DUPLEX UNS S31803
1. Introduction to Duplex Stainless Steel Fasteners
Duplex Stainless Steel UNS S31803 / UNS S32205 (EN 1.4462) fasteners represent a high-performance category of corrosion-resistant engineering fasteners designed for severe industrial environments where conventional austenitic stainless steels may not provide adequate strength or corrosion resistance.
The duplex microstructure consists of approximately:
- 50% Austenite (γ phase)
- 50% Ferrite (α phase)
This balanced structure combines:
| Property | Austenitic SS | Ferritic SS | Duplex S31803/S32205 |
|---|---|---|---|
| Strength | Medium | Medium | High |
| Toughness | Excellent | Moderate | Excellent |
| Chloride Resistance | Good | Moderate | Very High |
| SCC Resistance | Moderate | High | Excellent |
| Weldability | Excellent | Moderate | Very Good |
| Cost Efficiency | Moderate | Low | High Value |
The resulting material provides approximately twice the yield strength of standard 304 and 316 stainless steels while maintaining excellent corrosion resistance.
2. International Material Designations
Equivalent Standards
| Standard | Grade |
|---|---|
| UNS | S31803 |
| UNS | S32205 |
| EN | 1.4462 |
| DIN | X2CrNiMoN22-5-3 |
| ASTM | A182 F51 |
| ASTM | A276 S31803 |
| ASTM | A479 S31803 |
| ISO | Duplex Stainless Steel 2205 |
| NORSOK | M-630 MDS D45 |
| NACE | MR0175 / ISO 15156 |
3. Chemical Composition
UNS S31803 / S32205 Composition
| Element | S31803 (%) | S32205 (%) |
|---|---|---|
| Chromium | 21.0–23.0 | 22.0–23.0 |
| Nickel | 4.5–6.5 | 4.5–6.5 |
| Molybdenum | 2.5–3.5 | 3.0–3.5 |
| Nitrogen | 0.08–0.20 | 0.14–0.20 |
| Carbon | ≤0.03 | ≤0.03 |
| Manganese | ≤2.0 | ≤2.0 |
| Silicon | ≤1.0 | ≤1.0 |
| Phosphorus | ≤0.03 | ≤0.03 |
| Sulfur | ≤0.02 | ≤0.02 |
| Iron | Balance | Balance |
4. Why Duplex Fasteners Are Used
Industrial fastening systems are expected to perform under simultaneous exposure to:
- Static loads
- Dynamic loads
- Thermal cycling
- Corrosive chemicals
- Offshore atmospheres
- Pressure fluctuations
- Vibration
Duplex S31803/S32205 fasteners are selected when engineers require:
High Strength
Approximately:
- Yield Strength: 450–550 MPa
- Tensile Strength: 620–880 MPa
compared with:
- 316 Stainless Yield ≈ 205 MPa
This enables:
- Smaller diameter fasteners
- Reduced weight
- Higher load carrying capacity
Superior Corrosion Resistance
Excellent resistance to:
- Chloride pitting
- Crevice corrosion
- Stress corrosion cracking
- Seawater attack
- Sour gas environments
Improved Lifecycle Economics
Benefits include:
- Reduced maintenance
- Longer service intervals
- Lower replacement frequency
- Reduced downtime
These advantages are particularly valuable for EPC projects and long-term infrastructure assets.
5. Functional Role of Duplex Fasteners
Fasteners create mechanical joints that generate clamp force.
The purpose of a fastener is not merely holding components together.
Its primary function is:
Creating sufficient preload to keep joint members compressed throughout service life.
A properly designed duplex fastener joint:
- Prevents separation
- Controls vibration
- Minimizes fatigue
- Transfers load safely
- Maintains sealing pressure
6. Fastener Load Mechanics
Fundamental Force Relationship
When tightened:
Bolt experiences:
Tensile Force
Joint experiences:
Compressive Force
Under equilibrium:
This preload is the basis of all bolted joint performance.
7. Understanding Preload
Preload is the intentional tensile force generated during tightening.
Benefits
| Benefit | Effect |
|---|---|
| Joint Integrity | Prevents separation |
| Fatigue Resistance | Reduces cyclic stress |
| Leak Prevention | Maintains gasket compression |
| Vibration Resistance | Prevents loosening |
| Load Distribution | Shares load uniformly |
Engineering practice typically targets:
of proof load.
8. Load Transfer Mechanism
External loads are ideally carried through friction between clamped components.
Friction Load Capacity
Where:
| Symbol | Description |
|---|---|
| μ | Coefficient of friction |
| Fclamp | Clamp force |
If external load exceeds friction capacity:
- Joint slip occurs
- Bolt shear increases
- Fatigue risk rises
9. Torque-Tension Relationship
Applied torque creates preload.
The practical engineering equation:
Where:
| Variable | Definition |
|---|---|
| T | Torque |
| K | Nut factor |
| F | Desired preload |
| D | Nominal diameter |
Typical Nut Factors
| Condition | K Factor |
|---|---|
| Dry | 0.20–0.25 |
| Light Oil | 0.16–0.20 |
| PTFE Coated | 0.10–0.15 |
| Moly Lubricated | 0.08–0.12 |
Duplex fasteners often employ lubrication to achieve consistent preload.
10. Duplex Fastener Mechanical Properties
Typical Mechanical Properties
| Property | Value |
|---|---|
| Tensile Strength | 620–880 MPa |
| Yield Strength | ≥450 MPa |
| Elongation | ≥25% |
| Hardness | 248–290 HB |
| Modulus of Elasticity | 200 GPa |
| Density | 7.8 g/cm³ |
11. Comparison with Other Fastener Materials
Material Selection Matrix
| Material | UTS (MPa) | Yield (MPa) | Corrosion Resistance | Relative Cost | Typical Applications |
|---|---|---|---|---|---|
| Carbon Steel 8.8 | 800 | 640 | Low | Low | Structural |
| SS304 | 515 | 205 | Good | Medium | General Industry |
| SS316 | 515 | 205 | Very Good | Medium | Marine |
| Duplex 2205 | 620–880 | 450–550 | Excellent | High | |
| Super Duplex 2507 | 795–1000 | 550–650 | Outstanding | Very High | |
| SMO 254 | 650 | 300 | Exceptional | Very High | |
| Inconel 625 | 827 | 414 | Extreme | Premium |
12. Joint Design Principles
A fastener is only one element of a successful joint.
Joint performance depends upon:
Fastener
- Diameter
- Material
- Strength
Joint Members
- Thickness
- Modulus
- Surface finish
Interface Conditions
- Lubrication
- Coating
- Temperature
Service Conditions
- Vibration
- Pressure
- Corrosion
- Thermal cycling
13. Thread Engagement Design
Insufficient engagement causes thread stripping before bolt failure.
Recommended engagement:
| Material | Minimum Engagement |
|---|---|
| Steel | 1 × Diameter |
| Stainless Steel | 1–1.5 × Diameter |
| Aluminum | 1.5–2 × Diameter |
| Cast Iron | 1.5 × Diameter |
For Duplex 2205 assemblies:
is generally recommended.
14. Stress Area Calculation
Tensile stress area:
Where:
- d₂ = pitch diameter
- d₃ = minor diameter
This area determines:
- Proof load
- Yield load
- Tensile capacity
15. Preload Calculation Example
Fastener
M16 × 2.0 Duplex S32205
Stress Area:
Assume:
Proof Strength:
Proof Load:
Target preload:
75%
Required torque:
Assume:
K=0.18
Approximate installation torque:
200–205 Nm
16. Joint Stiffness Considerations
The ratio between:
- Bolt stiffness
- Joint stiffness
controls load distribution.
A stiffer joint:
- Retains preload longer
- Improves fatigue life
- Reduces bolt stress fluctuations
Engineers often design joints where:
remains minimized.
17. Fatigue Behavior of Duplex Fasteners
Most bolted joints fail due to fatigue rather than overload.
Fatigue life improves when:
- Proper preload maintained
- Joint separation prevented
- Stress concentration minimized
- Rolled threads used
SM Fasteners utilizes precision thread manufacturing processes that support improved fatigue performance through controlled thread geometry and dimensional consistency.
18. Common Failure Mechanisms
Fatigue Failure
Caused by:
- Cyclic loading
- Insufficient preload
- Vibration
Indicators:
- Beach marks
- Progressive crack growth
Shear Failure
Occurs when:
exceeds material capability.
Common in:
- Flange joints
- Structural assemblies
Thread Stripping
Occurs due to:
- Insufficient engagement
- Soft mating material
- Over-tightening
Galling
A concern in stainless and duplex fasteners.
Causes:
- High friction
- Lack of lubrication
- Excessive installation speed
Prevention:
- PTFE coatings
- Moly lubricants
- Controlled torque installation
Stress Corrosion Cracking
Duplex alloys provide substantially better SCC resistance than 304 or 316 stainless steels.
Common environments:
- Chloride-rich systems
- Offshore platforms
- Desalination plants
Hydrogen Embrittlement
Risk is lower than high-strength alloy steel fasteners but process control remains essential during:
- Pickling
- Electroplating
- Acid cleaning
19. Corrosion Resistance by Environment
| Environment | Duplex 2205 Performance |
|---|---|
| Atmospheric | Excellent |
| Industrial Pollution | Excellent |
| Offshore Marine | Excellent |
| Seawater Splash Zone | Very Good |
| Desalination Plants | Excellent |
| H₂S Service | Excellent |
| Sour Gas | Excellent |
| Organic Acids | Excellent |
| Sulfuric Acid (Dilute) | Good |
| Nitric Acid | Good |
| Hydrochloric Acid | Limited |
| Caustic Solutions | Very Good |
20. Duplex Fasteners in Critical Engineering Systems
Major sectors utilizing UNS S31803/S32205 fasteners include:
Oil & Gas
- Wellheads
- Pipelines
- Pressure vessels
- Offshore platforms
Petrochemical
- Heat exchangers
- Reactors
- Process piping
Power Generation
- FGD systems
- Cooling water circuits
- Turbine auxiliaries
Marine & Shipbuilding
- Deck equipment
- Seawater systems
- Structural assemblies
Infrastructure
- Bridges
- Coastal structures
- Water treatment facilities
OEM Equipment
- Pumps
- Compressors
- Valves
- Filtration systems
21. Duplex S31803/S32205 Fastener Product Portfolio
Duplex Stainless Steel UNS S31803/S32205 fasteners are manufactured in a wide range of configurations to satisfy the requirements of structural, pressure-containing, rotating equipment, offshore, marine, petrochemical, and EPC applications.
At SM Fasteners, Duplex 2205 fasteners are produced under controlled manufacturing and inspection systems aligned with ISO 9001 quality management requirements, supporting both standard and custom-engineered fastening solutions.
22. Primary Fastener Categories
Bolts
Bolts are externally threaded fasteners intended for assembly with nuts.
Typical configurations:
| Type | Typical Standard |
|---|---|
| Hex Head Bolt | ISO 4014 / ISO 4017 |
| Heavy Hex Bolt | ASTM A193 |
| Flange Bolt | DIN 6921 |
| Structural Bolt | EN 14399 |
| Machine Bolt | DIN 931 |
| Full Thread Bolt | DIN 933 |
| Custom Forged Bolt | Project Specific |
Applications:
- Pressure vessels
- Flanged piping
- Structural steel
- Heat exchangers
- Offshore equipment
Nuts
Internally threaded components that generate clamping force.
Common types:
| Nut Type | Standard |
|---|---|
| Hex Nut | ISO 4032 |
| Heavy Hex Nut | ASTM A194 |
| Jam Nut | DIN 439 |
| Lock Nut | DIN 985 |
| Slotted Nut | DIN 935 |
| Flange Nut | DIN 6923 |
Stud Bolts
Stud bolts are preferred for critical flange connections because preload is more consistent than conventional bolt arrangements.
Common standards:
| Type | Standard |
|---|---|
| Fully Threaded Stud | ASTM A193 |
| Tap-End Stud | MSS SP-95 |
| Double-End Stud | ASME B16.5 Applications |
| Continuous Thread Stud | ANSI B1.1 |
Industries:
- Refining
- LNG
- Offshore
- Power generation
Screws
| Screw Type | Typical Application |
|---|---|
| Socket Head Cap Screw | Precision machinery |
| Set Screw | Shaft locking |
| Countersunk Screw | Flush assemblies |
| Button Head Screw | Equipment enclosures |
| Machine Screw | Instrumentation |
Washers
Washers improve load distribution and reduce bearing stress.
| Type | Standard |
|---|---|
| Plain Washer | ISO 7089 |
| Heavy Washer | ASTM F436 |
| Spring Washer | DIN 127 |
| Belleville Washer | DIN 2093 |
| Spherical Washer | DIN 6319 |
Threaded Rods
Used where adjustable assembly length is required.
Applications:
- Pipe supports
- Structural bracing
- Anchor systems
- HVAC supports
Standards:
- DIN 975
- DIN 976
- ASTM A193
Rings and Specialty Components
SM Fasteners also manufactures:
- Eye bolts
- Lifting rings
- Retaining rings
- Locking rings
- Custom CNC fasteners
for project-specific engineering requirements.
23. PEEK Fasteners in Duplex Assemblies
Where galvanic isolation or electrical insulation is required, PEEK fasteners may complement duplex systems.
Typical applications:
| Industry | Use |
|---|---|
| Electronics | Isolation |
| Medical Equipment | Non-metallic fastening |
| Aerospace Interiors | Lightweight fastening |
| Chemical Processing | Non-conductive joints |
Advantages:
- Chemical resistance
- Electrical insulation
- Low weight
- Non-magnetic behavior
24. Fastener Geometry Fundamentals
Fastener performance depends heavily upon geometry.
Critical dimensions include:
Diameter
Determines:
- Tensile capacity
- Shear capacity
- Clamp load
Thread Pitch
Determines:
- Mechanical advantage
- Vibration resistance
- Adjustment precision
Grip Length
Influences:
- Joint stiffness
- Load distribution
Head Geometry
Determines:
- Wrench engagement
- Bearing pressure
- Installation access
25. Metric Thread System
Most industrial duplex fasteners use ISO Metric Threads.
Designation format:
Example:
M20 × 2.5 × 120
Where:
| Parameter | Meaning |
|---|---|
| M | Metric thread |
| 20 | Nominal diameter (mm) |
| 2.5 | Pitch (mm) |
| 120 | Length (mm) |
26. Coarse vs Fine Threads
| Feature | Coarse Thread | Fine Thread |
|---|---|---|
| Installation Speed | Faster | Slower |
| Thread Strength | Good | Higher |
| Vibration Resistance | Good | Excellent |
| Damage Tolerance | Better | Lower |
| Adjustment Accuracy | Lower | Higher |
| Galling Risk | Lower | Higher |
27. ISO Metric Thread Dimensions
Standard Metric Coarse Pitch Series
| Size | Pitch (mm) |
|---|---|
| M6 | 1.0 |
| M8 | 1.25 |
| M10 | 1.5 |
| M12 | 1.75 |
| M16 | 2.0 |
| M20 | 2.5 |
| M24 | 3.0 |
| M30 | 3.5 |
| M36 | 4.0 |
| M42 | 4.5 |
| M48 | 5.0 |
| M56 | 5.5 |
| M64 | 6.0 |
28. Hex Bolt Dimensional Logic
Hex bolt dimensions are governed by:
- ISO 4014
- ISO 4017
- DIN 931
- DIN 933
Key dimensions:
| Symbol | Description |
|---|---|
| d | Diameter |
| P | Pitch |
| k | Head height |
| s | Width across flats |
| e | Width across corners |
| b | Thread length |
29. Standard Hex Bolt Dimensions
ISO Metric Hex Bolts
| Size | Head Height k (mm) | Across Flats s (mm) |
|---|---|---|
| M6 | 4.0 | 10 |
| M8 | 5.3 | 13 |
| M10 | 6.4 | 17 |
| M12 | 7.5 | 19 |
| M16 | 10.0 | 24 |
| M20 | 12.5 | 30 |
| M24 | 15.0 | 36 |
| M30 | 18.7 | 46 |
| M36 | 22.5 | 55 |
30. Duplex Bolt Length Range
Typical manufacturing range:
| Diameter | Available Length |
|---|---|
| M6 | 10–100 mm |
| M8 | 12–150 mm |
| M10 | 20–200 mm |
| M12 | 20–300 mm |
| M16 | 25–400 mm |
| M20 | 30–500 mm |
| M24 | 40–600 mm |
| M30 | 50–800 mm |
| M36 | 60–1000 mm |
| M42–M100 | Project-specific |
SM Fasteners can manufacture non-standard lengths according to EPC drawings and customer specifications.
31. Thread Standards and Tolerances
Metric Thread Standards
| Standard | Description |
|---|---|
| ISO 68 | Basic profile |
| ISO 261 | Preferred sizes |
| ISO 262 | Selected combinations |
| ISO 965 | Tolerances |
| DIN 13 | Metric threads |
Unified Thread Standards
| Standard | Description |
|---|---|
| ANSI B1.1 | Unified threads |
| ASME B1.1 | UNC/UNF |
| ASTM References | Fastener dimensions |
British Thread Standards
| Standard | Description |
|---|---|
| BS 84 | BSW |
| BS 1083 | BSF |
| BS 3643 | Metric threads |
32. Thread Tolerance Classes
Metric External Threads
| Class | Application |
|---|---|
| 6g | Standard bolts |
| 4g6g | Precision |
| 8g | Loose fit |
Metric Internal Threads
| Class | Application |
|---|---|
| 6H | Standard nuts |
| 5H | Precision |
| 7H | Clearance fit |
Most Duplex fasteners are supplied as:
6g / 6H
33. UNC and UNF Thread Chart
| Diameter | UNC TPI | UNF TPI |
|---|---|---|
| 1/4″ | 20 | 28 |
| 5/16″ | 18 | 24 |
| 3/8″ | 16 | 24 |
| 1/2″ | 13 | 20 |
| 5/8″ | 11 | 18 |
| 3/4″ | 10 | 16 |
| 7/8″ | 9 | 14 |
| 1″ | 8 | 12 |
34. BSW and BSF Thread Chart
| Diameter | BSW TPI | BSF TPI |
|---|---|---|
| 1/4″ | 20 | 26 |
| 5/16″ | 18 | 22 |
| 3/8″ | 16 | 20 |
| 1/2″ | 12 | 16 |
| 5/8″ | 11 | 14 |
| 3/4″ | 10 | 12 |
35. Proof Load Fundamentals
Proof load is the maximum load a fastener can withstand without permanent deformation.
Where:
- Fp = Proof Load
- As = Tensile Stress Area
- Sp = Proof Stress
36. Duplex Fastener Proof Load Table
Typical Values
| Size | Stress Area (mm²) | Proof Load (kN) |
|---|---|---|
| M8 | 36.6 | 22 |
| M10 | 58.0 | 35 |
| M12 | 84.3 | 51 |
| M16 | 157 | 94 |
| M20 | 245 | 147 |
| M24 | 353 | 212 |
| M30 | 561 | 337 |
| M36 | 817 | 490 |
Based on approximately 600 MPa proof stress.
37. Tensile Capacity Table
Duplex UNS S32205
| Size | Stress Area (mm²) | Tensile Capacity (kN) |
|---|---|---|
| M8 | 36.6 | 26 |
| M10 | 58.0 | 42 |
| M12 | 84.3 | 61 |
| M16 | 157 | 113 |
| M20 | 245 | 176 |
| M24 | 353 | 254 |
| M30 | 561 | 404 |
| M36 | 817 | 588 |
Assuming:
38. Load Distribution in Multi-Bolt Joints
Load sharing depends upon:
- Bolt spacing
- Flange rigidity
- Gasket stiffness
- Thermal expansion
Design standards commonly referenced:
- ASME PCC-1
- ASME Section VIII
- EN 1591
39. Bolt Spacing Principles
Recommended spacing:
Minimum edge distance:
Where D is bolt diameter.
40. Heavy Hex vs Standard Hex Geometry
| Parameter | Standard Hex | Heavy Hex |
|---|---|---|
| Head Height | Standard | Larger |
| Bearing Area | Moderate | Higher |
| Torque Capacity | Moderate | Higher |
| Pressure Vessel Use | Limited | Preferred |
| ASTM A193 Service | Rare | Standard |
Heavy hex fasteners are commonly used in:
- Refineries
- LNG terminals
- Offshore platforms
- Pressure vessel systems
41. ASTM Standards Relevant to Duplex Fasteners
| Standard | Scope |
|---|---|
| ASTM A182 F51 | Duplex forgings |
| ASTM A276 | Bars and shapes |
| ASTM A479 | Pressure service bars |
| ASTM A815 | Duplex pipe fittings |
| ASTM A923 | Duplex microstructure testing |
| ASTM E562 | Ferrite measurement |
| ASTM G48 | Pitting resistance testing |
42. ISO Standards Relevant to Fasteners
| Standard | Description |
|---|---|
| ISO 898 | Mechanical properties |
| ISO 3506 | Stainless fasteners |
| ISO 4014 | Hex bolts |
| ISO 4017 | Fully threaded bolts |
| ISO 4032 | Hex nuts |
| ISO 7089 | Washers |
| ISO 965 | Thread tolerance |
43. DIN Standards Commonly Applied
| Standard | Description |
|---|---|
| DIN 931 | Partially threaded bolt |
| DIN 933 | Full thread bolt |
| DIN 934 | Hex nut |
| DIN 125 | Washer |
| DIN 127 | Spring washer |
| DIN 975 | Threaded rod |
| DIN 976 | Studding |
44. British Standards References
| Standard | Description |
|---|---|
| BS 3692 | Metric fasteners |
| BS 4190 | Hex bolts and nuts |
| BS 4320 | Washers |
| BS 3643 | Threads |
45. Interchangeability Considerations
Before substituting fasteners, engineers must verify:
- Thread form
- Pitch
- Strength level
- Corrosion resistance
- Temperature capability
- Certification requirements
Substituting 316 stainless with Duplex 2205 generally improves strength, but design verification remains mandatory.
46. Engineering Selection Matrix
| Service Condition | Recommended Duplex Fastener |
|---|---|
| Offshore Platform | S32205 |
| Desalination Plant | S32205 |
| Chloride Process Water | S32205 |
| Sour Gas Service | S32205 |
| Pressure Vessel | S32205 Heavy Hex |
| Structural Marine | S32205 |
| Chemical Processing | S32205 |
| LNG Facilities | S32205 |
47. Procurement Considerations
EPC buyers typically specify:
- Heat number traceability
- ASTM-compliant raw material
- EN 10204 3.1 certification
- PMI verification
- Mechanical test reports
- Dimensional inspection records
SM Fasteners supports project requirements through documented quality systems, material traceability, and custom-engineered fastener manufacturing across standard and non-standard dimensions.
48. Materials Engineering of Duplex Fasteners
Material selection is one of the most critical decisions in fastener engineering because fasteners are often the most highly stressed components within an assembly.
Selection must simultaneously satisfy:
- Mechanical strength requirements
- Corrosion resistance requirements
- Temperature limitations
- Fatigue performance
- Environmental compatibility
- Regulatory compliance
- Project lifecycle expectations
For offshore, petrochemical, LNG, power generation, and EPC projects, Duplex UNS S31803/S32205 (EN 1.4462) provides an optimized balance between strength, corrosion resistance, and cost effectiveness.
49. Metallurgical Structure of Duplex 2205
The defining characteristic of Duplex 2205 is its dual-phase microstructure.
Approximate phase balance:
| Phase | Percentage |
|---|---|
| Austenite | 40–60% |
| Ferrite | 40–60% |
Ideal target:
| Phase | Percentage |
|---|---|
| Austenite | 50% |
| Ferrite | 50% |
This balanced structure provides:
Ferrite Contribution
- High yield strength
- Improved SCC resistance
- Reduced thermal expansion
Austenite Contribution
- Toughness
- Ductility
- Improved fabrication characteristics
The resulting alloy offers superior performance compared with conventional 304 and 316 stainless steel fasteners.
50. PREN (Pitting Resistance Equivalent Number)
Resistance to localized chloride attack is commonly evaluated using PREN.
Formula:
Typical Duplex 2205:
Comparison:
| Material | Typical PREN |
|---|---|
| 304 SS | 18–20 |
| 316 SS | 24–26 |
| Duplex 2205 | 34–36 |
| Super Duplex 2507 | 40–45 |
| SMO 254 | 42–45 |
Higher PREN values generally indicate better resistance to pitting and crevice corrosion.
51. Material Selection Matrix
Comparative Engineering Properties
| Material | UTS MPa | Yield MPa | PREN | Relative Cost | Typical Environment |
|---|---|---|---|---|---|
| Carbon Steel 8.8 | 800 | 640 | Low | Low | Structural |
| AISI 304 | 515 | 205 | 18 | Medium | General Industrial |
| AISI 316 | 515 | 205 | 25 | Medium | Marine |
| Duplex 2205 | 620–880 | 450–550 | 35 | High Value | Offshore |
| Super Duplex 2507 | 795–1000 | 550–650 | 42 | Premium | Seawater |
| SMO 254 | 650 | 300 | 43 | Premium | Chlorides |
| Monel 400 | 550 | 240 | Excellent | Premium | HF Acid |
| Inconel 625 | 827 | 414 | Exceptional | Premium | High Temperature |
| Hastelloy C276 | 790 | 355 | Outstanding | Premium | Aggressive Chemicals |
52. Duplex vs Super Duplex Selection
Engineering Comparison
| Property | Duplex 2205 | Super Duplex 2507 |
|---|---|---|
| Chromium | 22% | 25% |
| Nickel | 5–6% | 7–8% |
| Molybdenum | 3% | 4% |
| PREN | 35 | 42–45 |
| Yield Strength | 450–550 MPa | 550–650 MPa |
| Seawater Resistance | Excellent | Outstanding |
| Cost | Lower | Higher |
Selection guideline:
Duplex 2205
Preferred for:
- Oil & Gas
- Petrochemical
- Power plants
- Desalination systems
Super Duplex 2507
Preferred for:
- Deepwater offshore
- High chloride exposure
- Severe marine immersion
- Critical subsea equipment
53. Corrosion Resistance by Environment
Service Environment Selection Table
| Environment | 316 SS | Duplex 2205 | Super Duplex 2507 | SMO 254 |
|---|---|---|---|---|
| Atmospheric | Excellent | Excellent | Excellent | Excellent |
| Coastal Marine | Good | Excellent | Excellent | Excellent |
| Offshore Splash Zone | Moderate | Excellent | Outstanding | Outstanding |
| Seawater Immersion | Limited | Very Good | Excellent | Excellent |
| Chloride Process Water | Moderate | Excellent | Excellent | Excellent |
| Sour Gas Service | Moderate | Excellent | Excellent | Excellent |
| Desalination Plants | Good | Excellent | Excellent | Excellent |
| Sulfuric Acid | Moderate | Good | Good | Excellent |
| Nitric Acid | Good | Good | Good | Good |
| Hydrochloric Acid | Poor | Limited | Moderate | Better |
54. NACE MR0175 / ISO 15156 Compliance
For oil and gas projects involving hydrogen sulfide (H₂S), fasteners frequently require compliance with:
NACE MR0175
and
ISO 15156
These standards govern:
- Material selection
- Hardness limitations
- Environmental suitability
- Sulfide stress cracking resistance
Duplex S31803/S32205 is widely accepted for sour service applications when manufactured and heat-treated within specified hardness limits.
55. Hardness Requirements for Sour Service
Typical limits:
| Requirement | Maximum Hardness |
|---|---|
| NACE Service | 28–32 HRC (application dependent) |
| Duplex Fasteners | Controlled by solution annealing |
Excessive hardness may increase susceptibility to:
- Sulfide stress cracking
- Hydrogen-assisted cracking
Therefore process control and testing are essential.
56. Service Temperature Limits
Recommended Operating Range
| Material | Service Temperature |
|---|---|
| Duplex 2205 | -50°C to +300°C |
| Super Duplex 2507 | -50°C to +300°C |
| 316 Stainless | -196°C to +550°C |
| Inconel 625 | Up to 980°C |
| Hastelloy C276 | Up to 1040°C |
Duplex materials are generally not recommended for prolonged exposure above approximately 300°C because microstructural changes can reduce toughness and corrosion resistance.
57. Material Verification Prior to Manufacturing
SM Fasteners follows material verification procedures before production begins.
Verification typically includes:
Review of
- Material Test Certificate (MTC)
- Heat number
- Chemical composition
- Mechanical properties
Incoming Inspection
- Visual examination
- Dimensional verification
- Positive Material Identification (PMI)
Only approved material proceeds to manufacturing.
58. Raw Material Forms Used
Fasteners may be manufactured from:
| Raw Material Form | Application |
|---|---|
| Round Bar | Bolts |
| Hex Bar | Nuts |
| Forging Stock | Heavy Hex Bolts |
| Rod Coil | Cold Formed Parts |
| Plate | Specialty Components |
Selection depends on:
- Fastener size
- Mechanical requirements
- Production volume
59. Manufacturing Route Overview
A controlled manufacturing workflow is essential for producing high-integrity duplex fasteners.
Typical Process Flow
Raw Material Receipt
↓
Material Verification
↓
Cutting
↓
Forging or Machining
↓
Heat Treatment
↓
Thread Manufacturing
↓
Surface Treatment
↓
Inspection
↓
Marking
↓
Packaging
↓
Dispatch
60. Hot Forging Process
Large duplex fasteners are generally produced by hot forging.
Benefits:
- Improved grain flow
- Better fatigue resistance
- Reduced material waste
- Higher structural integrity
Common products:
- Heavy hex bolts
- Stud bolts
- Large diameter fasteners
61. Cold Forming Process
Used for smaller fasteners.
Advantages:
| Benefit | Result |
|---|---|
| High productivity | Lower cost |
| Excellent finish | Better appearance |
| Work hardening | Increased strength |
| Dimensional consistency | Improved quality |
Typically used up to medium diameters.
62. CNC Machining Operations
Precision machining may be required for:
- Custom bolts
- Special heads
- Aerospace parts
- OEM components
Processes include:
- Turning
- Milling
- Drilling
- Threading
- Grooving
63. Thread Manufacturing Methods
Thread quality directly influences:
- Preload accuracy
- Fatigue life
- Assembly reliability
Two primary methods are used.
64. Thread Rolling
Threads are formed by plastic deformation.
Advantages:
| Property | Benefit |
|---|---|
| Surface Finish | Improved |
| Fatigue Life | Improved |
| Grain Flow | Continuous |
| Strength | Higher |
| Production Rate | High |
Preferred for critical fasteners.
65. Thread Cutting
Threads are machined by material removal.
Advantages:
| Property | Benefit |
|---|---|
| Flexibility | Excellent |
| Large Diameters | Possible |
| Custom Threads | Easy |
Limitations:
- Lower fatigue performance
- Interrupted grain structure
Typically used for:
- Large studs
- Custom fasteners
- Low-volume production
66. Solution Annealing
Solution annealing is the most important heat treatment for Duplex 2205.
Typical temperature:
| Process | Temperature |
|---|---|
| Solution Annealing | 1020–1100°C |
Followed by:
Rapid Water Quenching
Purpose:
- Restore phase balance
- Dissolve detrimental phases
- Improve corrosion resistance
- Optimize mechanical properties
67. Harmful Intermetallic Phases
Improper heat treatment may form:
| Phase | Effect |
|---|---|
| Sigma Phase | Severe embrittlement |
| Chi Phase | Toughness reduction |
| Carbides | Corrosion reduction |
| Nitrides | Reduced ductility |
Controlled processing prevents their formation.
68. Ferrite Content Control
Ferrite content significantly influences performance.
Typical acceptable range:
| Property | Value |
|---|---|
| Ferrite Content | 35–65% |
Measured according to:
- ASTM E562
- ASTM A923
69. Mechanical Property Development
After proper solution annealing:
| Property | Typical Value |
|---|---|
| Yield Strength | ≥450 MPa |
| Tensile Strength | 620–880 MPa |
| Elongation | ≥25% |
| Impact Toughness | High |
70. Surface Finishing Objectives
Surface finishing provides:
- Improved corrosion resistance
- Removal of contaminants
- Better appearance
- Reduced galling risk
71. Surface Finish Types
As Forged
Characteristics:
- Economical
- Rough surface
- Industrial applications
Machined Finish
Characteristics:
- Precise dimensions
- Smooth finish
- OEM equipment
Pickled Finish
Characteristics:
- Oxide removal
- Improved corrosion resistance
Passivated Finish
Characteristics:
- Enhanced chromium oxide layer
- Improved corrosion resistance
Electropolished Finish
Characteristics:
- Ultra-clean surface
- Reduced roughness
- Enhanced hygiene
72. Surface Finish Comparison
| Finish | Appearance | Corrosion Resistance | Cost |
|---|---|---|---|
| As Forged | Rough | Moderate | Low |
| Machined | Smooth | Good | Medium |
| Pickled | Matte | Very Good | Medium |
| Passivated | Bright | Excellent | Medium |
| Electropolished | Mirror | Excellent | High |
73. Coating Considerations for Duplex Fasteners
Unlike carbon steel fasteners, Duplex 2205 generally does not require protective coatings for corrosion resistance.
However coatings may be used for:
- Anti-galling
- Friction control
- Assembly efficiency
74. Common Coating Systems
| Coating | Purpose |
|---|---|
| PTFE | Anti-galling |
| Xylan | Low friction |
| Molybdenum Disulfide | Torque control |
| Fluoropolymer | Chemical resistance |
| Ceramic Coating | High temperature |
75. Surface Finish & Coating Performance Comparison
| Coating/Finish | Corrosion Protection | Friction Control | Galling Resistance |
|---|---|---|---|
| Pickled | High | Moderate | Moderate |
| Passivated | Very High | Moderate | Moderate |
| PTFE | High | Excellent | Excellent |
| Xylan | High | Excellent | Excellent |
| MoS₂ | Moderate | Excellent | Excellent |
| Electropolished | Very High | Good | Good |
76. Galvanic Compatibility Considerations
When Duplex fasteners are coupled with dissimilar materials:
Potential concerns:
- Galvanic corrosion
- Accelerated attack of less noble metals
Common mating materials:
| Material | Compatibility |
|---|---|
| Duplex Steel | Excellent |
| 316 Stainless | Excellent |
| Super Duplex | Excellent |
| Carbon Steel | Evaluate |
| Aluminum | Caution |
| Copper Alloys | Evaluate |
Insulating washers or PEEK components may be utilized where galvanic isolation is required.
77. Traceability During Manufacturing
Every production lot should maintain traceability through:
- Heat number tracking
- Batch control
- Manufacturing records
- Inspection records
- Material certificates
SM Fasteners integrates traceability practices within its ISO 9001 quality management framework to support EPC, oil & gas, power generation, and export project requirements.
78. Manufacturing Documentation Generated
Throughout production, documentation may include:
| Document | Purpose |
|---|---|
| Raw Material MTC | Material verification |
| Process Sheet | Manufacturing control |
| Heat Treatment Record | Thermal processing |
| Inspection Report | Dimensional compliance |
| PMI Report | Alloy verification |
| Final Release Report | Shipment approval |
79. Engineering Selection Summary
Duplex UNS S31803/S32205 should be selected when projects require:
✓ High strength
✓ Excellent chloride resistance
✓ Sour service suitability
✓ Long service life
✓ Reduced maintenance
✓ Improved weight efficiency
✓ Compliance with international oil & gas standards
