Simple calculations on a reciprocal roof
- A reciprocal roof is a kind of roof in which every rafter is supported by the previous one, resulting in a strong, self-supporting construction. But what will be the angle of my reciprocal roof? That’s for many amateur builders generally a process of trial and error. However, it is rather easy to calculate this roof angle. Grab a calculator and join in.
Usually a reciprocal frame will be covered in vegetation, so a relatively small angle is desired. Only two variables have influence on the angle: the thickness of the timber and the so called rummy. The rummy is the distance between two consecutive places where two poles meet each other, measured horizontally. The picture will clarify. The smaller the rummy, the larger the roof’s inclination. So, by selecting enough length of the rummy, you will be ensured of a limited roof angle.
The three pictures above further clarify the geometry of a reciprocal roof. Alpha represents approximately the roof angle of the entire reciprocal construction. The trick is to find alpha by applying some basic goniometry on the right-angled triangle. We’ll get back to that in a moment.
The circumference of the central opening is obviously dependent on the size of the rummy and the number of poles. The length of the contour is simply the rummy times the number of poles. The diameter of the central opening is more or less the circumference divided by π (3,1415). As the number of poles increases this approximation improves, because the central opening approaches a circle more and more. In the most extreme case the reciprocal frame consists of just three poles which leads to a triangular central opening. However, the diameter of even a hexagon is well approximated by taking six times the rummy and divide the result with π.
When using a high number of poles for a reciprocal frame, the central opening will probably get to large. Decreasing the rummy is not an option either, because this will increase the roof angle. The best option will then be to make a notch every time two poles meet. The effective diameter will thus be reduced locally and the roof angle will decrease subsequently. Still the key question remains: what will be the roof angle? Get your calculator, enter the (effective) pole diameter and divide by the rummy. Now take from the result the inverse sine (arcsin of sin-1) and there you have it: the roof angle in degrees. Make sure your calculator is actually set on degrees (deg). Alternatively, you can also use this small Excel sheet.
Although the number of poles influences the size of the central opening, it hardly changes the roof angle. It could change in the order of a degree because the poles will meet slightly different at varying numbers of poles, but that’s it. The roof angle is also not affected by the length of the poles.
Other properties of a reciprocal roof
The load of a reciprocal roof on the wall below is definitely favourable. Once the roof has settled in its definitive position, the weight only works vertically on the wall. So, the wall does not encounter outwards directed forces.
In the middle of the construction each pole rests on the previous one. Even without any fixing a reciprocal frame can be stable. Especially when using a larger number of poles the frame will remain standing. In actual construction a sturdy fixation is recommended, but it illustrates the intrinsic stability of a reciprocal frame.
Many reciprocal roofs are build with round wood. Posts are stronger than square or rectangular timber. An important advantage of round wood is that the fiber structure is nowhere cut. This yields more strength at the same weight.