(please type answer no write by hend) **Problem: Calculating Force in a Rotating System**The crank \( OA \) rotates in the vertical plane with a constant clockwise angular velocity \( \omega_0 \) of 2.8 rad/s. For the position where \( OA \) is horizontal, calculate the force under the light roller \( B \) of the 18.1-kg slender bar \( AB \).**Diagram Explanation:**The diagram shows a mechanical system with the following components and dimensions:- A crank \( OA \) with a length of 0.51 meters.- A slender bar \( AB \), which is 1.30 meters long.- The bar \( AB \) is positioned vertically downward when the crank \( OA \) is horizontal, with a vertical distance from point \( O \) to point \( B \) measuring 1.02 meters.- The angular velocity \( \omega_0 \) is indicated at the pivot \( O \).**Solution:**To solve for the force \( F_B \) under the roller \( B \):\[ F_B = \]**Answer:** Enter the calculated force in Newtons (N) in the space provided.

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Answered: The crank OA rotates in the vertical…

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

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The crank OA rotates in the vertical plane with a constant clockwise angular velocity wo of 2.8 rad/s. For the position where OA is horizontal, calculate the force under the light roller B of the 18.1-kg slender bar AB. 1.02 m B 0.51 m 1.30 m