cyclone-pcb-factory/Hardware/yOPERO/libs/obiscad/bevel.scad

486 lines
14 KiB
OpenSCAD

//---------------------------------------------------------------
//-- Openscad Bevel library
//-- Bevel the edges or add buttress to your parts!
//---------------------------------------------------------------
//-- This is a component of the obiscad opescad tools by Obijuan
//-- (C) Juan Gonzalez-Gomez (Obijuan)
//-- Sep-2012
//---------------------------------------------------------------
//-- Released under the GPL license
//---------------------------------------------------------------
use <vector.scad>
use <attach.scad>
//-----------------------------------------------------------------
//- Rotate a vector an angle teta around the axis given by the
//-- unit vector k
//-----------------------------------------------------------------
function Rot_axis_ang(p,k,teta) =
p*cos(teta) + cross(k,p*sin(teta)) + k*dot(k,p)*(1-cos(teta));
//-- Transformation defined by rotating vfrom vector to vto
//-- It is applied to vector v
//-- It returns the transformed vector
function Tovector(vfrom, vto, v) =
Rot_axis_ang(v, unitv(cross(vfrom,vto)), anglev(vfrom,vto));
//-- Auxiliary function for extending a vector of 3 components to 4
function ev(v,c=0) = [v[0], v[1], v[2], c];
//-- Calculate the determinant of a matrix given by 3 row vectors
function det(a,b,c) =
a[0]*(b[1]*c[2]-b[2]*c[1])
- a[1]*(b[0]*c[2]-b[2]*c[0])
+ a[2]*(b[0]*c[1]-b[1]*c[0]);
//-- Sign function. It only returns 2 values: -1 when x is negative,
//-- or 1 when x=0 or x>0
function sign2(x) = sign(x)+1 - abs(sign(x));
//--------------------------------------------------------------------
//-- Beveled concave corner
//-- NOT AN INTERFACE MODULE (The user should call bconcave_corner instead)
//--
//-- Parameters:
//-- * cr: Corner radius
//-- * cres: Corner resolution
//-- * l: Length
//- * th: Thickness
//--------------------------------------------------------------------
module bconcave_corner_aux(cr,cres,l,th)
{
//-- vector for translating the main cube
//-- so that the top rigth corner is on the origin
v1 = -[(cr+th)/2, (cr+th)/2, 0];
//-- The part frame of reference is on the
//-- internal corner
v2 = [cr,cr,0];
//-- Locate the frame of ref. in the internal
//-- corner
translate(v2)
difference() {
//-- Main cube for doing the corner
translate(v1)
//color("yellow",0.5)
cube([cr+th, cr+th, l],center=true);
//-- Cylinder used for beveling...
cylinder(r=cr, h=l+1, center=true, $fn=4*(cres+1));
}
}
//-----------------------------------------------------------------------------
//-- API MODULE
//--
//-- Beveled concave corner
//--
//-- Parameters:
//-- * cr: Corner radius
//-- * cres: Corner resolution
//-- * l: Length
//- * th: Thickness
//-- * ext_corner: Where the origin is locate. By default it is located
//-- in the internal corner (concave zone). If true,
//-- it will be in the external corner (convex zone)
//----------------------------------------------------------------------------
module bconcave_corner(cr=1,cres=4,th=1,l=10,ext_corner=false)
{
//-- Locate the origin in the exterior edge
if (ext_corner==true)
translate([th,th,0])
bconcave_corner_aux(cr,cres,l,th);
else
//-- Locate the origin in the interior edge
translate([0.01, 0.01,0])
bconcave_corner_aux(cr,cres,l,th);
}
//----------------------------------------------------------------------
//-- Auxiliary module (NOT FOR THE USER!)
//-- It is and standar "attach", particularized for placing concave
//-- corners
//----------------------------------------------------------------------
module bconcave_corner_attach_final(
cfrom, //-- Origin connector
cto, //-- Target connector
cr,
cres,
l,
th,
ext_corner)
{
//-- This block represent an attach operation
//-- It is equivalent to: attach(cto,cfrom)
translate(cto[0])
rotate(a=cto[2], v=cto[1])
rotate(a=anglev(cfrom[1],cto[1]),
v=cross(cfrom[1],cto[1]) )
translate(-cfrom[0])
//-- Place the concave corner (along with some debug information)
union() {
//color("Blue")
//connector(cfrom);
//connector([cfrom[0],cnormal_v,0]);
bconcave_corner(cr=cr,
cres=cres,
l=l,
th=th,
ext_corner=ext_corner);
}
}
//-------------------------------------------------------------------------
//-- Auxiliary module (NOT FOR THE USER!)
//-- It is the general module for performing the bconcave corner attach
//-- All the parameters should be passed to it
//--
//-- External connectors are where de concave corner will be placed. They
//-- are provided by the user
//--
//-- Internal connectors refers to the connectors of the concave corner
//--
//-- Then an attach between the internal and external connectors is done
//-------------------------------------------------------------------------
module bconcave_corner_attach_aux(
//-- External connectors
edge_c,
normal_c,
//-- Internal connectors
iedge_c,
inormal_c,
//-- Other params
cr,
cres,
th,
l,
ext_corner)
{
//-- Get the Corner vectors from the internal connectors
cedge_v = iedge_c[1]; //-- Corner edge vector
cnormal_v = inormal_c[1]; //-- Corner normal vector
//-- Get the vector paralell and normal to the edge
//-- From the external connectors
edge_v = edge_c[1]; //-- Edge verctor
enormal_v = normal_c[1]; //-- Edge normal vector
//---------------------------------------------------------------
//-- For doing a correct attach, first the roll angle for the
//-- external connector should be calculated. It determines the
//-- orientation of the concave corner around the edge vector
//--
//-- This orientation is calculated using the edge normal vectors
//-- that bisec the corner
//--
//-- There are 2 different cases: depending on the relative angle
//-- between the internal and external edges. They can be parallel
//-- or not
//-----------------------------------------------------------------
//-- The roll angle has two components: the value and the sign
//-- Calculate the sign of the rotation (the sign of roll)
s=sign2(det(cnormal_v,enormal_v,edge_v));
//-- Calculate the roll when the edges are paralell
rollp = s*anglev(cnormal_v, enormal_v);
//-- Calculate the roll in the general case
Tcnormal_v = Tovector(cedge_v, edge_v, cnormal_v);
rollg=s*anglev(Tcnormal_v, enormal_v);
//-- For the paralell case... use rollp
if (mod(cross(cedge_v,edge_v))==0) {
//echo("Paralell");
//-- Place the concave bevel corner!
bconcave_corner_attach_final(
cfrom = [[0,0,0], cedge_v, 0],
cto = [edge_c[0], edge_c[1], rollp],
cr = cr,
cres = cres,
l = l,
th = th,
ext_corner = ext_corner);
}
//-- For the general case, use rollg
else {
//echo("not paralell");
//-- Place the concave bevel corner!
bconcave_corner_attach_final(
cfrom = [[0,0,0], cedge_v, 0],
cto = [edge_c[0], edge_c[1], rollg],
cr = cr,
cres = cres,
l = l,
th = th,
ext_corner = ext_corner);
}
}
//---------------------------------------------------------------------------
//-- API MODULE
//--
//-- Bevel an edge. A concave corner is located so that the calling
//-- module can easily perform a difference() operation
//--
//-- Two connectors are needed:
//-- * edge_c : Connector located on the edge, paralell to the edge
//-- * normal_c : Connector located on the same point than edge_c
//-- pointing to the internal corner part, in the direction
//-- of the corner bisector
//-- * cr : Corner radius
//-- * cres : Corner resolution
//-- * l : Corner length
//--------------------------------------------------------------------------
module bevel(
edge_c,
normal_c,
cr=3,
cres=3,
l=5)
{
//-- Call the general module with the correct internal connectors
bconcave_corner_attach_aux(
//-- External connectors
edge_c = edge_c,
normal_c = normal_c,
//-- Internal connectors
iedge_c = [[0,0,0], unitv([0,0,1]), 0],
inormal_c = [[0,0,0], [-1,-1,0] , 0],
//-- The other params
cr=cr,
cres=cres,
l=l,
th=1,
ext_corner=false);
}
//---------------------------------------------------------------------------
//-- API MODULE
//--
//-- Attach a Beveled concave corner
//-- Two connectors are needed:
//-- * edge_c : Connector located on the edge, paralell to the edge
//-- * normal_c : Connector located on the same point than edge_c
//-- pointing to the internal corner part, in the direction
//-- of the corner bisector
//-- * cr : Corner radius
//-- * cres : Corner resolution
//-- * l : Corner length
//-- * th : Corner thickness (not visible when ext_corner=false)
//-- * ext_corner: If the exterior corner is used as a reference
//--------------------------------------------------------------------------
module bconcave_corner_attach(
edge_c,
normal_c,
cr=3,
cres=3,
l=5,
th=1,
ext_corner=false)
{
//-- Call the general module with the correct internal connectors
bconcave_corner_attach_aux(
//-- External connectors
edge_c = edge_c,
normal_c = normal_c,
//-- Internal connectors
iedge_c = [[0,0,0], unitv([0,0,1]), 0],
inormal_c = [[0,0,0], [1,1,0] , 0],
//-- The other params
cr=cr,
cres=cres,
l=l,
th=th,
ext_corner=ext_corner);
}
//-----------------------------------------------------------
//--- TEST MODULES
//-----------------------------------------------------------
//-----------------------------------------------------------------
//-- Testing the Bevel operator... All the 12 edges of a cube
//-- are beveled. All the cases are covered, so it is a good
//-- test for finding bugs!
//----------------------------------------------------------------
module Test1_beveled_cube()
{
//-------- Main object
size=[30,30,30];
//-- Define all the edges connectors
ec1 = [[size[0]/2, 0,size[2]/2], [0,1,0], 0];
en1 = [ec1[0], [1,0,1], 0];
ec2 = [[-size[0]/2, 0,size[2]/2], [0,1,0], 0];
en2 = [ec2[0], [-1,0,1], 0];
ec3 = [[-size[0]/2, 0,-size[2]/2], [0,1,0], 0];
en3 = [ec3[0], [-1,0,-1], 0];
ec4 = [[size[0]/2, 0,-size[2]/2], [0,1,0], 0];
en4 = [ec4[0], [1,0,-1], 0];
ec5 = [[0, size[0]/2,size[2]/2], [1,0,0], 0];
en5 = [ec5[0], [0,1,1], 0];
ec6 = [[0, -size[0]/2,size[2]/2], [1,0,0], 0];
en6 = [ec6[0], [0,-1,1], 0];
ec7 = [[0, -size[0]/2,-size[2]/2], [1,0,0], 0];
en7 = [ec7[0], [0,-1,-1], 0];
ec8 = [[0, size[0]/2,-size[2]/2], [1,0,0], 0];
en8 = [ec8[0], [0,1,-1], 0];
ec9 = [[size[2]/2, size[0]/2,0 ], [0,0,1], 0];
en9 = [ec9[0], [1,1,0], 0];
ec10 = [[size[2]/2, -size[0]/2,0 ], [0,0,1], 0];
en10 = [ec10[0], [1,-1,0], 0];
ec11 = [[-size[2]/2, -size[0]/2,0 ], [0,0,1], 0];
en11 = [ec11[0], [-1,-1,0], 0];
ec12 = [[-size[2]/2, size[0]/2,0 ], [0,0,1], 0];
en12 = [ec12[0], [-1,1,0], 0];
//-- for Debuging... Show a specefic connector
*connector(ec12);
*connector(en12);
//-- Parameters for all the beveled edges
//-- It can be changed for testing
cr=2;
cres=0;
//-- Remove from the main cube the concave corner parts
difference() {
//-- Draw the main cube
cube(size,center=true);
//-- Attach the concave corners for beveling!
bevel(ec1,en1,cr=cr,cres=0, l=size[1]+2);
bevel(ec2,en2,cr=cr,cres=0, l=size[1]+2);
bevel(ec3,en3,cr=cr,cres=0, l=size[1]+2);
bevel(ec4,en4,cr=cr,cres=0, l=size[1]+2);
bevel(ec5,en5,cr=cr,cres=0, l=size[0]+2);
bevel(ec6,en6,cr=cr,cres=0, l=size[0]+2);
bevel(ec7,en7,cr=cr,cres=0, l=size[0]+2);
bevel(ec8,en8,cr=cr,cres=0, l=size[0]+2);
bevel(ec9,en9,cr=cr,cres=0, l=size[0]+2);
bevel(ec10,en10,cr=cr,cres=0, l=size[0]+2);
bevel(ec11,en11,cr=cr,cres=0, l=size[0]+2);
bevel(ec12,en12,cr=cr,cres=0, l=size[0]+2);
}
}
//----------------------------------------------------------------
//-- Testing the bconcave_corner_attach operator
//-- It is used for adding buttress between two ortogonal parts
//----------------------------------------------------------------
module Test2_buttress()
{
size=[30,30,30];
th=3;
l=2;
cr = 6;
//-- A cross. It divides the space in 4 quadrants
difference() {
cube(size,center=true);
translate([size[0]/4 + th/2, 0, size[0]/4 + th/2])
cube([size[0]/2, size[1]+2, size[2]/2],center=true);
translate([-size[0]/4 - th/2, 0, size[0]/4 + th/2])
cube([size[0]/2, size[1]+2, size[2]/2],center=true);
translate([-size[0]/4 - th/2, 0, -size[0]/4 - th/2])
cube([size[0]/2, size[1]+2, size[2]/2],center=true);
translate([size[0]/4 + th/2, 0, -size[0]/4 - th/2])
cube([size[0]/2, size[1]+2, size[2]/2],center=true);
}
ec1 = [[th/2, size[1]/2-l/2, th/2], [0,1,0], 0];
en1 = [ec1[0],[1,0,1],0];
ec2 = [[th/2, -size[1]/2+l/2, th/2], [0,1,0], 0];
en2 = [ec2[0],[1,0,1],0];
ec3 = [[-th/2, 0, th/2], [0,1,0], 0];
en3 = [ec3[0],[-1,0,1],0];
ec4 = [[-th/2, 0, -th/2], [0,1,0], 0];
en4 = [ec4[0],[-1,0,-1],0];
ec5 = [[th/2, 0, -th/2], [0,1,0], 0];
en5 = [ec5[0],[1,0,-1],0];
*connector(ec5);
*connector(en5);
//-- quadrant 1: two buttress
bconcave_corner_attach(ec1,en1,cr, l=l, cres=0);
bconcave_corner_attach(ec2,en2,cr, l=l, cres=0);
//-- quadrant 2: one bit buttress
bconcave_corner_attach(ec3,en3,cr=3, l=size[1], cres=0);
//-- quadrant 3: a Rounded buttress
bconcave_corner_attach(ec4,en4,cr=8, l=size[1], cres=5);
//-- Quadrant 4: A rounded buttress in the middle
bconcave_corner_attach(ec5,en5,cr=8, l=size[1]/3, cres=5);
}
//-------------------------------------------------------------------
//-- TESTS
//-------------------------------------------------------------------
//-- example 1: A beveled concave corner
bconcave_corner(cr=15, cres=10, l=10, th=3, ext_corner=true);
//-- Example 2: Testing the bevel() operator
//Test1_beveled_cube();
//-- Example 3: Testing the bconcave_corner_attach() operator
//Test2_buttress();