What Happens to Normal Force on a Slanted Plank?

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Discussion Overview

The discussion revolves around the behavior of the normal force acting on a plank leaning against a wall, particularly when considering scenarios of balance, sliding, and the role of friction. Participants explore the implications of these forces in both static and dynamic contexts.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • Some participants suggest that if the plank is not slipping, there must be a normal force from the ground and a horizontal normal force from the wall preventing it from falling.
  • Others argue that the normal force from the wall is strictly horizontal and does not affect the vertical normal force from the ground, which should equal the weight of the plank (MG).
  • There is a discussion about whether the horizontal normal force can be considered a torque that prevents the plank from rotating down.
  • Some participants express uncertainty about the behavior of the normal forces when the plank begins to slide, questioning if the vertical normal force remains constant while the horizontal one changes.
  • One participant notes an observation about the sound made by a hockey stick when it hits the ground, suggesting a potential loss of contact with the wall during sliding.
  • There is a mention of the role of friction along the ground and wall in preventing the plank from falling, indicating that the normal force alone is not sufficient.
  • Concerns are raised about the lack of clarity in existing physics texts regarding the dynamics of the situation when the plank starts to slide.

Areas of Agreement / Disagreement

Participants express differing views on the relationship between the normal forces and the conditions under which the plank remains stationary or begins to slide. There is no consensus on how the forces interact during sliding, and the discussion remains unresolved regarding the implications of these forces in dynamic scenarios.

Contextual Notes

Participants highlight limitations in their understanding of the normal forces and their effects, particularly in scenarios involving sliding and the role of friction. There is also a reference to the need for further clarification from educational resources.

thejinx0r
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This has always puzzled me, the normal force, and I think I might understand this now, or at least part's of it.

So here's the case: there's a plank of wood leaning against a wall.

If it's not slipping/sliding or any of the sort, then there is no movement in the x or y direction.
Then, there must be a normal force from the floor holding it up. There must also be a normal force on the side that keeps it from falling.

That get's tricky here for me.

So, if it was perfectly balanced and not leaning on anything, then the normal force would just be equal to MG in the y-direction.

Now, if it is leaning on a wall, then the normal force coming from the wall would be only in the x direction. Thus, the horizontal normal force should not affect the vertical one. So, the normal force from the ground must also be equal to MG in this case.

I'm also learning about angular momentum right now. So, would the horizontal normal force be just a torque such that it prevents it from rotating down?

Now, uncertain territory begins:
Suppose the plank began to slide without friction.

The vertical normal force would then be a constant right?
And the horizontal normal force would change? But there is one little problem.
I've always noticed that my hockey stick (i.e a plank of wood) always seem to make a big bang sound as though the whole stick hit the floor and not just one edge.

So, does that mean that at some point, it loses contact with the wall?
 
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thejinx0r said:
This has always puzzled me, the normal force, and I think I might understand this now, or at least part's of it.

So here's the case: there's a plank of wood leaning against a wall.

If it's not slipping/sliding or any of the sort, then there is no movement in the x or y direction.
Then, there must be a normal force from the floor holding it up.
Not just. There might be a frictional component along the wall working in the y-direction.
There must also be a normal force on the side that keeps it from falling.
Not quite. The normal force from the wall is strictly horizontal, and prevents the plank from going into the wall.


So, if it was perfectly balanced and not leaning on anything, then the normal force would just be equal to MG in the y-direction.
correct.
Now, if it is leaning on a wall, then the normal force coming from the wall would be only in the x direction. Thus, the horizontal normal force should not affect the vertical one.
Indeed correct.
So, the normal force from the ground must also be equal to MG in this case.
Nope, answered above!
 
arildno said:
Not quite. The normal force from the wall is strictly horizontal, and prevents the plank from going into the wall.

Well, I see your point, but wouldn't it be considered falling if the wall was not there?
 
thejinx0r said:
Well, I see your point, but wouldn't it be considered falling if the wall was not there?

Nope. If the GROUND was witout friction, then the normal force would exert a horizontal force upon the plank so that the plank would start sliding down along the wall (the C.m of the plank would accelerate away from the wall.)
Thus, it is NOT the normal force from the wall by itself that normally prevents falling, but a combination of it and the friction along the ground (and, as asubsidiary point, some friction along the wall, as noted).
 
So, would the horizontal normal force be just a torque such that it prevents it from rotating down?

yes...for a stationary rigid plank of the type you describe the sum of the moments about any point is zero...a moment is the same thing as a torque...you can find complete explanations in many introductory physics texts...
 
Naty1 said:
yes...for a stationary rigid plank of the type you describe the sum of the moments about any point is zero...a moment is the same thing as a torque...you can find complete explanations in many introductory physics texts...

Ya, sort of true. I have a Kleppner and Kolenkow and there's nothing about it.
If there's one that you can recommend, then it would help me tremendously.

But anyways, I do understand the stationary part.
The part that I don't understand is when it starts to slide.

It's at the end of the first post, but I guess no one cared to comment.

I tried to go from first principles and what I knew about normal forces, but still not any better than yesterday,

Worst comes to worst, I'll just ask a teacher on Tuesday. (Tomorrow is Canadian thanks giving)
 

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