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walls.scad
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//////////////////////////////////////////////////////////////////////
// LibFile: walls.scad
// Walls and structural elements that 3D print without support.
// Includes:
// include <BOSL2/std.scad>
// include <BOSL2/walls.scad>
// FileGroup: Parts
// FileSummary: Walls and structural elements that 3D print without support.
//////////////////////////////////////////////////////////////////////
include<rounding.scad>
// Section: Walls
// Module: sparse_wall()
// Synopsis: Makes an open cross-braced rectangular wall.
// SynTags: Geom
// Topics: FDM Optimized, Walls
// See Also: hex_panel(), corrugated_wall(), thinning_wall(), thinning_triangle(), narrowing_strut()
//
// Usage:
// sparse_wall(h, l, thick, [maxang=], [strut=], [max_bridge=]) [ATTACHMENTS];
//
// Description:
// Makes an open rectangular strut with X-shaped cross-bracing, designed to reduce
// the need for support material in 3D printing.
//
// Arguments:
// h = height of strut wall.
// l = length of strut wall.
// thick = thickness of strut wall.
// ---
// maxang = maximum overhang angle of cross-braces, measured down from vertical. Default: 30
// strut = the width of the cross-braces. Default: 5
// max_bridge = maximum bridging distance between cross-braces. Default: 20
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
// orient = Vector to rotate top towards, after spin. See [orient](attachments.scad#subsection-orient). Default: `UP`
//
// See Also: corrugated_wall(), thinning_wall()
//
// Example: Typical Shape
// sparse_wall(h=40, l=100, thick=3);
// Example: Thinner Strut
// sparse_wall(h=40, l=100, thick=3, strut=2);
// Example: Larger maxang
// sparse_wall(h=40, l=100, thick=3, strut=2, maxang=45);
// Example: Longer max_bridge
// sparse_wall(h=40, l=100, thick=3, strut=2, maxang=45, max_bridge=30);
module sparse_wall(h=50, l=100, thick=4, maxang=30, strut=5, max_bridge=20, anchor=CENTER, spin=0, orient=UP)
{
zoff = h/2 - strut/2;
yoff = l/2 - strut/2;
maxhyp = 1.5 * (max_bridge+strut)/2 / sin(maxang);
maxz = 2 * maxhyp * cos(maxang);
zreps = ceil(2*zoff/maxz);
zstep = 2*zoff / zreps;
hyp = zstep/2 / cos(maxang);
maxy = min(2 * hyp * sin(maxang), max_bridge+strut);
yreps = ceil(2*yoff/maxy);
size = [thick, l, h];
attachable(anchor,spin,orient, size=size) {
yrot(90) {
linear_extrude(height=thick, convexity=4*yreps, center=true) {
sparse_wall2d([h,l], maxang=maxang, strut=strut, max_bridge=max_bridge);
}
}
children();
}
}
// Module: sparse_wall2d()
// Synopsis: Makes an open cross-braced rectangular wall.
// SynTags: Geom
// Topics: FDM Optimized, Walls
// See Also: sparse_wall(), hex_panel(), corrugated_wall(), thinning_wall(), thinning_triangle(), narrowing_strut()
//
// Usage:
// sparse_wall2d(size, [maxang=], [strut=], [max_bridge=]) [ATTACHMENTS];
//
// Description:
// Makes a 2D open rectangular square with X-shaped cross-bracing, designed to be extruded, to make a strut that reduces
// the need for support material in 3D printing.
//
// Arguments:
// size = The `[X,Y]` size of the outer rectangle.
// ---
// maxang = maximum overhang angle of cross-braces.
// strut = the width of the cross-braces.
// max_bridge = maximum bridging distance between cross-braces.
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
//
// See Also: corrugated_wall(), thinning_wall()
//
// Example: Typical Shape
// sparse_wall2d(size=[40,100]);
// Example: Thinner Strut
// sparse_wall2d(size=[40,100], strut=2);
// Example: Larger maxang
// sparse_wall2d(size=[40,100], strut=2, maxang=45);
// Example: Longer max_bridge
// sparse_wall2d(size=[40,100], strut=2, maxang=45, max_bridge=30);
module sparse_wall2d(size=[50,100], maxang=30, strut=5, max_bridge=20, anchor=CENTER, spin=0)
{
h = size.x;
l = size.y;
zoff = h/2 - strut/2;
yoff = l/2 - strut/2;
maxhyp = 1.5 * (max_bridge+strut)/2 / sin(maxang);
maxz = 2 * maxhyp * cos(maxang);
zreps = ceil(2*zoff/maxz);
zstep = 2*zoff / zreps;
hyp = zstep/2 / cos(maxang);
maxy = min(2 * hyp * sin(maxang), max_bridge+strut);
yreps = ceil(2*yoff/maxy);
ystep = 2*yoff / yreps;
ang = atan(ystep/zstep);
len = zstep / cos(ang);
attachable(anchor,spin, two_d=true, size=size) {
union() {
difference() {
square([h, l], center=true);
square([h-2*strut, l-2*strut], center=true);
}
ycopies(ystep, n=yreps) {
xcopies(zstep, n=zreps) {
skew(syx=tan(-ang)) square([(h-strut)/zreps, strut/cos(ang)], center=true);
skew(syx=tan( ang)) square([(h-strut)/zreps, strut/cos(ang)], center=true);
}
}
}
children();
}
}
// Module: sparse_cuboid()
// Synopsis: Makes an open cross-braced cuboid
// SynTags: Geom
// Topics: FDM Optimized, Walls
// See Also: sparse_wall(), hex_panel(), corrugated_wall(), thinning_wall(), thinning_triangle(), narrowing_strut(), cuboid()
// Usage:
// sparse_cuboid(size, [dir], [maxang=], [struct=]
// Description:
// Makes an open rectangular cuboid with X-shaped cross-bracing to reduce the need for material in 3d printing.
// The direction of the cross bracing can be aligned with the X, Y or Z axis. This module can be
// used as a drop-in replacement for {{cuboid()}} if you belatedly decide that your model would benefit from
// the sparse construction. Note that for Z aligned bracing the max_bridge parameter contrains the gaps that are parallel
// to the Y axis, and the angle is measured relative to the X direction.
// Arguments:
// size = The size of sparse wall, a number or length 3 vector.
// dir = direction of holes through the cuboid, must be a vector parallel to the X, Y or Z axes, or one of "X", "Y" or "Z". Default: "Y"
// ---
// maxang = maximum overhang angle of cross-braces, measured down from vertical. Default: 30
// strut = the width of the cross-braces. Default: 5
// max_bridge = maximum bridging distance between cross-braces. Default: 20
// chamfer = Size of chamfer, inset from sides. Default: No chamfering.
// rounding = Radius of the edge rounding. Default: No rounding.
// edges = Edges to mask. See [Specifying Edges](attachments.scad#section-specifying-edges). Default: all edges.
// except = Edges to explicitly NOT mask. See [Specifying Edges](attachments.scad#section-specifying-edges). Default: No edges.
// trimcorners = If true, rounds or chamfers corners where three chamfered/rounded edges meet. Default: `true`
// teardrop = If given as a number, rounding around the bottom edge of the cuboid won't exceed this many degrees from vertical. If true, the limit angle is 45 degrees. Default: `false`
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
// spin = Rotate this many degrees around the Z axis. See [spin](attachments.scad#subsection-spin). Default: `0`
// orient = Vector to rotate top towards. See [orient](attachments.scad#subsection-orient). Default: `UP`
// Examples:
// sparse_cuboid([10,20,30], strut=1);
// sparse_cuboid([10,20,30], "Y", strut=1);
// sparse_cuboid([10,20,30], UP, strut=1);
// sparse_cuboid(30, FWD, strut=2, rounding=2, $fn=24);
module sparse_cuboid(size, dir=RIGHT, strut=5, maxang=30, max_bridge=20,
chamfer,
rounding,
edges=EDGES_ALL,
except=[],
except_edges,
trimcorners=true,
teardrop=false,
anchor=CENTER, spin=0, orient=UP)
{
size = scalar_vec3(size);
dummy1=assert(in_list(dir,["X","Y","Z"]) || is_vector(dir,3), "dir must be a 3-vector or one of \"X\", \"Y\", or \"Z\"");
count = len([for(d=dir) if (d!=0) d]);
dummy2=assert(is_string(dir) || (count==1 && len(dir)<=3), "vector valued dir must have exactly one non-zero component");
dir = is_string(dir) ? dir
: dir.x ? "X"
: dir.y ? "Y"
: "Z";
attachable(anchor,spin,orient,size=size){
intersection(){
if (dir=="X")
sparse_wall(size.z,size.y,size.x,strut=strut,maxang=maxang, max_bridge=max_bridge);
else if (dir=="Y")
zrot(90)
sparse_wall(size.z,size.x,size.y,strut=strut,maxang=maxang, max_bridge=max_bridge);
else
yrot(90)
sparse_wall(size.x,size.y,size.z,strut=strut,maxang=maxang, max_bridge=max_bridge);
cuboid(size=size, chamfer=chamfer, rounding=rounding,edges=edges, except=except, except_edges=except_edges,
trimcorners=trimcorners, teardrop=teardrop);
}
children();
}
}
// Module: hex_panel()
// Synopsis: Create a hexagon braced panel of any shape
// SynTags: Geom
// Topics: FDM Optimized, Walls
// See Also: sparse_wall(), hex_panel(), corrugated_wall(), thinning_wall(), thinning_triangle(), narrowing_strut()
// Usage:
// hex_panel(shape, wall, spacing, [frame=], [bevel=], [bevel_frame=], [h=|height=|l=|length=], [anchor=], [orient=], [spin=])
// Description:
// Produces a panel with a honeycomb interior that can be rectangular with optional beveling, or
// an arbitrary polygon shape without beveling. The panel consists of a frame containing
// a honeycob interior. The frame is laid out in the XY plane with the honeycob interior
// and then extruded to the height h. The shape argument defines the outer bounderies of
// the frame.
// .
// The simplest way to define the frame shape is to give a cuboid size as a 3d vector for
// the shape argument. The h argument is not allowed in this case. With rectangular frames you can supply the
// bevel argument which applies a 45 deg bevel on the specified list of edges. These edges
// can be LEFT, RIGHT, FRONT, or BACK to place a bevel the edge facing upward. You can add
// BOTTOM, as in LEFT+BOT, to get a bevel that faces down. When beveling a separate beveled frame
// is added to the model. You can independently control its thickness by setting `bevel_frame`, which
// defaults to the frame thickness. Note also that `frame` and `bevel_frame` can be set to zero
// to produce just the honeycomb.
// .
// The other option is to provide a 2D path as the shape argument. The path must not intersect
// itself. You must give the height argument in this case and you cannot give the bevel argument.
// The panel is made from a linear extrusion of the specified shape. In this case, anchoring
// is done as usual for linear sweeps. The shape appears by default on its base and you can
// choose "hull" or "intersect" anchor types.
// Arguments:
// shape = 3D size vector or a 2D path
// strut = thickness of hexagonal bracing
// spacing = center-to-center spacing of hex cells in the honeycomb.
// ---
// frame = width of the frame around the honeycomb. Default: same as strut
// bevel = list of edges to bevel on rectangular case when shape is a size vector; allowed options are RIGHT, LEFT, BACK, or FRONT, or those directions with BOTTOM added. Default: []
// bevel_frame = width of the frame applied at bevels. Default: same as frame
// h / height / l / length = thickness of the panel when shape is a path
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER` for rectangular panels, `"zcenter"` for extrusions.
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
// orient = Vector to rotate top towards, after spin. See [orient](attachments.scad#subsection-orient). Default: `UP`
// atype = Select "hull", "intersect" anchor types. Default: "hull"
// cp = Centerpoint for determining "intersect" anchors or centering the shape. Determintes the base of the anchor vector. Can be "centroid", "mean", "box" or a 3D point. Default: "centroid"
// Named Anchors:
// "base" = Anchor to the base of the shape in its native position
// "top" = Anchor to the top of the shape in its native position
// "zcenter" = Center shape in the Z direction in the native XY position (default)
// Anchor Types:
// hull = Anchors to the convex hull of the linear sweep of the path, ignoring any end roundings.
// intersect = Anchors to the surface of the linear sweep of the path, ignoring any end roundings.
// Examples:
// hex_panel([50, 100, 5], strut=1.5, spacing=10);
// hex_panel([50, 100, 5], 1.5, 10, frame = 5);
// hex_panel([50, 100, 5], 5, 10.05);
// hex_panel([50, 100, 5], 1.5, 20, frame = 5);
// hex_panel([50, 100, 5], 1.5, 12, frame = 0);
// hex_panel([50, 100, 5], frame = 10, spacing = 20, strut = 4);
// hex_panel([50, 100, 10], 1.5, 10, frame = 5, bevel = [LEFT, RIGHT]);
// hex_panel([50, 100, 10], 1.5, 10, frame = 5, bevel = [FWD, BACK]);
// hex_panel([50, 100, 10], 1.5, 10, frame = 3, bevel = [LEFT, RIGHT, FWD, BACK]);
// hex_panel([50, 100, 10], 1.5, 10, frame = 1, bevel = [LEFT, RIGHT, FWD+BOTTOM, BACK+BOTTOM]);
// hex_panel([50, 100, 10], 1.5, 10, frame=2, bevel_frame=0, bevel = [FWD, BACK+BOT, RIGHT, LEFT]);
// Example: Triangle
// s = [[0, -40], [0, 40], [60, 0]];
// hex_panel(s, strut=1.5, spacing=10, h = 10, frame = 5);
// Example: Concave polygon
// s = [[0, -40], [0, 70], [60, 0], [80, 20], [70, -20]];
// hex_panel(s, 1.5, 10, h = 10, frame = 5);
// Example: Another concave example
// s = [[0, -40], [0, 40], [30, 20], [60, 40], [60, -40], [30, -20]];
// hex_panel(s, 1.5, 10, h = 10, frame = 5);
// Example: Circular panel
// hex_panel(circle(30), 1.5, 10, h = 10, frame = 5);
// Example: More complicated shape
// s = glued_circles(d=50, spread=50, tangent=30);
// hex_panel(s, 1.5, 10, h = 10, frame = 5);
// Example: Care is required when arranging panels vertically for 3d printability. Setting `orient=RIGHT` produces the correct result.
// hex_panel([50, 100, 10], 1.5, 10, frame = 5, bevel = [FWD, BACK], anchor = BACK + RIGHT + BOTTOM, orient = RIGHT);
// zrot(-90)hex_panel([50, 100, 10], 1.5, 10, frame = 5, bevel = [FWD, BACK], anchor = FWD + RIGHT + BOTTOM, orient = RIGHT);
// Example: In this example panels one of the panels is positioned with `orient=FWD` which produces hexagons with 60 deg overhang edges that may not be 3d printable. This example alsu uses `bevel_frame` to thin the material at the corner.
// hex_panel([50, 100, 10], 1.5, 10, frame = 5, bevel_frame=1, bevel = [FWD, BACK], anchor = BACK + RIGHT + BOTTOM, orient = RIGHT);
// hex_panel([100, 50, 10], 1.5, 10, frame = 5, bevel_frame=1, bevel = [LEFT, RIGHT], anchor = FWD + LEFT + BOTTOM, orient = FWD);
// Example: Joining panels with {{attach()}}. In this case panels were joined front beveled edge to back beveled edge, which means the hex structure doesn't align at the joint
// hex_panel([50, 100, 10], 1.5, 10, frame = 5, bevel_frame=0, bevel = [FWD, BACK], anchor = BACK + RIGHT + BOTTOM, orient = RIGHT)
// attach(BACK,FRONT)
// hex_panel([50, 100, 10], 1.5, 10, frame = 5, bevel_frame=0, bevel = [FWD, BACK]);
// Example: Joining panels with {{attach()}}. Attaching BACK to BACK aligns the hex structure which looks better.
// hex_panel([50, 100, 10], 1.5, 10, frame = 1, bevel = [FWD, BACK], anchor = BACK + RIGHT + BOTTOM, orient = RIGHT)
// attach(BACK,BACK)
// hex_panel([50, 100, 10], 1.5, 10, frame = 1, bevel = [FWD, BACK]);
module hex_panel(
shape,
strut,
spacing,
frame,
bevel_frame,
h, height, l, length,
bevel = [],
anchor,
orient = UP, cp="centroid", atype="hull",
spin = 0)
{
frame = first_defined([frame,strut]);
bevel_frame = first_defined([bevel_frame, frame]);
shape = force_path(shape,"shape");
bevel = is_vector(bevel) ? [bevel] : bevel;
bevOK = len([for(bev=bevel) if (norm([bev.x,bev.y])==1 && (bev.x==0 || bev.y==0) && (bev.z==0 || bev.z==-1)) 1]) == len(bevel);
dummy=
assert(is_finite(strut) && strut > 0, "strut must be positive")
assert(is_finite(frame) && frame >= 0, "frame must be nonnegative")
assert(is_finite(bevel_frame) && bevel_frame >= 0, "bevel_frame must be nonnegative")
assert(is_finite(spacing) && spacing>0, "spacing must be positive")
assert(is_path(shape,2) || is_vector(shape, 3), "shape must be a path or a 3D vector")
assert(len(bevel) == 0 || is_vector(shape, 3), "bevel must be used only on rectangular panels")
assert(is_path(shape) || all_positive(shape), "when shape is a size vector all components must be positive")
assert(bevOK, "bevel list contains an invalid entry")
assert(!(in_list(FRONT, bevel) && in_list(FRONT+BOTTOM, bevel)), "conflicting FRONT bevels")
assert(!(in_list(BACK, bevel) && in_list(BACK+BOTTOM, bevel)), "conflicting BACK bevels")
assert(!(in_list(RIGHT, bevel) && in_list(RIGHT+BOTTOM, bevel)), "conflicting RIGHT bevels")
assert(!(in_list(LEFT, bevel) && in_list(LEFT+BOTTOM, bevel)), "conflicting LEFT bevels")
assert(is_undef(h) || is_path(shape), "cannot give h with a size vector");
shp = is_path(shape) ? shape : square([shape.x, shape.y], center = true);
ht = is_path(shape) ? one_defined([h,l,height,length],"height,length,l,h")
: shape.z;
bounds = pointlist_bounds(shp);
sizes = bounds[1] - bounds[0]; // [xsize, ysize]
assert(frame*2 + spacing < sizes[0], "There must be room for at least 1 cell in the honeycomb");
assert(frame*2 + spacing < sizes[1], "There must be room for at least 1 cell in the honeycomb");
bevpaths = len(bevel)==0 ? []
: _bevelSolid(shape,bevel);
if (len(bevel) > 0) {
size1 = [bevpaths[0][0].x-bevpaths[0][1].x, bevpaths[0][2].y-bevpaths[0][1].y,ht];
size2 = [bevpaths[1][0].x-bevpaths[1][1].x, bevpaths[1][2].y-bevpaths[1][1].y];
shift = point2d(centroid(bevpaths[1])-centroid(bevpaths[0]));
offset = (centroid(bevpaths[0]));
attachable(anchor,spin,orient,size=size1,size2=size2,shift=shift,offset=offset){
down(ht/2)
intersection() {
union() {
linear_extrude(height = ht, convexity=8) {
_honeycomb(shp, spacing = spacing, hex_wall = strut);
offset_stroke(shp, width=[-frame, 0], closed=true);
}
for (b = bevel) _bevelWall(shape, b, bevel_frame);
}
vnf_polyhedron(vnf_vertex_array(bevpaths, col_wrap=true, caps=true));
}
children();
}
}
else if (is_vector(shape)){
attachable(anchor = anchor, spin = spin, orient = orient, size = shape) {
down(ht/2)
linear_extrude(height = ht, convexity=8) {
_honeycomb(shp, spacing = spacing, hex_wall = strut);
offset_stroke(shp, width=[-frame, 0], closed=true);
}
children();
}
}
else {
anchors = [
named_anchor("zcenter", [0,0,0], UP),
named_anchor("base", [0,0,-ht/2], UP),
named_anchor("top", [0,0,ht/2], UP)
];
attachable(anchor = default(anchor,"zcenter"), spin = spin, orient = orient, path=shp, h=ht, cp=cp, extent=atype=="hull",anchors=anchors) {
down(ht/2)
linear_extrude(height = ht, convexity=8) {
_honeycomb(shp, spacing = spacing, hex_wall = strut);
offset_stroke(shp, width=[-frame, 0], closed=true);
}
children();
}
}
}
module _honeycomb(shape, spacing=10, hex_wall=1)
{
hex = hexagon(id=spacing-hex_wall, spin=180/6);
bounds = pointlist_bounds(shape);
size = bounds[1] - bounds[0];
hex_rgn2 = grid_copies(spacing=spacing, size=size, stagger=true, p=hex);
center = (bounds[0] + bounds[1]) / 2;
hex_rgn = move(center, p=hex_rgn2);
difference(){
polygon(shape);
region(hex_rgn);
}
}
function _bevelSolid(shape, bevel) =
let(
tX = in_list(RIGHT, bevel) ? -shape.z : 0,
tx = in_list(LEFT, bevel) ? shape.z : 0,
tY = in_list(BACK, bevel) ? -shape.z : 0,
ty = in_list(FRONT, bevel) ? shape.z : 0,
bX = in_list(RIGHT + BOTTOM, bevel) ? -shape.z : 0,
bx = in_list(LEFT + BOTTOM, bevel) ? shape.z : 0,
bY = in_list(BACK + BOTTOM, bevel) ? -shape.z : 0,
by = in_list(FRONT + BOTTOM, bevel) ? shape.z : 0,
pathB = path3d(rect(select(shape,0,1)) + [[bX,by],[bx,by],[bx,bY],[bX,bY]]),
pathT = path3d(rect(select(shape,0,1)) + [[tX,ty],[tx,ty],[tx,tY],[tX,tY]],shape.z)
)
[pathB,pathT];
module _bevelWall(shape, bevel, thickness) {
l = bevel.y != 0 ? shape.x : shape.y;
d = bevel.y != 0 ? shape.y : shape.x;
zr = bevel.y == -1 ? 180
: bevel.y == 1 ? 0
: bevel.x == -1 ? 90
: bevel.x == 1 ? 270
: undef;
xr = bevel.x != 0 && bevel.z < 0 ? 180 : 0;
yr = bevel.y != 0 && bevel.z < 0 ? 180 : 0;
path = [[-thickness, 0], [0, 0], [-shape.z, -shape.z], [-shape.z-thickness, -shape.z]];
up(shape.z/2)
xrot(xr) yrot(yr) zrot(zr) down(shape.z/2)
back(d/2) right(l/2)
zrot(90) xrot(-90)
linear_extrude(l) polygon(path);
}
// Module: corrugated_wall()
// Synopsis: Makes a corrugated rectangular wall.
// SynTags: Geom
// Topics: FDM Optimized, Walls
// See Also: sparse_wall(), corrugated_wall(), thinning_wall(), thinning_triangle(), narrowing_strut()
//
// Usage:
// corrugated_wall(h, l, thick, [strut=], [wall=]) [ATTACHMENTS];
//
// Description:
// Makes a corrugated wall which relieves contraction stress while still
// providing support strength. Designed with 3D printing in mind.
//
// Arguments:
// h = height of strut wall.
// l = length of strut wall.
// thick = thickness of strut wall.
// ---
// strut = the width of the frame.
// wall = thickness of corrugations.
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
// orient = Vector to rotate top towards, after spin. See [orient](attachments.scad#subsection-orient). Default: `UP`
//
// See Also: sparse_wall(), thinning_wall()
//
// Example: Typical Shape
// corrugated_wall(h=50, l=100);
// Example: Wider Strut
// corrugated_wall(h=50, l=100, strut=8);
// Example: Thicker Wall
// corrugated_wall(h=50, l=100, strut=8, wall=3);
module corrugated_wall(h=50, l=100, thick=5, strut=5, wall=2, anchor=CENTER, spin=0, orient=UP)
{
amplitude = (thick - wall) / 2;
period = min(15, thick * 2);
steps = quantup(segs(thick/2),4);
step = period/steps;
il = l - 2*strut + 2*step;
size = [thick, l, h];
attachable(anchor,spin,orient, size=size) {
union() {
linear_extrude(height=h-2*strut+0.1, slices=2, convexity=ceil(2*il/period), center=true) {
polygon(
points=concat(
[for (y=[-il/2:step:il/2]) [amplitude*sin(y/period*360)-wall/2, y] ],
[for (y=[il/2:-step:-il/2]) [amplitude*sin(y/period*360)+wall/2, y] ]
)
);
}
difference() {
cube([thick, l, h], center=true);
cube([thick+0.5, l-2*strut, h-2*strut], center=true);
}
}
children();
}
}
// Module: thinning_wall()
// Synopsis: Makes a rectangular wall with a thin middle.
// SynTags: Geom
// Topics: FDM Optimized, Walls
// See Also: sparse_wall(), corrugated_wall(), thinning_wall(), thinning_triangle(), narrowing_strut()
//
// Usage:
// thinning_wall(h, l, thick, [ang=], [braces=], [strut=], [wall=]) [ATTACHMENTS];
//
// Description:
// Makes a rectangular wall which thins to a smaller width in the center,
// with angled supports to prevent critical overhangs.
//
// Arguments:
// h = Height of wall.
// l = Length of wall. If given as a vector of two numbers, specifies bottom and top lengths, respectively.
// thick = Thickness of wall.
// ---
// ang = Maximum overhang angle of diagonal brace.
// braces = If true, adds diagonal crossbraces for strength.
// strut = The width of the borders and diagonal braces. Default: `thick/2`
// wall = The thickness of the thinned portion of the wall. Default: `thick/2`
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
// orient = Vector to rotate top towards, after spin. See [orient](attachments.scad#subsection-orient). Default: `UP`
//
// See Also: sparse_wall(), corrugated_wall(), thinning_triangle()
//
// Example: Typical Shape
// thinning_wall(h=50, l=80, thick=4);
// Example: Trapezoidal
// thinning_wall(h=50, l=[80,50], thick=4);
// Example: Trapezoidal with Braces
// thinning_wall(h=50, l=[80,50], thick=4, strut=4, wall=2, braces=true);
module thinning_wall(h=50, l=100, thick=5, ang=30, braces=false, strut, wall, anchor=CENTER, spin=0, orient=UP)
{
l1 = (l[0] == undef)? l : l[0];
l2 = (l[1] == undef)? l : l[1];
strut = is_num(strut)? strut : min(h,l1,l2,thick)/2;
wall = is_num(wall)? wall : thick/2;
bevel_h = strut + (thick-wall)/2/tan(ang);
cp1 = circle_2tangents(strut, [0,0,+h/2], [l2/2,0,+h/2], [l1/2,0,-h/2])[0];
cp2 = circle_2tangents(bevel_h, [0,0,+h/2], [l2/2,0,+h/2], [l1/2,0,-h/2])[0];
cp3 = circle_2tangents(bevel_h, [0,0,-h/2], [l1/2,0,-h/2], [l2/2,0,+h/2])[0];
cp4 = circle_2tangents(strut, [0,0,-h/2], [l1/2,0,-h/2], [l2/2,0,+h/2])[0];
z1 = h/2;
z2 = cp1.z;
z3 = cp2.z;
x1 = l2/2;
x2 = cp1.x;
x3 = cp2.x;
x4 = l1/2;
x5 = cp4.x;
x6 = cp3.x;
y1 = thick/2;
y2 = wall/2;
corner1 = [ x2, 0, z2];
corner2 = [-x5, 0, -z2];
brace_len = norm(corner1-corner2);
size = [l1, thick, h];
attachable(anchor,spin,orient, size=size, size2=[l2,thick]) {
zrot(90) {
polyhedron(
points=[
[-x4, -y1, -z1],
[ x4, -y1, -z1],
[ x1, -y1, z1],
[-x1, -y1, z1],
[-x5, -y1, -z2],
[ x5, -y1, -z2],
[ x2, -y1, z2],
[-x2, -y1, z2],
[-x6, -y2, -z3],
[ x6, -y2, -z3],
[ x3, -y2, z3],
[-x3, -y2, z3],
[-x4, y1, -z1],
[ x4, y1, -z1],
[ x1, y1, z1],
[-x1, y1, z1],
[-x5, y1, -z2],
[ x5, y1, -z2],
[ x2, y1, z2],
[-x2, y1, z2],
[-x6, y2, -z3],
[ x6, y2, -z3],
[ x3, y2, z3],
[-x3, y2, z3],
],
faces=[
[ 4, 5, 1],
[ 5, 6, 2],
[ 6, 7, 3],
[ 7, 4, 0],
[ 4, 1, 0],
[ 5, 2, 1],
[ 6, 3, 2],
[ 7, 0, 3],
[ 8, 9, 5],
[ 9, 10, 6],
[10, 11, 7],
[11, 8, 4],
[ 8, 5, 4],
[ 9, 6, 5],
[10, 7, 6],
[11, 4, 7],
[11, 10, 9],
[20, 21, 22],
[11, 9, 8],
[20, 22, 23],
[16, 17, 21],
[17, 18, 22],
[18, 19, 23],
[19, 16, 20],
[16, 21, 20],
[17, 22, 21],
[18, 23, 22],
[19, 20, 23],
[12, 13, 17],
[13, 14, 18],
[14, 15, 19],
[15, 12, 16],
[12, 17, 16],
[13, 18, 17],
[14, 19, 18],
[15, 16, 19],
[ 0, 1, 13],
[ 1, 2, 14],
[ 2, 3, 15],
[ 3, 0, 12],
[ 0, 13, 12],
[ 1, 14, 13],
[ 2, 15, 14],
[ 3, 12, 15],
],
convexity=6
);
if(braces) {
bracepath = [
[-strut*0.33,thick/2],
[ strut*0.33,thick/2],
[ strut*0.33+(thick-wall)/2/tan(ang), wall/2],
[ strut*0.33+(thick-wall)/2/tan(ang),-wall/2],
[ strut*0.33,-thick/2],
[-strut*0.33,-thick/2],
[-strut*0.33-(thick-wall)/2/tan(ang),-wall/2],
[-strut*0.33-(thick-wall)/2/tan(ang), wall/2]
];
xflip_copy() {
intersection() {
extrude_from_to(corner1,corner2) {
polygon(bracepath);
}
prismoid([l1,thick],[l2,thick],h=h,anchor=CENTER);
}
}
}
}
children();
}
}
// Module: thinning_triangle()
// Synopsis: Makes a triangular wall with a thin middle.
// SynTags: Geom
// Topics: FDM Optimized, Walls
// See Also: sparse_wall(), corrugated_wall(), thinning_wall(), thinning_triangle(), narrowing_strut()
//
// Usage:
// thinning_triangle(h, l, thick, [ang=], [strut=], [wall=], [diagonly=], [center=]) [ATTACHMENTS];
//
// Description:
// Makes a triangular wall with thick edges, which thins to a smaller width in
// the center, with angled supports to prevent critical overhangs.
//
// Arguments:
// h = height of wall.
// l = length of wall.
// thick = thickness of wall.
// ---
// ang = maximum overhang angle of diagonal brace.
// strut = the width of the diagonal brace.
// wall = the thickness of the thinned portion of the wall.
// diagonly = boolean, which denotes only the diagonal side (hypotenuse) should be thick.
// center = If true, centers shape. If false, overrides `anchor` with `UP+BACK`.
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
// orient = Vector to rotate top towards, after spin. See [orient](attachments.scad#subsection-orient). Default: `UP`
//
// See Also: thinning_wall()
//
// Example: Centered
// thinning_triangle(h=50, l=80, thick=4, ang=30, strut=5, wall=2, center=true);
// Example: All Braces
// thinning_triangle(h=50, l=80, thick=4, ang=30, strut=5, wall=2, center=false);
// Example: Diagonal Brace Only
// thinning_triangle(h=50, l=80, thick=4, ang=30, strut=5, wall=2, diagonly=true, center=false);
module thinning_triangle(h=50, l=100, thick=5, ang=30, strut=5, wall=3, diagonly=false, center, anchor, spin=0, orient=UP)
{
dang = atan(h/l);
dlen = h/sin(dang);
size = [thick, l, h];
anchor = get_anchor(anchor, center, BOT+FRONT, CENTER);
attachable(anchor,spin,orient, size=size) {
difference() {
union() {
if (!diagonly) {
translate([0, 0, -h/2])
narrowing_strut(w=thick, l=l, wall=strut, ang=ang);
translate([0, -l/2, 0])
xrot(-90) narrowing_strut(w=thick, l=h-0.1, wall=strut, ang=ang);
}
intersection() {
cube(size=[thick, l, h], center=true);
xrot(-dang) yrot(180) {
narrowing_strut(w=thick, l=dlen*1.2, wall=strut, ang=ang);
}
}
cube(size=[wall, l-0.1, h-0.1], center=true);
}
xrot(-dang) {
translate([0, 0, h/2]) {
cube(size=[thick+0.1, l*2, h], center=true);
}
}
}
children();
}
}
// Module: narrowing_strut()
// Synopsis: Makes a strut like an extruded baseball home plate.
// SynTags: Geom
// Topics: FDM Optimized
// See Also: sparse_wall(), corrugated_wall(), thinning_wall(), thinning_triangle(), narrowing_strut()
//
// Usage:
// narrowing_strut(w, l, wall, [ang=]) [ATTACHMENTS];
//
// Description:
// Makes a rectangular strut with the top side narrowing in a triangle.
// The shape created may be likened to an extruded home plate from baseball.
// This is useful for constructing parts that minimize the need to support
// overhangs.
//
// Arguments:
// w = Width (thickness) of the strut.
// l = Length of the strut.
// wall = height of rectangular portion of the strut.
// ---
// ang = angle that the trianglar side will converge at.
// anchor = Translate so anchor point is at origin (0,0,0). See [anchor](attachments.scad#subsection-anchor). Default: `CENTER`
// spin = Rotate this many degrees around the Z axis after anchor. See [spin](attachments.scad#subsection-spin). Default: `0`
// orient = Vector to rotate top towards, after spin. See [orient](attachments.scad#subsection-orient). Default: `UP`
//
// Example:
// narrowing_strut(w=10, l=100, wall=5, ang=30);
module narrowing_strut(w=10, l=100, wall=5, ang=30, anchor=BOTTOM, spin=0, orient=UP)
{
h = wall + w/2/tan(ang);
size = [w, l, h];
attachable(anchor,spin,orient, size=size) {
xrot(90)
fwd(h/2) {
linear_extrude(height=l, center=true, slices=2) {
back(wall/2) square([w, wall], center=true);
back(wall-0.001) {
yscale(1/tan(ang)) {
difference() {
zrot(45) square(w/sqrt(2), center=true);
fwd(w/2) square(w, center=true);
}
}
}
}
}
children();
}
}
// vim: expandtab tabstop=4 shiftwidth=4 softtabstop=4 nowrap