Corrosion Protection for Gray/Ductile Iron: Coatings vs Material Choices

Corrosion Resistance Gray Ductile Iron

Who this helps: Design Engineers / Buyers specifying gray/grey & ductile (SG) iron parts for outdoor use, chemicals, salt, humidity or wash-down.
What you’ll get: a practical coating-selection matrix (with DFT/µm & mil), when material upgrades beat paint, design rules that stop under-film rust, plus copy-paste drawing notes.

Prepared by YB Metal Solution. Share your drawing via /rfqYB Metal will return a part-specific coating stack, material option and test plan.

Author: YB Metal Solution Engineering Team (hereafter YB Metal)

Table of contents

  • Corrosion basics for cast irons
  • When to solve it with coatings vs material
  • Real-world coating stacks (with DFT & use cases)
  • Material options & where they win
  • Design for durability: geometry, edges & galvanic pairs
  • Surface prep, Ra & adhesion checks
  • What to put on the drawing (copy–paste)
  • What YB Metal delivers
  • FAQs

Corrosion basics for cast irons

  • Graphite effect: Graphite acts cathodic to iron; in wet electrolytes it can form micro-galvanic cells, accelerating local iron loss. Gray iron (flakes) exposes more area than ductile (nodules), so gray tends to rust faster in the same environment.
  • Matrix matters: More pearlite/carbides can be slightly more corrosion-resistant than purely ferritic matrices, but surface condition dominates.
  • Defects drive failure: Porosity, burn-on and sand inclusions trap moisture → under-film rust. See: Surface Finish (Ra) guide and Sand Inclusion & Burn-On for prevention.

When to solve it with coatings vs material

  • Pick coatings when the environment is atmospheric (C2–C4), intermittent splash, or you can maintain paint.
  • Pick material upgrades when media is continuous (seawater, hot brine, acids/alkalis), or the part cannot be coated or maintained.
  • Often the most robust is both: modest material improvement (Cu/Ni-bearing DI or Ni-resist for chloride service) + duplex coating.

Real-world coating stacks (with DFT & use cases)

Values are typical; set exact test & DFT during PPAP. Units show µm / mil (1 mil = 25.4 µm).

Environment & needRecommended stackTotal DFT
Indoor dry / C1–C2 (machinery frames)Phosphate + powder coat (polyester/epoxy-polyester).60–90 µm / 2.4–3.5 mil
Outdoor general / C3 (transport housings)Zinc-rich epoxy primer (60–80 µm / 2.4–3.1) + epoxy mid (80–120 µm / 3.1–4.7) + PU top (40–60 µm / 1.6–2.4).180–260 µm / 7–10 mil
High salt / C4–C5 (coastal, road salt)Zinc-rich epoxy + high-build epoxy + aliphatic PU (or fluoropolymer) top; consider duplex e-coat + powder.220–320 µm / 9–13 mil
Wash-down / chemicalsEpoxy primer + novolac epoxy or epoxy + vinyl ester system; seal crevices.200–300 µm / 8–12 mil
Complex geometry / inside cavitiesE-coat (cathodic) for coverage + powder top for UV.25–35 µm e-coat + 60–90 µm powder
Touch-up / field repairZn-rich touch-up + 2-pack epoxy/PU; clean to Sa2½ equivalent.As specified

Prep & blast profile: target Ra 6–12 µm (240–475 µin) after shot-blast (S280–S330) for paint/powder. Avoid over-polish that kills adhesion.

Material options & where they win

OptionWhere it helpsNotes
Standard gray iron (EN-GJL / ASTM A48)Indoor, painted exteriorEasiest to machine; relies on coating for life.
Standard ductile iron (EN-GJS / ASTM A536)Slightly better base resistance than GI; higher strengthGood default for painted outdoor parts.
Cu/Ni-bearing ductile ironSplash seawater, de-icing saltsMinor alloy adds base resistance; still paint for long life.
Austempered DI (ADI)Strength/fatigue ↑; corrosion similar to DIADI is not a corrosion upgrade by itself—still coat.
High-Si irons (SiMo)High-temperature oxidation (600–900 °C)Not a general wet-corrosion solution.
Ni-Resist (austenitic cast iron)Seawater/hot brine; some chemicalsCost ↑↑; lower modulus; use for media-wetted internals.
Cast steel + coatingShock/impact + heavy corrosionOften heavier machining cost; coat as for iron.

Design tip: if media is aggressive only inside the cavity, consider unpainted exterior + corrosion-resistant liner or Ni-resist insert internally to control cost.

Design for durability: geometry, edges & galvanic pairs

  • Edges & radii: break/shamfer R 0.5–1.0 mm (0.02–0.04 in); sharp edges thin the coating.
  • Drain/vent: add weep holes to avoid liquid traps; slope flats ≥ 2–3° for drainage.
  • Crevices: avoid tight lap joints; specify sealant where unavoidable.
  • Galvanic couples: isolate iron from stainless/aluminum with non-conductive gaskets/washers; use compatible fasteners and seal threads.
  • Hangers & masking: provide hanging points and mask areas (fits/threads) on the drawing.
Tool prove-out to PPAP (if live) and PPAP for iron castings

Surface prep, Ra & adhesion checks

  • Blast to clean metal; remove burn-on/silica (these undercut paint).
  • Target Ra: 6–12 µm profile for paint; 1.6–3.2 µm after machining on sealing faces (do not coat).
  • Tests to call out (as needed): dry film thickness (DFT), cross-cut adhesion, impact, salt spray (neutral, ISO 9227/ASTM B117) or better cyclic tests, holiday (pinhole) test for thick films, gloss & color Δ.

Related articles on your site:

Fixturing irregular castings

What to put on the drawing (copy–paste)

Coating stack (example for C3/C4):

  • Prep: shot-blast to clean metal; blast profile Ra 6–12 µm (240–475 µin).
  • Primer: zinc-rich epoxy, DFT 60–80 µm (2.4–3.1 mil).
  • Mid-coat: high-build epoxy, DFT 80–120 µm (3.1–4.7 mil).
  • Topcoat: aliphatic polyurethane, DFT 40–60 µm (1.6–2.4 mil).
  • Color/Gloss: per spec; edges broken R0.5–1.0 mm (0.02–0.04 in).
  • Mask: threads, fits, sealing faces (see view).

Inspection & tests:

  • DFT at 5+ locations/part; cross-cut adhesion (per method); salt-spray ISO 9227 (hours per spec) or customer cyclic test; visual—no holidays/rust.
  • Provide batch certificates for coating materials and blast media cleanliness.

Material call-out (if upgrading):

  • Ductile iron EN-GJS-500-7 (ASTM A536 80-55-06) with Cu/Ni window for corrosion resistance.
  • Alternative (media-wetted only): Ni-Resist austenitic cast iron, grade per service.

What YB Metal delivers

YB Metal Solution quotes with a corrosion plan attached:

  • A coating selection matched to your environment (DFT numbers, cure, adhesion tests).
  • Surface prep & blast profile setup, plus masking & hanging instructions.
  • If required, material upgrade options (Cu/Ni DI or Ni-resist) with cost/lead-time impact.
  • Pilot evidence pack: DFT logs, adhesion photos, salt-spray/cyclic results, and coated-part dimensional check.

Need a plan for your environment? Upload your drawing—we’ll return recommendations and a quote.

FAQs

It can protect well, but carries distortion and trapped-gas risks on complex iron castings and may not coat internal cavities. Paint duplex systems are usually easier to control.

Not materially. ADI is a strength/fatigue upgrade; treat it like DI for corrosion and use coatings.

It depends on stack and spec. Use salt-spray as a comparative test, but for real life prefer a cyclic standard aligned to your market. Call hours/criteria on the drawing.

Usually under-film contamination: burn-on/silica left on the surface, wet coating, or crevice water traps. Fix prep/geometry, not just paint type.

Yes—mask them and call Ra 1.6–3.2 µm; apply a temporary corrosion inhibitor for shipment.

CTA — specify with proof, not guesses

Pick the right coating stack (and material only when it pays). Upload your drawing to /rfq and YB Metal will send a corrosion plan, test matrix and quotation.

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