Capstan equation

An example of when knowledge of the capstan equation might have been useful. The bent white tube contains a cord to raise and lower a curtain. The tube is bent some 40 degrees in two places. The blue line indicates a more efficient design.

An example of holding capstans and a powered capstan used to raise sails on a tall ship.

The capstan equation or belt friction equation, also known as Eytelwein's formula,^[1]^[2] relates the hold-force to the load-force if a flexible line is wound around a cylinder (a bollard, a winch or a capstan).^[3] ^[4]

Because of the interaction of frictional forces and tension, the tension on a line wrapped around a capstan may be different on either side of the capstan. A small holding force exerted on one side can carry a much larger loading force on the other side; this is the principle by which a capstan-type device operates.

A holding capstan is a ratchet device that can turn only in one direction; once a load is pulled into place in that direction, it can be held with a much smaller force. A powered capstan, also called a winch, rotates so that the applied tension is multiplied by the friction between rope and capstan. On a tall ship a holding capstan and a powered capstan are used in tandem so that a small force can be used to raise a heavy sail and then the rope can be easily removed from the powered capstan and tied off.

In rock climbing with so-called top-roping, a lighter person can hold (belay) a heavier person due to this effect.

The formula is

T_{{\text{load}}}=T_{{\text{hold}}}\ e^{{\mu \phi }}~,

where $T_{{\text{load}}}$ is the applied tension on the line, $T_{{\text{hold}}}$ is the resulting force exerted at the other side of the capstan, $\mu$ is the coefficient of friction between the rope and capstan materials, and $\phi$ is the total angle swept by all turns of the rope, measured in radians (i.e., with one full turn the angle $\phi =2\pi \,$ ).

Several assumptions must be true for the formula to be valid:

The rope is on the verge of full sliding, i.e. $T_{{\text{load}}}$ is the maximum load that one can hold. Smaller loads can be held as well, resulting in a smaller effective contact angle $\phi$ .
It is important that the line is not rigid, in which case significant force would be lost in the bending of the line tightly around the cylinder. (The equation must be modified for this case.) For instance a Bowden cable is to some extent rigid and doesn't obey the principles of the Capstan equation.
The line is non-elastic.

It can be observed that the force gain increases exponentially with the coefficient of friction, the number of turns around the cylinder, and the angle of contact. Note that the radius of the cylinder has no influence on the force gain.

The table below lists values of the factor $e^{{\mu \phi }}\,$ based on the number of turns and coefficient of friction μ.

Number of turns	Coefficient of friction μ
Number of turns	0.1	0.2	0.3	0.4	0.5	0.6	0.7
1	1.9	3.5	6.6	12	23	43	81
2	3.5	12	43	152	535	1881	6661
3	6.6	43	286	1881	12392	81612	437503
4	12	152	1881	23228	286751	3540026	43702631
5	23	535	12392	286751	6635624	153552935	3553321281

From the table it is evident why one seldom sees a sheet (a rope to the loose side of a sail) wound more than three turns around a winch. The force gain would be extreme besides being counter-productive since there is risk of a riding turn, result being that the sheet will foul, form a knot and not run out when eased (by slacking grip on the tail (free end)).

It is both ancient and modern practice for anchor capstans and jib winches to be slightly flared out at the base, rather than cylindrical, to prevent the rope (anchor warp or sail sheet) from sliding down. The rope wound several times around the winch can slip upwards gradually, with little risk of a riding turn, provided it is tailed (loose end is pulled clear), by hand or a self-tailer.

For instance, the factor 153552935 means, in theory, that a newborn baby would be capable of holding the weight of two USS Nimitz supercarriers (97 000 ton each, but for the baby it would be only a little more than 1 kg).

Proof of the capstan equation

Forces between a rope and capstan

The first step is to relate the radial or normal force $F$ (Newtons/radian) at any point of the rope wrapped around a capstan to the tension $T$ (Newtons) in the rope as shown in the figure. The y axis component of the upward force of the capstan on the rope, $F\varphi$ , must equal the Y axis downward component of the tension in the rope, $T_{{\text{hold}}}\sin(\varphi )$ .

$F\varphi =T_{{\text{hold}}}\sin(\varphi )$

In the limit as $\varphi$ goes to zero (the small-angle approximation), $\sin(\varphi )=\varphi$ and $T_{{\text{hold}}}=T_{{\text{load}}}=T$ so $\varphi$ cancels leaving

$F=T$

So the frictional force over a wrap angle $d\varphi$ is

\mu {F}d\varphi =\mu {T}d\varphi

where

\mu

is the coefficient of friction (nonslip).

The increase in rope tension $dT$ over a wrap angle $d\varphi$ is the frictional force over that angle so

dT=\mu {T}d\varphi

{\frac {1}{T}}dT=\mu d\varphi

Integration of both sides yields

\int _{{T_{{\text{hold}}}}}^{{T_{{\text{load}}}}}{\frac {1}{T}}\;{dT}=\int _{0}^{\phi }\mu \;{d}\varphi

\ln T_{{\text{load}}}-\ln T_{{\text{hold}}}=\ln {\frac {T_{{\text{load}}}}{T_{{\text{hold}}}}}=\mu \phi

and exponentiating both sides,

{\frac {T_{{\text{load}}}}{T_{{\text{hold}}}}}={e}^{{\mu \phi }}

Finally,

T_{{\text{load}}}=T_{{\text{hold}}}{e}^{{\mu \phi }}

Generalization of the Capstan equation for a rope laying on an arbitrary orthotropic surface

If a rope is laying in equilibrium under tangential forces on a rough orthotropic surface then three following conditions (all of them) are satisfied:

1. No separation – normal reaction $N$ is positive for all points of the rope curve:

$N=-k_{n}T>0$ , where $k_{n}$ is a normal curvature of the rope curve.

2. Dragging coefficient of friction $\mu_g$ and angle $\alpha$ are satisfying the following criteria for all points of the curve

$-\mu _{g}<\tan \alpha <+\mu _{g}$

3. Limit values of the tangential forces:

The forces at both ends of the rope $T$ and $T_{0}$ are satisfying the following inequality

$T_{0}e^{-\int _{s}\omega ds}\leq T\leq T_{0}e^{\int _{s}\omega ds}$

with $\omega =\mu _{\tau }{\sqrt {k_{n}^{2}-{\frac {k_{g}^{2}}{\mu _{g}^{2}}}}}=\mu _{\tau }k{\sqrt {\cos ^{2}\alpha -{\frac {\sin ^{2}\alpha }{\mu _{g}^{2}}}}}$ ,

�where $k_{g}$ is a geodesic curvature of the rope curve, $k$ is a curvature of a rope curve, $\mu _{\tau }$ is a coefficient of friction in the tangential direction.

If $\omega =const$ then $T_{0}e^{-\mu _{\tau }ks\,{\sqrt {\cos ^{2}\alpha -{\frac {\sin ^{2}\alpha }{\mu _{g}^{2}}}}}}\leq T\leq T_{0}e^{\mu _{\tau }ks\,{\sqrt {\cos ^{2}\alpha -{\frac {\sin ^{2}\alpha }{\mu _{g}^{2}}}}}}$ .

This generalization has been obtained by Konyukhov A.,^[5]^[6]

References

↑ http://www.atp.ruhr-uni-bochum.de/rt1/currentcourse/node57.html
↑ http://www.jrre.org/att_frict.pdf
↑ Johnson, K.L. (1985). Contact Mechanics (PDF). Retrieved February 14, 2011.
↑ Attaway, Stephen W. (1999). The Mechanics of Friction in Rope Rescue (PDF). International Technical Rescue Symposium. Retrieved February 1, 2010.
↑ Konyukhov, Alexander (2015-04-01). "Contact of ropes and orthotropic rough surfaces". ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik. 95 (4): 406–423. doi:10.1002/zamm.201300129. ISSN 1521-4001.
↑ Konyukhov A., Izi R. "Introduction to Computational Contact Mechanics: A Geometrical Approach". Wiley.

External links

Capstan equation calculator

This article is issued from Wikipedia - version of the 11/27/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.

Capstan equation

Proof of the capstan equation

Generalization of the Capstan equation for a rope laying on an arbitrary orthotropic surface

See also

References

Further reading

External links