ReCoil · WORKBENCH PRIVATE

ReCoil Workbench

▸ NEVER DROP A BARREL AGAIN.
Your desk — mock, notes, the convert-engineering doc, the parts list, CNC to-do, and the patent inventory. Updated 2026-07-06 (doc v4).
Tools · mocks · notes

Open your stuff

Convert-engineering doc · v4

Commercial slat-door conversion on resi stock parts

Working doc, not final spec. Every number gets verified per-door by measurement + the Convert Designer tool.

1 — The physics that runs a coiling door

SECTIONAL:  drum radius constant. Weight transfers to horizontal track
            as it opens. Torque demand falls ~linearly. Spring torque
            falls linearly per unwound turn. Matched.

COILING:    the curtain IS the load AND the drum.
            Hanging weight falls as it coils:   W(x) = w · (H - x)
            Coil radius GROWS per wrap:          R(n) = R_pipe + n · t
            Torque demand at barrel:             T(x) = W(x) · R(x)

KEY FACT:   max weight at MIN radius (closed), min weight at MAX radius
            (open). Geometry self-compensates — torque curve is FLATTER
            than the weight curve → friendly to linear-rate torsion springs.

TURNS:      commercial coils turn FEW times (~2-4) → factory springs are
            short/fat/huge-IPPT. RESI springs are the opposite: long,
            skinny, many-turn, modest IPPT (~55-70 in-lb/turn each).

2 — Central insight: a turns multiplier

k = (barrel-side drive radius) / (resi-shaft drive radius)
    Spring shaft turns   = k × barrel turns      (more turns — resi home field)
    Spring torque needed = barrel torque / k     (less torque — ditto)
The numbers want to work. 350 lb curtain, 8" avg coil radius → ~2,800 in-lb at the barrel. At k=4 the resi shaft sees ~700 in-lb and winds ~10 turns — native habitat, margin to spare.

3 — The concepts (A direct · B chain · C cable · D avoid)

A — DIRECT COUPLE (CNC hub, 1:1)     ← wins the VOLUME MID market
B — CHAIN TORQUE COUPLE              ← HEAVY doors; exact ratio, bidirectional
C — CABLE TORQUE COUPLE              ← tight clearance; cables only PULL
D — BOTTOM-BAR CABLE LIFT — AVOID (doesn't coil the curtain). Helper only.

8 — Simulation (three door classes)

MID 12x12, 1.6 psf, 6" pipe   ← THE VOLUME MARKET
    Winner: YOUR springs (.325 × 3.75"ID × 46" pair), DIRECT 1:1
    Match 89% · wind 7.8 turns · barrel 5.2 turns · peak 796 in-lb
    Wire 118 ksi → >50k cycles. UNDERSTRESSED. NO drums, NO cables.
LIGHT 10x10:  soft pair 1.8× too stiff at 1:1 → run ONE soft spring.
HEAVY 14x14, 2 psf:  1,311 in-lb → k≈1.5-2 chain couple + softer springs.
1/k² LAW: required stiffness falls with the SQUARE of ratio k.

9 — Wind direction / handedness (direct couple)

Shaft rotation = barrel rotation (1:1, no reversal). Springs store
torque in the barrel's COIL-UP direction: one LEFT + one RIGHT wound,
one each side, cones anchored to wall brackets, winding cones inboard.
SITE CHECK: hand-rotate barrel OPEN, confirm each spring TIGHTENS.

11 — Release routing · winding · pulley kit NEW

RELEASE CORD: extended cord, screw-eye guides down the jamb. FIRST eye
placed so the initial pull stays in the 8500 lever's throw plane; zigzag
freely after. Slack so routing never pre-loads the lever. Test at closed
AND half-travel.

SPIN DIRECTIONS: direct couple = one shaft, one rotation, no conflict.
Chain / open-cable = same direction both shafts; CROSSED cable = reversed.
Reversal is a ROUTING CHOICE, never a blocker.

PULLEY KIT (heavy variant): resi low-headroom / rear-mount redirect tricks
apply — sheaves zigzag the couple cable around obstructions. Each redirect
adds friction to the balance calc; RATED pulleys only at commercial tension.
Winding, solved — the worm-gear tensioner anchor (component #2). The stationary spring cone anchors as a self-locking worm-gear bracket: worm input takes a drill/ratchet, cannot back-drive, holds zero pressure on you — no winding bars at any torque, ever. Balance is micro-adjustable in the field by quarter-turns. Sized: output torque ≥ 1.5× peak shaft torque; keep total turns on a counter/index ring. This is the direct answer to "winding upward is dangerous."

12 — v0.2 validated designs + research NEW

RESEARCH: rolling-door inner shafts run 1" / 1-1/4" (resi sizes). Head
plates already carry barrel + hood. Inner-spring replacement is the trade's
worst job. → ReCoil's statement: NEVER DROP A BARREL AGAIN.

NUMBERS (verified):
  1" solid shaft @ 1,311 in-lb → 6,700 psi shear (30k+ capacity)
  Collar bolts (6 @ 2.6" R)    → 51-84 lb each (5/16 Gr5 rated >3,000)
  BEARINGS: curtain weight stays on stock head plates — barrel untouched.
  ReCoil shaft bearings carry only shaft+spring static (+chain radial).
  Resi 2" end bearings (2" race, 1" bore): comfortably rated. Confirmed.

STOCK-SHAFT REUSE: existing 1"/1-1/4" solid, straight, ends protrude →
REUSE natively. Bent/undersized/captive → replace with 1" solid CRS.
Either way inner springs de-tensioned at the stock wheel + retired in place.
Bill of materials

Parts used

CORE every job · CNC machined part · v0.2 latest design. All resi/truck stock except the CNC pieces.

PartSpec / note
CORE — every conversion
Shaft COREREUSE stock 1"/1-1/4" solid if straight & protruding; else 1" solid CRS. Resi bearings, springs, 8500 all fit it natively.
Resi torsion springs CORESized by the sizer. Mid ≈ .325 × 3.75" ID × 46" pair, one L + one R wound. Light = one soft spring. Heavy = softer long pair at k≈1.5-2.5.
Outside-mount collar hub CNC v0.2The first CNC part to cut. Split collar, 1.030" bore, clamped by 2× 3/8 cross bolts, 6 radial arms tab-bolt to the PIPE END WALL from outside — no barrel teardown, installs at the head plate. 1018 steel. (Supersedes v0.1 insert hub.)
Worm-gear tensioner anchor CNC v0.2Component #2. Self-locking worm; drill/ratchet input; can't back-drive → replaces winding bars. Micro-adjust by quarter-turns. Output ≥ 1.5× peak shaft torque; turn counter/index ring.
Resi 2" end bearings CORE2" race, 1" bore. Carry only shaft + spring static weight — barrel stays on stock head plates.
Back-mount bracket family v0.23/16" min steel plate, bolts to guide angle / jamb steel (never wood). Carries end bearing, worm anchor, hood lip, and (variant) chain-idler post. Slotted holes. One plate family, holes for all three concepts.
Extended hood v0.224 ga galvanized (stock hood practice), lengthened past the brackets to cover external springs/tensioner/chain. Weather + finger guard; doubles as the moving-parts guard the safety listing wants.
Safety bearing v0.2Rolling-door inertia brake (stops free-fall on spring/drive failure). Stock component — SPEC ONE drive-side on every motorized conversion. Non-negotiable.
LiftMaster 98032 COREResidential HD DC jackshaft (replaces the 98022) — monitors cable tension internally so no external monitor, 400–1,100 lb, mounts a 1" bar, 8.5" sideroom. Heavy/continuous commercial → JDC or LJ8900W instead. Datasheet-verified; full write-up on Door Systems.
Release cord + screw-eye guides COREExtended cord to the door side; first eye in the 8500 lever's throw plane, zigzag after. Redirect pulley if the pull angle is tight.
CHAIN COUPLE — heavy doors (Concept B)
Barrel-ring drive sprocket CNCRing-clamp sprocket — the chain-couple invention piece.
Shaft sprocket + idlerTooth count sets ratio k. Idler tensions and can flip rotation sense for safe wind handedness.
#41 / #48 roller chainTruck stock. Bidirectional — powers the door down as well as up.
CABLE COUPLE — tight-clearance variant (Concept C)
Resi cable drumsOn the spring shaft — truck stock.
Barrel-end drum flanges CNCLarger radius = ratio k. CNC or welded band on the barrel ends.
Aircraft cable + clamps2 sets min (both ends), 3rd center on wide doors. Crossed run = reversed rotation. Cables only PULL.
RATED redirect pulleysRated for commercial tension — NOT resi extension-spring sheaves. Route around clearance problems.
CNC notes · design to-do

What we cut & work on next

Winding safety — settled. Two layers: (1) you wind at the resi shaft, resi torque — the couple multiplies to the barrel, so no one ever hand-winds commercial pressure; (2) the worm-gear tensioner anchor self-locks, so there are no winding bars at all and no held pressure. That's the "wind pressure going down, not up" you wanted — built into the part.

Answering your cable-direction question (§11 confirms it)

CHAIN (open loop)    → both sprockets SAME direction
CHAIN (+ back idler) → FLIPS shaft to OPPOSITE (and tensions the chain)
CABLE (open run)     → drums SAME direction
CABLE (crossed /
      redirect pulley)→ drums OPPOSITE

You're never forced into a bad wind handedness — reversal is a routing choice. And the low-headroom / rear-mount pulley trick you pictured is real: sheaves can zigzag the couple cable around obstructions. Cautions: those resi tricks redirect lift cables to the bottom bar (here it's the shorter drum-to-drum loop, keep wraps clean, small fleet angles), and cable only pulls — need the motor to drive the door down through the couple? That's the chain's job, not cable.

Hub — v0.2 supersedes v0.1

v0.2 OUTSIDE-MOUNT COLLAR (cut this one):
  Split shaft collar, 1.030 bore, 2× 3/8 cross bolts, 6 radial arms →
  tabs bolt to the PIPE END WALL from OUTSIDE. Installs at the head
  plate, no barrel teardown. Positive bolt engagement (never friction-
  only). Two per door, or one drive-side + stock idler at the other end.
  Material: 1018 steel.
v0.1 insert hub (DXF, offline) = earlier concept, superseded.
MEASURE FIRST on a real barrel: pipe end-wall thickness/gauge, shaft
size + straightness, ring positions, guide bolt pattern, run-out.

Design to-do

Provisional #6 inventory

File before the first customer install

Public use without filing risks foreign rights. Eleven items (full detail on the Door Systems page):

  1. The externalized-counterbalance conversion method — inner springs retired, serviceable external resi-stock counterbalance (the "never drop a barrel" method).
  2. Outside-mount collar hub (v0.2) — tab-bolts to the pipe end wall from outside, no teardown.
  3. Worm-gear self-locking tensioner anchor — fine-adjust, no bars, can't back-drive. (Distinct from coarse in-barrel tension-wheel + pawl prior art.)
  4. The 1/k² ratio-selection method + Designer tool — picks spring/ratio per door.
  5. Unified back-mount bracket family — one plate, all three concepts.
  6. Extended hood as combined guard/enclosure — weather + moving-parts guard for the safety listing.
  7. Heavy-door chain-couple variant — with crossed-cable reversal option.
  8. Drum-hub bushing — dead-axle-to-live-shaft sheet-door method (through-pinned drum adapters to a 1" live shaft).
  9. Ratio-as-speed-governor — couple ratio balances springs (1/k²) and reduces curtain speed (1/k); light-curtain still required.
  10. Self-anchoring conversion mount — load path into the door's own guide/head-plate steel + head-unit consolidation + angle-iron adapter.
  11. Minimax wind targeting — wind a conversion to center mid-travel imbalance (coiling demand peaks after the floor); per-door, computed by the calculator.