Perpendicular force with a spiral

In summary, the stem is attached to the spiral at one end and turns like the support clockwise at w. If the spiral blocks the stem, there is friction between the stem and the disk.
  • #1
Cri85
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0

Homework Statement



A red Archimedean spiral is fixed to the ground. An external motor turns a grey support clockwise at w, the support can only turn around itself. On the support there is one orange disk that doesn't turn around itself at start. A stem is on the support.

That stem:

- turns like the support clockwise at w
- is attached on the spiral at one end
- has no mass
- is connected to the disk:
... - if the spiral attrack the stem: like gears can be: no friction between the stem and the disk, no sliding
...- if the spiral block the stem, there is friction between the stem and the disk

At start w=0.

1) the spiral attack or block the stem ?
2) drawn all forces
3) find the work that the motor need to give
4) find the work needed to move the stem around the spiral
5) does the disk has a rotation around itself ?

Datas:

Inertia of the support: I1
Inertia of the disk around main axis: I2
Inertia of the disk around itself: I3

There is no friction except between the stem and the disk

http://imageshack.com/a/img910/1162/77armo.png [Broken]

Homework Equations



--

The Attempt at a Solution



1) The support turns clockwise so the disk turns counterclockise at -w in the support reference, I need to add 2piR/4 when the support has turned of 90°. I noted R the radius of the disk. I measured it with 3 positions:

http://imageshack.com/a/img540/3440/9WNKka.png [Broken]

I don't know how to calculate this, if you have a method because it's only a graphical solution. With the graphical method, the spiral block the stem.

Edit:With a numerical method I found the the spiral attrack the stem. I found for my spiral, the distance pass from 11 to 13.194 and the tangent is at 1.3274, so the radius of the disk can be 1.3274, it become 1.3274*2*pi/4=2.0850 but the spiral move to 2.194, it confirms what I found with a graphic method. I take a=1.4 for the spiral. The parametric equations are : ##x=-1.4\theta cos\theta## and ##y=1.4\theta sin\theta##.

2) The stem gives the forces F2 to the disk and receives F1. The spiral receives the force F4. The support receives the forces F3.

http://imageshack.com/a/img673/3516/M03spN.png [Broken]

the stem rotates the disk clockwise.

3) the motor needs to give only the work for turn the support and the disk around the main axis, the work is :

##\frac{1}{2}I_1w^2+\frac{1}{2}I_2w^2##4) The force F4 is always perpendicular to the trajectory then the work needed is 0. The stem has no mass so its kinetic energy is always 0.

5) Yes, I measured the distance for 3 positions and the stem rotates the disk around itself clockwise, and there is friction. In this case the support must receive a counterclockwise torque for keep constant the energy. So, I think I'm wrong in my forces or the spiral don't attrack or block the stem ?

With a better image:

http://imageshack.com/a/img673/7249/JcXIC5.png [Broken]
 
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  • #2
Are you not told the constant for the spiral in terms of R? Determining the relationship from measurements of the diagram seems unsatisfactory.
Looks to me that the stem is always perpendicular to the spiral at point of contact. (In fact, you have assumed this in your force diagram.) That should give you a useful relationship.
Cri85 said:
3) find the work that the motor need to give
4) find the work needed to move the stem around the spiral
These questions are a bit confusing. If work is needed to move the stem then that's on-going, i.e. we're talking about power, or maybe work per radian; but unless the disk's rotation is accelerating the work to rotate the support and disk are only what was required to set it moving from rest. It's not clear what is being asked.
Cri85 said:
if the spiral attrack the stem: like gears can be: no friction between the stem and the disk, no sliding
Do you mean 'attract' the stem, i.e. pulls the stem out?
If there's no friction then there is sliding. Which do you mean?

In your attempt at solution diagram, the stem extension after a quarter turn is correct, but not the one after a half turn (2R).

Your work equation is not right. Even if the disk were not rotating in itself, it would still be orbiting the centre of the support.
Also, you've taken the angular velocity to be the same for support and disk. Have you shown they're the same?
 
  • #3
haruspex said:
Are you not told the constant for the spiral in terms of R?

True, I don't understood that point, I corrected my last calculation, like I see the picture R is choose for have the stem perpendiculary to the spiral, always. So, the equation of my spiral is ##x=−1.4\theta cos\theta## and ##y=1.4\theta sin\theta##. I have some trouble for find a general relation between the spiral and R but for my example with a=1.4, I found the derivated of 1.4y' = ##1.4\theta sin\theta##, it's ##sin\theta + \theta cos\theta##, I'm looking for y'=0, I found ##\theta=2.0287 rad## and the radius is R=1.25. Each 90° the spiral is far away of ##1.4*5*2pi/4*sin(5*2pi/4)-1.4*6*2pi/4*sin(6*2pi/4)=11-13.194=-2.194##. With ##R*2pi/4 < 2.194##. Like the support turns the spiral is far away after 90°. But maybe it's not like that R can be find ?

haruspex said:
Do you mean 'attract' the stem, i.e. pulls the stem out?
Yes, I need to find if the spiral push or pull the stem.

haruspex said:
If there's no friction then there is sliding. Which do you mean?
imagine the link between the disk and the stem like 2 gears, no friction and no sliding. But it's only is the spiral pull the stem not push.

haruspex said:
but not the one after a half turn (2R).
Why ? I don't see where my drawing is false, I reported all distances I found.

haruspex said:
It's not clear what is being asked.
I think the question is the work when the angular velocity is at w.

haruspex said:
Also, you've taken the angular velocity to be the same for support and disk. Have you shown they're the same?
The disk can turn around itself but it turns with the support at w, the axis of rotation of the disk is on the support, so the disk is at w too. But I'm not sure it turns around itself. I drawn a grey part inside the orange disk for show its axis of rotation is on the support.
 
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  • #4
Cri85 said:
the picture R is choose for have the stem perpendiculary to the spiral, always. So, the equation of my spiral is x=−1.4θcosθ and y=1.4θsinθ.
I've come to the conclusion that an Archimedean spiral cannot result in such constant perpendicularity.
Let P = (r, θ) be a point on the spiral with r only a little greater than R. Let Q be the point where the stem touches the disk. So OQP is a right angled triangle, |OQ| = R, |OP| = r. The angle QOP is small. The tangent to the spiral at P is parallel to OQ, so almost parallel with OP. I.e. the curve is headed almost directly away from O, making ##\frac{dr}{d\theta}## very large. But in an Archimedean spiral it should be constant.
So either it is not Archimedean or we must drop the perpendicularity assumption.
 
  • #5
haruspex said:
So either it is not Archimedean or we must drop the perpendicularity assumption.
I guessed it was a Archimedean spiral, the exercice don't speak about the Archimedean but the image shows the perpendicularity in 2 positions, so it must be perpendicular always. I think it's possible to have a shape always perpendicular to the stem, in this case is it a Theodorus of Cyrene's spiral ?

http://en.wikipedia.org/wiki/Spiral_of_Theodorus

If yes, the distance is ##d=\frac{\sqrt3}{cos(\frac{\pi}{2}-acos(\frac{1}{\sqrt(2)})-acos(\frac{\sqrt(2)}{\sqrt(3)})}+R=1.75+R## far away for an angle of 90° for the spiral. Like the disk turns counterclockwise the stem moves of 1.57R, the distance is 1.75+R far away, so the stem can push or pull the spiral, it depends of the diameter of R ?
 
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  • #6
Cri85 said:
I guessed it was a Archimedean spiral, the exercice don't speak about the Archimedean but the image shows the perpendicularity in 2 positions, so it must be perpendicular always. I think it's possible to have a shape always perpendicular to the stem, in this case is it a Theodorus of Cyrene's spiral ?
no. Try http://en.m.wikipedia.org/wiki/Involute
 
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  • #7
Thanks ! I calculated some examples with the disk in the center of the support, and the distance is always 1.57R for 90°, like the disks turns counterclockwise, the stem moves of pi/2*R=1.57R, so the stem moves like the spiral, the spiral don't push nor pull the stem ? It is the same result if the disk is not in the center ?
 
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  • #8
Cri85 said:
Thanks ! I calculated some examples with the disk in the center of the support, and the distance is always 1.57R for 90°, like the disks turns counterclockwise, the stem moves of pi/2*R=1.57R, so the stem moves like the spiral, the spiral don't push nor pull the stem ? It is the same result if the disk is not in the center ?
No, I think it will be different for the off-centre disk.
But instead of thinking of it as a straight straw, now, I think it will help to view it as a string wound onto a disk of radius R at the centre of the support.
Consider three points on the string at some instant: A where the string touches the off-centre disk, B where it forms a tangent to the central disk and C, another 90 degrees around the central disk. AB is the distance between the centres of the disks.
When the support turns 90 degrees, unwinding the string, C is now the tangent point. Where have A and B moved to?
 
  • #9
I try to do what you asked, I'm not sure to understand all your message, I drawn an image:

http://imageshack.com/a/img661/4720/81Snwo.png [Broken]

I noted A', B', C', points after unwinding the string. It's correct ? But I don't understand why the distance is not the same.
 
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  • #10
Cri85 said:
I try to do what you asked, I'm not sure to understand all your message, I drawn an image:

http://imageshack.com/a/img661/4720/81Snwo.png [Broken]

I noted A', B', C', points after unwinding the string. It's correct ? But I don't understand why the distance is not the same.
No, that's not what I tried to describe.
In keeping with the involute model, I've put another disk radius R at the centre of the support, but it doesn't rotate. We can think of the straw as a string unwinding from this disk as the support rotates. To avoid confusion, I'll call it the drum and reserve 'disk' for the disk in the statement of the problem.
A, B and C are points on the string and move with the string (to A', B', C' say). A is initially touching the disk, B touches the drum at the point where the string is currently unwinding from the drum, and C is a quarter turn further around the drum. So the line AB is initially tangential to both disk and drum.
After the support has turned 90 degrees, A', B' and C' will be in a straight line. The string now touches the disk at D. What is the distance B'D?
 
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  • #11
Sorry if I don't understand. Like that ?

http://imageshack.com/a/img913/8661/42rQHN.png [Broken]

B'D = AB -1.57 R ? It's the additionnal "length" (the spiral is far away) of the spiral after 90° ?
 
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  • #12
Cri85 said:
Sorry if I don't understand. Like that ?

http://imageshack.com/a/img913/8661/42rQHN.png [Broken]

B'D = AB -1.57 R ? It's the additionnal "length" (the spiral is far away) of the spiral after 90° ?
Yes. Can you figure out from that how the disk rotates?
 
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  • #13
The disk rotates counterclockwise at 1.57R each quarter, like I drawn so the distance traveled is greater than the spiral ? The spiral push the stem ?

Now, it depends of the distance AB ?

If I take AB=1.57R, the spiral don't increase its "length" ?
 
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  • #14
Cri85 said:
The disk rotates counterclockwise at 1.57R each quarter
Relative to the support or about its own centre?
Cri85 said:
so the distance traveled is greater than the spiral ?
I don't understand what you mean. The distance traveled by what, and what do you mean by distance 'travelled' by the spiral?
Cri85 said:
Now, it depends of the distance AB ?
I don't think so.

Sorry, i just realized I asked the wrong question at the end of post #10. I meant to ask for the distance A'D. Is this consistent with the disk not having changed its orientation? Imagine the disk staying still and the stem rolling around it from the first position to the second position your post #11 diagram. Does A still land at A'?
 
  • #15
haruspex said:
Relative to the support or about its own centre?
Relative to the support.

haruspex said:
I don't understand what you mean. The distance traveled by what, and what do you mean by distance 'travelled' by the spiral?
For resume, I would like to know if the spiral push or pull the stem. I need to know the distance D1 to reach the spiral, because the spiral increase more and more and I need to know what the distance D2 the stem move because the stem is on the support and the stem is push by the disk (and turn with the support turn in the same time).

haruspex said:
Is this consistent with the disk not having changed its orientation?
I'm ok with that.

haruspex said:
Imagine the disk staying still and the stem rolling around it from the first position to the second position your post #11 diagram. Does A still land at A'?
I understood ! yes, A'D is not 1.57R it's lower. A'D = R ? But A'D is D1 or D2 I defined just above ? A'D is used for build the spiral ?
 
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  • #16
Cri85 said:
Relative to the support.
Right. The support has rotated clockwise a quarter turn, but the disk has rotated anticlockwise a quarter turn relative to the support. So...?
Cri85 said:
A'D is not 1.57R
AB=A'B'=CD=distance between centre of disk and centre of support. BC (measured around the arc) = B'C = pi R/2. You can deduce A'D.
 
  • #17
haruspex said:
So...?
it don't turn in the lab frame reference

haruspex said:
You can deduce A'D.
A'D = 1.57R, but what is that distance ?
 
  • #18
Cri85 said:
it don't turn in the lab frame reference
Right. So now you can answer 1), 2) and 5). I leave you to attempt 3) and 4).
A'D = 1.57R, but what is that distance ?
To be accurate, it's pi R/2. This just confirms that the stem rolls around the disk without turning it.
 

1. What is a perpendicular force with a spiral?

A perpendicular force with a spiral refers to a type of force that acts on an object in a direction that is perpendicular to the motion of the object, while also following a spiral or curved path. This type of force is often seen in objects that are rotating or moving in circular or spiral motions.

2. How is a perpendicular force with a spiral different from other forces?

A perpendicular force with a spiral is unique in that it combines two types of forces: a perpendicular force and a spiral force. It is different from other types of forces because it acts at an angle to the object's motion and causes the object to follow a curved path instead of a straight line.

3. What are some real-life examples of perpendicular forces with a spiral?

Some common examples of perpendicular forces with a spiral include the gravitational pull on a planet causing it to orbit around a sun, the force of friction causing a car to turn on a curved road, and the force of air resistance causing a spinning top to follow a spiral path as it falls to the ground.

4. How does a perpendicular force with a spiral affect an object's motion?

A perpendicular force with a spiral can affect an object's motion by changing its direction and causing it to follow a curved path. The magnitude and direction of the force will determine the shape and size of the spiral that the object follows.

5. What are some applications of perpendicular forces with a spiral in science and technology?

Perpendicular forces with a spiral have many practical applications in science and technology. They are used in the design of roller coasters and other amusement park rides, in the study of celestial mechanics and planetary orbits, and in the development of devices such as centrifuges and gyroscopes.

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