9. The thin ( 3 mm ) thick plastic panel shownin the figure is lowered from a ship to asitethefloor.Theconstructiononосeanplastic panel weighs ( 200 N ) in air and isCablelowered at a rate of ( 2 m/s ). Assuming thediyspanel remains vertically oriented, calculate= 1000ingthe tension force in the cable. Take ( p = 110 m/s ), andwater Plastickg/m', v1.31use;%3DPunel上.-3m.1/21/5Cplam = 1.328 / ReCpturb = 0.072 / Rej.

Weight = 200 N Thickness = 3 mm velocity = 2 m/s density = 1000 kg/m3 Find tension in the cable

9. The thin ( 3 mm ) thick plastic panel shown in the figure is lowered from a ship to a construction site on the ocean floor. The plastic panel weighs ( 200 N ) in air and is lowered at a rate of ( 2 m/s ). Assuming the panel remains vertically oriented, calculate the tension force in the cable. Take ( p = 1000 kg/m', v = 1.31 * 10“ m²/s ), and use; %3D *

9. The thin ( 3 mm ) thick plastic panel shown in the figure is lowered from a ship to a construction site on the ocean floor. The plastic panel weighs ( 200 N ) in air and is lowered at a rate of ( 2 m/s ). Assuming the panel remains vertically oriented, calculate the tension force in the cable. Take ( p = 1000 kg/m', v = 1.31 * 10“ m²/s ), and use; %3D *

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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9. The thin ( 3 mm ) thick plastic panel shown in the figure is lowered from a ship to a construction site on the осean Поог. The plastic panel weighs ( 200 N) in air and is lowered at a rate of ( 2 m/s ). Assuming the ship Cble panel remains vertically oriented, calculate the tension force in the cable. Take ( p = 1000 10 m/s ), and use; kg/m', v 1.31 water Plustic Punel Cplam = 1.328/ Re, Cpturb = 0.072/Re 1/5
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9. The thin ( 3 mm ) thick plastic panel shown in the figure is lowered from a ship to a construction site on the ocean floor. The plastic panel weighs ( 200 N) in air and is lowered at a rate of ( 2 m/s ). Assuming the ship Cble panel remains vertically oriented, calculate ing the tension force in the cable. Take ( p = 1000 * 10* m²/s ), and use; water Plastic funel kg/m', v = 1.31 m Colam = 1.328 / Re Cpturb = 0.072 / Re
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