The super-container vessel in the figure has a total mass displacement of 23000 long tons. This vessel towed by a tugboat with a=20° angle with horizontal. If a constant tension is applied as F=320 kN by the tugboat, please calculate the time to bring the vessel to a speed of 2 knot from the rest. At these low speeds, please neglect the hull resistance that created by the motion. Note: (1 long tons = 1016.05 kg, 1 knot=1.151 mi/hr= 0.5144 m/s)

The super-container vessel in the figure has a total mass displacement of 23000 long tons. This vessel towed by a tugboat with a=20° angle with horizontal. If a constant tension is applied as F=320 kN by the tugboat, please calculate the time to bring the vessel to a speed of 2 knot from the rest. At these low speeds, please neglect the hull resistance that created by the motion. Note: (1 long tons = 1016.05 kg, 1 knot=1.151 mi/hr= 0.5144 m/s)

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Description: The super-container vessel in the figure has a total mass displacement of 23000 longtons. This vessel towed by a tugboat with a=20° angle with horizontal. If a constanttension is applied as F=320 kN by the tugboat, please calculate the time to bring

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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