Anchor Bolt Design With Tension and Shear Not Using Anchor Reinforcement

ANCHOR BOLT DESIGN

Combined Tension and Shear

Result Summary

Anchor Rod Embedment, Spacing and Edge Distance

OK

Overall

ratio

=

0.82

OK

Seismic Design

Tension

=

NG

Shear

=

OK

Design Code Reference

Anchor bolt design based on

Code Abbreviation

ACI 318-14 Building Code Requirements for Structural Concrete and Commentary

ACI 318-14

PIP STE05121 Anchor Bolt Design Guide-2006

PIP STE05121

AISC Design Guide 1: Base Plate and Anchor Rod Design 2nd Ed

AISC Design Guide 1

Code Reference

Anchor Bolt Data

Factored tensile force

N_u

=

[kips]

Factored shear force

V_u

=

[kips]

Concrete strength

f'_c

=

[ksi]

Anchor bolt material

=

Anchor tensile strength

f_uta

=

58.0

[ksi]

ACI 318-14

Anchor is ductile steel element

2.3 & 17.3.3 (a)

Anchor bolt diameter

d_a

=

[in]

Anchor bolt has sleeve

=

PIP STE05121

Anchor bolt edge distance c₁

c₁

=

[in]

4.50

OK

Page A -1 Table 1

Anchor bolt edge distance c₂

c₂

=

[in]

4.50

OK

Anchor bolt edge distance c₃

c₃

=

[in]

4.50

OK

Anchor bolt edge distance c₄

c₄

=

[in]

4.50

OK

Anchor bolt embedment depth

h_ef

=

[in]

ACI 318-14

c_i ≥ 1.5h_ef for at least two edges to avoid reducing of h_ef when N_u > 0

OK

17.4.2.3

Anchor bolt adjusted h_ef for design

h_ef

=

[in]

12.00

OK

17.4.2.3

Concrete thickness

h_a

=

[in]

15.00

OK

PIP STE05121

Outermost bolt line spacing s₁

s₁

=

[in]

4.00

OK

Page A -1 Table 1

Outermost bolt line spacing s₂

s₂

=

[in]

4.00

OK

For conc shear breakout check use

Number of anchor at bolt line 1

n₁

=

Number of anchor at bolt line 2

n₂

=

For conc side-face blowout check use

No of anchor bolt along width edge

n_bw

=

No of anchor bolt along depth edge

n_bd

=

No of anchor bolt carrying tension

n_t

=

No of anchor bolt carrying shear

n_s

=

Oversized holes in base plate ?

=

Anchor bolt head type

Anchor effective cross section area

A_se

=

0.606

[in²]

Anchor bolt head bearing area

A_brg

=

[in²]

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

=

ACI 318-14

Supplementary reinforcement

For tension

=

Condition A

17.3.3 (c)

For shear

Y_c,v

=

Condition A

17.5.2.7

ACI 318-14

Provide built-up grout pad ?

=

17.5.1.3

Concrete cracking

=

17.4.2.6, 17.4.3.6, 17.5.2.7

ACI 318-14

Seismic design category SDC >= C

=

17.2.3.1

Anchor bolt load E <= 0.2U

Tensile

=

Shear

=

17.2.3.4.1 & 17.2.3.5.1

Anchor bolt satisfies opion

Tensile

=

Shear

=

17.2.3.4.3 & 17.2.3.5.3

Strength reduction factors

ACI 318-14

Anchor reinforcement

f_s

=

0.75

17.4.2.9 & 17.5.2.9

Anchor rod - ductile steel

f_t,s

=

0.75

f_v,s

=

0.65

17.3.3 (a)

Concrete

f_t,c

=

0.75 Cdn-A

f_v,c

=

0.75 Cdn-A

17.3.3 (c)

CONCLUSION

Anchor Rod Embedment, Spacing and Edge Distance

OK

Overall

ratio

=

0.82

OK

Tension

Anchor Rod Tensile Resistance

ratio

=

0.14

OK

Concrete Tensile Breakout Resistance

ratio

=

0.35

OK

Anchor Pullout Resistance

ratio

=

0.11

OK

Side Blowout Resistance

ratio

=

0.00

NA

Shear

Anchor Rod Shear Resistance

ratio

=

0.34

OK

Concrete Shear Breakout Resistance - Perpendicular To Edge

ratio

=

0.64

OK

Concrete Shear Breakout Resistance - Parallel To Edge

ratio

=

0.16

OK

Concrete Pryout Shear Resistance

ratio

=

0.19

OK

Tension Shear Interaction

ratio

=

0.82

OK

Seismic Design

ACI 318-14

Tension

Applicable

NG

17.2.3.4

Option A is NOT satisfied

Seismic SDC>=C and E>0.2U , Option A is selected to satisfy additional seismic requirements as per 17.2.3.4.3

Shear

Applicable

OK

17.2.3.5

Seismic SDC>=C and E>0.2U , Option C is selected to satisfy additional seismic requirements as per 17.2.3.5.3

Assumptions

ACI 318-14

1. Concrete is cracked

17.4.2.6, 17.4.3.6, 17.5.2.7

2. Condition A - supplementary reinforcement provided

17.3.3 (c)

3. Load combinations shall be per ACI 318-14 5.3.1

17.3.3

4. Tensile load acts through center of bolt group Y_ec,N =1.0

17.4.2.4

5. Shear load acts through center of bolt group Y_ec,V =1.0

17.5.2.5

6. Anchor bolt washer shall be tack welded to base plate for all anchor bolts to transfer shear

AISC Design Guide 1

Section 3.5.3

CACULATION

Anchor Rod Tensile Resistance

ACI 318-14

f _t,s N_sa

=

f _t,s n_t A_se f_uta

=

105.44

[kips]

17.4.1.2 Eq 17.4.1.2

ratio

=

0.14

>

N_u

OK

Concrete Tensile Breakout Resistance

ACI 318-14

N_b

=

24 l √f_c h_ef^1.5 if h_ef<11" or h_ef>25"

=

72.57

[kips]

17.4.2.2 Eq 17.4.2.2a

16 l √f_c h_ef^(5/3) if 11"≤ h_ef≤25"

17.4.2.2 Eq 17.4.2.2b

Projected conc failure area

1.5 h_ef

=

18.00

[in]

A_NC

=

[s₁+min(c₁,1.5h_ef)+min(c₃,1.5h_ef)]x

=

1444.0

[in²]

[s₂+min(c₂,1.5h_ef)+min(c₄,1.5h_ef)]

A_NCO

=

9 h_ef²

=

1296.0

[in²]

17.4.2.1 Eq 17.4.2.1c

A_NC

=

min ( A_NC, n_t A_NCO )

=

1444.0

[in²]

17.4.2.1

Min edge distance

c_min

=

min( c₁, c₂, c₃, c₄ )

=

15.00

[in]

Eccentricity effects

Ψ_ec,N

=

1.0 for no eccentric load

17.4.2.4

Edge effects

Ψ_ed,N

=

min[ (0.7+0.3c_min/1.5h_ef), 1.0 ]

=

0.95

17.4.2.5

Concrete cracking

Ψ_c,N

=

1.00 for cracked concrete

17.4.2.6

Concrete splitting

Ψ_cp,N

=

1.00 for cast-in anchor

17.4.2.7

Concrete breakout resistance

f_tcN_cbg

=

f_tc	A_NC	Ψ_ec,N Ψ_ed,N Ψ_c,N Ψ_cp,N N_b
	A_NCO

=

57.61

[kips]

17.4.2.1 Eq 17.4.2.1b

Seismic design strength reduction

=

x 0.75 applicable

=

43.21

[kips]

17.2.3.4.4

ratio

=

0.35

>

N_u

OK

Anchor Pullout Resistance

ACI 318-14

Single bolt pullout resistance

N_p

=

8 A_brg f_c'

=

62.44

[kips]

17.4.3.4 Eq 17.4.3.4

f_t,c N_pn

=

f _t,c n_tΨ_c,p N_p

=

174.84

[kips]

17.4.3.1 Eq 17.4.3.1

Ψ_c,p

=

1.00 for cracked concrete

17.4.3.6

f _t,c

=

0.70

pullout strength is always Condition B

17.3.3(c)

Seismic design strength reduction

=

x 0.75 applicable

=

131.13

[kips]

17.2.3.4.4

ratio

=

0.11

>

N_u

OK

Side Blowout Resistance

Failure Along Pedestal Width Edge

ACI 318-14

Tensile load carried by anchors close to edge which may cause side-face blowout

along pedestal width edge

N_buw

=

N_u x n_bw / n_t

=

7.50

[kips]

R17.4.4.2

c

=

min ( c₁ , c₃ )

=

15.00

[in]

s

=

s₂

=

5.00

[in]

Check if side blowout applicable

h_ef

=

12.00

[in]

<

2.5c

side bowout is NOT applicable

17.4.4.1

Failure Along Pedestal Depth Edge

ACI 318-14

Tensile load carried by anchors close to edge which may cause side-face blowout

along pedestal depth edge

N_bud

=

N_u x n_bd / n_t

=

7.50

[kips]

R17.4.4.2

c

=

min ( c₂, c₄ )

=

15.00

[in]

s

=

s₁

=

5.00

[in]

Check if side blowout applicable

h_ef

=

12.00

[in]

<

2.5c

side bowout is NOT applicable

17.4.4.1

Group side blowout resistance

f_tc N_sbg

=

0.00

[kips]

Govern Tensile Resistance

N_r

=

min ( f N_sa, f N_cbg, f N_pn, f N_sbg )

=

43.21

[kips]

Anchor Rod Shear Resistance

ACI 318-14

f _v,sV_sa

=

f _v,s n_s 0.6 A_se f_uta

=

54.83

[kips]

17.5.1.2 (b)

Reduction due to built-up grout pad

=

x 0.8 , applicable

=

43.86

[kips]

17.5.1.3

ratio

=

0.34

>

V_u

OK

Conc. Shear Breakout Resistance - Perpendicular To Edge

Mode 1 Failure cone at front anchors, strength check against 0.5 x V_u

Mode 3 Failure cone at front anchors, strength check against 1.0 x V_u , applicable when oversized holes are used in base plate

Bolt edge distance

c₁

=

15.00

[in]

ACI 318-14

Limiting c_a1 when anchors are influenced by 3 or more edges

=

No

17.5.2.4

Bolt edge distance - adjusted

c₁

=

c_a1 needs NOT to be adjusted

=

15.00

[in]

17.5.2.4

c₂

=

15.00

[in]

1.5c₁

=

22.50

[in]

ACI 318-14

A_vc

=

[min(c₂,1.5c₁) + s₂ + min(c₄,1.5c₁)]x

=

637.5

[in²]

17.5.2.1

min(1.5c₁, h_a)

ACI 318-14

A_vco

=

4.5c₁²

=

1012.5

[in²]

17.5.2.1 Eq 17.5.2.1c

A_vc

=

min ( A_vc, n₁ A_vco )

=

637.5

[in²]

17.5.2.1

l_e

=

min( 8d_a , h_ef )

=

8.00

[in]

17.5.2.2

V_b1

=

44.45

[kips]

17.5.2.2 Eq 17.5.2.2a

V_b2

=

37.70

[kips]

17.5.2.2 Eq 17.5.2.2b

V_b

=

min( V_b1 , V_b2 )

=

37.70

[kips]

17.5.2.2

Eccentricity effects

Ψ_ec,v

=

1.0 shear acts through center of group

17.5.2.5

Edge effects

Ψ_ed,v

=

min[ (0.7+0.3c₂/1.5c₁), 1.0 ]

=

0.90

17.5.2.6

Concrete cracking

Ψ_c,v

=

concrete is cracked

=

1.20

17.5.2.7

Member thickness

Ψ_h,v

=

max[ (sqrt(1.5c₁ / h_a) , 1.0 ]

=

1.22

17.5.2.8

ACI 318-14

Conc shear breakout resistance

V_cbg

=

f_v,c	A_vc	Ψ_ec,v Ψ_ed,v Ψ_c,v Ψ_h,v V_b
	A_vco

=

23.55

[kips]

17.5.2.1 Eq 17.5.2.1b

Mode 3 is used for checking

V_cbg1

=

1.0 x V_cbg

=

23.55

[kips]

Mode 2 Failure cone at back anchors

Bolt edge distance

c_a1

=

c₁ + s₁

=

20.00

[in]

ACI 318-14

Limiting c_a1 when anchors are influenced by 3 or more edges

=

Yes

17.5.2.4

Bolt edge distance - adjusted

c_a1

=

c_a1 needs to be adjusted

=

16.67

[in]

17.5.2.4

c₂

=

15.00

[in]

1.5c_a1

=

25.00

[in]

ACI 318-14

A_vc

=

[min(c₂,1.5c_a1)+ s₂ + min(c₄,1.5c_a1)]x

=

675.0

[in²]

17.5.2.1

min(1.5c_a1, h_a)

ACI 318-14

A_vco

=

4.5c_a1²

=

1250.0

[in²]

17.5.2.1 Eq 17.5.2.1c

A_vc

=

min ( A_vc, n₂ A_vco )

=

675.0

[in²]

17.5.2.1

l_e

=

min( 8d_a , h_ef )

=

8.00

[in]

17.5.2.2

V_b1

=

52.06

[kips]

17.5.2.2 Eq 17.5.2.2a

V_b2

=

44.16

[kips]

17.5.2.2 Eq 17.5.2.2b

V_b

=

min( V_b1 , V_b2 )

=

44.16

[kips]

17.5.2.2

Eccentricity effects

Ψ_ec,v

=

1.0 shear acts through center of group

17.5.2.5

Edge effects

Ψ_ed,v

=

min[ (0.7+0.3c₂/1.5c_a1), 1.0 ]

=

0.88

17.5.2.6

Concrete cracking

Ψ_c,v

=

concrete is cracked

=

1.20

17.5.2.7

Member thickness

Ψ_h,v

=

max[ (sqrt(1.5c_a1 / h_a) , 1.0 ]

=

1.29

17.5.2.8

ACI 318-14

Conc shear breakout resistance

V_cbg2

=

f_v,c	A_vc	Ψ_ec,v Ψ_ed,v Ψ_c,v Ψ_h,v V_b
	A_vco

=

24.38

[kips]

17.5.2.1 Eq 17.5.2.1b

Min shear breakout resistance

f_v,cV_cbg

=

min ( V_cbg1 , V_cbg2 )

=

23.55

[kips]

shear perpendicular to edge

ratio

=

0.64

>

V_u

OK

Conc. Shear Breakout Resistance - Parallel To Edge

Mode 1 Shear taken evenly by all anchor bolts, strength check against 0.5 x V_u

Bolt edge distance

c_a1

=

min(c₂ , c₄)

=

15.00

[in]

ACI 318-14

Limiting c_a1 when anchors are influenced by 3 or more edges

=

No

17.5.2.4

Bolt edge distance - adjusted

c_a1

=

c_a1 needs NOT to be adjusted

=

15.00

[in]

17.5.2.4

1.5c_a1

=

22.50

[in]

ACI 318-14

A_vc

=

[min(c₁,1.5c_a1) + s₁+ min(c₃,1.5c_a1)]x

=

637.5

[in²]

17.5.2.1

min(1.5c_a1, h_a)

ACI 318-14

A_vco

=

4.5c_a1²

=

1012.5

[in²]

17.5.2.1 Eq 17.5.2.1c

A_vc

=

min ( A_vc, n_bd A_vco )

=

637.5

[in²]

17.5.2.1

l_e

=

min( 8d_a , h_ef )

=

8.00

[in]

17.5.2.2

V_b1

=

44.45

[kips]

17.5.2.2 Eq 17.5.2.2a

V_b2

=

37.70

[kips]

17.5.2.2 Eq 17.5.2.2b

V_b

=

min( V_b1 , V_b2 )

=

37.70

[kips]

17.5.2.2

Eccentricity effects

Ψ_ec,v

=

1.0 shear acts through center of group

17.5.2.5

Edge effects

Ψ_ed,v

=

1.00

17.5.2.1 (c)

Concrete cracking

Ψ_c,v

=

concrete is cracked

=

1.20

17.5.2.7

Member thickness

Ψ_h,v

=

max[ (sqrt(1.5c_a1 / h_a) , 1.0 ]

=

1.22

17.5.2.8

ACI 318-14

Conc shear breakout resistance

V_cbg-p1

=

2xf_v,c	A_vc	Ψ_ec,v Ψ_ed,v Ψ_c,v Ψ_h,v V_b
	A_vco

=

52.33

[kips]

17.5.2.1 Eq 17.5.2.1b

17.5.2.1 (c)

Mode 2 Shear taken evenly by back anchor bolts, strength check against 0.5 x V_u

Bolt edge distance

c_a1

=

min(c₂ , c₄)

=

15.00

[in]

ACI 318-14

Limiting c_a1 when anchors are influenced by 3 or more edges

=

No

17.5.2.4

Bolt edge distance - adjusted

c_a1

=

c_a1 needs NOT to be adjusted

=

15.00

[in]

17.5.2.4

1.5c_a1

=

22.50

[in]

ACI 318-14

A_vc

=

[min(s₁+c₁,1.5c_a1) +min(c₃,1.5c_a1)]x

=

637.5

[in²]

17.5.2.1

min(1.5c_a1, h_a)

ACI 318-14

A_vco

=

4.5c_a1²

=

1012.5

[in²]

17.5.2.1 Eq 17.5.2.1c

A_vc

=

min ( A_vc, n_bd A_vco )

=

637.5

[in²]

17.5.2.1

l_e

=

min( 8d_a , h_ef )

=

8.00

[in]

17.5.2.2

V_b1

=

44.45

[kips]

17.5.2.2 Eq 17.5.2.2a

V_b2

=

37.70

[kips]

17.5.2.2 Eq 17.5.2.2b

V_b

=

min( V_b1 , V_b2 )

=

37.70

[kips]

17.5.2.2

Eccentricity effects

Ψ_ec,v

=

1.0 shear acts through center of group

17.5.2.5

Edge effects

Ψ_ed,v

=

1.00

17.5.2.1 (c)

Concrete cracking

Ψ_c,v

=

concrete is cracked

=

1.20

17.5.2.7

Member thickness

Ψ_h,v

=

max[ (sqrt(1.5c_a1 / h_a) , 1.0 ]

=

1.22

17.5.2.8

ACI 318-14

Conc shear breakout resistance

V_cbg-p2

=

2xf_v,c	A_vc	Ψ_ec,v Ψ_ed,v Ψ_c,v Ψ_h,v V_b
	A_vco

=

52.33

[kips]

17.5.2.1 Eq 17.5.2.1b

17.5.2.1 (c)

Mode 3 Shear taken evenly by front anchor bolts, strength check against 0.5 x V_u

Bolt edge distance

c_a1

=

min(c₂ , c₄)

=

15.00

[in]

ACI 318-14

Limiting c_a1 when anchors are influenced by 3 or more edges

=

No

17.5.2.4

Bolt edge distance - adjusted

c_a1

=

c_a1 needs NOT to be adjusted

=

15.00

[in]

17.5.2.4

1.5c_a1

=

22.50

[in]

ACI 318-14

A_vc

=

[min(c₁,1.5c_a1) + min(s₁+c₃,1.5c_a1)]x

=

562.5

[in²]

17.5.2.1

min(1.5c_a1, h_a)

ACI 318-14

A_vco

=

4.5c_a1²

=

1012.5

[in²]

17.5.2.1 Eq 17.5.2.1c

A_vc

=

min ( A_vc, n_bd A_vco )

=

562.5

[in²]

17.5.2.1

l_e

=

min( 8d_a , h_ef )

=

8.00

[in]

17.5.2.2

V_b1

=

44.45

[kips]

17.5.2.2 Eq 17.5.2.2a

V_b2

=

37.70

[kips]

17.5.2.2 Eq 17.5.2.2b

V_b

=

min( V_b1 , V_b2 )

=

37.70

[kips]

17.5.2.2

Eccentricity effects

Ψ_ec,v

=

1.0 shear acts through center of group

17.5.2.5

Edge effects

Ψ_ed,v

=

1.00

17.5.2.1 (c)

Concrete cracking

Ψ_c,v

=

concrete is cracked

=

1.20

17.5.2.7

Member thickness

Ψ_h,v

=

max[ (sqrt(1.5c_a1 / h_a) , 1.0 ]

=

1.22

17.5.2.8

ACI 318-14

Conc shear breakout resistance

V_cbg-p3

=

2xf_v,c	A_vc	Ψ_ec,v Ψ_ed,v Ψ_c,v Ψ_h,v V_b
	A_vco

=

46.18

[kips]

17.5.2.1 Eq 17.5.2.1b

17.5.2.1 (c)

Min shear breakout resistance

f_vcV_cbgp

=

min(V_cbg-p1 ,V_cbg-p2 , V_cbg-p3 )x2 side

=

92.35

[kips]

shear parallel to edge

ratio

=

0.16

>

V_u

OK

Conc. Pryout Shear Resistance

ACI 318-14

k_cp

=

2.0

17.5.3.1

Factored shear pryout resistance

f_v,cV_cpg

=

f_v,c k_cp N_cbg

=

107.54

[kips]

17.5.3.1 Eq 17.5.3.1b

f _v,c

=

0.7 pryout strength is always Condition B

17.3.3 (c)

Seismic design strength reduction

=

x 0.75 applicable

=

80.66

[kips]

17.2.3.4.4

ratio

=

0.19

>

V_u

OK

Govern Shear Resistance

V_r

=

min ( fV_sa , fV_cbg , fV_cbg-p , fV_cpg )

=

23.55

[kips]

Tension Shear Interaction

ACI 318-14

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

=

Yes

17.6.1 & 17.6.2

N_u / f N_n + V_u / f V_n

=

0.98

17.6.3 Eq 17.6.3

ratio

=

0.82

<

1.2

OK

Seismic Design

Tension

Applicable

NG

Option A is selected.

ACI 318-14

The program will flag OK if 17.2.3.4.3(a) subsections 1 & 2 are met and the ductile anchor steel strength
has the highest utilization ratio. User has to verify the conditions in 17.2.3.4.3(a) subsections 3~6, as applicable, are met.

17.2.3.4.3(a)

Steel nominal strength x 1.2

1.2N_sa

=

168.71

[kips]

Conc governed nominal strength

N_cbg

=

76.81

[kips]

N_pn

=

249.77

[kips]

N_sbg

=

0.00

[kips]

N_u / min( N_cbg , N_pn , N_sbg )

=

0.20

N_u / 1.2N_sa

=

0.09

<

0.20

NG

Option A is NOT satisfied

Seismic SDC>=C and E>0.2U , Option A is selected to satisfy additional seismic requirements as per 17.2.3.4.3

Shear

Applicable

OK

Option C is selected.

ACI 318-14

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 Ω_o

17.2.3.5.3(c)

Seismic SDC>=C and E>0.2U , Option C is selected to satisfy additional seismic requirements as per 17.2.3.5.3