Single Stud Anchor Design With Tension and Shear Not Using Anchor Reinforcement

STUD ANCHOR DESIGN

Combined Tension and Shear

Result Summary

Anchor Rod Embedment, Spacing and Edge Distance

OK

Overall

ratio

=

0.71

OK

Seismic Design

Tension

=

OK

Shear

=

OK

Design Code Reference

Welded stud 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

Code Reference

Welded Stud Data

Factored tensile force

N_u

=

[kips]

Factored shear force

V_u

=

[kips]

Concrete strength

f'_c

=

[ksi]

Welded stud material

=

Anchor tensile strength

f_uta

=

65.0

[ksi]

ACI 318-14

Anchor is ductile steel element

2.3 & 17.3.3 (a)

Welded stud diameter

d_a

=

[in]

Anchor effective cross section area

A_se

=

0.442

[in²]

Welded stud head bearing area

A_brg

=

[in²]

PIP STE05121

Welded stud edge distance c₁

c₁

=

[in]

4.50

OK

Page A -1 Table 1

Welded stud edge distance c₂

c₂

=

[in]

4.50

OK

Welded stud edge distance c₃

c₃

=

[in]

4.50

OK

Welded stud edge distance c₄

c₄

=

[in]

4.50

OK

Welded stud 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

Welded stud adjusted h_ef for design

h_ef

=

[in]

9.00

OK

17.4.2.3

Concrete thickness

h_a

=

[in]

15.00

OK

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

Welded stud load E <= 0.2U

Tensile

=

Shear

=

17.2.3.4.1 & 17.2.3.5.1

Welded stud 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

=

0.71

OK

Tension

Anchor Rod Tensile Resistance

ratio

=

0.46

OK

Concrete Tensile Breakout Resistance

ratio

=

0.31

OK

Anchor Pullout Resistance

ratio

=

0.58

OK

Side Blowout Resistance

ratio

=

0.00

NA

Shear

Anchor Rod Shear Resistance

ratio

=

0.27

OK

Concrete Shear Breakout Resistance - Perpendicular To Edge

ratio

=

0.24

OK

Concrete Shear Breakout Resistance - Parallel To Edge

ratio

=

0.11

OK

Concrete Pryout Shear Resistance

ratio

=

0.08

OK

Tension Shear Interaction

ratio

=

0.71

OK

Seismic Design

ACI 318-14

Tension

Applicable

OK

17.2.3.4

Seismic SDC>=C and E>0.2U , Option D 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

CACULATION

Anchor Rod Tensile Resistance

ACI 318-14

f _t,s N_sa

=

f _t,s A_se f_uta

=

21.55

[kips]

17.4.1.2 Eq 17.4.1.2

ratio

=

0.46

>

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

=

[min(c₁,1.5h_ef)+min(c₃,1.5h_ef)]x

=

1089.0

[in²]

[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, 1x A_NCO )

=

1089.0

[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

=

43.45

[kips]

17.4.2.1 Eq 17.4.2.1b

Seismic design strength reduction

=

x 0.75 applicable

=

32.59

[kips]

17.2.3.4.4

ratio

=

0.31

>

N_u

OK

Anchor Pullout Resistance

ACI 318-14

Single bolt pullout resistance

N_p

=

8 A_brg f_c'

=

32.66

[kips]

17.4.3.4 Eq 17.4.3.4

f_t,c N_pn

=

f _t,c Ψ_c,p N_p

=

22.86

[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

=

17.14

[kips]

17.2.3.4.4

ratio

=

0.58

>

N_u

OK

Side Blowout Resistance

c

=

min ( c₁, c₂, c₃, c₄ )

=

15.00

[in]

Check if side blowout applicable

h_ef

=

12.00

[in]

ACI 318-14

<

2.5c

side bowout is NOT applicable

17.4.4.1

Single anchor SB resistance

f_t,c N_sb

=

0.00

[kips]

17.4.4.1 Eq 17.4.4.1

Edge reduction factor

=

( 1+ c_a2 / c_a1 ) / 4

=

0.50

17.4.4.1

SB resistance after edge reduction

f_tcN_sb

=

f_t,c N_sb x [1+c_a2 / c_a1] / 4

=

0.00

[kips]

17.4.4.1

Seismic design strength reduction

=

x 0.75 applicable

=

0.00

[kips]

17.2.3.4.4

ratio

=

0.00

N_u

NA

Govern Tensile Resistance

N_r

=

min ( f N_sa, f N_cb, f N_pn, f N_sb )

=

17.14

[kips]

Anchor Rod Shear Resistance

ACI 318-14

f _v,sV_sa

=

f _v,s A_se f_uta

=

18.67

[kips]

17.5.1.2 Eq 17.5.1.2a

Reduction due to built-up grout pad

=

x 1.0 , not applicable

=

18.67

[kips]

17.5.1.3

ratio

=

0.27

>

V_u

OK

Conc. Shear Breakout Resistance - Perpendicular To Edge

Bolt edge distance

c_a1

=

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

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(c₂,1.5c_a1)+ s₂ +min(c₄,1.5c_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, 1x A_vco )

=

562.5

[in²]

17.5.2.1

l_e

=

min( 8d_a , h_ef )

=

6.00

[in]

17.5.2.2

V_b1

=

38.49

[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_cb

=

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

=

20.78

[kips]

17.5.2.1 Eq 17.5.2.1b

- perpendicular to edge

ratio

=

0.24

>

V_u

OK

Conc. Shear Breakout Resistance - Parallel To Edge

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

=

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 )

=

6.00

[in]

17.5.2.2

V_b1

=

38.49

[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_cb-p

=

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

- parallel to edge

17.5.2.1 (c)

ratio

=

0.11

>

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_cp

=

f_v,c k_cp N_cb

=

81.10

[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

=

60.83

[kips]

17.2.3.4.4

ratio

=

0.08

>

V_u

OK

Govern Shear Resistance

V_r

=

min ( fV_sa , fV_cb , fV_cb-p , fV_cp )

=

18.67

[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

=

0.85

17.6.3 Eq 17.6.3

ratio

=

0.71

<

1.2

OK

Seismic Design

Tension

Applicable

OK

Option D is selected.

ACI 318-14

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 Ω_o

17.2.3.4.3(d)

Seismic SDC>=C and E>0.2U , Option D 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