remote-rig/hardware/case/camera-node-case-v4.scad

// RemoteRig camera node case v4
// Parametric OpenSCAD prototype for a status-panel camera node enclosure.
// Units: millimeters.  Coordinate system: X=width, Y=depth/front-back, Z=height.
// Front/service lid is on the -Y face. Rear strap channels are on the +Y face.
//
// Prototype assumptions to confirm against purchased parts:
// - 1.3 inch OLED module/window opening: 31 x 16 mm visible window, 35 x 19 mm panel clearance.
// - Small rocker switch cutout: 13 x 19 mm rectangular snap-in opening.
// - LEDs: two 3 mm panel LEDs (PWR + RGB STAT) with 3.2 mm holes.
// - Boards: ESP32-C3 Super Mini 22.5 x 18 mm, ESP-01S 24.7 x 14.3 x 12 mm.

$fn = 48;

// ----- Main enclosure parameters -----
case_w = 68;                 // external width; room for OLED + LEDs + switch
case_d = 42;                 // external depth; board stack + wiring clearance
case_h = 32;                 // external height
wall = 2.2;
corner_r = 3.0;
front_recess_d = 2.0;        // lid sits in this front pocket, nominally flush
lid_clearance = 0.35;
lid_w = case_w - 8;
lid_h = case_h - 6;
lid_t = 2.0;
lid_lip_t = 1.2;             // locating lip protrudes inside service opening
lid_lip_inset = 2.1;
// Central body opening avoids the four corner screw bosses.  Separate local
// clearances below handle the OLED/switch bodies without cutting away bosses.
service_opening_w = 46.0;
service_opening_h = 11.5;

// Hardware
screw_d = 2.4;               // M2 self-tapping / pilot; confirm hardware
screw_head_d = 4.6;
boss_d = 6.0;
boss_len = 8.0;

// Front panel components
// OLED values are intentionally conservative prototype placeholders.
oled_window_w = 31.0;
oled_window_h = 16.0;
oled_bezel_w = 35.0;         // engraved/recessed visual outline around window
oled_bezel_h = 19.0;
led_hole_d = 3.2;            // 3 mm LED clearance
rocker_w = 13.0;             // prototype cutout; measure purchased rocker
rocker_h = 19.0;
vent_slot_w = 7.0;
vent_slot_h = 1.7;

// Rear reusable cloth zip-tie / Velcro strap channels
strap_bridge_w = case_w - 12;
strap_bridge_h = 7.5;        // outer raised tab height
strap_slot_h = 4.2;          // strap thickness opening; adjust for cloth ties
strap_gap_y = 3.2;           // clearance behind bridge for strap material
strap_bridge_y = strap_gap_y + 2.2;
strap_z1 = 8.5;
strap_z2 = 23.5;

// Cable exit
cable_notch_w = 13.0;
cable_notch_h = 6.0;

// ----- Utility geometry -----
module rounded_box(size=[10,10,10], r=2, center_xy=true) {
    // Rounded in XY, straight in Z.
    linear_extrude(height=size[2])
        offset(r=r)
            square([size[0]-2*r, size[1]-2*r], center=center_xy);
}

module y_cylinder(d, h, center=true) {
    rotate([90,0,0]) cylinder(d=d, h=h, center=center);
}

module screw_boss(x, z) {
    translate([x, -case_d/2 + front_recess_d + boss_len/2, z])
        difference() {
            y_cylinder(d=boss_d, h=boss_len);
            y_cylinder(d=screw_d, h=boss_len + 0.8);
        }
}

module strap_bridge(zc) {
    // Raised rear bridge with a smooth-ish strap tunnel through it.
    // It intentionally overlaps the main shell by ~2.2 mm so the STL is a
    // single printable body, not separate coincident strap-tab volumes.
    translate([0, case_d/2 + strap_bridge_y/2 - 2.2, zc - strap_bridge_h/2])
        difference() {
            rounded_box([strap_bridge_w, strap_bridge_y, strap_bridge_h], r=2.0);
            // Through-slot for the cloth tie.  It cuts all the way through Y,
            // while leaving side posts that tie the upper/lower rails together.
            // Matching rear-wall cutouts are made in camera_node_body_v4().
            translate([0, 0, (strap_bridge_h - strap_slot_h)/2])
                rounded_box([strap_bridge_w - 8.0, strap_bridge_y + 0.8, strap_slot_h], r=1.2);
        }
}

// ----- Printable body -----
module camera_node_body_v4() {
    difference() {
        union() {
            difference() {
                union() {
                    // Outer shell.
                    translate([0,0,0]) rounded_box([case_w, case_d, case_h], r=corner_r);

                    // Rear cloth zip-tie / Velcro strap bridges.
                    strap_bridge(strap_z1);
                    strap_bridge(strap_z2);
                }

            // Front recessed lid pocket (shallow, so the lid can sit flush).
            translate([0, -case_d/2 - 0.2, case_h/2])
                cube([lid_w + lid_clearance, front_recess_d + 0.3, lid_h + lid_clearance], center=true);

            // Through service opening behind the lid, leaving a recessed ledge/frame.
            service_depth = front_recess_d + wall + 2.0;
            translate([0, -case_d/2 + service_depth/2, case_h/2])
                cube([service_opening_w, service_depth + 0.4, service_opening_h], center=true);

            // Local front clearances for the OLED module and rocker-switch body.
            // These keep the screw-boss corner material intact while still leaving
            // room for front-panel components and wiring to enter the body cavity.
            translate([0, -case_d/2 + service_depth/2, (case_h - lid_h)/2 + lid_h - 9.5])
                cube([oled_bezel_w + 2.0, service_depth + 0.4, oled_bezel_h + 3.0], center=true);
            translate([15.5, -case_d/2 + service_depth/2, (case_h - lid_h)/2 + 12.0])
                cube([rocker_w + 3.0, service_depth + 0.4, rocker_h + 3.0], center=true);

            // Rear-wall pass-through slots for reusable cloth zip-ties / Velcro.
            // The slots align with the raised bridges, so straps can thread through
            // the back of the case instead of sitting in a closed decorative groove.
            for (zc=[strap_z1, strap_z2])
                translate([0, case_d/2 + 1.0, zc])
                    cube([strap_bridge_w - 8.0, 8.0, strap_slot_h], center=true);

            // Interior electronics cavity: ESP32-C3 Super Mini + ESP-01S plus wiring/service clearance.
            cavity_d = case_d - front_recess_d - 2*wall;
            translate([0, -case_d/2 + front_recess_d + wall + cavity_d/2, case_h/2])
                cube([case_w - 2*wall, cavity_d, case_h - 2*wall], center=true);

            // Bottom cable exit / strain-relief notch on lower front edge.
            translate([0, -case_d/2 + 2.0, -0.05])
                cube([cable_notch_w, 9.0, cable_notch_h], center=true);
        }

            // Four protected screw bosses are added after shell hollowing so the
            // electronics cavity cannot cut away the receiving material.
            screw_x = lid_w/2 - 5.0;
            screw_z_low = (case_h - lid_h)/2 + 4.2;
            screw_z_high = case_h - screw_z_low;
            screw_boss(-screw_x, screw_z_low);
            screw_boss( screw_x, screw_z_low);
            screw_boss(-screw_x, screw_z_high);
            screw_boss( screw_x, screw_z_high);
        }

        // Final body-level pilot holes cut through the front frame into the
        // protected bosses. Without this pass the boss pilot holes can be
        // hidden behind solid frame material.
        screw_x = lid_w/2 - 5.0;
        screw_z_low = (case_h - lid_h)/2 + 4.2;
        screw_z_high = case_h - screw_z_low;
        for (x=[-screw_x, screw_x], z=[screw_z_low, screw_z_high])
            translate([x, -case_d/2 + front_recess_d + boss_len/2, z])
                y_cylinder(d=screw_d, h=boss_len + front_recess_d + 4.0);
    }
}

// ----- Printable front service lid / status panel -----
module camera_node_lid_v4() {
    difference() {
        union() {
            // Visible flush panel.
            translate([0,0,0]) rounded_box([lid_w, lid_t, lid_h], r=0.65);

            // Rear locating lip fits inside the central service opening and helps
            // panel alignment.  Center it on the body's central opening so it
            // does not collide with lower vent geometry.
            lip_h = service_opening_h - 0.5;
            translate([0, lid_t/2 + lid_lip_t/2 - 0.2, (lid_h - lip_h)/2])
                rounded_box([service_opening_w - 0.5, lid_lip_t, lip_h], r=0.45);

            // Shallow raised text pads/labels are omitted for print simplicity; add decals or paint-fill.
        }

        // OLED window and shallow module outline/recess.
        translate([0, -0.2, lid_h - 9.5])
            cube([oled_window_w, lid_t + lid_lip_t + 0.8, oled_window_h], center=true);
        translate([0, -0.35, lid_h - 9.5])
            cube([oled_bezel_w, 0.7, oled_bezel_h], center=true);

        // LED holes: separate power LED and single RGB status LED.
        translate([-17.0, -0.2, 11.5]) y_cylinder(d=led_hole_d, h=lid_t + lid_lip_t + 1.0);
        translate([-9.0, -0.2, 11.5]) y_cylinder(d=led_hole_d, h=lid_t + lid_lip_t + 1.0);

        // Rocker switch snap-in opening.
        translate([15.5, -0.2, 12.0])
            cube([rocker_w, lid_t + lid_lip_t + 1.0, rocker_h], center=true);

        // Lower vent / style slots.
        for (i=[-2:2])
            translate([i*9.5, -0.2, 4.8])
                cube([vent_slot_w, lid_t + lid_lip_t + 1.0, vent_slot_h], center=true);

        // Screw clearance/counterbore holes.
        screw_x = lid_w/2 - 5.0;
        screw_z_low = 4.2;
        screw_z_high = lid_h - screw_z_low;
        for (x=[-screw_x, screw_x], z=[screw_z_low, screw_z_high]) {
            translate([x, -0.2, z]) y_cylinder(d=screw_d + 0.4, h=lid_t + lid_lip_t + 1.0);
            translate([x, -0.15, z]) y_cylinder(d=screw_head_d, h=1.2);
        }
    }
}

// ----- Non-print preview assembly -----
module camera_node_preview_v4(show_lid=true) {
    color("lightgray") camera_node_body_v4();
    if (show_lid)
        translate([0, -case_d/2 - lid_t/2 - 0.2, (case_h - lid_h)/2])
            color("gainsboro") camera_node_lid_v4();

    // Internal board volume guides (not printed): ESP32-C3 and ESP-01S envelopes.
    color([0,0.45,0,0.35]) translate([-13, -1, 9]) cube([22.5, 18, 4], center=true);
    color([0,0.2,0.8,0.35]) translate([13, -1, 20]) cube([24.7, 14.3, 12], center=true);
}

// Select part to render from OpenSCAD CLI with: -D 'part="body"'
part = "preview"; // "body", "lid", or "preview"

if (part == "body") {
    camera_node_body_v4();
} else if (part == "lid") {
    camera_node_lid_v4();
} else {
    camera_node_preview_v4();
}