = 65 ksc, fs = 1,700 ksc, n = 10, d = 75 cm

5.0 m

k = 0.277, j = 0.908, R = 8.161 ksc

Beam weight wbm = 0.4 × 0.8 × 2.4(t/m3) = 0.768 t/m Required M = (6.768) (5)2 / 8 = 21.15 t-m Mc = Rbd2 = 8.161(40)(75)2/105 = 18.36 t-m < req’d M

Double RC

Mc 18.36 × 105 As1 = = = 15.86 cm 2 f s jd 1, 700 × 0.908 × 75 M − Mc (21.15 − 18.36) ×105 As 2 = = = 2.34 cm 2 f s (d − d ′) 1, 700 × (75 − 5)

Tension steel As = As1 + As2 = 15.86 + 2.34 = 18.20 cm2 USE 6DB20 (As = 18.85 cm2) Compression steel

As′ =

1 1− k 1 1 − 0.277 = × 2.34 × = 4.02 cm 2 As 2 2 k − d′ d 2 0.277 − 5 / 75

USE 2DB20 (As = 6.28 cm2)

0.80 m

2DB20

6DB20 0.40 m

175 3 3