Understanding Torque: Magnitude and Direction

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Discussion Overview

The discussion revolves around the concept of torque, specifically focusing on the relationship between force vectors, their application points, and how these factors influence the production of torque. Participants explore definitions, vector properties, and the implications of moving force vectors in different contexts.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested

Main Points Raised

  • Some participants assert that moving a force vector does not change its magnitude or direction, but question how this affects torque.
  • Others emphasize that torque involves two vectors and that the position of the force vector is crucial in determining the resulting torque.
  • One participant argues that applying the same force at different locations can lead to different rotational effects, highlighting the importance of the position vector in torque calculations.
  • Another point raised is that torque is defined as the cross product of the distance vector and the force vector, suggesting that changing the position of the force vector alters the torque's direction.
  • Some participants express confusion over the definitions and implications of moving force vectors, while others attempt to clarify these concepts.

Areas of Agreement / Disagreement

Participants do not reach a consensus on the implications of moving force vectors in relation to torque. There are multiple competing views regarding the significance of vector positions and the definitions of torque.

Contextual Notes

There are unresolved assumptions regarding the definitions of vectors and torque, as well as the conditions under which force vectors can be treated as free vectors versus localized vectors.

gracy
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electr5.gif

As we know all vectors with the same magnitude and direction are equal despite their different locations.so we can move the force vector such that
TOR.png

Now how will it produce torque?Please tell me where am i getting wrong?
TOR.png
 
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gracy said:
Now how will it produce torque?
The definition of torque contains two vectors, not just the force vector.
 
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But other force vector is also there ,there are two vectors!
 
gracy said:
Now how will it produce torque?
here it implies this system containing two vectors!
 
gracy said:
But other force vector is also there ,there are two vectors!
Look up the definition of torque. What vectors are there?
 
gracy said:
Please tell me where am i getting wrong?
You cannot move force vectors like that. Where did you learn that you could?

You can replace a force vector with another force vector and a couple.
 
DaleSpam said:
You can replace a force vector with another force vector and a couple.
Sorry,but I did not understand.
 
DaleSpam said:
You cannot move force vectors like that. Where did you learn that you could?
Kindly look at
upload_2015-9-9_18-39-41.png
 
Gracy, if you move the vector, it isn't the same vector. It might be parallel to the initial one and of the same magnitude, but where the force is applied is important. That picture you posted does state that moving the vector doesn't change it, but if you read on, it states that changing the position vector, at least in this case, does not change magnitude or direction. In a physical situation, the position is important.
Take this example, the Earth goes around the sun. There's a force that pulls the Earth towards the sun and if you were to draw a vector diagram it would be an arrow with the tail at the Earth's centre of mass and the head pointing towards the sun. Now say you move this vector over to a point on the circumference of the earth. Then that force would be applying a torque on the Earth which would make it spin much faster than it is right now and we would all be quite dizzy. But that isn't the case.
So you see, in a physical situation, the position of the vector does matter and you can't move it somewhere without changing the physics of the situation.
 
  • #10
gracy said:
Kindly look at
Kindly look at the definition of torque. It involves what is called "tail" in your reference.
 
  • #11
gracy said:
Kindly look at
I see your confusion. The link is primarily teaching about vectors, but it does explicitly mention force and velocity as generic examples of vectors. There are some caveats that were not made clear in the article.

IF you are only interested in the motion of the center of mass THEN you can treat force as a free vector. Otherwise, force is a localized vector for exactly the reason that you showed. If you apply the same force (magnitude and direction) at different locations the center of mass will move the same, but the rotations and deformations will generally be different.
 
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  • #12
Another thing you'll should know is that torque is a vector quantity. It is the cross product of the distance vector and the force vector. If you don't know what a cross product is, look it up.
The important point here is the fact that you're using a distance VECTOR. So, even though, when you move your force vector as shown,your force vector is essentially the same, your distance vector has changed. Its magnitude is the same but its direction is opposite, hence you get the wrong direction for the torque and the two torqyes seem to cancel each other out.
 
  • #13
UncertaintyAjay said:
the two torqyes
Two forces,you meant?
 
  • #14
Torques. The forces cancel each other out even in the first diagram where the force vector hasn't been moved. That's why the dipole doesn't have any translational motion. It only rotates. But in the first diagram,the torques add up, in the second they cancel each other out.
 
  • #15
You should have listened to what A.T said in his first two posts and googled this. Would have saved you a lot of confusion.
 
  • #16
UncertaintyAjay said:
If you don't know what a cross product is, look it up.
obviously I know!
 
  • #17
UncertaintyAjay said:
You should have listened to what A.T said in his first two posts and googled this. Would have saved you a lot of confusion.
I am not confused.
 
  • #18
Okay, that cross product thing was in case you didn't know. It is in no way a disparaging comment or something.
 
  • #19
UncertaintyAjay said:
disparaging comment or something.
Why would it be?i just meant it is very basic.
 
  • #20
Ohhh,
 

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