6. The m kg crate shown in Figure 6 is hoisted up bythe incline using the cable and motor M. For aKt2short time, the force in the cable is F%3Dnewton wheret is in seconds. If the crate has aninitial velocity v12 m/s when ts,||Draw the free body diagram of the problem.b. Determine the velocity when t = 2 s. Thecoefficient of kinetic friction between the crate15and the incline is uk = 0.3.Figure 6.618K =%3D147.6m =kg

Answered: Image /qna-images/answer/81ef7c88-5ad6-406e-b92f-f6b2a8a6e4ed.jpg

6. The m kg crate shown in Figure 6 is hoisted up by the incline using the cable and motor M. For a short time, the force in the cable is F = = Kt2 newton where t is in seconds. If the crate has an initial velocity vị 2 m/s when t = 0 s, a. Draw the free body diagram of the problem. b. Determine the velocity when t = 2 s. The %3D coefficient of kinetic friction between the crate and the incline is uk = 0.3. 618 K = 147.6 m = kg

6. The m kg crate shown in Figure 6 is hoisted up by the incline using the cable and motor M. For a short time, the force in the cable is F = = Kt2 newton where t is in seconds. If the crate has an initial velocity vị 2 m/s when t = 0 s, a. Draw the free body diagram of the problem. b. Determine the velocity when t = 2 s. The %3D coefficient of kinetic friction between the crate and the incline is uk = 0.3. 618 K = 147.6 m = kg

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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