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Spherical Ring


SphericalRingSolid
SphericalRing

A spherical ring is a sphere with a cylindrical hole cut so that the centers of the cylinder and sphere coincide, also called a napkin ring. Let the sphere have radius R and the cylinder radius r.

From the right diagram, the surface area of the spherical ring is equal to twice that of a cylinder of half-height

 1/2L=sqrt(R^2-r^2)
(1)

and radius r plus twice that of the zone of radius R and height L/2, giving

S=2(2pirsqrt(R^2-r^2)+2piRsqrt(R^2-r^2))
(2)
=4pi(r+R)sqrt(R^2-r^2).
(3)

Note that as illustrated above, the hole cut out consists of a cylindrical portion plus two spherical caps. The volume of the entire cylinder is

 V_(cylinder)=piLr^2,
(4)

and the volume of the upper segment is

 V_(cap)=1/3pih^2(3R-h).
(5)

The volume removed upon drilling of a cylindrical hole is then

V_(hole)=V_(cylinder)+2V_(cap)
(6)
=1/6pi(8R^3-L^3),
(7)

where the expressions

R^2=r^2+(1/2L)^2
(8)
R=1/2L+h
(9)

obtained from trigonometry have been used to re-express the result.

The volume of the spherical ring itself is then given by

V_(ring)=V_(sphere)-V_(hole)
(10)
=4/3(R^2-r^2)^(3/2)
(11)
=1/6piL^3.
(12)

By the final equation, the remaining volume of any center-drilled sphere can be calculated given only the length of the hole. In particular, if the sphere gets bigger while L remains constant, then the circumference of the ring gets bigger, increasing the volume, but the ring gets narrower, decreasing it. The two effects exactly cancel each other out, leading Gardner (1959, pp. 113-121) to term this an "incredible problem."

The volume can also be found more easily by looking at cross-sections orthogonal to the axis. It then turns out that the area of the cross section does not depend on R, leading to the above result.

The centroid of the spherical ring is at the origin, the mean square (spherical) radius is

 <rho^2>=1/5(2r^2+3R^2),
(13)

and the moment of inertia about the origin is given by

 I=[1/2MR^2-1/(40)ML^2 0 0; 0 1/2MR^2-1/(40)ML^2 0; 0 0 MR^2+3/(20)ML^2].
(14)

See also

Cylinder, Sphere, Spherical Cap, Torus

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References

Gardner, M. Hexaflexagons and Other Mathematical Diversions: The First Scientific American Book of Puzzles and Games. New York: Simon and Schuster, 1959.

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Spherical Ring

Cite this as:

Weisstein, Eric W. "Spherical Ring." From MathWorld--A Wolfram Web Resource. https://mathworld.wolfram.com/SphericalRing.html

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