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Long Weld Neck Flange
A world-class technical reference for EPC contractors, pressure vessel engineers, piping engineers, procurement heads, TPI inspection agencies, and global project buyers specifying long weld neck flanges on pressure vessels, columns, reactors, heat exchangers, and critical high-pressure piping nozzle connections in Oil & Gas, Petrochemical, Power, and LNG industries.
Structural Role
& Load Characteristics
Long weld neck (LWN) flanges are flanges with an extended, tapered hub that functions simultaneously as a flange and as a pressure vessel nozzle neck. The elongated hub replaces the traditional short nozzle stub by integrating the neck directly into the forged flange body — eliminating one circumferential weld and reducing stress concentration at the shell-to-nozzle junction on pressure vessels, columns, reactors, and heat exchangers.
1.1 — Technical Definition and Functional Role
A long weld neck (LWN) flange — also referred to as a nozzle flange, extended neck flange, or barrel flange — consists of a standard flange body (raised face, RTJ, flat face, or tongue-and-groove) with a substantially elongated, tapered cylindrical neck that extends beyond the hub into the vessel or equipment wall thickness zone. The neck wall thickness is matched to the pressure vessel shell or head wall at the attachment weld location, providing a smooth, code-compliant transition with controlled stress intensification at the nozzle-to-shell junction.
In EPC and pressure vessel engineering, the LWN flange serves a dual structural function: it acts as both the pressure-retaining flange (sealing the flanged piping connection) and as the nozzle neck through the vessel shell or head. This dual function eliminates the short pipe stub conventionally inserted between the vessel shell and the flange, removing one circumferential butt weld — a significant benefit for radiographic inspection, weld repair risk reduction, and fatigue resistance in high-cycle pressure service.
RR Hydraulic manufactures long weld neck flanges under all applicable standards — ASME B16.5, ASME B16.47 Series A/B, ASME Section VIII, EN 1092-1, and project-specific engineering specifications — with full EN 10204 3.1 / 3.2 traceability and TPI capability.
1.2 — LWN Flange vs Standard Weld Neck vs Other Nozzle Types
| Parameter | Long Weld Neck (LWN) | Standard Weld Neck | Slip-On Flange | Socket Weld Flange | Nozzle Stub + Short WN |
|---|---|---|---|---|---|
| Hub length | Extended — matches vessel nozzle | Short standard hub | No hub — plain bore | Socket bore hub | Separate stub + WN assembly |
| Circumferential welds | 1 (neck to vessel shell) | 2 (stub-to-shell + stub-to-WN) | 2 (face + back fillet) | 1 (fillet) | 2–3 welds |
| Stress at nozzle junction | Lowest — gradual taper | Higher — abrupt transition | Highest — no taper | High — fillet only | High — weld HAZ zones |
| NDE accessibility | Excellent — single weld, full RT | Good — two welds, full RT | Limited — fillet welds | Limited — fillet welds | Complex — multiple welds |
| ASME VIII application | Primary for vessel nozzles | Piping, some vessel nozzles | Low-pressure, non-critical | Not used on vessels | Large bore vessel nozzles |
| Pressure class | Class 150–2500 / PN 10–400 | Class 150–2500 | Class 150–600 | Class 150–2500 (small bore) | All classes |
| Fatigue resistance | Highest — eliminates weld at SIF zone | Good | Poor | Moderate | Moderate |
| Cost | Higher (complex forging) | Moderate | Lowest | Low–Moderate | Moderate + fabrication |
| Delivery | Longer lead — custom forging | Standard stock | Standard stock | Standard stock | Multiple parts from stock |
| Preferred for | Vessel nozzles, reactors, critical piping | General process piping | Low-pressure utility | Small-bore high-pressure | Large-bore vessel nozzles |
1.3 — Structural and Pressure-Retaining Function
The long weld neck flange eliminates the stress intensification problem inherent in conventional short nozzle assemblies. In a standard vessel nozzle constructed from a pipe stub plus a short weld neck flange, there are two circumferential welds — each introducing a heat-affected zone (HAZ), weld residual stress, and a potential flaw initiation site. The LWN replaces both welds with a single, accessible attachment weld at the base of the neck, where the neck OD and wall thickness are designed to match the vessel shell at that location.
Stress Intensification Factor (SIF) Reduction
The tapered neck geometry of the LWN flange distributes the stress transition from the vessel shell wall thickness to the flange hub gradually — reducing the stress intensification factor (SIF) at the shell-to-nozzle junction. Lower SIF directly extends fatigue life under cyclic pressure loading and reduces the risk of nozzle cracking in high-cycle process vessels.
Elimination of Circumferential Weld
Replacing a two-weld nozzle assembly (stub + short WN) with a single LWN attachment weld reduces the number of weld joints requiring radiographic examination (RT), magnetic particle inspection (MPI), and post-weld heat treatment (PWHT) — reducing fabrication time, inspection cost, and quality risk on each nozzle.
Pressure Vessel Code Compliance
ASME Section VIII Division 1 and Division 2 recognise LWN flanges as an integral nozzle configuration. The neck wall thickness and taper must comply with the applicable nozzle reinforcement rules in ASME VIII UG-36 through UG-45. The extended neck provides additional reinforcement area that may reduce or eliminate the need for a separate reinforcement pad (repad).
Nozzle Reinforcement Benefit
For vessel nozzles where the shell opening requires reinforcement per ASME VIII UG-37, the LWN neck contributes to the required reinforcement area calculation through the excess metal in the neck wall above the minimum required thickness. This often reduces or eliminates the repad, simplifying vessel fabrication and NDE.
Thermal Cycling Advantage
The smooth, continuous neck-to-shell transition of the LWN flange minimises thermal gradient stress during temperature transients. Vessels and reactors in high-temperature service with frequent startup/shutdown cycles benefit from the lower stress concentration at the nozzle junction — a primary advantage over the abrupt transition of a conventional stub nozzle.
Inspection Accessibility
The single external circumferential butt weld at the LWN neck-to-shell interface is fully accessible for radiographic (RT), ultrasonic (UT), magnetic particle (MPI), and post-weld heat treatment (PWHT) inspection operations — superior to the restricted access conditions on vessels with internals, insulation, or close nozzle spacing that limit the physical approach to internal welds.
1.4 — Load Characteristics and Nozzle Design Considerations
Long weld neck flanges on pressure vessel nozzles must withstand the combination of: internal pressure loads (ASME VIII design), external piping loads transmitted to the nozzle (moments and forces from thermal expansion, weight, and dynamic loads), flange bolt preload and gasket seating loads, and thermal cycling loads. These combined loads must be assessed in the nozzle design per the applicable code.
= P × R_n / (S × E − 0.6P) [ASME VIII UG-27]
t_nozzle_pipe = Minimum pipe wall thickness for the equivalent pipe schedule (per UG-45)
P = Design pressure (MPa)
R_n = Inside radius of nozzle (mm)
S = Allowable stress of nozzle material at design temperature (MPa)
E = Joint efficiency (1.0 for seamless forging)
LWN neck contribution to reinforcement area (A_neck):
A_neck = 2 × (t_neck − t_n) × L_neck × f_r1
f_r1 = S_nozzle / S_vessel (strength ratio); L_neck = reinforcement zone length per UG-40
| Service Category | Safety Factor | Governing Code | Key LWN-Specific Requirement |
|---|---|---|---|
| Pressure vessel nozzle (standard) | 3.5:1 (UTS:allowable) per ASME VIII | ASME VIII Div. 1 | UG-36 to UG-45 nozzle design; reinforcement check per UG-37 |
| High-pressure vessel (Div.2) | 2.4:1 (UTS:allowable) | ASME VIII Div. 2 | Fatigue analysis mandatory; design by analysis |
| Severe cyclic service | Per fatigue curve | ASME VIII Div. 2 / B31.3 | LWN preferred — lower SIF; fatigue assessment per Annex 3-F |
| NACE sour service | 3.5:1 | NACE MR0175 / ASME VIII | A105N normalised; max 22 HRC; PWHT weld per NACE SP0472 |
| Cryogenic (LNG) | 3.5:1 + Charpy verified | ASME VIII / A350 | Impact test at design temp; fracture mechanics assessment |
| High-temperature (>450°C) | 3.5:1; creep-limited | ASME VIII / ASME I | Allowable stress at temperature; creep-fatigue interaction check |
| Lethal / Category M fluid | 3.5:1 + 100% RT | ASME VIII UW-2 / B31.3 | 100% RT on all welds; full penetration butt weld only; LWN mandatory |
| Offshore / subsea | Per DNV / DNVGL | DNV-ST-F101 / DNV-SE-0175 | Enhanced NDE; corrosion allowance; HISC assessment for duplex |
Submit your nozzle schedule, pressure class, material spec, neck length, and bore for a documented RFQ within 24 hours.
Neck Geometry
& Standards Compliance
Long weld neck flange dimensions are governed by ASME B16.5 (NPS ½–24), ASME B16.47 Series A and B (NPS 26–60), and pressure vessel codes including ASME VIII. The neck length, bore, and taper are typically custom-engineered to match the vessel shell thickness and nozzle geometry — requiring detailed dimensional data from the vessel engineering drawing. All standards are supported with full certification at RR Hydraulic.
Submit NPS, pressure class, material, neck length, bore, and facing type to sales@rrhydraulics.com for a fully certified offer.
2.1 — Key Dimensional Parameters of a Long Weld Neck Flange
Unlike standard weld neck flanges where all dimensions are fully standardised in ASME B16.5 tables, the long weld neck flange has its flange body dimensions per ASME B16.5 / B16.47 but its neck length (L), neck bore (B), and neck OD at weld end are typically custom-specified by the vessel engineer to match the nozzle design. The following parameters must be defined on the purchase order:
Neck Length (L)
The extended hub length from the back of the flange to the weld end of the neck. Determined by the vessel wall thickness, insulation thickness, reinforcement zone requirement (UG-40), and accessibility for field welding and NDE. Typical LWN neck lengths range from 150 mm to 600 mm; custom lengths are manufactured to specification.
Neck Bore (B)
The inside diameter of the LWN neck at the weld end — must match the pipe or nozzle inside diameter at the vessel attachment point. Bore is specified to match the pipe schedule (e.g., NPS 4 Sch 80 bore = 97.18 mm ID) or the vessel shell opening ID. Bore machined to specified tolerance ±0.5 mm from nominal.
Neck OD at Weld End
The outside diameter of the LWN neck at the weld bevel location — must match the pipe OD or shell opening for a full-penetration butt weld. Transition taper from flange hub OD to weld-end OD must comply with ASME B31.3 / B31.1 pipe thickness transition rules: max 30° taper or per vessel drawing specification.
Neck Wall Thickness (t_neck)
The neck wall thickness at the weld end must equal or exceed the minimum required by ASME VIII UG-45 for pressure containment. It must also be compatible with the pipe or vessel shell wall thickness for welding — per ASME B31.3 transition requirements if the thicknesses differ significantly (ratio >1.5:1 typically requires a bevel or taper transition).
Weld Bevel Geometry
The weld end of the LWN neck is machined with a standard butt weld bevel — typically 37.5° ± 2.5° with a 1.6 mm root face, per ASME B16.25 or the applicable welding procedure specification (WPS). For material thickness transitions, compound bevels or internal taper per ASME B31.3 are machined to match the mating component.
Flange Face Type and Finish
The flange face (raised face, RTJ, flat face, T&G) is standard per ASME B16.5 / B16.47 for the specified pressure class and NPS. RTJ facing requires a precision-machined ring groove per ASME B16.20. Raised face surface finish: 125–250 µin Ra (3.2–6.3 µm) serrated concentric per B16.5. RTJ groove walls: Ra ≤ 1.6 µm (63 µin).
2.2 — ASME B16.5 LWN Flange: Flange Body Dimensional Table
The flange body dimensions (flange OD, bolt circle, bolt hole count and size, raised face diameter, and flange thickness) follow standard ASME B16.5 weld neck flange tables. Only the hub / neck dimensions differ from a standard weld neck flange. The following table provides ASME B16.5 flange body data for Class 300 and Class 600 — the most commonly specified classes for LWN flanges on pressure vessels.
| NPS | Pipe OD (mm) | Flange OD Cl.300 | BCD Cl.300 | Bolts×Dia Cl.300 | RF Dia Cl.300 | Flange OD Cl.600 | BCD Cl.600 | Bolts×Dia Cl.600 | RF Dia Cl.600 |
|---|---|---|---|---|---|---|---|---|---|
| 2″ | 60.3 | 165.1 | 127.0 | 8×¾” | 82.6 | 165.1 | 127.0 | 8×¾” | 82.6 |
| 3″ | 88.9 | 209.5 | 168.3 | 8×¾” | 107.9 | 209.5 | 168.3 | 8×¾” | 107.9 |
| 4″ | 114.3 | 254.0 | 200.2 | 8×¾” | 133.4 | 273.1 | 215.9 | 8×⅞” | 133.4 |
| 6″ | 168.3 | 317.5 | 266.7 | 12×¾” | 190.5 | 355.6 | 292.1 | 12×1″ | 190.5 |
| 8″ | 219.1 | 381.0 | 330.2 | 12×⅞” | 247.7 | 419.1 | 349.2 | 12×1⅛” | 247.7 |
| 10″ | 273.1 | 444.5 | 387.4 | 16×1″ | 304.8 | 508.0 | 431.8 | 16×1¼” | 304.8 |
| 12″ | 323.9 | 520.7 | 450.8 | 16×1⅛” | 362.0 | 584.2 | 495.3 | 20×1¼” | 362.0 |
| 14″ | 355.6 | 584.2 | 514.4 | 20×1⅛” | 396.9 | 641.4 | 546.1 | 20×1⅜” | 396.9 |
| 16″ | 406.4 | 647.7 | 571.5 | 20×1¼” | 450.9 | 704.9 | 603.2 | 20×1½” | 450.9 |
| 18″ | 457.2 | 711.2 | 628.6 | 24×1¼” | 501.7 | 774.7 | 660.4 | 20×1⅝” | 501.7 |
| 20″ | 508.0 | 774.7 | 685.8 | 24×1¼” | 552.5 | 857.3 | 736.6 | 24×1⅝” | 552.5 |
| 24″ | 609.6 | 914.4 | 812.8 | 24×1½” | 654.1 | 1022.4 | 876.3 | 24×2″ | 654.1 |
| NPS | Flange OD Cl.900 | BCD Cl.900 | Bolts×Dia Cl.900 | Flange Thick Cl.900 (mm) | Flange OD Cl.1500 | BCD Cl.1500 | Bolts×Dia Cl.1500 | Flange Thick Cl.1500 (mm) |
|---|---|---|---|---|---|---|---|---|
| 2″ | 215.9 | 165.1 | 8×⅞” | 39.6 | 244.5 | 177.8 | 8×1″ | 50.8 |
| 3″ | 279.4 | 215.9 | 8×1⅛” | 50.8 | 342.9 | 254.0 | 8×1¼” | 66.5 |
| 4″ | 355.6 | 279.4 | 8×1¼” | 57.2 | 431.8 | 330.2 | 8×1½” | 79.2 |
| 6″ | 482.6 | 387.4 | 12×1⅜” | 73.0 | 558.8 | 444.5 | 12×1¾” | 101.6 |
| 8″ | 584.2 | 469.9 | 12×1⅝” | 88.9 | 673.1 | 539.8 | 12×2″ | 123.9 |
| 10″ | 692.2 | 558.8 | 16×1¾” | 101.6 | 787.4 | 635.0 | 12×2¼” | 142.9 |
| 12″ | 800.1 | 647.7 | 20×1¾” | 114.3 | 914.4 | 736.6 | 16×2¼” | 165.1 |
2.3 — Pressure Rating Table
| Temperature (°C) | Class 150 | Class 300 | Class 600 | Class 900 | Class 1500 | Class 2500 |
|---|---|---|---|---|---|---|
| −29 to 38 | 19.6 | 51.1 | 102.1 | 153.2 | 255.3 | 425.5 |
| 100 | 17.7 | 46.6 | 93.2 | 139.8 | 233.0 | 388.3 |
| 200 | 13.8 | 43.8 | 87.6 | 131.4 | 219.0 | 365.0 |
| 300 | 10.2 | 39.8 | 79.6 | 119.4 | 199.0 | 331.6 |
| 400 | 6.5 | 36.5 | 73.0 | 109.5 | 182.5 | 304.2 |
| 450 | 5.1 | 31.6 | 63.2 | 94.8 | 158.0 | 263.3 |
| 500 | — | 26.5 | 53.0 | 79.5 | 132.5 | 220.8 |
| 538 | — | 20.5 | 41.0 | 61.5 | 102.5 | 170.9 |
2.4 — Applicable Standards and Compliance Framework
ASME B16.5
Pipe Flanges and Flanged Fittings, NPS ½–24. Defines flange body geometry, pressure–temperature ratings, material groups, bolt dimensions, and facing tolerances for LWN flanges through NPS 24. The neck length and geometry for LWN flanges are specified by the purchaser beyond the B16.5 standard hub geometry.
ASME B16.47 Series A / B
Large Diameter Steel Flanges, NPS 26–60. Series A (formerly MSS SP-44) is used for pressure vessel nozzles and heavy-wall piping; Series B (formerly API 605) for lower-pressure large-bore applications. LWN flanges in large bore are almost exclusively Series A for vessel nozzle applications. Bolt data and flange geometry differ significantly between Series A and B.
ASME Section VIII Div. 1
Rules for Construction of Pressure Vessels. UG-36 through UG-45 govern nozzle design including LWN flanges used as integral vessel nozzles. UG-37 reinforcement area calculation, UG-40 reinforcement zone, UG-41 weld strength, and UG-45 minimum nozzle neck thickness all apply to LWN flange nozzle design.
ASME Section VIII Div. 2
Alternative Rules for Pressure Vessels — design by analysis. Required for higher-pressure vessels and vessels subject to cyclic loading. Fatigue assessment per Annex 3-F applies to nozzle junctions including LWN flange connections. Stress intensification factors (SIF) and stress concentration factors (SCF) are explicitly calculated, favouring the LWN geometry over conventional stub nozzles.
ASTM A105N
Carbon steel forgings for piping components — normalised condition. A105N is the standard NACE-compliant grade for carbon steel LWN flanges in sour service. Normalising heat treatment reduces hardness to ≤187 HB — the NACE MR0175 limit for carbon steel pressure-retaining components in H₂S-containing environments.
ASTM A182
Forged or Rolled Alloy and Stainless Steel Pipe Flanges and Fittings. Covers all alloy steel and SS LWN flanges: F11, F22 (Cr-Mo for elevated temperature), F304L, F316L (austenitic SS), F51 (Duplex 2205), F53 (Super Duplex S32750), F91 (9Cr-1Mo-V for very high temperature), and exotic grades.
ASTM A350 LF2 / LF3
Forgings for piping components with notch toughness requirements. LF2 (impact tested at −45°C) and LF3 (impact tested at −101°C) for LWN flanges on low-temperature and cryogenic vessel nozzles. Charpy impact testing per ASTM A350 Table S5 is mandatory — each individual test piece from the production forging must meet the energy requirement.
EN 1092-1 / DIN 2501
European flange standard — circular flanges for pipes, valves, fittings, and accessories. Type 11 (weld neck) and Type 13 (socket weld) are the relevant EN 1092-1 types. PN-rated flanges (PN 10 through PN 400) per EN 1092-1 are used on European-coded vessels. LWN flanges in PN rating are custom-necked per vessel engineer specification with EN 1092-1 body dimensions.
NACE MR0175 / ISO 15156
Materials for sour H₂S service in oil and gas production. Carbon steel LWN flanges (A105N): max hardness 22 HRC (237 HB). Alloy steel F11, F22: verify hardness at weld HAZ post-PWHT. SS grades (F304L, F316L, F51) are inherently NACE-compliant when hardness is within the austenitic/duplex limits. 100% hardness verification on all LWN flanges for sour service supply.
2.5 — Neck Length and Geometry: Selection Guide
| Application | Typical Neck Length (mm) | Neck OD Configuration | Bore Specification | Design Reference | Engineering Note |
|---|---|---|---|---|---|
| Vessel shell nozzle — standard | 150–300 | Tapered to pipe OD | Match pipe schedule ID | ASME VIII UG-45 | Neck contributes to reinforcement area |
| Vessel head nozzle — dished head | 200–400 | Parallel or tapered | Match head opening ID | ASME VIII UG-36 / UG-37 | Head thickness varies — match at weld |
| Column / tower nozzle | 200–500 | Tapered to match shell | Match column wall ID | ASME VIII / project spec | Long neck accommodates insulation thickness |
| Heat exchanger channel nozzle | 150–250 | Parallel — uniform wall | Match channel flange bore | TEMA / ASME VIII | Often stainless in tube-side process service |
| Reactor nozzle — thick wall | 300–600 | Heavy wall — match reactor | Match reactor bore | ASME VIII Div. 2 | High-thickness: compound bevel required |
| Cryogenic vessel nozzle | 200–400 | Tapered; A350 LF3 material | Match cryogenic pipe ID | ASME VIII / A350 | Impact test at −101°C; A182 F304L option |
| High-temperature nozzle (>450°C) | 150–300 | Tapered; F22 / F91 material | Match alloy steel pipe ID | ASME I / VIII | PWHT mandatory; creep assessment |
| Offshore / subsea vessel nozzle | 200–450 | Duplex / Super Duplex | Match duplex pipe ID | DNV / ASME VIII | HISC assessment; cathodic protection zone |
2.6 — Facing Types for LWN Flanges
Raised Face (RF) — Standard
Most common facing for LWN flanges in process piping connections. 2 mm raised ring height for Class 150/300; 7 mm for Class 600–2500. Serrated concentric finish 125–250 µin Ra per ASME B16.5. Compatible with spiral wound, CAF, and soft gaskets. Standard for the majority of vessel nozzle flanged connections in O&G and petrochemical service.
Ring-Type Joint (RTJ) — High Pressure
Precision-machined octagonal groove per ASME B16.20. Required for Class 600–2500 in high-pressure, high-temperature, and hazardous fluid service. Metal ring (R, RX, BX) provides metal-to-metal seal — highest integrity facing type. RTJ groove dimensions are ring-number-specific; ring number must be specified on the purchase order for each NPS/class combination.
Flat Face (FF)
Full face — no raised ring. Used when mating to flat face flanges on equipment with brittle body materials (cast iron, non-metallic). Full-face gasket extends to bolt holes. Not typically used for LWN flanges on steel vessel nozzles — primarily encountered on utility connections to cast iron pump bodies or strainer housings.
Tongue and Groove (T&G)
Male (tongue) and female (groove) mating faces — gasket fully captured in groove. Used on heat exchanger channel-to-shell flanges and compressor cylinder head flanges where a fully confined gasket is required to prevent blowout under high-pressure cyclic loading. Must be ordered as matched pairs — tongue on one flange, groove on mating flange.
Heat Treatment
& Manufacturing Process
Long weld neck flange material is selected to match the connected vessel or pipe material — matching both mechanical properties and weldability. RR Hydraulic manufactures LWN flanges in all standard and exotic grades — from ASTM A105N carbon steel through Super Duplex and Inconel — with full EN 10204 3.1 / 3.2 traceability and heat treatment documentation.
3.1 — Material Grade Overview and Mechanical Properties
| Material | ASTM Grade | UTS (MPa) | Yield (MPa) | Elong. (%) | Design Temp Range (°C) | Max Hardness (HB) | Primary Vessel Application |
|---|---|---|---|---|---|---|---|
| Carbon Steel (N) | ASTM A105N | 485 | 250 | 22 | −29 to +538 | 187 (NACE) | General process vessels, separators, drums |
| CS Low-Temp | ASTM A350 LF2 | 485 | 250 | 22 | −46 to +345 | 197 | Cryogenic vessels, LNG, ethylene plants |
| CS Low-Temp | ASTM A350 LF3 | 450 | 240 | 22 | −101 to +345 | 197 | LNG storage, sub-zero process vessels |
| 1.25Cr-0.5Mo | ASTM A182 F11 Cl.3 | 485 | 275 | 20 | −29 to +593 | 217 | Catalytic reformer, steam drums, heater pass |
| 2.25Cr-1Mo | ASTM A182 F22 Cl.3 | 415 | 205 | 20 | −29 to +649 | 241 | Hydrocracker reactor, high-temp vessel nozzles |
| 9Cr-1Mo-V (P91) | ASTM A182 F91 | 585 | 415 | 20 | −29 to +649 | 250 | Ultra-high-temp power vessel nozzles, boilers |
| SS 304L | ASTM A182 F304L | 450 | 170 | 30 | −196 to +425 | 192 | Corrosive vessel nozzles, food, pharma, cryogenic |
| SS 316L | ASTM A182 F316L | 450 | 170 | 30 | −196 to +425 | 192 | Marine, chloride-containing vessels, offshore |
| SS 321 | ASTM A182 F321 | 485 | 205 | 30 | −196 to +816 | 192 | High-temp SS vessels; stabilised grade |
| Duplex 2205 | ASTM A182 F51 | 620 | 450 | 25 | −50 to +315 | 293 | Offshore, sour service, seawater vessels |
| Super Duplex | ASTM A182 F53 (S32750) | 750 | 550 | 15 | −50 to +260 | 310 | Seawater injection, high-chloride, subsea |
| Inconel 625 | ASTM B564 N06625 | 827 | 414 | 30 | −196 to +980 | — | Extreme corrosion, very high-temp, sour+Cl⁻ |
3.2 — Yield Strength and Mechanical Properties by Heat Treatment
| Grade / Spec | Heat Treatment | UTS (MPa) | Yield (MPa) | Elongation (%) | Hardness (HB) | Charpy @ Temp (J) | NACE Compliant |
|---|---|---|---|---|---|---|---|
| A105N | Normalised 900°C / air cool | 485 | 250 | 22 | ≤187 | Not req. | Yes (≤187 HB) |
| A350 LF2 | Normalised + impact tested | 485 | 250 | 22 | ≤197 | 27 J @ −45°C | Conditional |
| A350 LF3 | Normalised + impact tested | 450 | 240 | 22 | ≤197 | 27 J @ −101°C | Conditional |
| A182 F11 Cl.3 | Normalised + tempered 680°C | 485 | 275 | 20 | ≤221 | Not req. | Yes |
| A182 F22 Cl.3 | Normalised + tempered 690°C | 415 | 205 | 20 | ≤241 | Not req. | Yes |
| A182 F91 | Normalised 1040°C + tempered 760°C | 585 | 415 | 20 | ≤250 | Not req. | Yes |
| A182 F304L | Solution annealed 1040°C | 450 | 170 | 30 | ≤192 | N/A (austenitic) | Yes |
| A182 F316L | Solution annealed 1040°C | 450 | 170 | 30 | ≤192 | N/A | Yes |
| A182 F51 (Duplex) | Solution annealed 1020–1100°C | 620 | 450 | 25 | ≤293 | N/A | Yes (28 HRC max) |
| A182 F53 (S.Duplex) | Solution annealed 1025–1125°C | 750 | 550 | 15 | ≤310 | N/A | Conditional |
| A182 F91 (P91) | N+T as above; mandatory PWHT | 585 | 415 | 20 | 197–250 | Not req. | Yes |
3.3 — Corrosion Resistance by Material vs Service Media
| Material | H₂S Sour* | CO₂ / Wet Gas | Cl⁻ / Seawater | Acids (HCl/H₂SO₄) | Caustic / Alkali | High Temp (>450°C) | Cryogenic |
|---|---|---|---|---|---|---|---|
| A105N CS | Conditional* | Fair | Poor | Poor | Good | Good to 538°C | Not suitable |
| A350 LF2 / LF3 | Conditional* | Fair | Poor | Poor | Good | Limited | Excellent |
| A182 F11 / F22 | Conditional* | Good | Poor | Poor | Good | Very Good | Not suitable |
| A182 F91 (P91) | Conditional* | Good | Poor | Poor | Good | Excellent to 649°C | Not suitable |
| A182 F304L | Fair | Good | Poor (SCC) | Fair | Very Good | Good to 816°C | Excellent |
| A182 F316L | Good | Very Good | Fair | Good | Very Good | Good to 816°C | Excellent |
| A182 F51 Duplex | Very Good | Excellent | Very Good | Very Good | Very Good | Limited >315°C | Good to −50°C |
| A182 F53 S.Duplex | Excellent | Excellent | Excellent | Excellent | Excellent | Limited >260°C | Good to −50°C |
| Inconel 625 | Excellent | Excellent | Excellent | Excellent | Excellent | Excellent to 980°C | Excellent |
* Sour service: A105N normalised (≤187 HB) mandatory per NACE MR0175 / ISO 15156. Alloy grades F11/F22/F91 must be verified for HAZ hardness post-PWHT. SS and duplex grades comply within standard hardness limits.
3.4 — Manufacturing Process
3.4.1 — Hot Forging: The Only Acceptable Manufacturing Method
Long weld neck flanges for pressure vessel and high-pressure piping applications must be manufactured exclusively by open-die or closed-die hot forging from ingot, billet, or bar stock conforming to the applicable ASTM material specification. The extended neck geometry and the requirement for continuous grain flow through the neck and into the flange hub — critical for fatigue and fracture resistance at the vessel-to-nozzle junction — cannot be achieved by machining from plate, welding of separate components, or casting.
3.4.2 — CNC Machining Tolerances for LWN Flanges
- Bore (inside diameter): ±0.5 mm from nominal — machined to match specified pipe schedule ID or vessel engineer drawing dimension
- Neck OD at weld bevel: ±0.8 mm — matches mating pipe or vessel shell OD for butt weld fitup per ASME B31.3 / B31.1 fitup tolerance (max 1.6 mm misalignment for equivalent thickness components)
- Weld bevel angle: 37.5° ± 2.5° from pipe axis; root face 1.6 mm ± 0.8 mm per ASME B16.25
- Flange face flatness: max 0.8 mm TIR across raised face diameter per ASME B16.5
- Bolt hole position: ±0.8 mm on BCD; angular spacing ±0.5° per ASME B16.5 — bolt holes must straddle the flange centreline
- Neck length (L): ±3 mm from specified dimension — critical for correct positioning of nozzle relative to vessel shell wall
- RTJ groove dimensions: ±0.05 mm on groove sealing surfaces per ASME B16.20 groove geometry table
- Surface finish: neck OD Ra ≤ 6.3 µm; bore Ra ≤ 3.2 µm; weld bevel Ra ≤ 12.5 µm (adequate for weld fitup); RTJ groove walls Ra ≤ 1.6 µm
3.4.3 — Post-Weld Heat Treatment (PWHT) Requirements
PWHT is required after the LWN neck-to-vessel shell butt weld based on material and wall thickness as follows:
- Carbon steel (A105N) per ASME VIII / B31.3: PWHT required when weld groove thickness exceeds 19 mm (¾”) — typical for Class 600+ thick-wall vessel nozzles. PWHT at 595–650°C, 1 hour per 25 mm thickness minimum.
- A182 F11 (1.25Cr-0.5Mo): PWHT mandatory regardless of thickness. Temperature 620–650°C; 1 hour per 25 mm minimum. Verify HAZ hardness post-PWHT ≤ 241 HB for NACE compliance.
- A182 F22 (2.25Cr-1Mo): PWHT mandatory. Temperature 690–760°C; 1 hour per 25 mm minimum. Hardness post-PWHT ≤ 241 HB.
- A182 F91 (9Cr-1Mo-V / P91): PWHT mandatory at 730–800°C; controlled heating rate (≤55°C/hour above 425°C) and cooling rate (≤55°C/hour to 315°C) required per ASME B31.1 / EPRI guidelines. Hardness post-PWHT 197–250 HB mandatory.
- Austenitic SS (F304L, F316L): PWHT not required and not recommended. Use low-carbon L grades to prevent sensitisation. Control weld heat input to minimise HAZ grain growth.
- Duplex SS (F51, F53): Solution annealing after welding preferred; if not feasible (installed condition), control heat input ≤ 2.5 kJ/mm and use correct filler metal (matching or over-alloyed) to maintain 40–60% ferrite in weld HAZ.
Industry Applications
& Documentation
RR Hydraulic maintains full traceability from raw forging heat to final packed shipment on all LWN flange orders. Dimensional inspection, EN 10204 3.1 / 3.2 MTRs, volumetric UT on forging blanks, NACE hardness compliance, Charpy impact test certificates, and complete EPC export documentation packages are standard on all project-grade supply.
4.1 — Inspection & NDT Protocol
4.2 — EN 10204 Material Test Certificate Requirements
| Certificate | Content | Signatory | Standard EPC Requirement | When Mandatory for LWN Flanges |
|---|---|---|---|---|
| 2.1 | Conformity declaration only | Manufacturer | Not acceptable for pressure vessel nozzles | Never acceptable for ASME VIII vessels |
| 2.2 | Non-specific test results | Manufacturer | Not acceptable in O&G / pressure vessel EPC | Not acceptable for any pressure service LWN |
| 3.1 | Heat-traceable forging lot mech + chem results | Manufacturer’s authorised QC Inspector | Minimum for all pressure vessel and piping LWN flanges | All Class 150+ LWN flange supply |
| 3.2 | 3.1 + countersigned by independent TPI (SGS / BV / DNV / Lloyds) | Manufacturer + TPI Inspector | Critical vessel nozzles, NACE, cryogenic, offshore, ASME VIII Div.2 | All Class 600+, sour service, LNG, and ASME VIII Div.2 vessel supply |
4.3 — Pressure Test and Weld Inspection Requirements
Long weld neck flanges are inspected as part of the completed vessel or piping system. Key inspection and test requirements at the nozzle weld:
- Pre-weld inspection: Verify dimensional fitup of LWN neck to vessel shell — maximum root gap, misalignment, and bevel geometry per WPS and ASME B31.3 / VIII requirements before tack welding
- In-process weld NDE: VT (visual) after each weld pass; MT or PT on root pass (where accessible) per ASME VIII UW-51 / B31.3 requirements
- Full RT / UT on completed weld: Radiographic testing (RT) or ultrasonic testing (UT) on the completed LWN neck-to-shell butt weld per ASME VIII UW-11 and B31.3 Chapter VI — specific requirements depend on material, service, and joint efficiency factor used in design
- PWHT verification: Time-temperature recording chart from PWHT operation; post-PWHT hardness testing at weld, HAZ, and parent metal locations per project NDE plan
- Hydrostatic test (ASME VIII): Completed vessel tested at 1.3 × MAWP (Div. 1) or 1.25 × MAWP (Div. 2) after all PWHT and NDE — hold for minimum 30 minutes before inspection of all nozzle welds and flange joints
- Post-hydrostatic NDE: MPI / LPI on flange face and nozzle weld area after pressure test to detect any flaws opened by the test pressure
4.4 — Applications by Industry
Oil & Gas — Production Separators & Drums
LWN flanges in A105N for three-phase separator nozzles, flash drums, and scrubbers. NACE MR0175 compliance mandatory for all nozzles in H₂S-containing service — normalised A105N with ≤187 HB hardness verified 100%. EN 10204 3.2 with TPI witness for Class 600 and above. Reinforcement pad may be eliminated where LWN neck contributes sufficient area per UG-37.
Refinery — Hydrocracker & Catalytic Reformer Reactors
High-temperature reactor nozzles in A182 F22 (2.25Cr-1Mo) or F91 (9Cr-1Mo-V) for hydrocracker and catalytic reformer service at 350–650°C. PWHT mandatory on all welds — controlled time-temperature recording required. Nelson curve compliance (API 941) for hydrogen service at elevated temperature and pressure. ASME VIII Div. 2 analysis for cyclic pressure reactors.
LNG Terminals — Cryogenic Storage Vessels
Cryogenic LWN flanges in A350 LF3 for vessel nozzles at −165°C LNG service. Charpy impact testing at −196°C on special project specifications. A182 F304L used for inner tank nozzle connections in double-wall LNG storage tanks. Fracture mechanics assessment per BS 7910 for through-thickness defect tolerance at cryogenic temperature mandatory on critical nozzles.
Power Generation — Steam Drums & High-Pressure Vessels
Boiler drum and steam vessel nozzles in A105N (low-temperature), A182 F11 Cl.3 (intermediate temperature), and F22 Cl.3 / F91 (high-temperature). ASME Section I (Power Boilers) and ASME VIII govern design. PWHT on all Cr-Mo nozzle welds — production PWHT records and post-PWHT hardness certificates required for ASME Code stamped vessels.
Offshore Platforms — Topside Process Vessels
Topside separator, scrubber, and reboiler vessel nozzles in A182 F316L or Duplex F51 for marine atmosphere and chloride-containing process fluid resistance. HISC (Hydrogen Induced Stress Cracking) assessment mandatory for super duplex F53 nozzles in cathodic protection zones per DNV RP-F112. All offshore LWN flange supply with EN 10204 3.2 and DNVGL / Lloyds TPI.
Heat Exchangers — Channel and Shell Nozzles
TEMA heat exchanger channel-to-nozzle LWN flanges in A182 F316L (tube-side corrosive service) or A105N (shell-side carbon steel service). RTJ or T&G facing for high-pressure channel closure flanges. Tube-side LWN flanges in duplex or Inconel where chloride-containing process fluids require enhanced corrosion resistance. All supply with TEMA and ASME VIII material documentation.
4.5 — Export Packaging Specification
- Individual LWN flanges wrapped in VCI (Volatile Corrosion Inhibitor) poly film — critical for carbon and alloy steel grades to prevent atmospheric corrosion on precision-machined bore and flange face surfaces during ocean freight and site storage
- Bore protection: foam or plastic bore caps on both ends of the LWN neck — protects the precision bore and weld bevel from damage and contamination; prevents moisture entry into the bore during transit
- Flange face protection: cardboard or foam disc bonded to the raised face or RTJ groove — prevents damage to the serrated surface finish or precision RTJ groove during transit and handling; re-machining at site is not acceptable
- Individual item tagging: stainless steel or weather-proof polypropylene tag attached to each LWN flange with heat number, ASTM grade, NPS, pressure class, neck length, bore, facing type, and PO item number
- Crating: LWN flanges bolted to ISPM-15 heat-treated timber base frames (not stacked) — flange face vertical, neck horizontal; heavy flanges (NPS 8+) individually crated and secured against movement with timber blocking and steel banding
- Crate markings: Project PO, item tag, ASTM grade, NPS, class, neck length, gross weight, net weight, crate dimensions, country of origin, “PROTECT FLANGE FACE — DO NOT DROP” handling symbols per ISO 780 / ASTM D5276
- Documentation: complete MTC package, dimensional inspection report, and TPI release note enclosed inside crate lid and in external waterproof document pocket — cross-referenced to forging heat number on each flange tag
4.6 — Complete EPC Project Documentation Package
| # | Document | Standard / Format | Mandatory / Conditional | Notes |
|---|---|---|---|---|
| 01 | Material Test Certificate (MTC) | EN 10204 3.1 / 3.2 | Mandatory — all pressure vessel / piping | Forging heat-traceable; one MTC per heat |
| 02 | Chemical Composition Report | Forging lot certified lab analysis | Mandatory (within MTC) | All elements per ASTM A105 / A182 / A350 |
| 03 | Mechanical Properties Report | UTS, yield, elongation, RA, hardness | Mandatory (within MTC) | Per applicable ASTM material specification |
| 04 | Hardness Test Report | ASTM E10 Brinell / E18 Rockwell | Mandatory — NACE / sour service | Individual flange results; A105N ≤187 HB |
| 05 | Charpy Impact Test Report | ASTM A370 / EN 10045 | Mandatory — A350 LF2 / LF3 | Test temp + individual + average J-values |
| 06 | Dimensional Inspection Report | Per ASME B16.5 / B16.47 + project drawing | Mandatory | All flange body + neck geometry per spec |
| 07 | Bore Dimensional Report | Per project nozzle schedule drawing | Mandatory | Bore ID, neck length, weld bevel geometry |
| 08 | Flange Face Finish Report | ASME B16.5 / B16.20 | Mandatory — RTJ facing | Ra measurement; RTJ groove depth/width |
| 09 | First Article Inspection Report (FAI) | Project-specific format | Mandatory — new items / first lot | Released before batch production |
| 10 | UT Report — Forging (Volumetric) | ASTM A388 / EN 10308 | Mandatory — Class 900+, NACE, ASME VIII | Pre-machining blank inspection |
| 11 | MPI Report | ASTM E709 / EN ISO 9934 | Mandatory — CS/alloy, Class 600+, NACE | Full surface after final machining |
| 12 | LPI Report | ASTM E165 / EN ISO 3452 | Mandatory — SS / duplex grades | Full surface; F316L, F51, F53 mandatory |
| 13 | PMI Report (XRF) | Per lot — SS / duplex / exotic grades | Mandatory — non-CS grades | 100% individual flange verification |
| 14 | TPI Witness Certificate | SGS / BV / DNV / Lloyds countersigned | Mandatory — EN 10204 3.2 orders | Witness at manufacturer works |
| 15 | NACE MR0175 Compliance Statement | Hardness + HT condition declaration | Mandatory — sour service LWN flanges | References forging heat + hardness results |
| 16 | Heat Treatment Certificate | Time-temperature chart + furnace records | Mandatory — A350; F11/F22/F91 grades | Production HT; PWHT records where applicable |
| 17 | RTJ Groove Inspection Certificate | Per ASME B16.20 | Conditional — RTJ facing LWN flanges | Ring number, groove dims, finish |
| 18 | Forging Process Certificate | Manufacturer’s forging procedure record | Conditional — ASME VIII Div.2 / nuclear | Confirms open-die or closed-die forging; no bar/plate |
| 19 | ISO 9001:2015 Certificate | Third-party QMS certification | Mandatory — all EPC / ASME VIII vessel supply | Scope covering forged flange manufacture |
| 20 | Country of Origin Certificate | Chamber of Commerce | Mandatory — all export | For customs and duty classification |
| 21 | Packing List | Item-level per shipment | Mandatory | Cross-references MTC and TPI numbers |
| 22 | Commercial Invoice | Per INCOTERMS 2020 | Mandatory | Includes HS tariff code |
| 23 | Bill of Lading / Air Waybill | Per freight mode | Mandatory | Issued by freight forwarder |
4.7 — ISO and Quality System Compliance
ISO 9001:2015
Quality Management System covering raw forging material procurement, forging process control, heat treatment verification, dimensional inspection, NDT, surface finish measurement, bore gauge calibration, and full material traceability through all production stages. Mandatory for all EPC, O&G, and ASME VIII vessel project procurement qualification.
ISO 9606
Qualification testing of welders. LWN flanges are joined to vessel shells by butt welding in the field — all welders performing the LWN neck-to-shell welds must hold current ISO 9606-1 qualification (or AWS / ASME IX equivalent) in the applicable process (GTAW, SMAW, SAW) and material group. This applies to the field installation welding, not to LWN flange manufacture.
ISO 10474
Steel and steel products — inspection documents. Legacy framework from which EN 10204 certificate types derive. Some ASME project specifications or legacy vessel codes reference ISO 10474 Type 3.1.B (= EN 10204 3.1). Current operative standard for material certification of LWN flanges is EN 10204; ISO 10474 references are cross-mapped on request.
ISO 4413
Safety requirements for hydraulic fluid power systems. LWN flanges used on hydraulic power unit (HPU) pressure vessels, accumulators, and high-pressure hydraulic manifold housings must comply with ISO 4413 pressure containment and cleanliness requirements. Bore cleanliness post-machining: ISO 4406 code 16/13 or better for hydraulic system LWN connections.
Submit your nozzle schedule, material specification, pressure class, neck length, and quantity to RR Hydraulic for a complete, certified commercial offer.
