1.3 BOM, Subassemblies & Kitting

Material readiness andis modulethe breakdown.

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Turningengine aof predictable box build. A design intoonly abecomes smoothlymanufacturable built product starts with reshapingonce the BOM is reshaped into tested subassemblies and howoperator-friendly materialskits, showwith upevery attorque spec, consumable, and variant captured in the line.right Thesystem. handoffWhen ismodules EBOMare →pre-verified MBOM:and EBOMcarts (engineeringare billscanned clean, the line can flow without the distractions of materials)shortages, capturesmix-ups, “whator itlast-minute is,” while MBOM (manufacturing bill of materials) defines “how we build it” with real modules and kits. Breaking work into small, testable subassemblies keeps the main line fast and predictable, while kitting turns planning into something a cart—and an operator—can trust at start. Control lives in systems too: MES (manufacturing execution system) runs the shop-floor rules, and ERP (enterprise resource planning) holds the business record so variants, labels, and consumables match the SKU. Traceability—serial numbers, lot IDs, torque logs, and software images—creates product genealogy that pays off in RMAs and compliance. With clear alternates via an AVL (approved vendor list) and clean readiness gates, shortages become manageable detours instead of line-stopping surprises.fixes.

1.3.1 EBOM → MBOM: make the product buildable

EBOM (engineering BOM): “what it is” — parts on drawings.
MBOM (manufacturing BOM): “how we build it” — modules, kits, and consumables grouped for the line.

Convert once, own in MES/ERP

Break the product into L1 subassemblies (fan wall, PSU tray, front I/O, harness set, label set).
Add consumables (TIMs, threadlock, adhesives, gaskets, tape, labels) as real MBOM lines with units/kit
Record torque groups and program images as pseudo-items (so kitting can verify them exist before start).
Keep variant columns (A/B/C)—same MBOM, different marks.

1.3.2 Module breakdown (build the slow bits off the main line)

A good module saves time on the box line and can be tested alone.

Module (L1)	Contents	Why it helps	Test/Check
PSU tray	PSU, cage, EMI fingers, earth bond	Early torque/earth; easy swap	Earth bond < 0.1 Ω
Fan wall	Fans, guard, harness, label	Cable work off-line; airflow arrows validated	Spin & current
Front I/O	PCBAs, light pipes, buttons, harness	Cosmetic alignment off-line	Button/LED check
Display/door	Hinge, gasket, bezel	Seal & flushness off-line	Gasket compression
Harness set	Pre-tested loom bundle	One SKU, one bag	Continuity log
Label set	Regulatory + brand + SN placeholder	Zero hunting; region-safe	Visual vs map
Accessory kit	Cord, screws, rails, manual	Pack ready; region-safe	Count & region

Rule: If it’s fiddly, has torque, or needs test—make it a module.

1.3.3 BOM that the floor can pick (columns that matter)

Item	Qty/Unit	Int. PN	Mfr PN	Description	Variant A/B/C	Alt/AVL	Torque/Spec	Notes
10	1	800-110	—	Subassy, PSU Tray	✔/✔/✔	—	Earth <0.1 Ω	L1 module
20	1	520-015	ABC-123	Fan, 80×80, 12 V	✔/—/✔	DEF-456	0.8 N·m	Arrow ↑
30	1	760-042	—	Kit, Labels (EU)	—/✔/—	—	—	Map LB-22
40	1	911-007	—	TIM Kit (pads/paste)	✔/✔/✔	—	Bead 1.5 mm	Syringe 3 g
50	1	600-201	—	SW Image, v3.2	✔/✔/—	—	Checksum 9F…	MES-pushed

Tips

Put subassemblies in the top 20 lines; raw parts later.
Use Alt/AVL openly; don’t hide in a PDF.
Put torque / bead sizes / gasket compression right in BOM notes.

1.3.4 Kitting patterns (choose one, or blend)

Full cart kit (one cart = one unit): fastest at line start; great for high mix.
Module supermarket + light point-of-use pick: keep L1 modules on a min/max supermarket; line picks only a short list (screws, pads, ties).
Wave kitting: pre-stage N units for a shift; good for runners.

Cart layout (top → bottom)

Label bin (locked to SKU), program card, torque map print.
L1 modules: trays, fan wall, I/O, harness set.
Small parts totes: screws by torque group (color cups), spacers, washers.
Consumables: TIM kit, threadlock, tape, gaskets (sealed & dated).
Accessories: cords, rails, manuals, region items.

Color bands on the cart = Variant (e.g., A=Blue, B=Orange).

1.3.5 Material readiness gates (no kit, no start)

The line starts only when the kit passes these:

Variant check — Cart barcode = SKU/Variant; MES unlocks SWI, label map, and test only on match.
Subassembly status — L1 modules show PASS in MES (with their own SNs/earth test where relevant).
Critical-lot scans — PSU, PSU earth strap, harness SN, gaskets, TIMs, adhesives (lot/expiry), labels (region).
Torque & tools — Drivers in cal; bits present; torque map printed on the cart.
MSD/age-sensitive — None? Great. If present (e.g., some gaskets/adhesives), window open and noted.

Fail any → NG-QUAR the cart; do not “borrow” parts ad hoc.

1.3.6 Shortage playbook (calm, visible, reversible)

Ladder (in order):

Use AVL alternate (same spec) — MES swap with reason code.
Variant swap (if safe): run SKU B while A is short—product wheel helps.
Partial build to a clean hold point (e.g., up to lid close) — park in WIP-HOLD with red tag & list.
Module pull from supermarket — keep the box line moving.
Stop — when safety/regulatory items are missing (earth strap, gasket, label set), don’t build.

Never substitute safety/EMC pieces without PE/QE sign-off.

1.3.7 Label & region control (easy to get wrong)

Label kits per region/SKU in sealed bags with map ID; MES prints SN/regulatory from SKU only.
Power cords/accessories tied to SKU; pack cell verifies by scan.
Language manuals: SKU-bound; no free picking.

1.3.8 Data that binds it all (genealogy that matters)

Bind subassembly SNs to the final unit SN at install:

PSU tray SN, fan wall SN, harness SN(s).
Lot IDs: labels, gaskets, TIMs, threadlock, adhesives.
Torque record: sampled results per map (station logger).
Programming image checksum + time.

This is your box-build genealogy—gold for RMAs.

1.3.9 Metrics that tell you kitting works

Kit accuracy = (kits started with zero line-side adds) ≥ 98–99%.
Start-on-time rate per shift.
Pick errors PPM (wrong part in kit).
Module FPY (L1) — if low, the line will starve.
Shortage minutes (bottleneck starved) trending down.

1.3.10 Common traps → smallest reliable fix

Trap	Symptom	Fix
EBOM handed to floor	Endless hunting	Build a MBOM with modules/consumables; publish in MES
Raw screws by length only	Wrong torque/hardware	Torque groups: color cups + PN + N·m on cart
Labels free-picked	Region mix-ups	Label kits per SKU + MES print; block start without kit
TIMs as “shop supply”	Over/under paste	TIM kit with bead gauges & photo map; lot/expiry scan
Modules without test	Rework at final line	Test L1: earth, spin, LED/button, continuity before box
Quiet alternates	Fire drills at shortage	Put AVL in BOM; enable MES swap with reason
Borrowing from other kits	Ghost shortages later	Block cart close until reconciled; red-tag any borrow

1.3.11 Pocket checklists

Designing the MBOM

L1 modules defined; each has a test and a PASS state
Consumables (TIMs, gaskets, adhesives, threadlock) added as lines
Torque groups and program image listed as pseudo-items
Variant columns (A/B/C) filled; AVL alternates set

Building a kit

Cart scanned to SKU/Variant; MES unlocks SWI/labels/test
L1 modules show PASS; SNs printed on traveler
Critical lots scanned (PSU, harness, label set, TIMs/gaskets/adhesives)
Torque bits present; drivers in cal; torque map on cart

At line start

Kit OK tile green; no adds; MSD/expiry OK
First article: dry fit + routing check; torque audit sample
Bind module SNs to unit SN as installed

Bottom line:Conclusion: translateConverting EBOMs into tested MBOM modules, enforcing kitting gates, and tying data to MES creates a controlled, traceable build process. With this structure, material handling stops being a source of delays and becomes the engineeringfoundation BOMfor intoconsistent, moduleshigh-quality and kits, test the tricky parts off-line, and start only with a green cart that matches the SKU. With AVL alternates ready, labeled torque groups, and kit scans tied to MES, material becomes boring—and box build becomes flow.output.