CE3MN Cast Duplex Stainless Steel

1. Sommarju eżekuttiv

CE3MN is the cast counterpart to wrought super-duplex alloys (E.g., US S32750): it combines very high chromium (≈24–26 %), significant molybdenum (≈3–4 %), elevated nickel (≈6–8 %), controlled copper and nitrogen
to produce a two-phase microstructure with high yield strength, excellent resistance to pitting/crevice corrosion and substantially improved resistance to chloride-induced stress-corrosion cracking relative to conventional austenitics.

Its cast form allows complex geometry components for harsh environments (Korpi tal-valv, Kisi tal-pompa, manifolds), but requires strict process control (tidwib, solidifikazzjoni, ittemprar soluzzjoni) to deliver the expected performance and to avoid embrittling intermetallic phases.

2. What is CE3MN Cast Duplex Stainless Steel?

CE3MN cast duplex Azzar li ma jissaddadx hija ta 'prestazzjoni għolja, two-phase (ferritic-austenitic) stainless alloy engineered specifically for demanding corrosive and mechanically stressed environments where conventional austenitic or ferritic stainless steels do not provide adequate durability.

Jappartjeni għall- super-duplex stainless steel family, distinguished by elevated chromium (Cr), molibdenu (Mo), Nitroġenu (N) u n-nikil (Fi) contents that deliver an exceptional combination of saħħa, localized corrosion resistance and crack resistance.

In standardized nomenclature, CE3MN is commonly referenced in casting specifications such as ASTM A995 / ASME SA351 & SA995 gradi (per eżempju CD3MWCuN, also marketed as “6A”). Tagħha UNS designation is J93404.

It is widely accepted as the cast equivalent to wrought super-duplex stainless steels like US S32750 / ASTM A F55, and is used when lightweight, complex geometries or single-piece components of high corrosion resistance are required.

The conceptual goal behind CE3MN is to bridge the gap between conventional duplex stainless steels (E.g., 2205) u ligi b'bażi ​​tan-nikil

by maximizing corrosion resistance (particularly pitting and crevice corrosion in chloride environments) while maintaining good mechanical performance, weldability and cost efficiency for large or intricate cast parts.

It is frequently selected for Korpi tal-valv, Kisi tal-pompa, manifolds and subsea components fil- żejt & gass, petrokimiku, Marine, desalination and power industries.

3. Chemical Composition of CE3MN Cast Duplex Stainless Steel

Element	Firxa tipika (wt%)	Rwol / comment
Cr (Kromju)	24.0 - 26.0	Primary element for passivity and general corrosion resistance; major contributor to PREN.
Fi (Nickel)	6.0 - 8.0	Austenite stabiliser; improves toughness and helps achieve duplex phase balance.
Mo (Molibdenu)	3.0 - 4.0	Strongly increases pitting and crevice corrosion resistance; key PREN contributor.
N (Nitroġenu)	0.14 - 0.30	Potent pitting-resistance and strength enhancer (multiplies in PREN formula); critical for duplex performance.
Cu (Ram)	0.3 - 1.5	Present in some cast grades to improve resistance in certain reducing environments and to modify solidification behaviour.
Ċ (Karbonju)	≤ 0.03	Kept low to limit carbide precipitation and intergranular embrittlement.
Mn (Manganiż)	≤ 2.0	Deoxidiser / partial austenite former; controlled to avoid excessive inclusion formation or segregation.
U (Silikon)	≤ 1.0	Deoxidiser; limited to control oxidation and inclusion formation.
P (Fosfru)	≤ 0.03	Impurity control — kept low to preserve toughness.
S (Kubrit)	≤ 0.01	Impurity — minimised to avoid hot cracking and loss of ductility.
Fe (Ħadid)	Bilanċ (≈ 40–50%)	Remainder of alloy — ferrite + austenite matrix.

4. Microstructure and phase balance

• Dual-phase structure: CE3MN is intentionally duplex — ferrite (d) + Austenite (c).
  The mechanical and corrosion properties are a direct function of the phase fraction, chemistry partitioning u omoġeneità mikrostrutturali.
• Target phase balance: Typically aim for ~40–60% ferrite; too much ferrite lowers toughness and weldability; too little ferrite reduces strength and resistance to chloride stress-corrosion cracking.
• Intermetallics risk: Tkessiħ bil-mod, improper heat cycles (or local re-heating) promote σ (sigma), χ, and other chromium-rich intermetallics which are fraġli, Cr/Mo-rich and Ni-poor; these dramatically reduce toughness and corrosion resistance.

5. Typical physical & mechanical properties — CE3MN (cast super-duplex stainless steel)

Ambitu & twissijiet: values below are typical engineering ranges for cast CE3MN/J93404 in a properly solution-annealed condition.

Ikkastjar (especially large/thick sections) show greater scatter than wrought products and are sensitive to section size, trattament tas-sħana, and actual phase balance (δ/γ).

For design and safety-critical work always use supplier-certified test data for the specific heat/lot and validate with part-level tests.

Physical properties (tipiku)

Proprjetà	Valur tipiku (cast CE3MN, solution-annealed)	Kumment
Densità	≈ 7.8 - 8.0 g·cm⁻³	Similar to other stainless alloys; Uża 7.85 g/cm³ for mass calculations.
Tidwib / solidification range	≈ 1,375 - 1,425 ° C.	Broad solidification range due to high alloying; affects feeding and shrinkage.
Konduttività termali (20 ° C.)	≈ 12 - 18 W · m⁻¹ · k⁻¹	Lower than carbon steels; impacts thermal gradients during casting and welding.
Specific heat (20 ° C.)	≈ 420 - 500 J · kg⁻¹ · k⁻¹	Use ~460 J·kg⁻¹·K⁻¹ for thermal calculations.
Koeffiċjent ta 'espansjoni termali (20–300 ° C.)	≈ 12.5 - 14.5 ×10⁻⁶ K⁻¹	Lower than many austenitic grades; important when joining to other metals.
Modulu ta 'Young (room temp)	≈ 190 - 210 GPA	For elastic design use 200 GPa conservatively.
Reżistività elettrika (20 ° C.)	≈ 0.6 - 0.9 μΩ·m	Typical stainless range; varies with exact composition.
Magnetiżmu	Slightly ferritic; may show weak magnetic response	Fully austenitic regions non-magnetic; duplex shows mild magnetism due to ferrite.

Proprjetajiet mekkaniċi (tipiku, solution-annealed cast form)

Proprjetà	Firxa tipika	Noti
Saħħa ta 'rendiment (RP0.2)	≈ 400 - 550 MPA	Much higher than 300-series stainless steels; depends on section, heat-treatment and ferrite fraction.
Qawwa tat-tensjoni (Rm)	≈ 750 - 900 MPA	Use certified lot data for allowable stresses.
Titwil (A, % fi 50 mm)	≈ 10 - 25 %	Cast parts trend toward the lower end; thicker sections and residual σ/χ reduce ductility.
Ebusija (HB)	≈ 220 - 360 HB	Cast super-duplex values vary with microstructure and any intermetallics; hardness correlates with strength and embrittlement.
Charpy V-notch impact	≈ 30 - 120 J (room temp)	Firxa wiesgħa: mitfugħa, section size and precipitates lead to scatter—measure for critical parts.
Fracture toughness (K_ic, approximate)	≈ 50 - 120 Mpa · √m	Highly dependent on microstructure, notch size and testing method; use part-specific fracture mechanics where necessary.
Għeja (rotating bending / endurance)	Indicative endurance ≈ 250 - 400 MPA	Finitura tal-wiċċ, residual stress and porosity dominate fatigue life—quantify experimentally.
Creep resistance	Moderat (not high-temperature creep alloy)	Suitable for intermittent elevated-temperature exposure; not recommended for sustained high-stress creep service above ~350–400 °C without qualification.

Elevated-temperature behaviour & service guidance

• Practical continuous service temperature: tipikament ≤ ~300 °C for corrosion-sensitive applications; mechanical strength will drop progressively with temperature.
• Short-term exposure: material retains reasonable strength to ~400–500 °C but long-term exposure risks precipitation of intermetallics (a, χ) that embrittle the alloy.
• Creep & stress rupture: CE3MN offers better high-temperature strength than many austenitics but is le a substitute for nickel-base alloys where long-term creep is required.
  For sustained load at elevated temperature select appropriate creep-rated material and perform creep testing.

6. Casting behavior and solidification challenges

CE3MN’s design as a cast alloy enables one-piece components with complex internal passages, integrated features and fewer joints — advantages in manufacturing efficiency, leak minimization and part integrity compared with fabrications from multiple forgings or weldments.

Ikkastjar CE3MN introduces process-specific risks:

• Non-equilibrium solidification and segregation: interdendritic residual liquid becomes enriched in Cr, Mo and Ni (or conversely depleted depending on element partition coefficients),
  producing local chemistry variations that can foster intermetallic formation (σ/χ) in the as-cast condition.
• Wide freezing range: high alloy content broadens solidification interval, increasing shrinkage risk and feeding difficulty—requiring careful riser design, chills and feeding strategy.
• Hot tearing and hot cracking: duplex cast alloys can be susceptible to hot tearing if restraint and thermal gradients are not managed; grain refinement and gating optimization help.
• Surface and internal defects: porożità (gas and shrinkage), oxide entrainment and inclusions are common if melt control and filtration are insufficient.

Mitigazzjoni: precise melt chemistry control, ceramic-foam filtration, Degassing, optimized gating and feeder layout guided by solidification simulation, and post-casting solution annealing are essential.

7. Trattament tas-sħana, iwweldjar, and fabrication controls

Ittemprar tas-soluzzjoni & quench

• Skop: dissolve as-cast intermetallics and homogenize chemistry to achieve the desired duplex balance.
• Typical practice: solution anneal in the range 1,050–1,100 °C (exact range depends on part section) followed by rapid quench to avoid intermetallic reprecipitation.
• Caveats: large/ thick castings require hold times and quench strategies tailored to section size; insufficient solutionizing leaves residual σ/χ and segregation.

Iwweldjar & thermal cutting

• Weld metallurgy: consumables should be selected to match or slightly overmatch alloy chemistry and to promote balanced phase ratio in HAZ/weld metal.
• Kontroll tad-dħul tas-sħana: excessive or improperly sequenced heat input shifts phase balance and can locally precipitate σ/χ.
• Post-weld treatment: for critical assemblies, post-weld solution anneal or local heat treatment may be required to restore microstructure.
• Thermal cutting caution: as observed in practice, tisħin minn qabel + local hot cutting (E.g., oxy-fuel) followed by slow cooling can produce σ/χ precipitation and embrittlement at the cut edge;
  best practice is to solution-treat before any thermal cutting or to use cold-cutting (sawing) followed by solution anneal.

8. Common defects and failure modes (practical focus)

• a / χ intermetallic precipitation: forms in interdendritic and α/γ interfaces on slow cooling or during post-casting thermal exposure; causes embrittlement and corrosion susceptibility.
• Segregazzjoni (Ni/Cr/Mo partitioning): leads to local PREN depression and preferential attack.
• Gas and shrinkage porosity: reduce load-bearing section and fatigue life.
• Dmugħ sħun: from constrained solidification in thick sections.
• Thermal-cut induced embrittlement: cutting risers on as-cast components without prior solution anneal can precipitate σ/χ at the cut root and initiate cracking (practical remedy: solution anneal before thermal cutting or cold saw then solutionize).

9. Typical Applications of CE3MN Cast Duplex Stainless Steel

CE3MN cast duplex stainless steel is selected for applications where saħħa mekkanika għolja, excellent resistance to localized corrosion, and structural reliability under severe service conditions are simultaneously required.

As a cast super-duplex grade, it is particularly well suited to complex, thick-walled, pressure-containing components that are difficult or uneconomical to manufacture from wrought products.

Żejt & gas and petrochemical industry

• Valve bodies and valve components (valvoli tal-ballun, valvi tal-bieb, valvoli tal-kontroll) for sour service and high-chloride environments
• Pump casings and impellers handling seawater, ilma prodott, or aggressive hydrocarbon mixtures
• Manifolds and flow control components exposed to high pressure, erożjoni, and corrosive fluids

Offshore and marine engineering

• Seawater handling systems (housings tal-pompa, passaturi, valve blocks)
• Offshore platform structural castings subject to continuous seawater exposure
• Desalination plant components including brine pumps and valve bodies

Chemical and process industries

• Reactor internals and casings exposed to mixed acids, kloruri, u temperaturi elevati
• Heat exchanger components such as channel heads and water boxes
• Agitator housings and pump components in aggressive chemical service

Power generation and energy systems

• Cooling water systems in thermal and nuclear power plants
• Flue gas desulfurization (FGD) system components
• High-pressure water handling castings in renewable energy facilities

Polpa, karta, and environmental engineering

• Digester and bleaching system components
• Pompi, miksers, u korpi tal-valvi exposed to chloride-rich and alkaline media
• Wastewater and effluent treatment equipment

Minjieri, mineral processing, and slurry handling

• Slurry pump casings and impellers
• Ilbies- and corrosion-resistant housings for mineral transport systems

High-integrity pressure-containing components

• Komponenti ta' tank tal-pressjoni
• Thick-walled cast housings and covers
• Custom-engineered cast parts with complex internal passages

10. Comparison with Other Alternative Materials

CE3MN cast duplex stainless steel is often selected over other stainless steels, super-austenitic alloys, and nickel-based alloys because of its unique combination of corrosion resistance, Qawwa mekkanika, and cost-effectiveness in cast form.

The following comparison highlights its relative performance and application suitability.

Proprjetà / Kriterju	CE3MN (Cast Duplex, 25Cr-7Ni-Mo-N)	316L / 1.4404 (Austenitic SS)	904L / 1.4539 (Super-Austenitic SS)	Ligi bbażati fuq in-nikil (E.g., Hastelloy C-22)
Reżistenza għall-korrużjoni	Reżistenza eċċellenti għall-pitting, korrużjoni tax-xquq, and stress corrosion in chloride environments; Injam ≈ 40	Moderat; prone to pitting/crevice in high-chloride media	Għoli ħafna; comparable PREN (≈ 40–42), strong acid resistance	Outstanding in oxidizing and reducing acids
Qawwa Mekkanika	Saħħa għolja (Rp0.2 ≈ 450–550 MPa, Rm ≈ 750–900 MPa); toughness tajba	Moderat (Rp0.2 ≈ 200–250 MPa, Rm ≈ 500–600 MPa)	Moderat għal għoli; lower than duplex in yield	Għoli, but often expensive to fabricate
Fażi / Mikrostruttura	Duplex (ferrite + Austenite) for optimized strength-corrosion balance	Fully austenitic	Fully austenitic	Fully austenitic or complex
Kastabbiltà	Excellent for complex, thick-walled parts; lower shrinkage than high-alloy austenitics	Tajjeb, but lower strength in thick sections	Fqir; expensive for large castings	Diffiċli; spiża għolja, complex melt control
Elevated-Temperature Performance	Moderat; suitable ≤ 300–350 °C; limited creep	Moderat; austenite softens at high T	Moderat; slightly better than 316L	Eċċellenti; can handle 400–600 °C in aggressive media
Spiża & Disponibbiltà	Moderat; more economical than 904L and nickel alloys	Baxx; disponibbli b'mod wiesa'	Għoli; limited casting suppliers	Għoli ħafna; specialty alloy
Applikazzjonijiet tipiċi	Valvoli, pompi, pressure housings in chloride-rich, pressjoni għolja, servizz kimiku	General chemical equipment, ikel, water handling	Acid-resistant tanks, Skambjaturi tas-sħana	Highly aggressive chemical processes, extreme temperature or corrosion

Key Takeaways:

1. CE3MN vs 316L: CE3MN offers far superior corrosion resistance in chloride and aggressive chemical environments, with higher strength, making it ideal for high-pressure or thick-walled components.
2. CE3MN vs 904L: CE3MN provides higher mechanical strength and castability, often at lower cost, while 904L is preferable for thin-walled, highly acid-resistant components.
3. CE3MN vs Nickel-Based Alloys: Nickel alloys outperform in extreme corrosive and high-temperature conditions,
   but CE3MN provides an economical balance of strength, Reżistenza għall-korrużjoni, and manufacturability for most industrial applications.

11. Konklużjoni

CE3MN cast duplex stainless steel is a purpose-built alloy for demanding corrosive and mechanically loaded environments where complex cast geometries are required.

Tagħha super-duplex chemistry delivers an attractive combination of high strength and excellent localized-corrosion resistance — but these advantages only materialize when melting, ikkastjar, solution annealing and fabrication are executed with discipline to avoid segregation and brittle intermetallic precipitation.

For critical industrial or subsea components, procuring CE3MN from proven suppliers with rigorous qualification and testing will yield durable, high-performance castings that justify the material and processing premium.