|
Grootte: 3421
Commentaar:
|
← Versie 25 sinds 2017-03-11 14:06:07 ⇥
Grootte: 0
Commentaar:
|
| Verwijderingen worden op deze manier gemarkeerd. | Toevoegingen worden op deze manier gemarkeerd. |
| Regel 1: | Regel 1: |
| Involute - or evolvent - curves are used as the shape of teeth of gears. For an introduction to more advanced math, see https://en.wikipedia.org/wiki/Involute. However, this page is more practical. <<TableOfContents()>> = What is an involute curve? = The example in the picture shows the basics. {{attachment:involute_q_and_d.jpg||width=300}} {{{Involute: a quick and dirty example}}} In plain language. A cord is coiled around a cylinder. At the end of the cord is a pencil. The cord is unrolled while the cord is held taut. The pencil draws a curve. This curve is called an involute. {{attachment:involute_basic_0-4pi.svg}} {{{Involute curve with x- and y-axis, without base circle.}}} = Practical use = The main reason for using gears with involute shapes is that there is no friction between teeth - against common believe. The teeth roll on each other when rotating. It is the gear application that makes a polar calculation based on radii more useful than a Cartesian calculation based on (x,y) - we are only interested in the first small part that starts from the base circle. On the other hand, a polar approach has its limits, see below. = Mathematics = {{attachment:involute_with_base.svg}} {{{Involute with base circle}}} Angles are in radians, 360 degrees equals (2 * pi) radians. Overall, see illustration: * The blue curve is the involute. * Points on that curve have coordinates X3 and Y3. * From those points runs a cord A1*R1, tangent to the base circle. * The base circle has a radius R1. {{attachment:involute_math.svg}} {{{Mathematics of involute}}} In detail: * The first triangle: * Start at point (0,0) * Hypotenuse is R1 * The angle is A1 * {{{X1 = R1 * cos (A1)}}} * {{{Y1 = R1 * sin (A1)}}} * The second triangle: * Start at the end of R1 * Hypotenuse is A1*R1 * A1*R1 is perpendicular to R1 * Therefore, the angle is again A1 * {{{X2 = R1 * A1 * sin (A1)}}} * {{{Y2 = R1 * A1 * cos (A1)}}} * About the length of hypotenuse A1*R1: * If A1 goes all the way around from {{{0}}} to {{{2 * pi}}} radians (equals 360 degrees), than the length of the cord changes from {{{0}}} to {{{2 * pi * R1}}}. After all, the circumference of a circle equals {{{2 * pi * R1}}}. * The length of the cord is thus equal to the product of angle A1 and radius R1, hence {{{A1 * R1}}}. * Cartesian coordinates: * Points on the involute curve have Cartesian coordinates (X3,Y3). * {{{X3 = X1 + X2}}} * {{{Y3 = Y1 - Y2}}} * Polar coordinates: * Points on the involute curve have polar coordinates (R2,A2). * About R2: * R1 and A1*R1 are always perpendicular. * Radius R2 can be calculated using the Pythagorean theorem. * {{{R2 = sqrt (R1^2 + (A1 * R1)^2) = R1 * sqrt (1 + A1^2)}}}. * About A2: * This can be calculated by using asin, acos or atan. * Unfortunately, these functions do not go all the way around with one argument supplied. For example, {{{A2 = acos (X3 / R2)}}} and that is only true for {{{0 < A2 < pi}}}. See example. * Fortunately, many environments offer a solution when X- and Y values are both entered as arguments. For example, !LibreOffice Calc has a formula {{{ATAN2(X-value;Y-value)}}} and LISP for CAD offers {{{(ATAN Y-value X-value)}}}. {{attachment:involute_ang_acos.svg}} {{{Wrongly drawn by using acos(X3/R2) for angle A2}}} |
