"The condition of equilibrium is when the sum of the forces acting on a body is the zero vector. Suppose a body has a force of 2 pounds acting on it to the right, 5 pounds acting on it upward, and 3 pounds acting on it 45° from the horizontal. What single force is needed to produce a state of equilibrium on the body?"

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AmeerAbdullah AmeerAbdullah · Answer 1 · 2020-06-02T03:27:35+02:00

Answer:

The answer is [tex]F= 2.881[/tex] pounds

Explanation:

We will start this question by representing the force vectors in Cartesian coordinate system:

Let the single force we need be represented by [tex]F=(x,y)[/tex]

Since, the body is in equilibrium the summation of all the forces acting on it should be zero:

∑[tex]F_{x} = 0[/tex] (Sum of all forces in [tex]x[/tex] direction is equal to zero)

[tex]x + 2 - 3cos(45) =0[/tex] ([tex]x[/tex] component of force 3 is negative because it is acting in opposite direction)

[tex]x = 0.1213[/tex]

∑[tex]F_{y}=0[/tex] (Sum of all forces in [tex]y[/tex] direction is equal to zero)

[tex]y+5-3sin(45)=0[/tex] ([tex]y[/tex] component of force 3 is negative because it is acting in opposite direction)

[tex]y=-2.8786[/tex]

So,

[tex]F=(0.1213,-2.8786)[/tex]

Hence, to get the scalar quantity of a single force:

[tex]F=\sqrt[2]{(0.1213)^{2}+(-2.8786)^{2} }[/tex]

[tex]F= 2.881[/tex] pounds