3.3 Environmental & Life Tests

Flex, vibration, temperature/humidity exposures for confidence in use.

Environmental and life testing provesturns a wire harness canfrom survivea itslab-built real-worldassembly stresses—flexing,into a proven field survivor. By exposing samples to bending, vibration, temperature swings,heat, humidity, chemicals, UV, and ingress—withoutcorrosive losingagents, electricalthese tests uncover the weaknesses that only appear after long use or mechanicalharsh integrity.conditions. TestsRunning are run on representative builds mounted with actual clamp spacing, and monitored for glitches, resistance drift, and visible damage. Profiles are tailored to the product’s environment, from gentle office bends to million-cycle drag-chain runs or salt fog for marine gear. Electricalelectrical checks before and after each exposurestress confirmcycle insulationensures healththat performance, insulation, and contact performance,integrity whileremain detailedintact. logsThe tieprocess resultstransforms durability from an assumption into measurable proof, tailored to the harness’product’s serialreal record.operating Done this way, the tests become a predictable proof of durability, not a gamble.environment.

3.3.1 What this proves (and when to run it)

Design/qualification: “Will this harness survive its world?” Run at NPI or when materials change (wire, boots, backshells, overmold).
Process monitoring: “Are builds consistent?” Run smaller samples per quarter or per vendor shift (sleeve, resin, contacts).
Failure analysis: reproduce the customer’s environment to see the break and fix the mechanism.

Always bookend exposures with electrical checks: Continuity → Resistance (Kelvin on power) → IR → Hipot (3.1), plus visuals.

3.3.2 Test planning (four decisions first)

Specimens: exact PN–Rev–Variant; route them on a board to final install clamp spacing and bend radii.
Instrumentation: continuity glitch monitor (≥1 kHz), Kelvin taps on power/grounds, thermocouples on suspect joints.
Success criteria: define limits up front (drops, ΔR, ΔT, IR/Hipot, cosmetic).
Sequence (typical): Baseline → Flex/Torsion → Vibration → Temp/Humidity cycles → Chemical/Ingress (if relevant) → Final electrical.

Keep one unit as a control (no exposure) to compare drifts.

3.3.3 Flex & bend cycling (where most field issues start)

Setups

Mandrel bend: wrap over a radius = design minimum (static: ≥6× OD; dynamic: ≥10× OD unless high-flex cable).
Rolling flex / drag-chain: for motion-class cables.
Torsion: clamp ends; twist ±90–180° about axis.

Starter profiles (tune to product)

Class	Mandrel bend	Rolling flex	Torsion
Office/benign	5k cycles, 30 cpm	—	±90°, 2k cycles
Machine bay	20k cycles, 30–60 cpm	200–500k cycles at chain radius	±180°, 10k cycles
High-flex chain	—	1–5 million at vendor-rated radius	±180°, 50k cycles

Monitor & limits

Continuity glitches >1 ms = fail; ≤3 blips <1 ms allowed (log).
ΔR end-to-end ≤ 10–20% vs baseline (Kelvin on power).
No jacket cracks, sleeve retreat, or shield breakouts.

3.3.4 Vibration (find loose pins, fretting, bad clamps)

Replicate the installed clamp scheme on the shaker; first clamp before first bend.

Screening sweep (find resonances)

Sine 5→200 Hz, 0.5 g, 2 oct/min, 3 axes; dwell 1 min at peaks if needed.

Random vibration starter (industrial)

10–500 Hz, overall 3–5 grms, 3 axes, 30–60 min/axis (tune to product/vehicle spec if provided).

Pass indicators

0 continuity opens >1 ms during any axis.
No bent/broken contacts or backshell loosening.
Post-test IR ≥ limit and Hipot PASS (21.1).

3.3.5 Temperature cycling & thermal shock

Temperature cycling (air-to-air)

Range: −40 → +85 °C (or your product limits), ramp ≤ 5 °C/min, dwell 30 min at extremes, 50–100 cycles.
Monitor continuity at extremes if possible.

Thermal shock (two-chamber)

−40 ↔ +85/105 °C, transfer ≤ 30 s, dwell 10–15 min, 50–100 cycles.

Pass

No cracks in boots/overmolds, label legible, ΔR ≤ 10–20%, IR/Hipot PASS.
Shield bonds intact (< 0.1 Ω end-to-end or to chassis point).

3.3.6 Humidity & moisture

Insulation resistance loves to fall when wet. Prove your materials.

Damp heat steady state (starter)

40 °C / 95% RH, 96 h; unpowered, then 1 h dry at room conditions → run IR/Hipot.

Damp heat severe (materials-permitting)

85 °C / 85% RH, 168–500 h (verify jacket/adhesive ratings first).
Acceptance: IR ≥ 10–100 MΩ (per product), boots/labels still adhered, no green corrosion.

3.3.7 Chemicals, UV, salt fog (if the environment demands it)

Chemical splash/soak

Fluids: oil/coolant/IPA/brake fluid/cleaners from your use-case.
Method: 24–72 h soak or periodic splash at room temp; then flex 2k cycles on mandrel.
Pass: no swelling >10%, no softening/cracks, labels legible, IR/Hipot PASS.

UV/outdoor

UV exposure (lamp/arc) ≥ 100 h; then bend test. Pass = no embrittlement/cracking; print still readable.

Salt fog

5% NaCl, 35 °C, 48–96 h; focus on backshells/lugs. Pass = no red rust on stainless, minor cosmetic only on plated, continuity unchanged.

3.3.8 Ingress (IP) & washdowns

IP54 spray: multi-angle spray 5–10 min; IR/Hipot afterward.
IP67 dunk: 1 m / 30 min with mated seals; look for bubbles; post IR/Hipot.
Washdown: if applicable, run spray with detergent and relabel legibility check.

3.3.9 Mate/unmate life & latch strength

Cycle per expected service.

Mating cycles

50–100 cycles for general purpose; ≥500 if field-serviceable.
Track contact resistance (per pin) every 25 cycles; drift ≤ 50 mΩ from baseline.

Latch/CPA pull

Pull at rated direction; latch must hold ≥ spec without damage; visual OK after test.

3.3.10 What to record (tie to SN, not a notebook)

Profile IDs (flex/vibe/temp), dates, operator, fixture IDs.
Baseline and post-exposure: Continuity/shorts, Kelvin R, IR/Hipot, shield bond Ω, photos.
Real-time: glitch timestamps, ΔT at connectors, resonance notes.
Disposition (PASS/REWORK/FAIL) with mechanism if failed (e.g., “shield wire break at bend after 12k cycles”).

Store with the harness SN (20.5) so RMAs find it in seconds.

3.3.11 Starter acceptance table (tune to your spec)

Test	Pass (starter)
Flex / torsion	0 opens >1 ms; ΔR ≤ 20%; no jacket/shield damage
Random vibration	0 opens >1 ms/axis; no mechanical damage
Temp cycle / shock	Visual OK; IR ≥ limit; Hipot PASS; ΔR ≤ 20%
Humidity	IR ≥ 10–100 MΩ (per product); labels intact
Chemicals	No cracks/swelling >10%; labels readable; electrical PASS
Salt fog	No functional corrosion; continuity unchanged
IP67 (if claimed)	No leaks; IR/Hipot PASS post-test
Mating life	Contact ΔR ≤ 50 mΩ; latch intact

3.3.12 Common traps → smallest reliable fix

Trap	Symptom	Fix
Testing on “free cable”	Unrealistic failures	Replicate clamp distances and first-bend position
Wrong radius in flex test	Early breaks	Use design min radius (or vendor-rated radius for high-flex)
No glitch monitor	Intermittents unseen	Add ≥1 kHz continuity logging during motion
Hipot right after humidity	False fails	Stabilize/dry to room conditions before IR/Hipot
Overcooking heat-shrink in cycles	Brittle stiff zones	Control heat; keep stiff zone short (20.4)
Generic chemicals	Pass in lab, fail in field	Test actual fluids used by the customer
Fixture loosens on shaker	Pin damage, false faults	PM clamps & nests; torque audit before each run

3.3.13 Pocket checklists

Setup

Specimens PN–Rev–Variant; board-mounted with real clamp spacing
TC and Kelvin leads on suspect points; glitch logger armed
Success limits posted; control unit set aside

Run

Flex/drag-chain to target cycles; log glitches/ΔR
Vib: sine sweep then random 3 axes; no opens >1 ms
Temp/humidity per profile; stabilize before electrical retest
Chemical/UV/salt/IP as required

Closeout

Post-test Continuity, Kelvin R, IR, Hipot recorded
Visuals & photos (boots, labels, overmold, shields)
Failures tagged with mechanism; samples archived

BottomWhen line:harnesses mountare thequalified harnessunder likecontrolled itenvironmental lives, bendstresses and shakeresults itare smart,logged heatwith traceable detail, reliability is no longer left to chance. The outcome is fewer failures in service, stronger confidence in design choices, and wetproduction itthat todelivers thedurability realas limits,a thenstandard re-check the basics. Log glitches, resistance drift, and cosmetic health, all tied to the SN. Do that, and environmental testing stops being drama—and starts being confidence.feature.