STEEL DESIGN W/ ACCESS
STEEL DESIGN W/ ACCESS
6th Edition
ISBN: 9781337761499
Author: Segui
Publisher: CENGAGE L
Question
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Chapter 3, Problem 3.8.4P
To determine

(a)

The double angle section for a tension member of the roof truss using Load And Resistance Factor Design (LRFD) method.

Expert Solution
Check Mark

Answer to Problem 3.8.4P

The double angle section to be selected for the bottom chord by LFRD method is 2L6×L6×716

The double angle section to be selected for the web members by LFRD method is 2L3×L2×316

Explanation of Solution

Given:

Metal deck load is 4psf of roof surface.

Build up roof load is 12psf.

Purlins load is 6psf of roof surface.

Snow load is 18psf of horizontal projection.

Truss load is 5psf of horizontal projection.

The trusses are spaced at 25ft.

Thickness of gusset plate is 38in.

A572Grade50 steel.

Calculation:

The properties of A572Grade50 steel from the AISC steel manual are as follows.

  • The yield strength (Fy) is 50ksi.
  • The ultimate strength is (Fu) is 65ksi.

The truss diagram is shown below.

STEEL DESIGN W/ ACCESS, Chapter 3, Problem 3.8.4P , additional homework tip  1

Figure (1)

Write the expression to calculate the area on which the load will act on the truss.

A=2×h×lt ...... (I)

Here, the area on which the load will act is A, the hypotenuse length of the truss is h and the length of the truss is lt.

Calculate the value of the hypotenuse length of the truss.

h=82+402ft=1664ft=40.79ft

Here, the hypotenuse height EH of ΔAEH is h.

Substitute 40.79ft for h and 25ft for lt in Equation (I).

A=2×(40.79ft)×(25ft)=2040ft2

Write the expression to calculate the total dead load.

D=(MD+R+P)A+(Tw×PA) ...... (II)

Here, the total dead load is D, the metal deck load is MD, the roof load is R, the purlin load is P, the truss load is Tw and the projection area is PA.

Substitute 4psf for MD, 12psf for R, 6psf for P, 2040ft2 for A, 5psf for Tw and 2000ft2 for PA in Equation (II).

D=((4psf+12psf+6psf)×(2040ft2))+(5psf×2000ft2)=44880lb+10000lb=54880lb

Write the expression to calculate the load per truss.

DL=DNT ...... (III)

Here, the dead load per truss is DL, the number of trusses is NT.

Substitute 54880lb for D and 8 for NT in Equation (III).

DL=54880lb8=6860lb

Write the expression to calculate the snow load per truss.

S=SL×PANT ...... (IV)

Here, the snow load per truss is S and the snow load is SL.

Substitute 18psf for SL, 8 for NT and 2000ft2 for PA in Equation (IV).

S=(18psf)×(2000ft2)8=4500lb

Write the expression to calculate the factored load by LRFD.

Pn=1.2DL+1.6S ...... (V)

Here, the factored load is Pn.

Substitute 6860lb for DL and 4500lb for S in Equation (V).

Pn=(1.2×6860lb)+(1.6×4500lb)=(15432lb)(1kips1000lb)=15.43kips

The free body diagram of join E is shown below.

STEEL DESIGN W/ ACCESS, Chapter 3, Problem 3.8.4P , additional homework tip  2

Figure (2)

Here, the vertical reaction at support E is R and the force members are FEF and FDE.

Write the expression to calculate the value of R.

R=NS×Pn2 ...... (VI)

Here, the number of spans is NS.

Substitute 8 for NS and 15.43kips for Pn in Equation (VI).

R=8×15.43kips2=61.72kips

Consider the forces in vertical equilibrium.

RVHhFDE=0 ...... (VII)

Here, the vertical height is VH.

Substitute 8ft for VH, 61.72kips for R and 40.79ft for h in Equation (VII).

61.72kips8ft(82+402)ftFDE=0FDE=61.72kips8ft(82+402)ftFDE=314.7kips

Consider the force in horizontal equilibrium.

FDE×(40ft40.79ft)FFE=0

Substitute 314.7kips for FDE.

(314.7kips)×(40ft40.79ft)FFE=0FFE=308.61kips

Write the expression to calculate the gross area.

Ag=FFE0.9Fy ...... (VIII)

Here, the yield strength is Fy and the required gross area is Ag.

Substitute 308.61kips for FFE and 50ksi for Fy in Equation (VIII).

Ag=308.61kips0.9×50ksi=6.858in2

Write the expression to calculate the effective area.

Ae=FFE0.75Fu ...... (IX)

Here, the ultimate strength is Fu and the required effective area is Ae.

Substitute 308.61kips for FFE and 65ksi for Fy in Equation (IX).

Ae=308.61kips0.75×65ksi=6.33in2

Write the expression to calculate the radius of gyration.

rmin=L300 ...... (X)

Here, the length of the member is L and the minimum radius of gyration is rmin.

Substitute 25ft for L in Equation (X).

rmin=10ft×(12in1ft)300=0.4in

From the above calculated values try double angle section 2L6×L6×716.

The properties for 2L6×L6×716 section from AISC steel manual are as follows.

  • The gross area (Ag) is 10.2in2.
  • The radius of gyration is 1.86in.

The gross area of the section is greater than the required gross area of 6.858in2.

Thus, the section in terms of gross area is ok.

The radius of gyration of the section is greater than the required radius of gyration of 0.4in.

Thus, the section in terms of radius of gyration is ok.

Write the expression to calculate the effective net area.

Ae=UAg ...... (XI)

Here, the effective net area is Ae and the shear lag factor is U.

Substitute 10.2in2 for An and 0.85 for U in Equation (XI).

Ae=0.85×10.2in2=8.67in2

The section’s effective area is greater than the required area of 6.33in2.

Thus, the section in terms of effective area is ok.

For the web members.

The maximum force occurs at AH.

Calculate the length of member of member HG.

L=82+102ft=12.81ft

Here, the length of the member HG is L.

Consider the moment about E.

812.81FAH×(25ft)(15.42×60)k-ft=0FAH=(925.28×2512.81)kipsFAH=59.26kips

Here, the force on the member AH is FAH.

Write the expression to calculate the gross area of the member.

Ag=FAH0.9Fy ...... (XII)

Substitute 59.26kips for FAH and 50ksi for Fy in Equation (XII).

Ag=59.26kips0.9×50ksi=1.32in2

Write the expression to calculate the effective area.

Ae=FAH0.75Fu ...... (XIII)

Here, the ultimate strength is Fu and the required effective area is Ae.

Substitute 59.26kips for FFE and 65ksi for Fu in Equation (XIII).

Ae=59.26kips0.75×65ksi=1.22in2

Calculate the radius of gyration.

Substitute 12.81ft for L in Equation (X).

rmin=(12.81ft)×(12in1ft)300=0.51in

From the above calculated values try double angle section 2L3×L2×316.

The properties for 2L6×L6×716 section from AISC steel manual are as follows.

  • The gross area (Ag) is 1.83in2.
  • The radius of gyration is 0.577in.

The gross area of the section is greater than the required gross area of 1.32in2.

Thus, the section in terms of gross area is ok.

The radius of gyration of the section is greater than the required radius of gyration of 0.512in.

Calculate the effective area.

Substitute 1.83in2 for An and 0.85 for U in Equation (XI).

Ae=0.85×1.83in2=1.55in2

The effective area of the section is greater than the required effective area of 1.22in2.

Thus, the section in terms of effective area is ok.

Conclusion:

The double angle section 2L6×L6×716 is safe in terms of gross area, the radius of gyration and the effective area for the bottom chord.

Thus, the double angle section to be selected for the bottom chord by LFRD method is 2L6×L6×716.

The double angle section 2L3×L2×316 is safe in terms of gross area, the radius of gyration and the effective area for the web members.

Thus, the double angle section to be selected for the web members by LFRD method is 2L3×L2×316.

To determine

(b)

The double angle section for a tension member using Allowed Strength Design (ASD) method.

Expert Solution
Check Mark

Answer to Problem 3.8.4P

The double angle section to be selected for the bottom chord by ASD method is 2L6×L6×716.

The double angle section to be selected for the web members by ASD method is 2L3×L2×316.

Explanation of Solution

Calculation:

Write the expression to calculate the factored load using ASD.

Pn=DL+S ...... (XIV)

Substitute 6860lb for DL and 4500lb for S in Equation (XIV).

Pn=6860lb+4500lb=11360lb(103kips1lb)=11.3kips

Calculate the vertical reactions R.

Substitute 8 for NS and 11.3kips for Pn in Equation (VI).

R=8×11.3kips2=45.2kips

Calculate the value of force in the member DE.

Substitute 8ft for VH, 45.2kips for R and 40.79ft for h in Equation (VII).

45.2kips8ft40.79ftFDE=0FDE=45.2kips8ft40.79ftFDE=230.5kips

Consider the force in horizontal equilibrium.

FDE×(40ft40.79ft)FFE=0

Substitute 230.5kips for FDE.

230.5kips×(40ft40.79ft)FFE=0FFE=226.04kips

Write the expression to calculate the required gross area.

FFE=0.6FyAg ....... (XV)

Substitute 50ksi for Fy and 226.04kips for FFE in Equation (XV).

226.04kips=0.6×50ksi×AgAg=226.04kips0.6×50ksiAg=7.53in2

Write the expression to calculate the net area.

FFE=0.5FuAn ...... (XVI)

Substitute 65ksi for Fu and 226.04kips for FFE in Equation (XVI).

226.04kips=0.5×65ksi×AeAe=226.04kips0.5×65ksiAe=6.95in2

From the above calculated values try double angle section 2L6×L6×716.

The properties for 2L6×L6×716 section from AISC steel manual are as follows.

  • The gross area (Ag) is 10.2in2.
  • The radius of gyration is 1.86in.

The gross area of the section is greater than the required gross area of 7.53in2.

Thus, the section in terms of gross area is ok.

The radius of gyration of the section is greater than the required radius of gyration of 0.4in.

Thus, the section in terms of radius of gyration is ok.

The section’s effective area is greater than the required area of 6.95in2.

Thus, the section in terms of effective area is ok.

For the web members.

The maximum force occurs in the member AH.

Consider the moment about E.

812.81FAH×25ft11.3kips×60ft=0FAH=(6788×2512.81)kipsFAH=43.43kips

Write the expression to calculate the required gross area.

FAH=0.6FyAg ....... (XVII)

Substitute 50ksi for Fy and 43.43kips for FAH in Equation (XVII).

43.43kips=0.6×50ksi×AgAg=43.43kips0.6×50ksiAg=1.45in2

Write the expression to calculate the net area.

FAH=0.5FuAn ...... (XVIII)

Substitute 65ksi for Fu and 43.43kips for FAH in Equation (XVIII).

43.43kips=0.5×65ksi×AeAe=43.43kips0.5×65ksiAe=1.33in2

From the above calculated values try double angle section 2L3×L2×316.

The properties for 2L6×L6×716 section from AISC steel manual are as follows.

  • The gross area (Ag) is 1.83in2.
  • The radius of gyration is 0.577in.

The gross area of the section is greater than the required gross area of 1.32in2.

Thus, the section in terms of gross area is ok.

The radius of gyration of the section is greater than the required radius of gyration of 0.512in.

The effective area of the section is greater than the required effective area of 1.33in2.

Conclusion:

The double angle section 2L6×L6×716 is safe in terms of gross area, the radius of gyration and the effective area for the bottom chord.

Thus, the double angle section to be selected for the bottom chord by ASD method is 2L6×L6×716.

The double angle section 2L3×L2×316 is safe in terms of gross area, the radius of gyration and the effective area for the web members.

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