module foot(radius,wall,len,foot_radius,foot_height,angle,hole_radius,hole_dist,end=true,hole=true,circlet=true) { cut_h = (radius+wall)*sin(angle); cut_r = (radius+wall)/cos(angle); difference() { union() { difference() { rotate([0,angle,0]) cylinder(r=radius + wall, h = len); translate([0,0,-cut_h]) cylinder(r=cut_r, h=cut_h); } translate([0,0,-0.01]) cylinder(r = foot_radius, h = foot_height); if (circlet) { translate([-(wall+radius),0,foot_height+2]) rotate([90, 0, 0]) difference() { cylinder(r=8, h=4, center=true); cylinder(r=4, h=5, center=true); } } if (end) { translate([cut_r,0,radius+wall]) rotate([0,90,0]) cylinder(r=radius + wall, h = len); } } if (circlet) { rotate([0, angle, 0]) translate([0,0, radius * sin(angle) + foot_height]) cylinder(r = radius, h = len); } if (hole) { translate([0,foot_radius - hole_dist,-1]) cylinder(r=hole_radius, h=foot_height + 2); translate([0,-foot_radius + hole_dist,-1]) cylinder(r=hole_radius, h=foot_height + 2); } if (end) { translate([cut_r+wall/2,0,radius+wall]) rotate([0,90,0]) translate([0,0,wall]) cylinder(r=radius, h=len); } } } module t_connector(radius, wall, len, angle) { rotate([90,0,0]) difference() { union() { cylinder(r=radius + wall, h=len*2, center=true); rotate([0, angle, 0]) cylinder(r=radius + wall, h=len); } translate([0,0,len/2+wall/2]) cylinder(r=radius, h=len, center=true); translate([0,0,-len/2-wall/2]) cylinder(r=radius, h=len, center=true); rotate([0, angle, 0]) translate([0, 0, radius+wall]) cylinder(r=radius, h=len); } } module star_connector(radius, wall, len, angles) { rotate([90,0,0]) difference() { union() { sphere(r=radius + wall); for (a = angles) { rotate([0, a, 0]) cylinder(r=radius + wall, h=len); } } for (a = angles) { rotate([0, a, 0]) translate([0, 0, radius+wall]) cylinder(r=radius, h=len); } } }