parametrize screw/hex nut types

2023-01-01 16:20:47 -05:00
parent d0c89d13c6
commit 1b923fa215
4 changed files with 162 additions and 188 deletions
--- a/.idea/codeStyles/codeStyleConfig.xml
+++ b/.idea/codeStyles/codeStyleConfig.xml
@ -0,0 +1,5 @@
 <component name="ProjectCodeStyleConfiguration">
  <state>
    <option name="PREFERRED_PROJECT_CODE_STYLE" value="Default" />
  </state>
 </component>
--- a/cases/rack2/config.scad
+++ b/cases/rack2/config.scad
@ -23,10 +23,12 @@ screwDiff = 10;
 numRailScrews = 20;
 // Screw type used for rackmount units. See screws.scad.
-railMainScrewType = "m4";
+mainRailScrewType = "m4";
 // Screw type used to affix side rails.
-railSideMountScrewType = "m4";
+mainRailSideMountScrewType = "m4";
 // Screw type used for constructing the actual rack frame.
-rackScrewType = "m3";
+rackFrameScrewType = "m3";
 // Currently, only m3 screws are supported here (tolerance issues)
 assert(rackFrameScrewType == "m3");
--- a/cases/rack2/mainRail.scad
+++ b/cases/rack2/mainRail.scad
@ -1,121 +1,121 @@
 include <./config.scad>
 include <./screws.scad>
 // Distance between the middle of a screw mount and the rail's vertical edges
 railScrewHoleToInnerEdge = 5;
 railScrewHoleToOuterEdge = 5;
 // Distance between the midpoint of the rail screw holes.
 rackMountScrewWidth = maxUnitWidth + 2*railScrewHoleToInnerEdge;
 railFrontThickness = 6; // Make sure that the nuts for the chosen screw type can slot within the front face
 railSideMountThickness = 2.5;
 railOtherThickness = 2.5;
 // Extra spacing for the rack unit screws.
 frontScrewSpacing = 8;
 /* Small horizontal planes at the top and bottom of the main rails. Used so we can fasten the rail to the frame
   Note that this value is also used for a depression at the bottom/top of the frame for aligning the rail */
 railFootThickness = 3;
-railTotalHeight = screwDiff * (numRailScrews+1) + 2*railFootThickness;
+railTotalHeight = screwDiff * (numRailScrews + 1) + 2 * railFootThickness;
 sideSupportExtraSpace = 2;
 sideSupportScrewHoleToFrontEdge = 5;
 sideSupportScrewHoleToBackEdge = 4.5;
 sideSupportDepth = sideSupportScrewHoleToBackEdge + sideSupportScrewHoleToFrontEdge;
 frontFaceWidth = railScrewHoleToInnerEdge + railScrewHoleToOuterEdge;
 module _frontRailSegment() {
    difference() {
        cube(size=[frontFaceWidth, railFrontThickness, railTotalHeight]);
        for (i=[1:numRailScrews]) {
            translate(v=[railScrewHoleToOuterEdge, railFrontThickness/2, i*screwDiff + railFootThickness])
                rotate(a=[90,0,0])
                    m4HexNutPocketNegative();
        }
    }
 }
 module _connectingLBracketRailSegment() {
    difference() {
        cube(size = [railOtherThickness, frontScrewSpacing + railOtherThickness, railTotalHeight]);
        union () {
            translate(v=[0,4,railFootThickness + screwDiff / 2])
                rotate(a=[0,90,0])
                    cylinder(r=m3RadiusSlacked, h = 10, $fn=32, center=true);
            translate(v=[0,4,railTotalHeight-(railFootThickness + screwDiff / 2)])
                rotate(a=[0,90,0])
                    cylinder(r=m3RadiusSlacked, h = 10, $fn=32, center=true);
        }
    }
    translate(v=[0, frontScrewSpacing + railOtherThickness, 0])
    rotate(a=[0,0,270])
        cube(size=[railOtherThickness, frontFaceWidth - sideSupportExtraSpace, railTotalHeight]);
 }
 module _sideSupportSegment() {
    difference() {
        cube(size=[sideSupportDepth, railSideMountThickness, railTotalHeight]);
        for (i=[1:numRailScrews]) {
            translate(v=[sideSupportScrewHoleToFrontEdge, railFrontThickness/2, i*screwDiff + railFootThickness])
            rotate(a=[90,0,0])
                    cylinder(r=m4RadiusSlacked, h=10, $fn=32);
        }
    }
 }
 module _railFeet() {
    difference() {
        cube(size = [frontFaceWidth - sideSupportExtraSpace, sideSupportDepth, railFootThickness]);
        hull() {
            translate(v = [1.5, 5, 0])
                cylinder(r = m3RadiusSlacked, h = 10, $fn = 32);
            translate(v = [0, 5, 0])
            cube(size=[0.1, m3RadiusSlacked*2, 10], center=true);
        }
    }
 }
 module mainRail() {
    union() {
        _frontRailSegment();
        translate(v = [0, railFrontThickness, 0])
            _connectingLBracketRailSegment();
        translate(v = [frontFaceWidth-sideSupportExtraSpace, railFrontThickness + railOtherThickness + frontScrewSpacing, 0])
            rotate(a = [0, 0, 90])
                _sideSupportSegment();
        translate(v = [0, railFrontThickness + railOtherThickness + frontScrewSpacing, 0]) {
            _railFeet();
            translate(v = [0, 0, railTotalHeight-railFootThickness])
                _railFeet();
        }
    }
 }
 mainRail();
 echo("Total Rail Height = ", railTotalHeight);
 module mainRail() {
  // Distance between the middle of a screw mount and the rail's vertical edges
  railScrewHoleToInnerEdge = 5;
  railScrewHoleToOuterEdge = 5;
  // Distance between the midpoint of the rail screw holes.
  rackMountScrewWidth = maxUnitWidth + 2 * railScrewHoleToInnerEdge;
  railFrontThickness = 6; // Make sure that the nuts for the chosen screw type can slot within the front face
  railSideMountThickness = 2.5;
  railOtherThickness = 2.5;
  // Extra spacing for the rack unit screws.
  frontScrewSpacing = 8;
  sideSupportExtraSpace = 2;
  sideSupportScrewHoleToFrontEdge = 5;
  sideSupportScrewHoleToBackEdge = 4.5;
  sideSupportDepth = sideSupportScrewHoleToBackEdge + sideSupportScrewHoleToFrontEdge;
  frontFaceWidth = railScrewHoleToInnerEdge + railScrewHoleToOuterEdge;
  union() {
    _frontRailSegment();
    translate(v = [0, railFrontThickness, 0])
    _connectingLBracketRailSegment();
    translate(v = [frontFaceWidth - sideSupportExtraSpace, railFrontThickness + railOtherThickness + frontScrewSpacing,
      0])
    rotate(a = [0, 0, 90])
    _sideSupportSegment();
    translate(v = [0, railFrontThickness + railOtherThickness + frontScrewSpacing, 0]) {
      _railFeet();
      translate(v = [0, 0, railTotalHeight - railFootThickness])
      _railFeet();
    }
  }
  module _frontRailSegment() {
    difference() {
      cube(size = [frontFaceWidth, railFrontThickness, railTotalHeight]);
      for (i = [1:numRailScrews]) {
        translate(v = [railScrewHoleToOuterEdge, railFrontThickness / 2, i * screwDiff + railFootThickness])
        rotate(a = [90, 0, 0])
        hexNutPocket_N(mainRailScrewType);
      }
    }
  }
  module _connectingLBracketRailSegment() {
    difference() {
      cube(size = [railOtherThickness, frontScrewSpacing + railOtherThickness, railTotalHeight]);
      union() {
        translate(v = [0, 4, railFootThickness + screwDiff / 2])
        rotate(a = [0, 90, 0])
        cylinder(r = screwRadiusSlacked(rackFrameScrewType), h = 10, $fn = 32, center = true);
        translate(v = [0, 4, railTotalHeight - (railFootThickness + screwDiff / 2)])
        rotate(a = [0, 90, 0])
        cylinder(r = screwRadiusSlacked(rackFrameScrewType), h = 10, $fn = 32, center = true);
      }
    }
    translate(v = [0, frontScrewSpacing + railOtherThickness, 0])
    rotate(a = [0, 0, 270])
    cube(size = [railOtherThickness, frontFaceWidth - sideSupportExtraSpace, railTotalHeight]);
  }
  module _sideSupportSegment() {
    difference() {
      cube(size = [sideSupportDepth, railSideMountThickness, railTotalHeight]);
      for (i = [1:numRailScrews]) {
        translate(v = [sideSupportScrewHoleToFrontEdge, railFrontThickness / 2, i * screwDiff + railFootThickness])
        rotate(a = [90, 0, 0])
        cylinder(r = screwRadiusSlacked(mainRailSideMountScrewType), h = 10, $fn = 32);
      }
    }
  }
  module _railFeet() {
    difference() {
      cube(size = [frontFaceWidth - sideSupportExtraSpace, sideSupportDepth, railFootThickness]);
      hull() {
        translate(v = [1.5, 5, 0])
        cylinder(r = screwRadiusSlacked(rackFrameScrewType), h = 10, $fn = 32);
        translate(v = [0, 5, 0])
        cube(size = [0.1, screwRadiusSlacked(rackFrameScrewType) * 2, 10], center = true);
      }
    }
  }
 }
--- a/cases/rack2/screws.scad
+++ b/cases/rack2/screws.scad
@ -1,113 +1,80 @@
 /* Some common screw dimensions and helper functions/modules */
-/* Some common screw dimensions */
+inf = 400;
 inf = 400; // basically infinity
 /********************************************************************************/
 // M3 dimensions
 m3HoleRadiusSlack = 0.15;
 m3Diameter = 3.0;
-m3Radius = m3Diameter/2.0;
+m3Radius = m3Diameter / 2.0;
 m3RadiusSlacked = m3Radius + m3HoleRadiusSlack;
 // legacy TODO: replace
 m3ptr = m3RadiusSlacked;
 // NUTS!
 m3HexNutWidthAcrossFlats = 5.41;
 m3HexNutWidthAcrossCorners = FtoG(m3HexNutWidthAcrossFlats);
 m3HexNutThickness = 2.18;
 module m3HexNutPocketNegative() {
  hexNutPocketNegative(m3RadiusSlacked,
                       m3HexNutWidthAcrossCorners/2 + 0.1,
                       m3HexNutThickness + 0.2);
 }
 // TODO: remove test
 *difference() {
  cube(size=[8,12,5], center=true);
  rotate(a=[0,0,20])
  m3HexNutPocketNegative();
 }
 *m3HexNutPocketNegative();
 /********************************************************************************/
 // M4 dimensions
 m4HoleRadiusSlack = 0.15;
 m4Diameter = 4.0;
-m4Radius = m4Diameter/2.0;
+m4Radius = m4Diameter / 2.0;
 m4RadiusSlacked = m4Radius + m4HoleRadiusSlack;
 m4HexNutWidthAcrossFlats = 6.89;
 m4HexNutWidthAcrossCorners = FtoG(m4HexNutWidthAcrossFlats);
 m4HexNutThickness = 3.07;
 module m4HexNutPocketNegative() {
  hexNutPocketNegative(m4RadiusSlacked,
                       m4HexNutWidthAcrossCorners/2 + 0.1,
                       m4HexNutThickness + 0.2);
 }
 // TODO: remove test
 *difference() {
  translate(v=[0,1,0])
  cube(size=[10,12,6], center=true);
  rotate(a=[0,0,20])
  m4HexNutPocketNegative();
 }
 *m4HexNutPocketNegative();
 /********************************************************************************/
-
+function screwRadiusSlacked(screwType) =
-// Convert a regular hexagon widthAcrossFlats to widthAcrossCorners
+  (screwType == "m3")
-function FtoG(widthAcrossFlats) = widthAcrossFlats * (2/sqrt(3));  
+  ? m3RadiusSlacked
-
+  : (screwType == "m4")
-// Convert a regular hexagon widthAcrossCorners to widthAcrossFlats
+  ? m4RadiusSlacked
-function GtoF(widthAcrossCorners) =  widthAcrossCorners * (sqrt(3)/2);
+  : error("Unsupported screw type");
-module hexNutPocketNegative(
+module hexNutPocket_N(screwType) {
-  innerRadius,
+  if (screwType == "m3") {
-  widthAcrossCorners,
+    hexNutPocketHelper_N(m3RadiusSlacked,
-  thickness)
+        m3HexNutWidthAcrossCorners / 2 + 0.1,
      m3HexNutThickness + 0.2);
  } else if (screwType == "m4") {
    hexNutPocketHelper_N(m4RadiusSlacked,
        m4HexNutWidthAcrossCorners / 2 + 0.1,
      m4HexNutThickness + 0.2);
  } else {
    error("Unsupported screw type");
  }
 }
 module hexNutPocketHelper_N(
 innerRadius,
 widthAcrossCorners,
 thickness)
 {
  union() {
    hull() {
      // hexagonal cylinder representing where the nut should fit
-      cylinder(r=widthAcrossCorners, h=thickness, center=true, $fn=6);
+      cylinder(r = widthAcrossCorners, h = thickness, center = true, $fn = 6);
      // negative volume for sliding in the nut
-      translate(v=[inf,0,0])
+      translate(v = [inf, 0, 0])
-      cylinder(r=widthAcrossCorners, h=thickness, center=true, $fn=6);
+      cylinder(r = widthAcrossCorners, h = thickness, center = true, $fn = 6);
    }
    // negative volume for screw lead
-    translate(v=[0,0,-10])
+    translate(v = [0, 0, - 10])
-    cylinder(r=innerRadius, h = inf, $fn=32);
+    cylinder(r = innerRadius, h = inf, $fn = 32);
    hull() {
-     translate(v=[inf,0,0])
+      translate(v = [inf, 0, 0])
-       cylinder(r=innerRadius, h = inf, $fn=32);
+      cylinder(r = innerRadius, h = inf, $fn = 32);
-     cylinder(r=innerRadius, h = inf, $fn=32);
+      cylinder(r = innerRadius, h = inf, $fn = 32);
    }
  }
 }
 // Convert a regular hexagon widthAcrossFlats to widthAcrossCorners
 function FtoG(widthAcrossFlats) = widthAcrossFlats * (2 / sqrt(3));
 // Convert a regular hexagon widthAcrossCorners to widthAcrossFlats
 function GtoF(widthAcrossCorners) = widthAcrossCorners * (sqrt(3) / 2);