
Gears_h = gears_circular_pitch * gears_number_of_teeth_big / 180

Gears_d = gears_circular_pitch * (gears_number_of_teeth_big + gears_number_of_teeth_small ) / 360 The final file output is in Listing 1, but we will fill it in step by step during this exercise.
OPENSCAD BOX HOW TO
This exercise is aiming at seeing different modeling methods first, but also at learning how to organize parts in the printing area for a most efficient and robust 3D printing.įirst, let’s create a lib/sizes.scad file where we will put the dimensions used in the project: in this way you can share them between different project files, so that you can easily change them during the exercise. In this second and final episode we’ll build something more complex: a mechanism with gears and a structure to enclose and support them.ĭifferently from the previous examples, this time we’ll not print the box in a single piece but in separate parts then we’ll assemble and interlock them together. Limiting ourselves to primitive and simple operations, we had created a parametric box suitable for housing electronic circuits. In the previous tutorial episode we have seen that OpenSCAD describes objects from its basic primitives such as boxes, spheres and cylinders, using set operations (unions, intersections …) and geometric transformations. OpenSCAD is a free 3D modeling software whose strength is the capability of creating more “technical” rather than “artistic” objects, those requiring precise measurements, well-defined geometries and obtainable by repeating or replicating similar components.

Here we complete the overview of the free 3D modeling and editing software by creating modular models that can be assembled together.
