--- /dev/null
+// Retrieved from https://www.thingiverse.com/thing:4120804
+
+/*
+ roundedCube() v1.0.3 by robert@cosmicrealms.com from https://github.com/Sembiance/openscad-modules
+ Allows you to round any edge of a cube
+
+ Usage
+ =====
+ Prototype: roundedCube(dim, r, x, y, z, xcorners, ycorners, zcorners, $fn)
+ Arguments:
+ - dim = Array of x,y,z numbers representing cube size
+ - r = Radius of corners. Default: 1
+ - x = Round the corners along the X axis of the cube. Default: false
+ - y = Round the corners along the Y axis of the cube. Default: false
+ - z = Round the corners along the Z axis of the cube. Default: true
+ - xcorners = Array of 4 booleans, one for each X side of the cube, if true then round that side. Default: [true, true, true, true]
+ - ycorners = Array of 4 booleans, one for each Y side of the cube, if true then round that side. Default: [true, true, true, true]
+ - zcorners = Array of 4 booleans, one for each Z side of the cube, if true then round that side. Default: [true, true, true, true]
+ - rx = Radius of the x corners. Default: [r, r, r, r]
+ - ry = Radius of the y corners. Default: [r, r, r, r]
+ - rz = Radius of the z corners. Default: [r, r, r, r]
+ - center = Whether to render the cube centered or not. Default: false
+ - $fn = How smooth you want the rounding to be. Default: 128
+
+ Change Log
+ ==========
+ 2018-08-21: v1.0.3 - Added ability to set the radius of each corner individually with vectors: rx, ry, rz
+ 2017-05-15: v1.0.2 - Fixed bugs relating to rounding corners on the X axis
+ 2017-04-22: v1.0.1 - Added center option
+ 2017-01-04: v1.0.0 - Initial Release
+
+ Thanks to Sergio Vilches for the initial code inspiration
+*/
+
+// Example code:
+
+/*cube([5, 10, 4]);
+
+translate([8, 0, 0]) { roundedCube([5, 10, 4], r=1); }
+translate([16, 0, 0]) { roundedCube([5, 10, 4], r=1, zcorners=[true, false, true, false]); }
+
+translate([24, 0, 0]) { roundedCube([5, 10, 4], r=1, y=true, z=false); }
+translate([32, 0, 0]) { roundedCube([5, 10, 4], r=1, x=true, z=false); }
+translate([40, 0, 0]) { roundedCube([5, 10, 4], r=1, x=true, y=true, z=true); }
+*/
+
+module roundedCube(dim, r=1, x=false, y=false, z=true, xcorners=[true,true,true,true], ycorners=[true,true,true,true], zcorners=[true,true,true,true], center=false, rx=[undef, undef, undef, undef], ry=[undef, undef, undef, undef], rz=[undef, undef, undef, undef], $fn=128)
+{
+ translate([(center==true ? (-(dim[0]/2)) : 0), (center==true ? (-(dim[1]/2)) : 0), (center==true ? (-(dim[2]/2)) : 0)])
+ {
+ difference()
+ {
+ cube(dim);
+
+ if(z)
+ {
+ translate([0, 0, -0.1])
+ {
+ if(zcorners[0])
+ translate([0, dim[1]-(rz[0]==undef ? r : rz[0])]) { rotateAround([0, 0, 90], [(rz[0]==undef ? r : rz[0])/2, (rz[0]==undef ? r : rz[0])/2, 0]) { meniscus(h=dim[2], r=(rz[0]==undef ? r : rz[0]), fn=$fn); } }
+ if(zcorners[1])
+ translate([dim[0]-(rz[1]==undef ? r : rz[1]), dim[1]-(rz[1]==undef ? r : rz[1])]) { meniscus(h=dim[2], r=(rz[1]==undef ? r : rz[1]), fn=$fn); }
+ if(zcorners[2])
+ translate([dim[0]-(rz[2]==undef ? r : rz[2]), 0]) { rotateAround([0, 0, -90], [(rz[2]==undef ? r : rz[2])/2, (rz[2]==undef ? r : rz[2])/2, 0]) { meniscus(h=dim[2], r=(rz[2]==undef ? r : rz[2]), fn=$fn); } }
+ if(zcorners[3])
+ rotateAround([0, 0, -180], [(rz[3]==undef ? r : rz[3])/2, (rz[3]==undef ? r : rz[3])/2, 0]) { meniscus(h=dim[2], r=(rz[3]==undef ? r : rz[3]), fn=$fn); }
+ }
+ }
+
+ if(y)
+ {
+ translate([0, -0.1, 0])
+ {
+ if(ycorners[0])
+ translate([0, 0, dim[2]-(ry[0]==undef ? r : ry[0])]) { rotateAround([0, 180, 0], [(ry[0]==undef ? r : ry[0])/2, 0, (ry[0]==undef ? r : ry[0])/2]) { rotateAround([-90, 0, 0], [0, (ry[0]==undef ? r : ry[0])/2, (ry[0]==undef ? r : ry[0])/2]) { meniscus(h=dim[1], r=(ry[0]==undef ? r : ry[0])); } } }
+ if(ycorners[1])
+ translate([dim[0]-(ry[1]==undef ? r : ry[1]), 0, dim[2]-(ry[1]==undef ? r : ry[1])]) { rotateAround([0, -90, 0], [(ry[1]==undef ? r : ry[1])/2, 0, (ry[1]==undef ? r : ry[1])/2]) { rotateAround([-90, 0, 0], [0, (ry[1]==undef ? r : ry[1])/2, (ry[1]==undef ? r : ry[1])/2]) { meniscus(h=dim[1], r=(ry[1]==undef ? r : ry[1])); } } }
+ if(ycorners[2])
+ translate([dim[0]-(ry[2]==undef ? r : ry[2]), 0]) { rotateAround([-90, 0, 0], [0, (ry[2]==undef ? r : ry[2])/2, (ry[2]==undef ? r : ry[2])/2]) { meniscus(h=dim[1], r=(ry[2]==undef ? r : ry[2])); } }
+ if(ycorners[3])
+ rotateAround([0, 90, 0], [(ry[3]==undef ? r : ry[3])/2, 0, (ry[3]==undef ? r : ry[3])/2]) { rotateAround([-90, 0, 0], [0, (ry[3]==undef ? r : ry[3])/2, (ry[3]==undef ? r : ry[3])/2]) { meniscus(h=dim[1], r=(ry[3]==undef ? r : ry[3])); } }
+ }
+ }
+
+ if(x)
+ {
+ translate([-0.1, 0, 0])
+ {
+ if(xcorners[0])
+ translate([0, dim[1]-(rx[0]==undef ? r : rx[0])]) { rotateAround([0, 90, 0], [(rx[0]==undef ? r : rx[0])/2, 0, (rx[0]==undef ? r : rx[0])/2]) { meniscus(h=dim[0], r=(rx[0]==undef ? r : rx[0])); } }
+ if(xcorners[1])
+ translate([0, dim[1]-(rx[1]==undef ? r : rx[1]), dim[2]-(rx[1]==undef ? r : rx[1])]) { rotateAround([90, 0, 0], [0, (rx[1]==undef ? r : rx[1])/2, (rx[1]==undef ? r : rx[1])/2]) { rotateAround([0, 90, 0], [(rx[1]==undef ? r : rx[1])/2, 0, (rx[1]==undef ? r : rx[1])/2]) { meniscus(h=dim[0], r=(rx[1]==undef ? r : rx[1])); } } }
+ if(xcorners[2])
+ translate([0, 0, dim[2]-(rx[2]==undef ? r : rx[2])]) { rotateAround([180, 0, 0], [0, (rx[2]==undef ? r : rx[2])/2, (rx[2]==undef ? r : rx[2])/2]) { rotateAround([0, 90, 0], [(rx[2]==undef ? r : rx[2])/2, 0, (rx[2]==undef ? r : rx[2])/2]) { meniscus(h=dim[0], r=(rx[2]==undef ? r : rx[2])); } } }
+ if(xcorners[3])
+ rotateAround([-90, 0, 0], [0, (rx[3]==undef ? r : rx[3])/2, (rx[3]==undef ? r : rx[3])/2]) { rotateAround([0, 90, 0], [(rx[3]==undef ? r : rx[3])/2, 0, (rx[3]==undef ? r : rx[3])/2]) { meniscus(h=dim[0], r=(rx[3]==undef ? r : rx[3])); } }
+ }
+ }
+ }
+ }
+}
+
+module meniscus(h, r, fn=128)
+{
+ $fn=fn;
+
+ difference()
+ {
+ cube([r+0.2, r+0.2, h+0.2]);
+ translate([0, 0, -0.1]) { cylinder(h=h+0.4, r=r); }
+ }
+}
+
+module rotateAround(a, v) { translate(v) { rotate(a) { translate(-v) { children(); } } } }
projects / tattlekey / blobdiff