The belt problem is a mathematics problem which requires finding the length of a crossed belt that connects two circular pulleys with radius r1 and r2 whose centers are separated by a distance P (see diagram). The solution of the belt problem requires trigonometry and the concepts of the bitangent line, the vertical angle, and congruent angles.
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Clearly triangles ACO and ADO are congruent right angled triangles, as are triangles BEO and BFO. In addition, triangles ACO and BEO are similar. Therefore angles CAO, DAO, EBO and FBO are all equal. Denoting this angle by , the length of the belt is
This uses the fact that the length of an arc = the radius × the measure of the angle facing the arc in radians.
To find we see from the similarity of triangles ACO and BEO that
For fixed P the length of the belt depends only on the sum of the radius values r1 + r2, and not on their individual values.
There are other types of problems similar to the belt problem. The pulley problem, as shown, is similar to the belt problem; however, the belt does not cross itself. In the pulley problem the length of the belt is
where represents the radius of the larger pulley, represents the radius of the smaller one, and:
The belt problem is used in real life[1] in the design of aeroplanes, bicycle gears, cars, and other items with pulleys or belts that cross each other as in the belt problem. The pulley problem is also used in the design of conveyor belts found in airport luggage belts and automated factory lines.[2]