Task III Based on Figure 3. Use the D’Alembert's principle to determine the following knowing that the coefficient of friction p=0.2, O=45°, and the acceleration of gravity g=9.81 m/s². You have to show the free body diagrams and all steps of your solution. A. The expression of the acceleration of the two masses in terms of mj and m2. B. The tension in the rope in terms of m¡ and m2. C. If m¡ = K kg, m2 = (K+5) kg, determine the acceleration of two blocks and the tension in the rope. (k= the final two numbers of your ID +10, and, gravitational acceleration, g = 9.81 m/s³).

Elements Of Electromagnetics
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ISBN:9780190698614
Author:Sadiku, Matthew N. O.
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a
g=9.81m/s²
m2
-H=0.2
m1
45%
Figure 3: a pulley with two masses
Transcribed Image Text:a g=9.81m/s² m2 -H=0.2 m1 45% Figure 3: a pulley with two masses
Task III
Based on Figure 3. Use the D'Alembert's principle to determine the following knowing that the coefficient of
friction u=0.2, 0=45°, and the acceleration of gravity g=9.81 m/s². You have to show the free body diagrams
and all steps of your solution.
A. The expression of the acceleration of the two masses in terms of mi and m2.
B. The tension in the rope in terms of mi and m2.
C. If mi = K kg, m2 = (Á+5) kg, determine the acceleration of two blocks and the tension in the rope.
(k= the final two numbers of your ID +10, and, gravitational acceleration, g = 9.81 m/s²).
Transcribed Image Text:Task III Based on Figure 3. Use the D'Alembert's principle to determine the following knowing that the coefficient of friction u=0.2, 0=45°, and the acceleration of gravity g=9.81 m/s². You have to show the free body diagrams and all steps of your solution. A. The expression of the acceleration of the two masses in terms of mi and m2. B. The tension in the rope in terms of mi and m2. C. If mi = K kg, m2 = (Á+5) kg, determine the acceleration of two blocks and the tension in the rope. (k= the final two numbers of your ID +10, and, gravitational acceleration, g = 9.81 m/s²).
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