2.2 Fasteners, Torque & Thread Management

Proper tools, locking methods, and verification.

Fasteners are small parts with outsized consequences: they set the feel of the product, guard seals, and keep grounds reliable long after it ships. The core aim is clamp load—the squeezing force that holds the stack—delivered by torque (controlled twisting force) without crushing plastics or chewing up threads. Because clamp depends on friction, surface finishes, lubricants, and threadlockers can swing results wildly; the same torque on a dry zinc screw and an oiled one does not create the same joint. Mixed materials are standard in box build—steel, aluminum, and molded bosses—so picking the right thread form or insert is as much about serviceability as strength. Consistent technique and verified tools turn this into a repeatable process, while simple checks and traceable logs make it defensible when a rattle or leak shows up in the field. Nail these fundamentals and everything downstream—gaskets, EMC (electromagnetic compatibility) bonds, and customer perception—stays solid.

2.2.1 The idea (in one line)

Get the right clamp load into the joint—every time—without stripping threads, crushing plastics, or leaving anything loose.

2.2.2 Picking fasteners (cheat sheet for box build)

Use	Go-to choice	Why	Watch-outs
Steel/aluminum, repeat service	Metric machine screws (M2–M6, Torx) into threaded metal or steel inserts	Predictable torque, long life	Paint/powder in threads, galvanic mix
Plastics (bosses)	Plastic thread-formers (PT/Delta PT)	Cuts/form threads that resist pull-out	Pilot hole size critical; low speed
Sheet metal to sheet metal	Thread-forming screws (Tri-lobular)	No nuts; quick	Burrs; use controlled speed
Ground/Earth points	Serrated/star washer + machine screw	Reliable bite through finish	Don’t over-torque thin sheets
Reusable nut connections	Prevailing-torque nuts (nylon insert/metal crimp)	Built-in anti-loosening	Temp limits for nylon

Engagement rule of thumb

Into steel: ≥ 1.0×D thread engagement.
Into aluminum: ≥ 1.5×D or use steel insert.
Into plastics: follow screw vendor chart (often 2–3×D equivalent).

2.2.3 Tools & bits (make the driver do the thinking)

Tool	Best for	Pros	Watch-outs
Cam-over clutch screwdriver	Small screws (M2–M4)	Slips at set torque; great repeatability	Not for high torque
Click torque wrench/driver	General use	Familiar, inexpensive	Operator feel varies; easy to “double-click”
Shut-off (pneumatic/electric)	Medium torque, runners	Auto stop at set torque; fast	Needs PM; reaction control
DC smart driver	Critical joints / traceability	Logs torque/angle; OK/NOK logic	Cost; needs programming
Torque analyzer (bench)	Setup & audits	Verifies tools and bits	Use proper rundown adapter

Bits

Prefer Torx (TX) over Phillips—less cam-out. Keep bits labeled & rotated; worn bits drive rejects.

2.2.4 Torque basics without the headache

Clamp load F comes from torque T and friction: T = K × F × D

D = nominal diameter; K (nut factor) ≈ 0.20 dry, 0.18 zinc-plated, 0.12–0.15 lubricated.
Lubrication or threadlockers change K → same torque ≠ same clamp. Always spec torque with condition (“dry,” “oiled,” “Loctite 243”).

Practical knobs

If you change finish/locker, re-validate torque.
For soft stacks (gaskets/TIMs), consider torque + angle or sequence patterns to avoid squeeze-out.

2.2.5 Starter torque map (sanity ranges—tune to your joint)

(For machine screws into steel/aluminum inserts, “dry” zinc-plated; always validate on your parts.)

Size	Typical range (N·m)	Notes
M2	0.2–0.3	Small covers, light brackets
M2.5	0.35–0.6	Common PCB standoffs
M3	0.6–1.0	Fan guards, light chassis
M4	1.5–2.5	Heavier brackets, lid screws
M5	3–5	PSU trays, rail mounts
M6	6–9	Structural rails

Plastics (thread-forming): typically 0.2–1.2 N·m depending on boss and screw; set by strip-to-drive ratio (target ≥ 1.5×).

2.2.6 Locking methods (choose by vibration & service)

Method	Use when	Rework?	Notes
Medium threadlocker (blue 243)	General vibration, serviceable	Yes	Clean threads; note cure time
Low threadlocker (purple 222)	Small screws, plastics near	Yes	For M2–M3 where blue is too strong
High strength (red 271)	Permanent joints	No (heat)	Avoid near plastics/gaskets unless spec’d
Prevailing-torque nuts (nylock)	Repeated service	Yes	Temp limit ~100 °C for nylon
Serrated flange/star washer	Ground bonds, anti-rotate	Yes	Bites paint; good for EMC
Chemical patch (pre-applied)	Runners, speed	Yes	Consistent friction; stocking mgmt
Nord-Lock wedges	Severe vibration	Yes	Maintain clamp; higher torque needed
Safety wire / staking	Critical safety	No (cut)	Rare in box build; clear instructions needed

2.2.7 Thread health & prep

Go/No-Go gauge critical holes (23.1). Chase paint with taps; don’t upsize without MRB.
Blow out chips; no oily taps near label or gasket lands.
For plastics: confirm pilot diameter/depth; run at low speed and no impact.

2.2.8 Running the screw (repeatable moves)

Start by hand for 2–3 turns—prevents cross-thread.
Seat all screws lightly in a pattern, then final torque in criss-cross on lids/frames.
For gaskets/TIMs, walk torque in two passes (50% then 100%).
Record OK/NOK and apply a witness mark (paint pen) on critical fasteners.

2.2.9 Verification & audits (prove the numbers)

Setup: verify driver on a torque analyzer with the right rundown adapter; record setpoint & tool ID.
In-process audits: per cell/hour, do residual torque check (break-loose method) on a sample (target 80–100% of spec).
Smart drivers: log torque + angle curves; use OK windows.
Earth bond joints: measure < 0.1 Ω after tightening (23.1/22.1).

2.2.10 Plastics & inserts (keep bosses alive)

Use thread-forming screws; avoid machine screws directly into raw plastic unless specified.
Set torque by strip test: find strip torque on scrap, then run production at ~60–70% of strip.
Prefer heat-set brass inserts for serviceable joints; spec ultrasonic/heat install parameters.
If you hear cracking, stop—boss is failing.

2.2.11 Rework & repair rules

Allowed (record it):

Replace stripped metal threads with helicoil/keensert per drawing.
Replace failed plastic bosses with threaded insert + epoxy sleeve only if engineering allows.

Not allowed without MRB:

Upsizing screws ad hoc; mixing thread standards; grinding washers to fit; “just add more threadlocker.”

2.2.12 Acceptance cues (quick visual)

Head flush; no tilt; washer fully bearing.
Witness mark aligned across head and base.
No paint shear or spider cracks around holes.
Earth washer teeth visible bite into metal.
No ooze of excess threadlocker onto seals/labels.

2.2.13 Common traps → smallest reliable fix

Trap	Symptom	Fix
Same torque, different finish	Loose or stripped joints	Re-set torque for dry vs lubricated; note in SWI
Cross-thread at first touch	Crunch, tilted head	Hand-start 2–3 turns; lower start speed
Overtorque on plastics	Boss cracks later	Strip test → run at 60–70%; use thread-formers
Click “double-hit”	Overshoot	Teach one steady pull; prefer cam-over for small screws
Lock washer as only EMC bond	Poor continuity	Add serrated/star washer; verify <0.1 Ω
Random bit wear	Cam-out, shiny heads	Bit rotation schedule; Torx over Phillips
No audit trail	Can’t prove torque	Tool ID + daily analyzer check + residual audits

2.2.14 Pocket checklists

Before the build

Torque map posted; tools in cal with IDs
Bits correct (Torx preferred), spares at station
Threads checked/clean; earth lands bare & clean
Locking method & condition (“dry/243/etc.”) on SWI

During

Hand-start; seat, then pattern to final torque
Two-pass torque for gaskets/TIMs
Witness marks on critical fasteners
Earth joints measured <0.1 Ω where required

Audit

Tool verified on analyzer at start of shift
Residual torque spot-checks pass (80–100% spec)
Any strip/cross-thread → stop, MRB, not “heavier hand”

Bottom line: choose the right screw and locking, set torque for the actual friction, start by hand, and verify with simple, regular checks. Do that, and threads last, gaskets seal, bonds conduct—and nothing rattles back to haunt you.