Structural Steel Design (6th Edition)
6th Edition
ISBN: 9780134589657
Author: Jack C. McCormac, Stephen F. Csernak
Publisher: PEARSON
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Question
Chapter 10, Problem 10.1PFS
To determine
To Select: The lightest section for the continuous beam in the figure using the LFRD method, use elastic method, and factored loads and
Expert Solution & Answer
Answer to Problem 10.1PFS
Explanation of Solution
Given:
The continuous beam is shown below.
And steel is
Calculation:
Compute the factored acting on the beam using the equation.
Draw the bending moment diagram with maximum and minimum values.
Using
Calculate the maximum factored positive moment of the beam.
Select a W-section from table 3.2 of the AISC Manual such that.
Since,
Therefore, use
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Students have asked these similar questions
An 80-foot long plate girder (see below) is fabricated from a ½-inch x 78-inch web and two 3inch x 22-inch flanges. Continuous lateral support is provided. The steel is A992. The loading consists of a uniform service dead load of 1.0 kip/ft (including the self-weight), a uniform service live load of 2.0 kips/ft, and a concentrated service live load of 500 kips at midspan. Stiffeners are placed at each end and at 4 feet, 16 feet, and 28 feet from each end. Once stiffener is placed at midspan. Determine whether the flexural strength is adequate using LRFD.
A girder supports concentrated dead and live loads. Determine the following required
strengths for the girder based on the controlling load combinations.Use statics or Table 3-22a from the Steel Manual.
The maximum bending moment, MD (kip-ft), due to dead load.
The maximum bending moment, ML (kip-ft), due to live load.
ASD required flexural strength, Ma (kip-ft)
LRFD required flexural strength, Mu (kip-ft)
A W 16 x50 is used as a beans to carry a uniform we and dead load including own weight of 37 kN/m and an axial tension load of T acting through the centroid, of the member. It has a simple span of 5.7 m. The compression flange of the member is laterally supported against local buckling.Use A 36 steel, Fy = 248 MPa.Properties of W 16x 50A = 9483.85 mm^2d= 412.75 mmbf= 179.65 mmtf= 15 95 mmtw= 9.65 mmSx= 1324 × 10^3 mm^3Sy = 172 x 10^3 mm^3
Questions:Determine the Safe axial load T that the beam could carry
Hint Answer: 432.69 KN
Chapter 10 Solutions
Structural Steel Design (6th Edition)
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