3.3 Depanelization Choices

Separating boards from their panels is the last mechanical step before a product is truly finished, and it carries more risk than it appears. The wrong depaneling method can silently introduce cracks in brittle components, leave edges out of tolerance, or contaminate surfaces with fiber dust. V-scoring delivers speed at the cost of higher stress, routers trade dust for cleaner outlines, and lasers offer precision with minimal strain but higher cost. Success depends on aligning method with board fragility, cosmetic requirements, and throughput goals—while managing dust, static, and fixture stability to keep reliability intact.

3.3.1 The problem in one minute

You’ve got good panels. Now you need good singles—without cracking MLCCs, snowing the room with fiberglass, or chewing ugly edges that won’t fit bezels. The right depanel method depends on stress tolerance, edge spec, throughput, and what debris your product can tolerate (none, ideally).

3.3.2 Three main methods (what each is best at)

Method	How it works	Edge quality	Stress on PCA	Debris/ESD	Where it shines	Watch-outs
V-score + “pizza cutter”	Factory-scored grooves snapped or rolled apart	Fair; slight knife burr	Higher (board bending)	Low dust; static from rollers	Fast, cheap, high volume, straight seams	Keep parts ≥2–3 mm from score; rails help
Tab-route (router + mousebites)	Milled outline + perforated tabs snapped or milled	Good–very good	Low–medium (if well-fixtured)	Glass dust; manage with vac & ionizer	Curvy outlines, tight bezels, metal-core	Bit wear = burrs; noise; keep guards on
Laser (UV/CO₂)	Ablates outline without force	Excellent (UV best)	Very low	Char/soot minimal with UV, more with CO₂	Thin/flex/rigid-flex, tiny gaps, tight keepouts	Slower; capex; heat-affected edge if overdone

Rule of thumb: if components are close to the edge or you’ve cracked MLCCs before, move away from snap-heavy V-score toward router or laser.

3.3.3 Design knobs that make any method easier

Keepouts from final edge
- V-score: fragile parts (MLCCs, crystals) ≥ 2–3 mm, robust parts ≥ 1.5 mm.
- Router/laser: you can live with ≥ 1.0–1.5 mm; more for tall/heavy parts.
Rails & tabs
- Add breakaway rails so machines grip panels, not products.
- Mousebites: 0.30–0.50 mm webs, hole Ø 0.5–0.8 mm, pitch 0.8–1.2 mm. Tabs every 50–75 mm along long edges; avoid corners and connectors.
- Put robber tabs where cosmetics don’t matter; plan to sand/polish after.
Score geometry (if V-score)
- Blade angles 30°/45° common; residual web 0.30–0.50 mm.
- Straight lines only; don’t score into cutouts or tight radii.

3.3.4 Router setup (stress low, edges nice)

Hardware & bits

Spindle: 40–80 krpm typical.
Bit: 0.8–2.0 mm single-flute (O-flute) carbide for FR-4; larger for aluminum/MCPCB.
Kerf: ~bit Ø (plan clearances).
Vacuum extraction at the nose; add ionized air to knock down static.

Feeds & speeds (starter)

Feed: 50–150 mm/s depending on thickness and bit Ø.
Step-down: full-depth for thin boards; two passes for ≥1.6 mm or heavy copper.
Climb cut finish pass for cleaner edge.
Fixtures: vacuum table or pin fixture with top clamping fingers to stop chatter.

If edges fuzz/burr: new bit, slower feed/finish pass, check Z height; add deburr brush station for mousebite stubs.

Safety: router dust = glass fiber. Enclose, vacuum, HEPA. Ground the spindle and use ionizers—static can zap boards.

3.3.5 V-score separation (fast, cheap, but mind the strain)

Tools: manual snap fixture, rolling “pizza” cutter, or pneumatic foot-pedal separator.

How to reduce strain

Use a rolling blade rather than hand snap; it keeps the board flat.
Add hold-down rails and support fingers under the seam.
Don’t score over big inner copper pours without thermals—it makes the seam hard and raises force.
Measure bend strain during NPI (simple strain gauge or electronic strain checker near the edge). Many teams aim <500–700 με at risk parts.

Typical failure tells: cracked MLCCs near the seam, hairline fractures at BGA corners on thin boards. If you see them, switch the method or move parts back.

3.3.6 Laser depaneling (cleanest edges, lowest force)

Pick the wavelength

UV (355 nm): crisp edge, tiny heat-affected zone; best for FR-4/flex and close-to-edge parts.
CO₂ (10.6 µm): faster bulk removal, more soot/amber edge; OK for mask/FR-4 but watch cosmetics.

Programming

Multiple light passes > one heavy pass (keeps HAZ small).
Assist gas (N₂) and vacuum at the cut keep char off.
Leave 0.05–0.10 mm skin, then do a clean final pass to prevent splash-through on small slugs.

Where it wins: rigid-flex (no fibrils), very tight bezels, coated or sensitive assemblies where bending is forbidden.

3.3.7 Rigid-flex, MCPCB, and awkward builds

Rigid-flex: laser or sharp router only; no V-score across flex. Mask flex zones during handling; fixturing must support both stacks.
Metal-core / aluminum: router with aluminum-capable bits; collect chips separately; check burrs—edge may need a light chamfer.
Thick copper / 2+ mm boards: router or laser; V-score forces get high and crack parts.

3.3.8 Stress, debris, and ESD—quick risk table

Risk	V-score	Router	Laser	Mitigations
Mechanical strain	High	Low–Med	Lowest	Add rails, use roller, move parts back; router/laser if cracks
Fiber/particulate	Low	High (glass dust)	Low–Med (char)	Vac + HEPA; ionized air; wipe benches; post-clean if needed
ESD	Low	Medium (static)	Low	Ground spindles, ionizers, ESD mats, wrist straps
Edge cosmetics	Fair	Good–Excellent	Excellent (UV)	Finish pass, brush; laser multi-pass
Throughput/cost	Fast, cheap	Medium	Slower, higher capex	Choose by volume and risk

3.3.9 Symptom → smallest reliable fix

Symptom	Likely cause	First move
Cracked MLCCs near edge	V-score snap strain	Switch to router/laser; add rails; push keepout to ≥3 mm; use roller not hand snap
Fuzzy/burred edges	Dull bit; too fast feed	New bit; add finish pass; lower feed 20%; brush/deburr wheel
Mousebite teeth ugly	Tabs too wide/few; no finish	Smaller webs (0.3–0.4 mm), more tabs; quick end-mill nibble or sand pad
Charred laser edge	Power too high; slow pass	More passes at lower power; N₂ assist; final “polish” pass
Dust everywhere / AOI haze	Weak extraction	Nose-vac upgrade; HEPA check; ionized air at cutter; wipe & tack-roll after
Outline out-of-tolerance	Tool deflection, kerf error	Slower feed; thicker bit; comp kerf in CAM; verify fixture clamp

3.3.10 First-article & NPI checks (10-minute routine)

Method pick agreed (score/router/laser) with edge keepouts validated.
Strain check at worst refdes during separation (target <500–700 με or per component spec).
Edge gauge: measure outline vs drawing; record kerf/offsets.
Debris check: white cloth wipe near cuts, AOI lens check; dial extraction before ramp.
Cosmetics: compare edge to limit sample; mousebite finish acceptable?
Recipe saved (bit, rpm, feed, passes / blade pressure / laser power & speed).

3.3.11 Pocket checklists

Design-for-depanel (put on panel drawing)

Method intended (V-score / tab-route / laser)
Keepouts from final edge (V-score ≥ 2–3 mm; router/laser ≥ 1–1.5 mm)
Tab pattern (spacing, web, hole Ø) and don’t place near connectors
Rails present with tooling holes and fiducials

Router setup

Bit Ø / type posted; new bit installed; spindle 40–80 krpm
Feed & finish pass set; nose vacuum + ionizer on
Fixture clamps secure; test cut, measure kerf

V-score run

Roller height set; support fingers under seam
Strain gage at risk part (first lot); parts clear of score line
No hand snaps on live product unless approved

Laser run

UV/CO₂ recipe loaded; multi-pass, low HAZ strategy
Assist gas & vacuum at cut; sample edge inspected
Char minimal; outline within spec

After depanel

Deburr mousebites where called out; collect dust; ESD-safe wipe
Scan SNs if panel → singles; update traveler

When depanelization is chosen and controlled with intent, it becomes a seamless step rather than a hidden yield risk. Boards emerge with intact parts, clean edges, and consistent dimensions, ready for downstream assembly and customer inspection.