How to Find the Volume of a Torus

A torus is the doughnut shape swept out by a circle turning about an axis at a distance from it. Its volume is 2 × π² × center distance × tube radius², by the theorem of Pappus. The center distance runs from the center of the doughnut to the center of the tube and must exceed the tube radius.

A torus is what a circle sweeps out when it turns about an axis lying outside it: a doughnut, a swim ring, an O-ring.

V=2π2Rr2V = 2\pi^2 R r^2

RR must be greater than rr. If it is not, the tube passes through itself and the formula no longer holds.

The theorem of Pappus

The volume is the area of the shape that was turned, multiplied by the distance its centroid travelled. The cross-section of the tube is a circle of area πr2\pi r^2, and its center travels once around a circle of radius RR, a distance of 2πR2\pi R.

V=πr2×2πR=2π2Rr2V = \pi r^2 \times 2\pi R = 2\pi^2 R r^2

Example

With the defaults, a center distance of R=10R = 10 and a tube radius of r=3r = 3.

V=2π2×10×32=180π21776.5288V = 2\pi^2 \times 10 \times 3^2 = 180\pi^2 \approx 1776.5288

Measuring it

RR reaches the center of the tube, not the edge of the hole. Measuring from the outside, with an outer diameter DD and a tube diameter dd, gives R=(Dd)÷2R = (D - d) \div 2 and r=d÷2r = d \div 2. The hole itself has diameter 2(Rr)2(R - r).