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MCQ
3. A masonry dam (density = 20,000 N/m3) 6 m high, one metre wide at the top and 4 m wide at the base, has vertical water face. The minimum stress at the base of the dam when the reservoir is full, will be --
75 N/m2
750 N/m2
7500 N/m2
75000 N/m
6. A load of 1960 N is raised at the end of a steel wire. The minimum diameter of the wire so that stress in the wire does not exceed 100 N/mm2 is:
4.0 mm
4.5 mm
5.0 mm
5.5 mm
7. A compound truss may be formed by connecting two simple rigid frames, by --
Two bars
Three bars
Three parallel bars
Three bars intersecting at a point
10. A bar L metre long and having its area of cross- section A, is subjected to a gradually applied tensile load W. The strain energy stored in the bar is --
WL/2AE
WL/AE
WIL/AE
W^2L/2AE
11. The maximum deflection due to a uniformly distributed load w/unit length over entire span of a cantilever of length 1 and of flexural rigidly EI, is --
wl3/3El
wl4/3E1
wl4/8EI
wl4/12E1
12. A spring of mean radius 40 mm contains 8 action coils of steel (N80000 N/mm2), 4 mm in diameter. The clearance between the coils being 1 mm when unloaded, the minimum compressive load to remove the clearance, is --
25 N
30 N
35 N
40 N
14. If a concrete column 200 x 200 mm in cross- section is reinforced with four steel bars of 1200 mm2 total cross-sectional area. Calculate the safe load for the column if permissible stress in concrete is 5 N/mm2 and Es is 15 Ec
264 MN
274 MN
284 MN
294 MN
15. An isolated load W is acting at a distance a from the left hand support, of a three hinged arch of span 21 and rise h hinged at the crown, the horizontal reaction at the support, is--
Wa/h
Wa/2h
2W/ha
2h/Wa
16. The ratio of the area of cross-section of a circular section to the area of its core, is--
Material is homogeneous
Material is isotropic
Young's modulus is same in tension as well as in compression
All the above
17. At any point of a beam, the section modulus may be obtained by dividing the moment of inertia of the section by--
Depth of the section
Depth of the neutral axis
Maximum tensile stress at the section
Maximum compressive stress at the section
18. At any point of a beam, the section modulus may be obtained by dividing the moment of inertia of the section by--
Depth of the section
Depth of the neutral axis
Maximum tensile stress at the section
Maximum compressive stress at the section
19. The forces acting normally on the cross section of a bar shown in the given figure introduce--
Compressive stress
Tensile stress
Shear stress
None of these
20. For determining the force in the member AB of the truss shown in the given figure by method of sections, the section is made to pass through AB, AD and ED and the moments are taken about
Joint C
Joint B
Joint D
Joint A