Force Acting on Rope: Homework Solutions

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The discussion revolves around a physics homework problem involving a 10 kg picture hanging by two ropes. The main questions are whether the forces on ropes A and B are equal and how to calculate the force on rope A. The accepted answer for the force on rope A is 49N, derived from the gravitational force and the angle of the rope, but there is confusion regarding the horizontal component and the overall force distribution. Participants suggest using Lami's theorem and resolving the weight into components to understand the equilibrium better. The conversation highlights the need for clarity in visualizing the forces acting on the ropes to solve the problem accurately.
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Homework Statement


From http://library.thinkquest.org/10796/index.html (#6b, 6c)
A 10 kg picture is hanging on a wall by two ropes.
http://library.thinkquest.org/10796/ch5/IMG00008.GIF
...
b. Are the forces acting on the ropes A and B equal in magnitude?
c. How big is the force acting on the rope A?

The site accepts the answer 49N for #6c, but I'm not sure why.

Homework Equations


F_g=mg
F=\sqrt{F_x^2+F_y^2}
F_x=F\times \cos \theta

The Attempt at a Solution


The answer for #6c appears to be equal to
10\textrm{kg}\times 9.80\textrm{m/s}^2\times \textrm{cos }60^\circ=49\textrm{N,}
but that doesn't make sense to me; shouldn't we combine the weight of the picture with the rightward pull? In that case, how do we find the rightward pull?

Or, is there an imaginary diagonal force--equal in magnitude to the gravitational force--of which we want the horizontal component? In that case, why?

The answer to #6b is "No," but I'm not sure why. (I'm guessing that once I understand #6c, then #6b will follow.)

Thank you!
 
Last edited:
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Actually, I suppose that combining the force of gravity in this case (98N) with a horizontal vector couldn't reduce the magnitude to just 49N...
Is it the second option that I proposed, then? \sqrt{F_g^2\ \textrm{cos}^2\theta +F_g^2\ \textrm{cos}^2(90^\circ-\theta)}=F_g\textrm{,} so it seems plausible. The forces on the ropes, not including from the wall or ceiling where they're above, should add up to the force exerted by the picture, right?

Still, even if I've found the way to do the problem, I don't feel like I have a sufficient understanding of it.
 
You can resolve mg to 2 components of opposing direction to A and B since they are 90° apart.
To me it is mgCos30°.
 
azizlwl said:
You can resolve mg to 2 components of opposing direction to A and B since they are 90° apart.
To me it is mgCos30°.
I'm sorry; I don't understand what you mean. Would you mind drawing it?

Would it be something like this?
34j3y9k.png

mg\textrm{cos(30}^\circ \textrm{)}

EDIT - whoops, sorry, I edited without realizing you had posted again.
 
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intdx said:
I'm sorry; I don't understand what you mean. Would you mind drawing it?

Just extend line A and B downward. These 2 directions can be components of mg.
 
Hello intdx,
Try Lami's theorem here.Or otherwise resolve the weight along OA and OB to check for equilibrium.
regards
Yukoel
 

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