Calculate the magnitude of the acceleration of glider B.Answer: a = im/s? The 245-kg glider Bis being towed by airplane A, which is flying horizontally with a constant speed of v = 183 km/h. The tow cable hasa length r = 59 m and may be assumed to form a straight line. The glider is gaining altitude and when e reaches 14°, the angle isincreasing at the constant rate 0 = 8 deg/s. At the same time the tension in the tow cable is 2370 N for this position. Calculate theaerodynamic lift L and drag D acting on the glider.Assume o = 10°.DBA

Answered: Image /qna-images/answer/7dd6a4fe-e8dd-4f4a-bd5d-cd76d00a85a3.jpg

Answered: The 245-kg glider B is being towed by…

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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The 3950-lb van is driven from position A to position B on the barge, which is towed at a constant speed vo= 6 mi/hr. The van starts from rest relative to the barge at A, accelerates to v= 17 mi/hr relative to the barge over a distance of d = 73 ft, and then stops with a deceleration of the same magnitude. Determine the magnitude of the horizontal force F between the tires of the van and the barge during this maneuver. Answer: F= i + B lb
Problem 7) (14-90 from Hibbeler Text): When the 5-kg box (traveling to the left) reaches point A it has a speed va = 10 m/sec. Determine the normal force the box exerts on the surface when it reaches point B. Neglect friction. Note that the coordinates x and y are in meters. y = x 9 m B x/2 + y!/2 = 3 9 m
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