Distance between 2 pullies

  • Thread starter itchy8me
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In summary, the author has tried to solve an equation that is not solvable, and has come up with an approximate solution. He has drawn a picture to help him understand the situation.
  • #1
itchy8me
21
0
hi there,

i have two pulleys of known radii. i also have a belt of known length (radii). I need to find the distance between the two pulley centres so that the belt raps neatly around both pulleys.
I've had a go at it for a while now and the furthest i have come is:

1)
to make an equation that is not solvable (i have an angle inside and outside a cosinus function)

&

2)
to start the problem off with the distance between the pulleys being the sum of the radii then working out what the belt length should be for that distance, then subttracting this length from the actual belt length which gives me the length that is left over on the belt. However when i work backwards from here, substituting a new belt length between the pulleys using the leftover lengths i realize that the angles the tangents(belt) form on the pulleys also change and therefore my whole equation comes crashing down on itself.

so, how can i go about calculating this distance?

thanks,
wernher

edit: although this is not a homework question, i believe it falls under the criteria of a textbook type question. sorry for posting this here.
 
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  • #2
Well, I do not know specifics about pulleys so some of my math or assumptions might be wrong, but here goes nothing.

Assume we have pulleys with radii R,r respectively such that R>r.
Assume we have a belt with radius p, thus length[itex] P= 2p\pi[/itex].
Let c be the distance from the tops(bottoms) of the pulleys.
Then
[tex]P=R\pi + r\pi + 2c[/tex]
Let x be the distance between the pulleys.
Using the Pythagorean theorem, we see that
[tex](R-r)^{2}+(R+x+r)^{2}=c^{2}[/tex]
so
[tex]c=\sqrt{2(R^{2}+r^{2})+2(R+r)x+x^{2}}[/tex]
Thus
[tex]P=R\pi + r\pi + 2\left (\sqrt{2(R^{2}+r^{2})+2(R+r)x+x^{2}}\right )[/tex]
Solving for x, we see that
[tex]x=-(R+r)+\sqrt{(P - r - r\pi + R - R\pi) (P + r - r\pi - (1 + \pi) R)}[/tex]
which is in terms of all our given quantities.

Here is a picture I drew that I used.

l_05205fe8ba0749da9aca02c6bb9c5620.jpg


Once again, I do not know about pulleys, so this may all be hogwash.
 
  • #3
looks good to me. except i don't quite get what [tex]R \pi \ \& \ r \pi[/tex] in the equation of P are? they're supposed to be the length's of the belt on the circumference of the pulley's right?... shouldn't these terms be fractions of the form:

[tex]2 \pi R\frac{180 + 2 \alpha}{360} \ \& \ 2 \pi r\frac{180 - 2 \alpha}{360}[/tex]

? ( [tex]\left(\alpha\right)[/tex] being the angle of the the hypotomus c, which i worked out was the same angle that lies between the radius extending to the tangents and the vertical radius)
 
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  • #4
I assumed that the belt goes from north pole to north pole (south pole to south pole) and thus the length of belt that gets accounted for being in contact with the pulleys would be half of the sum of the circumferences of the pulleys. I do not know enough about pulleys to know if and how to account for the angles
 
  • #5
okay, i guess that's a good assumption(approximation) if the sizes are not that different, what happens though when they are very different and close to each other?
 
  • #6
The above solution is approximate as already stated. To get an exact solution, consider the attached picture:

1. The small solid circle on the left has radius r, center C1 = (0,0) and equation y2 = r2 - x2. The large solid circle on the right has radius R, center C2 = (d,0) and equation y2 = R2 - (x - d)2. The dashed circle has radius R-r, center C3 = (d,0) and equation y2 = (R - r)2 - (x - d)2.

2. It should be clear from the geometry that the lower red line is parallel to the upper one, starts at C1 and is tangent to the dashed circle.

3. The lower line has as it's equation y = mx (i.e. y = 0 @ x = 0), where m is the slope of the line. But, m is also the derivative of the dashed circle at the tangent point (xt, yt)

4. By equating m = y/x with the derivative of the dashed circle, you can solve for xt and yt. Using these values, m can be calculated.

5. Once you know m you can find the tangent point on the large circle by equating m with the derivative the the larger circle. The same can be done with the smaller circle.

6. Once the tangent points are determined, you can calculate the "belt length" for any value of d.

7. It might be possible to come up with a single algebraic equation for "belt length" as a function of d, but it would be pretty complicated. If we assume such an algebraic expression L = f(d) can be determined, then to find the value of d, just solve L1 = f(d) for d, where L1 is the desired belt length.
 

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  • #7
It is my turn!
See the attachment.

The hardest part is to see that the angle, a, formed by the separation of the pullies and the difference in the radius is the same as the angle to the point of tangency of the belt on each pully. Once you see that the angle is clearly given by:

[tex] Sin (a) = \frac {R -r} d [/tex]

The length of belt between the points of tangency is:
[tex] L = d \sqrt { 1 - \sin^2 a } [/tex]

For the length around the large pully we have:
[tex] L = \pi R + 2Ra [/tex]

For the small pully we have:
[tex] L = \pi r - 2ra [/tex]

Adding up the pieces gives:

Belt Length = [tex] 2 d \sqrt{1 -sin^2 a } + \pi R + 2Ra +\pi r - 2ra [/tex]
 

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  • #8
hotvette said:
The above solution is approximate as already stated. To get an exact solution, consider the attached picture:

1. The small solid circle on the left has radius r, center C1 = (0,0) and equation y2 = r2 - x2. The large solid circle on the right has radius R, center C2 = (d,0) and equation y2 = R2 - (x - d)2. The dashed circle has radius R-r, center C3 = (d,0) and equation y2 = (R - r)2 - (x - d)2.

2. It should be clear from the geometry that the lower red line is parallel to the upper one, starts at C1 and is tangent to the dashed circle.

3. The lower line has as it's equation y = mx (i.e. y = 0 @ x = 0), where m is the slope of the line. But, m is also the derivative of the dashed circle at the tangent point (xt, yt)

4. By equating m = y/x with the derivative of the dashed circle, you can solve for xt and yt. Using these values, m can be calculated.

5. Once you know m you can find the tangent point on the large circle by equating m with the derivative the the larger circle. The same can be done with the smaller circle.

6. Once the tangent points are determined, you can calculate the "belt length" for any value of d.

7. It might be possible to come up with a single algebraic equation for "belt length" as a function of d, but it would be pretty complicated. If we assume such an algebraic expression L = f(d) can be determined, then to find the value of d, just solve L1 = f(d) for d, where L1 is the desired belt length.

we want to calculate d for any belt length. Your quite correct though, deriving a solvable equation is proving to be killing a lot of trees here. I'm going to post what i have done once i either give up or find the solution. I'm working from the same perspective though, equating intersections and gradients hoping in the end to substitute them all into the equation for the total belt length.
 
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  • #9
Integral said:
It is my turn!
See the attachment.

The hardest part is to see that the angle, a, formed by the separation of the pullies and the difference in the radius is the same as the angle to the point of tangency of the belt on each pully. Once you see that the angle is clearly given by:

[tex] Sin (a) = \frac {R -r} d [/tex]

The length of belt between the points of tangency is:
[tex] L = d \sqrt { 1 - \sin^2 a } [/tex]

For the length around the large pully we have:
[tex] L = \pi R + 2Ra [/tex]

For the small pully we have:
[tex] L = \pi r - 2ra [/tex]

Adding up the pieces gives:

Belt Length = [tex] 2 d \sqrt{1 -sin^2 a } + \pi R + 2Ra +\pi r - 2ra [/tex]

this was my first assessment, it's correct, however "a" is proving to be quite a *****
 
  • #10
itchy8me said:
this was my first assessment, it's correct, however "a" is proving to be quite a *****

What do you mean?

[tex] a = sin^{-1}( \frac {R-r} d) [/tex]
 
  • #11
Integral said:
What do you mean?

[tex] a = sin^{-1}( \frac {R-r} d) [/tex]

yup that's what i mean, and we have 2 unknowns there, "a" and "d".
 
  • #12
And we have 2 equations.

a can be completely eliminated from the expression for belt length. So you can get an expression for d in terms of belt length. Unfortunately since d is inside the argument for sine it will not be possible to isolate it.

However the expression you get looks to be amenable to a fixed point iteration. That is create an expression for d which has d in it. Then make a guess at d, use it to compute d, take the result and recompute. It should only take a few iterations to find a meaningful value for d.
 
  • #13
Integral said:
And we have 2 equations.

a can be completely eliminated from the expression for belt length. So you can get an expression for d in terms of belt length. Unfortunately since d is inside the argument for sine it will not be possible to isolate it.

However the expression you get looks to be amenable to a fixed point iteration. That is create an expression for d which has d in it. Then make a guess at d, use it to compute d, take the result and recompute. It should only take a few iterations to find a meaningful value for d.

true , i forgot i simplified it to this https://www.physicsforums.com/showthread.php?t=389968 . Isolating was indeed the problem. What i however meant is that they are indeed both unknowns that cannot be solved for .. at this point in the equation.

iterating would be feasible, but surely there must be some nice equation that describes it ;)
 
  • #14
itchy8me said:
true , i forgot i simplified it to this https://www.physicsforums.com/showthread.php?t=389968 . Isolating was indeed the problem. What i however meant is that they are indeed both unknowns that cannot be solved for .. at this point in the equation.
Actually since you have a in terms of d there is only a single unknown.

iterating would be feasible, but surely there must be some nice equation that describes it ;)

Not necessarily, since we are looking for a angle it is not true that there is a clean simple closed form solution. If you make a small angle approximation you can get a clean solution.That is sina ~a if either the pulleys are nearly the same diameter or the separation is much greater then the difference in diameters.
 
  • #15
Integral said:
Actually since you have a in terms of d there is only a single unknown.



Not necessarily, since we are looking for a angle it is not true that there is a clean simple closed form solution. If you make a small angle approximation you can get a clean solution.That is sina ~a if either the pulleys are nearly the same diameter or the separation is much greater then the difference in diameters.


my appreciation of math will come to an end if there is no clean solution. I'm wondering now if it cannot be solved with limits and surface areas.
 
  • #16
Well, if this causes you to loose respect for math, then I guess you did not have much respect for it to begin with. You will find that MOST real world applications do not have good closed form solutions.
 
  • #17
Integral said:
Well, if this causes you to loose respect for math, then I guess you did not have much respect for it to begin with. You will find that MOST real world applications do not have good closed form solutions.

That being so would beg the question if math as a language is complete, my guess is not and therefore no harm done ;)

I'm however a very stubborn person and i will try and solve this until there are no more trees left.

edit: by the way when you say most "real world applications" i take it your describing the small details that are left out of equations and which could be included, therefore it would not be the math that fails to describe it but the detail.
 
  • #18
We can usually mathematically describe a system in great detail, however this usually results in an equation which can only be solved numerically.

As for your problem I recast the result as:

[tex] d = \frac { ( bl - \pi (R+r) -2(R-r) \sin^{-1}(\frac {R-r} {d} )} {2 \sqrt{1- ({\frac{R-r} d})^2 } }[/tex]

Where bl is the belt length, I used ,

[tex] d= \frac {Bl - \pi (R+r)} 2 [/tex]

the small angle approximation to get a initial guess.

By the 2nd iteration the result is more accurate then you will have the capability of measuring.


Belt Length 50
Rb 6
Rs 2

D=
12.43362939 This is my first guess
11.74803617 This result would get you a useful separtion
11.74570521
11.74570518
11.74570518
11.74570518
11.74570518
 
  • #19
Integral said:
We can usually mathematically describe a system in great detail, however this usually results in an equation which can only be solved numerically.

As for your problem I recast the result as:

[tex] d = \frac { ( bl - \pi (R+r) -2(R-r) \sin^{-1}(\frac {R-r} {d} )} {2 \sqrt{1- ({\frac{R-r} d})^2 } }[/tex]

Where bl is the belt length, I used ,

[tex] d= \frac {Bl - \pi (R+r)} 2 [/tex]

the small angle approximation to get a initial guess.

By the 2nd iteration the result is more accurate then you will have the capability of measuring.


Belt Length 50
Rb 6
Rs 2

D=
12.43362939 This is my first guess
11.74803617 This result would get you a useful separtion
11.74570521
11.74570518
11.74570518
11.74570518
11.74570518

You are correct. This is a very good solution and approaches beyond measurable precision. esspecially with the help of a computer.

thank you :)
 

1. What is the formula for calculating the distance between two pulleys?

The formula for calculating the distance between two pulleys is D = (N1 + N2) x C, where D is the distance, N1 and N2 are the number of teeth on each pulley, and C is the circular pitch.

2. How do you measure the distance between two pulleys?

To measure the distance between two pulleys, use a measuring tape or ruler to measure the diameter of each pulley. Then, use the formula D = (N1 + N2) x C to calculate the distance.

3. What is the importance of the distance between two pulleys?

The distance between two pulleys is important because it determines the tension and speed of the belt or chain connecting the pulleys. If the distance is too small, the belt or chain may slip, and if it is too large, the belt or chain may wear out quickly.

4. How does the distance between two pulleys affect the output of a machine?

The distance between two pulleys affects the output of a machine by determining the speed and torque of the output shaft. A larger distance will result in a higher output speed, while a smaller distance will result in a higher output torque.

5. Can the distance between two pulleys be changed?

Yes, the distance between two pulleys can be changed by adjusting the position of one or both pulleys. This can be done by using adjustable pulleys or by physically moving the pulleys closer or farther apart.

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