Foundation Design: Principles and Practices (3rd Edition)
3rd Edition
ISBN: 9780133411898
Author: Donald P. Coduto, William A. Kitch, Man-chu Ronald Yeung
Publisher: PEARSON
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Textbook Question
Chapter 7, Problem 7.24QPP
Two columns, A and B, are to be built 6 ft 0 in apart (measured from their centerlines). Column A has a vertical downward dead load and live loads of 90 k and 80 k, respectively. Column B has corresponding loads of 250 k and 175 k. The dead loads are always present, but the live loads may or may not be present at various times during the life of the structure. It is also possible that the live load would be present on one column, but not the other. These two columns are to be supported on a 4 ft 0 in deep rectangular spread footing founded on a soil with the following parameters:
- The location of the resultant of the loads from columns A and B depends on the amount of live load acting on each at any particular time. Considering all of the possible loading conditions, how close could it be to column A? To column B?
- Using the results of part (a), determine the minimum footing length, L, and the location of the columns on the footing necessary to keep the resultant force within the middle third of the footing under all possible loading conditions. The footing does not need to be symmetrical. The footing must extend at least 24 in beyond the centerline of each column.
- Determine the minimum required footing width, B, to maintain a factor of safety of at least 2.5 against a bearing capacity failure under all possible loading conditions.
- If the B computed in part c is less than the L computed in part (b), then use a rectangular footing with dimensions
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A steel channel is used as a purlin of a truss. The top chord of the truss is inclined at a slope of 1
vertical to 4 horizontal and the distance between the trusses is equal to 6m. The purlin has a weight
of 79 N/m and is spaced at 1.2m on centers. The dead load including the roof materials is 720 Pa, the
live load is known to be 1000 Pa and it is subjected to a wind load of 1440 Pa. The coefficient of
pressure at leeward and windward are 0.6 and 0.2 respectively.
Properties of C200 x 76mm
Sx = 6.19x10^4 mm^3
Sy = 1.38x10^4 mm^3
W = 79 N/m
Allowable bending stress
• Fbx = Fby = 207 MPa
Assume all loads passes through the centroid.
Determine the maximum bending stress for a load combination of 0.75(D + L+W)
127.11
256.17
181.15
129.06
Determine the maximum ratio of the actual to the allowable bending stress for load combination of
0.75(D + L + W).
0.90
O 1.25
1.54
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127.11
170.73
169.48…
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55 MPa
التحديد
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Determine the maximum BM
occurs for the beam shown
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3 kN/m
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2m
4 m
-24 kNm O
-48 kNm
-12 kNm
- 96 kNm
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FOR THE RIGID BEAM SHOWN
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2- Calculate the design ultimate load Wu on the on the
beams B1,B2, B3, B4
3.6 m
4.8
4 m
Assume:
DL = 6 kN/m²
LL = 4 kN/m2
Beam size = 400x750 mm
10 m
B1
B2
B3
B4
Chapter 7 Solutions
Foundation Design: Principles and Practices (3rd Edition)
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