Single Anchor Bolt Design With Tension and Shear Using Anchor Reinforcement

ANCHOR BOLT DESIGN

Combined Tension and Shear

Result Summary

Anchor Rod Embedment, Spacing and Edge Distance

OK

Min Rquired Anchor Reinft. Development Length

ratio

=

0.78

OK

Overall

ratio

=

0.96

OK

Seismic Design

Tension

=

OK

Shear

=

OK

Design Code Reference

Anchor bolt design based on

Code Abbreviation

CSA A23.3-14 Design of Concrete Structures Annex D

CSA A23.3-14

PIP STE05121 Anchor Bolt Design Guide-2006

PIP STE05121

Code Reference

Anchor Bolt Data

Factored tensile force

N_u

=

[kN]

Factored shear force

V_u

=

[kN]

Concrete strength

f'_c

=

[MPa]

Anchor bolt material

=

Anchor tensile strength

f_uta

=

400

[MPa]

CSA A23.3-14

Anchor is ductile steel element

D.2

Anchor bolt diameter

d_a

=

[in]

=

12.7

[mm]

Anchor bolt has sleeve

=

PIP STE05121

Anchor bolt embedment depth

h_ef

=

[mm]

152

OK

Page A -1 Table 1

Pedestal height

h_a

=

[mm]

456

OK

PIP STE05121

Anchor bolt edge distance c₁

c₁

=

[mm]

114

OK

Page A -1 Table 1

Anchor bolt edge distance c₂

c₂

=

[mm]

114

OK

Anchor bolt edge distance c₃

c₃

=

[mm]

114

OK

Anchor bolt edge distance c₄

c₄

=

[mm]

114

OK

CSA A23.3-14

To be considered effective for resisting anchor tension, vertical reinforcing bars shall be located

Figure D.10

within 0.5h_ef from the outmost anchor's centerline

Avg ver. bar center to anchor rod center distance

d_ar

=

[mm]

Rebar specification

=

No of ver. rebar that are effective for resisting anchor tension

n_v

=

Ver. rebar size No.

=

25.4

[mm]

single rebar area A_s

=

509.0

[mm²]

Ver. rebar top anchorage option

CSA A23.3-14

To be considered effective for resisting anchor shear, hor. reinft shall be located

Figure D.17B

within min( 0.5c₁, 0.3c₂ ) from the outmost anchor's centerline

min (0.5c_1, 0.3c₂)

=

38

[mm]

No of tie leg that are effective to resist anchor shear

n_leg

=

No of tie layer that are effective to resist anchor shear

n_lay

=

Hor. tie rebar size No.

=

12.7

[mm]

single rebar area A_s

=

129.0

[mm²]

For anchor reinft shear breakout strength calc

Rebar yield strength - ver. rebar

f_y-v

=

[MPa]

Rebar yield strength - hor. rebar

f_y-h

=

[MPa]

Anchor bolt head type

Anchor effective cross section area

A_se

=

92

[mm²]

Anchor bolt head bearing area

A_brg

=

[mm²]

Anchor bolt 1/8" (3mm) corrosion allowance

=

CSA A23.3-14

Provide built-up grout pad ?

=

D.7.1.3

Seismic design I_EF_aS_a(0.2) ≥0.35

=

D.4.3.3

Anchor bolt load E <= 0.2U

Tensile

=

Shear

=

D.4.3.5.1 & D.4.3.6.1

Anchor bolt satisfies opion

Tensile

=

Shear

=

D.4.3.5.3 & D.4.3.6.3

Strength resistance factors

CSA A23.3-14

Concrete

f_c

=

0.65

8.4.2

Steel anchor and reinforcing bar

f_s

=

0.85

R_ar

=

0.85

8.4.3 a) D.6.2.9 D.7.2.9

Anchor rod - ductile steel

R_t,s

=

0.80

R_v,s

=

0.75

D.5.3 a)

Concrete - condition A

R_t,c

=

1.15

R_v,c

=

1.15

D.5.3 c)

CONCLUSION

Anchor Rod Embedment, Spacing and Edge Distance

OK

CSA A23.3-14

Min Rquired Anchor Reinft. Development Length

ratio

=

0.78

OK

12.5.1

Overall

ratio

=

0.96

OK

Tension

Anchor Rod Tensile Resistance

ratio

=

0.36

OK

Anchor Reinft Tensile Breakout Resistance

ratio

=

0.03

OK

Anchor Pullout Resistance

ratio

=

0.21

OK

Side Blowout Resistance

ratio

=

0.18

OK

Shear

Anchor Rod Shear Resistance

ratio

=

0.79

OK

Anchor Reinft Shear Breakout Resistance

Strut Bearing Strength

ratio

=

0.05

OK

Tie Reinforcement

ratio

=

0.06

OK

Conc. Pryout Not Govern When h_ef >= 12d_a

OK

Tension Shear Interaction

ratio

=

0.96

OK

Seismic Design

CSA A23.3-14

Tension

Applicable

OK

D.4.3.5

Seismic I_EF_aS_a(0.2)>=0.35 and E>0.2U , Option D is selected to satisfy additional seismic requirements as per D.4.3.5.3

CSA A23.3-14

Shear

Applicable

OK

D.4.3.6

Seismic I_EF_aS_a(0.2)>=0.35 and E>0.2U , Option C is selected to satisfy additional seismic requirements as per D.4.3.6.3

Assumptions

CSA A23.3-14

1. Concrete is cracked

D.6.2.6, D.6.3.6, D.7.2.7

2. Condition A - supplementary reinforcement is provided

D.5.3 c)

3. Anchors shall be designed for factored load combinations specified in CSA A23.3-14 clause 8

D.4.2

4. Anchor reinft strength is used to replace concrete tension / shear breakout strength as per

D.6.2.9 & D.7.2.9

CSA A23.3-14 Annex D clause D.6.2.9 and D.7.2.9

5. For tie reinft, only the top most 2 or 3 layers of ties (50mm from TOC and 2x75mm after) are
effective

6. Strut-and-Tie model is used to anlyze the shear transfer and to design the required tie reinft

CSA A23.3-14

7. Anchor reinft used in structures where R_d>2.5 shall meet requirements specified in D.4.3.8

D.4.3.8

CACULATION

Anchor Rod Tensile Resistance

CSA A23.3-14

N_sar

=

f_s A_se f_uta R_t,s

=

24.9

[kN]

D.6.1.2 Eq D.2

ratio

=

0.36

>

N_u

OK

Anchor Reinft Tensile Breakout Resistance

CSA A23.3-14

Min required full yield tension l_dh

l_dh

=

180 degree hook case

=

[mm]

12.5.2, 12.5.3 b)

Actual development lenngth

l_a

=

h_ef - c (50mm) - d_ar x tan35

=

[mm]

>

203

OK

12.5.1

CSA A23.3-14

Anchor reinft breakout resistance

N_nr

=

f_sx f_y-vx n_v A_sx R_arx (l_a / l_d , if l_a < l_d)

=

257.4

[kN]

D.4.3.5.5, D.6.2.9, 12.2.5

ratio

=

0.03

>

N_u

OK

Anchor Pullout Resistance

CSA A23.3-14

Single bolt pullout resistance

N_pr

=

8 A_brg f_c f_c' R_t,c

=

56.1

[kN]

D.6.3.4 Eq D.16

f_t,c N_cp

=

f _t,cΨ_c,p N_pr

=

56.1

[kN]

D.6.3.1 Eq D.15

Ψ_c,p

=

1 for cracked conc

D.6.3.6

R_t,c

=

1.00

pullout strength is always Condition B

D.5.3 c)

Seismic design strength reduction

=

x 0.75 applicable

=

42.1

[kN]

D.4.3.5.4

ratio

=

0.21

>

N_u

OK

Side Blowout Resistance

c

=

min ( c₁, c₂, c₃, c₄ )

=

125

[mm]

Check if side blowout applicable

h_ef

=

380

[mm]

CSA A23.3-14

>

2.5c

side bowout is applicable

D.6.4.1

Single anchor SB resistance

N_sbr

=

129.1

[kN]

D.6.4.1 Eq D.18

Edge reduction factor

=

( 1+ c_a2 / c_a1 ) / 4

=

0.50

D.6.4.1

SB resistance after edge reduction

N_sbr

=

N_sbr x [1+c_a2 / c_a1] / 4

=

64.5

[kN]

D.6.4.1

Seismic design strength reduction

=

x 0.75 applicable

=

48.4

[kN]

D.4.3.5.4

ratio

=

0.18

>

N_u

OK

Govern Tensile Resistance

N_r

=

min ( f N_sa, f N_n, f N_cp, f N_sb )

=

24.9

[kN]

Anchor Rod Shear Resistance

CSA A23.3-14

V_sar

=

f_s 0.6 A_se f_uta R_v,s

=

14.0

[kN]

D.7.1.2 b) Eq D.31

Reduction due to built-up grout pad

=

x 0.8 , applicable

=

11.2

[kN]

D.7.1.3

ratio

=

0.79

>

V_u

OK

Anchor Reinft Shear Breakout Resistance

ACI 318M-11

Strut-and-Tie model is used to anlyze the shear transfer and to design the required tie reinft

STM strength reduction factor

f_st

=

0.75

9.3.2.6

Strut-and-Tie model geometry

d_v

=

55

[mm]

d_h

=

55

[mm]

θ

=

45

d_t

=

78

[mm]

Strut compression force

C_s

=

0.5 V_u / sinθ

=

6.3

[kN]

Strut Bearing Strength

ACI 318M-11

Strut compressive strength

f_ce

=

0.85 f'_c

=

30.4

[MPa]

A.3.2 (A-3)

* Bearing of anchor bolt

CSA A23.3-14

Anchor bearing length

l_e

=

min( 8d_a , h_ef )

=

102

[mm]

D.7.2.2 a)

Anchor bearing area

A_brg

=

l_e x d_a

=

1290

[mm²]

Anchor bearing resistance

C_r

=

1 x f_st x f_ce x A_brg

=

29.4

[kN]

>

V_u

OK

* Bearing of ver reinft bar

Ver bar bearing area

A_brg

=

(l_e +1.5 x d_t- d_a/2 -d_b/2) x d_b

=

5060

[mm²]

Ver bar bearing resistance

C_r

=

f_st x f_ce x A_brg

=

115.5

[kN]

ratio

=

0.05

>

C_s

OK

Tie Reinforcement

* For tie reinft, only the top most 2 or 3 layers of ties (50mm from TOC and 2x75mm after) are effective

* For enclosed tie, at hook location the tie cannot develop full yield strength f_y . Use the pullout resistance in

tension of a single hooked bolt as per CSA A23.3-14 Eq D.17 as the max force can be developed at hook T_h

* Assume 100% of hor. tie bars can develop full yield strength

Total number of hor tie bar

n

=

n_leg (leg) x n_lay (layer)

=

4

CSA A23.3-14

Pull out resistance at hook

T_h

=

f_c 0.9 f_c' e_h d_a R_t,c

=

15.2

[kN]

D.6.3.5 Eq D.17

e_h

=

4.5 d_b

=

57

[mm]

Single tie bar tension resistance

T_r

=

f_s x f_y-h x A_s x R_ar

=

38.6

[kN]

D.7.2.9 Eq D.43

CSA A23.3-14

Total tie bar tension resistance

V_nr

=

1.0 x n x T_r

=

154.3

[kN]

D.4.3.6.4 & D.7.2.9

ratio

=

0.06

>

V_u

OK

Conc. Pryout Shear Resistance

The pryout failure is only critical for short and stiff anchors. It is reasonable to assume that for general

cast-in place headed anchors with h_ef > = 12d_a , the pryout failure will not govern

12d_a

=

152

[mm]

h_ef

=

380

[mm]

>

12d_a

OK

Govern Shear Resistance

V_r

=

min ( V_sar , V_nr )

=

11.2

[kN]

Tension Shear Interaction

CSA A23.3-14

Check if N_u >0.2f N_n and V_u >0.2f V_n

=

Yes

D.8.2 & D.8.3

N_u / f N_n + V_u / f V_n

=

1.15

D.8.4 Eq D.46

ratio

=

0.96

<

1.2

OK

Seismic Design

Tension

Applicable

OK

Option D is selected.

CSA A23.3-14

User has to ensure that the tensile load N_u user input above includes the seismic load E, with E increased
by multiplying overstrength factor R_dR_o=1.3 or as specified in NBCC clause 4.1.8.18

D.4.3.5.3 d)

Seismic I_EF_aS_a(0.2)>=0.35 and E>0.2U , Option D is selected to satisfy additional seismic requirements as per D.4.3.5.3

Shear

Applicable

OK

Option C is selected.

CSA A23.3-14

User has to ensure that the shear load V_u user input above includes the seismic load E, with E increased
by multiplying overstrength factor R_dR_o=1.3 or as specified in NBCC clause 4.1.8.18

D.4.3.6.3 c)

Seismic I_EF_aS_a(0.2)>=0.35 and E>0.2U , Option C is selected to satisfy additional seismic requirements as per D.4.3.6.3