International Edition---engineering Mechanics: Statics, 4th Edition
4th Edition
ISBN: 9781305501607
Author: Andrew Pytel And Jaan Kiusalaas
Publisher: CENGAGE L
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Chapter 6, Problem 6.63P
The cable of the suspension bridge spans
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Cable AB supports the uniformly distributed load of
4 kN/m. If the slope of the cable at A is zero,
compute (a) the maximum tensile force in the cable;
and (b) the length of the cable
B
50 m
4 kN/m
Tmax = 250 kN; S = 70 m
Tmax = 300 kN; S = 75 m
Tmax = 350 kN ; S = 80 m
Tmax = 400 kN; S = 85 m
40 m
A
O
O
3. The rigid bar AB is supported by two rods made of the same material. If the bar is horizontal before
the load P is applied, find the distance x that locates the position where P must act if the bar is to
remain horizontal. Neglect the weight of bar AB.
L = 3 ft
A = 0.2 in.2
L = 2 ft
A = 0.4 in.2
х
X
B
10 ft
F1
2m
F2
A
3.2m
1.8m
AF, = 153 N load and a F, = 99 N are applied to the frame which is supported by pins at A and B. These loads are applied perpendicular to the beams. The two beams AC and BC make a
right triangle. You may neglect the weight of the members.
Find the magnitude of the force at pin C. For this problem, use the coordinate frame given.
1.5 m
4------
1.5 m
+-----
2.4m
Chapter 6 Solutions
International Edition---engineering Mechanics: Statics, 4th Edition
Ch. 6 - Determine the internal force system acting on...Ch. 6 - Determine the internal force system acting on...Ch. 6 - Determine the internal force system acting on...Ch. 6 - Find the internal force systems acting on sections...Ch. 6 - Find the internal force systems acting on sections...Ch. 6 - Find the internal force systems acting on sections...Ch. 6 - The three identical cantilever beams carry...Ch. 6 - Determine the internal force systems acting on...Ch. 6 - For the structural component shown, determine the...Ch. 6 - Compute the internal force system acting on...
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- The simply supported beam below has two different distributed loads acting on it. In the first section, the distributed load has a constant value of w = 20 kN/m. In the second section, the distributed load has a constant value of v= 6 kN/m. If the loads were to be replaced by a single load H such that the two loadings are equivalent, then what would the distance d need to be in m? W A 2m 1m V B d H↓↓ Barrow_forwardThe cable carrying 60-lb loads at B and C is held in the position shown by the horizontal force P = 80 lb applied at A. Determine the following: Find the vertical load Ay acting on the frame at support A. Find the vertical load By acting on the frame at pin B. Find the horizontal load Cx acting on the frame at support C. Find the vertical load Cy acting on the frame at support C. Find the horizontal load Ax acting on the frame at support A.arrow_forward5. The cable supports the three loads shown. Determine the magnitude of P1 if P2 = 600 N and yn = 3 m. Also find sag yp 1 m |E Ув YD 4 m B D C P2 P, P - 3 m - 6 m 6 m - - 3 marrow_forward
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