Stud Ends — Engineering Reference | RR Hydraulic
Formal Request for Quotation — Stud Ends
Submit Your
RFQ Today
RR Hydraulic supplies stud ends (lap-joint stud ends, loose flanges, and weld-neck stud end assemblies) across all pipe sizes, pressure classes, materials, and facing types — ASME B16.9 / B16.5 compliant in ASTM A403 WP316L, WP304, WP22, WP91, and Duplex grades for EPC process piping applications. Submit your NPS, pressure class, material, facing type, and quantity for a competitive, fully documented quotation within 24 hours.

Certifications: EN 10204 3.1 / 3.2 MTRs, NACE MR0175 compliance, PWHT records, Third-Party Inspection (SGS / BV / DNV / Lloyds), and complete EPC export documentation packages.
Email RFQ → sales@rrhydraulics.com
Response within 24 business hours  ·  All specifications treated confidentially
Engineering Reference Document

Stud
Ends

A world-class technical reference for EPC piping engineers, procurement heads, TPI inspection agencies, and global project buyers specifying stud ends — lap-joint stub ends, loose-flange assemblies, and weld-neck stud end pipe terminations used throughout process piping to achieve the material economy of a carbon steel loose backing flange with a corrosion-resistant stainless or alloy stud end lap, to allow free rotation of the flange bolt holes for alignment, and to enable fast disassembly of corrosion-resistant piping systems for maintenance without disturbing the pipe spool welds.

ASME B16.9 / MSS SP-43 ASME B16.5 / B16.47 Pressure Classes Type A / Type B Lap Joint ASTM A403 WP316L / WP304 Carbon Steel Backing Flange (A105N) NPS ½” – 24″ Full Range EN 10204 3.1 / 3.2 ISO 9001:2015
Part 01 / Technical Definition
Engineering Rationale,
Type Classification
& Material Economy

Stud ends — also called stub ends or lap-joint ends — are pipe fitting end preparations that create a lap-joint flange connection: the stud end provides the pipe connection weld and the sealing face, while a separate loose (backing) flange rotates freely around the pipe to align bolt holes without rotating the pipe spool itself.

Stud Ends — RR Hydraulic Engineering Reference

1.1 — Technical Definition and Engineering Context

A stud end (stub end) is a short pipe fitting with a butt-weld inlet end (matching the pipe schedule and bore) and a lapped (enlarged diameter) outlet face — the lap provides the sealing face for a flat-face or raised-face gasket and serves as the retaining shoulder for the loose backing flange. The assembly — stud end welded to the pipe end, loose flange sliding freely on the pipe — is the lap-joint flange connection defined in ASME B16.5 and constitutes one of the five standard flange face types alongside weld-neck, slip-on, socket-weld, and blind flanges.

The engineering and economic rationale for specifying stud ends is threefold: (1) Material economy: The only pressure-retaining component at the flange joint is the stud end lap and the pipe — the loose backing flange carries no internal pressure load. This allows the loose flange to be manufactured from a lower cost material (carbon steel ASTM A105N or A181) even when the pipe and stud end are manufactured from expensive alloy materials (SS 316L, Duplex, Inconel, titanium) — the carbon steel flange performs the structural clamping function while the alloy stud end provides the corrosion-resistant sealing face. On large SS piping systems, this material split can reduce flange procurement cost by 60–80% compared to all-SS weld-neck flanges. (2) Bolt hole rotation: The loose backing flange rotates freely around the pipe — allowing perfect bolt hole alignment at the flanged joint without rotating the pipe spool. This is especially valuable in large-bore piping (NPS 12″ and above) where rotating a heavy pipe spool to align bolt holes is impractical. (3) Easy disassembly: Lap-joint connections can be opened for maintenance, inspection, or seal replacement without cutting or disturbing the pipe spool — the backing flanges slide back along the pipe when the bolts are removed, giving full access to the flange joint face.

1.2 — Stud End Type Classification

Type A Stud End (Long Pattern)

A stud end with a long overall length — the butt-weld end and the lap face are separated by a sufficient pipe-equivalent length that the fitting conforms to ASME B16.9 face-to-end dimensions for butt-weld fittings. The long pattern Type A stud end can be used as a pipe spool component with the lap facing any pipe length — the fitting length equals the ASME B16.9 face-to-end dimension for the corresponding 90° elbow. Type A is the standard for EPC process piping project supply where the piping specification references ASME B16.9 for wrought butt-weld fittings. Available in NPS ½”–24″ and larger; schedule-matched to the pipe; all ASTM A403 grades.

Type B Stud End (Short Pattern)

A stud end with a shorter overall length — the butt-weld end is closer to the lap face. The short pattern Type B stud end is used where the piping layout is congested and the minimum pipe spool length from the flange face to the nearest weld must be minimised. Type B dimensions per MSS SP-43 (Wrought and Fabricated Butt-Welding Fittings for Low Pressure Applications) — typically used for lower-pressure applications (ASME Class 150# and 300#) where the reduced body length is structurally adequate. Not interchangeable with Type A in high-pressure piping systems where ASME B16.9 dimensions are mandatory — verify the applicable fitting standard on the project piping specification before ordering.

Lap-Joint Backing Flange (Loose Flange)

The separate sliding flange that sits behind the stud end lap face — manufactured from carbon steel (ASTM A105N or A181 Gr.II) regardless of the pipe and stud end material in most applications. The backing flange has a bore slightly larger than the pipe OD to allow free rotation. It is not welded to the pipe — it slides freely. The backing flange bolt hole circle, bolt hole diameter, and raised face (or flat face) dimensions match the applicable ASME B16.5 or B16.47 pressure class for the nominal pipe size. For EPC supply: the backing flange is specified separately from the stud end — provide the NPS, pressure class (150#, 300#, 600#, etc.), and backing flange material when ordering.

Long Radius Elbow with Lap-Joint End

A standard long-radius (1.5D) or short-radius (1.0D) butt-weld elbow with one or both ends prepared as a stud end (lapped) rather than a standard butt-weld bevel. Used where a direction change and a flanged connection coincide at the same fitting location — eliminates a separate stud end fitting and one butt weld in the piping layout. The lapped elbow end serves as both the directional change and the flange connection point. Less common than straight stub ends but valuable in congested piping arrangements. Available in all ASTM A403 grades and schedules. Per ASME B16.9 with the lapped end profile per ASME B16.5 Appendix E.

Reducing Stud End

A stud end with a different bore diameter at the butt-weld inlet end compared to the lap face outside diameter — used to transition between two pipe schedules at a flanged connection without a separate reducer fitting. The reducing stud end achieves both the schedule/diameter transition and the lap-joint flange connection in a single fitting. Custom-manufactured to project drawing dimensions — not in standard ASME B16.9 tables. Specified when: the pipe schedule changes at a flanged break point (the upstream pipe is heavy-wall high-pressure; the downstream pipe is standard wall); or when a pipe-size reduction occurs at a flanged equipment nozzle where the equipment nozzle NPS differs from the connecting pipe NPS.

Stub End with Raised Face (RF) or Flat Face (FF)

Stud ends are available with raised face (RF) or flat face (FF) lap profiles. Raised face: the lap sealing surface is raised 1.6 mm (Class 150#/300#) or 6.4 mm (Class 600# and above) above the backing flange contact face — the standard for spiral-wound gasket or ring-type joint flange connections. Flat face: the entire lap face is flat — used for connections to cast iron or ductile iron equipment flanges where a flat-face gasket is required to prevent the brittle equipment flange from cracking under the uneven bearing force of a raised-face connection. Verify the flange facing type specified in the project piping class before ordering stud ends — RF and FF are not interchangeable in service.

1.3 — Lap-Joint vs Weld-Neck Flange: Engineering Comparison

Table 1.A — Lap-Joint Stud End vs Weld-Neck Flange: Engineering and Economic Comparison
ParameterLap-Joint (Stud End + Backing Flange)Weld-Neck FlangeEngineering Significance
Flange materialCarbon steel (backing) + alloy (stud end)Must match pipe material throughout60–80% flange cost saving on SS/alloy piping
Bolt hole alignmentFree rotation — always alignableFixed to pipe — must rotate spoolLap-joint invaluable on large-bore and tight spaces
DisassemblyFlanges slide back — full accessFlanges stay at pipe endLap-joint preferred for frequent maintenance
Pressure integrityStud end + pipe carries pressureFlange + pipe carries pressureBoth fully code-compliant; weld-neck slightly stiffer
Fatigue / vibrationLower (no hub stress concentration)Higher (tapered hub SIF)Lap-joint better for vibrating equipment connections
High-pressure serviceUp to ASME Class 2500#Up to ASME Class 2500#Equivalent pressure ratings with correct backing flange
Bore match to pipeExact bore match (same schedule)May have hub bore taperLap-joint provides smooth bore continuity for clean-in-place
NDE of weldBW to pipe — standard RT/UTBW to pipe — standard RT/UTIdentical NDE accessibility for both types

1.4 — Material Economy Calculation

Stud End vs Weld-Neck Flange Material Cost Saving — Worked Example
Saving (%) = (C_WN − C_LJ) / C_WN × 100
C_WN = Cost of weld-neck flange in process pipe material (e.g., SS 316L ASTM A182 F316L)
C_LJ = Cost of stud end (alloy) + backing flange (carbon steel A105N)

Example — 6″ NPS ASME Class 300# flange assembly, SS 316L vs lap-joint:
Option A: SS 316L weld-neck flange (ASTM A182 F316L, ASME B16.5 Class 300#): C_WN = 100 (index)
Option B: SS 316L stud end (ASTM A403 WP316L) + A105N carbon steel backing flange (ASME B16.5 Class 300#):
   SS 316L stud end cost ≈ 20% of the full SS weld-neck flange (short length fitting vs heavy forging)
   A105N backing flange cost ≈ 12% of the SS weld-neck flange (CS material vs SS)
   C_LJ total ≈ 32 vs C_WN = 100 → Saving ≈ 68% per flanged connection

On a large SS 316L piping system with 500 flanged connections: 500 × (100 − 32) = 34,000 index units saved — a major procurement cost reduction on alloy piping systems.
When NOT to use stud ends (weld-neck preferred):
(1) Services above ASME Class 600# where the additional stiffness of the weld-neck hub provides better joint integrity under high bolt loading
(2) Piping classes that explicitly exclude lap-joint connections (some company piping standards prohibit lap-joint on high-pressure or toxic services)
(3) Where the process fluid is so corrosive that even the external surface of the backing flange (carbon steel) would be attacked — use all-alloy weld-neck flanges
(4) Where the crevice between the stud end lap face and the backing flange bore is unacceptable for the service fluid (crevice corrosion risk in concentrated chloride service)
Specifying stud ends for alloy piping, corrosion-resistant flanged connections, or large-bore piping?
Submit your NPS, pressure class, pipe schedule, material, and quantity for a documented RFQ within 24 hours.
Part 02 / Standards & Dimensional Design
Lap Dimensions,
Pressure Classes
& Standards Compliance

Stud end lap dimensions — lap OD, lap height, bore ID, and overall length — are governed by ASME B16.9 (Type A) and MSS SP-43 (Type B). Lap face dimensions must match the ASME B16.5 backing flange bore for the applicable pressure class. All applicable standards are supported at RR Hydraulic.

Stud End Dimensional Reference — RR Hydraulic
Formal R.F.Q. — Stud Ends for EPC / Process Piping / Corrosion-Resistant Alloy Systems
Submit NPS, pressure class, pipe schedule, facing type, material, and quantity to sales@rrhydraulics.com for a certified offer.

2.1 — ASME B16.9 Type A Stud End Key Dimensions

Table 2.A — ASME B16.9 Type A Stud End Lap Dimensions (Selected Sizes)
NPSPipe OD (mm)Lap OD (mm)Lap Height (mm)Overall Length (mm)Bore (Sch 40S)Max Pressure Class
½”21.334.96.43815.8ASME Cl. 2500#
¾”26.742.96.43820.9ASME Cl. 2500#
1″33.450.86.45126.6ASME Cl. 2500#
1½”48.373.06.45740.9ASME Cl. 2500#
2″60.392.16.46452.5ASME Cl. 2500#
3″88.9127.06.47677.9ASME Cl. 1500#
4″114.3157.29.586102.3ASME Cl. 1500#
6″168.3215.99.5105154.1ASME Cl. 900#
8″219.1269.99.5124202.7ASME Cl. 900#
10″273.1323.99.5143254.5ASME Cl. 600#
12″323.9381.012.7165304.8ASME Cl. 600#
16″406.4469.912.7191381.0ASME Cl. 300#
24″609.6685.812.7248574.7ASME Cl. 150#

2.2 — Applicable Standards and Compliance Framework

ASME B16.9

Factory-Made Wrought Buttwelding Fittings — the primary standard governing Type A stud ends (long pattern). B16.9 specifies the face-to-end (overall length), lap OD, and lap height dimensions for stub ends from NPS ½” through NPS 24″ (and by agreement to 48″). B16.9 also defines the butt-weld inlet bevel per ASME B16.25. The B16.9 face-to-end dimension for the stud end is identical to the corresponding elbow — this ensures that stud ends are dimensionally interchangeable with other butt-weld fittings in the piping layout without affecting spool length calculations. All ASME B31.3 process piping EPC projects specify stud ends to ASME B16.9 Type A for high-pressure (Class 600# and above) applications.

MSS SP-43

Wrought and Fabricated Butt-Welding Fittings for Low Pressure Applications — covers Type B stud ends (short pattern) for ASME Class 150# and 300# applications. MSS SP-43 provides reduced overall lengths compared to ASME B16.9 — acceptable for low-pressure service where the shorter fitting length does not compromise pressure integrity. Type B dimensions are widely used in SS and alloy piping for chemical and process applications at lower pressures. For EPC projects: always confirm with the project piping specification whether Type A (B16.9) or Type B (MSS SP-43) is required — the two types are not interchangeable and mixing them in a piping spool affects the spool face-to-face dimension.

ASME B16.5

Pipe Flanges and Flanged Fittings — governs the lap-joint backing flange dimensions for NPS ½”–24″. B16.5 Appendix E defines the lap joint interface dimensions: the backing flange bore (slightly larger than pipe OD to allow free rotation), the lap face OD (must match the stud end lap OD within tolerance), and the lap face height clearance. The lap OD of the stud end must conform to B16.5 Appendix E tolerance (±0.8 mm) to ensure that the backing flange freely rotates over the lap without binding and that the lap face projects into the gasket seating zone with the correct bearing load distribution. Stud ends with undersized lap OD will allow the gasket to be compressed unevenly by the backing flange; oversized lap OD prevents the backing flange from passing over the lap face.

ASTM A403

Wrought Austenitic Stainless Steel Piping Fittings — the primary material standard for SS stud ends. Covers WP304, WP304L, WP316, WP316L, WP321, WP347, and other austenitic grades in the W (wrought) and WX (wrought extra-strength) conditions. For EPC: WP316L is the standard for corrosive service stud ends (low carbon SS 316 — prevents sensitisation at the butt weld HAZ). The “WP” prefix indicates the fitting is made from wrought (not cast) material — wrought material has superior toughness, fatigue resistance, and microstructural consistency compared to cast equivalents. EN 10204 3.1 mandatory on all ASTM A403 stud end lots for EPC supply.

ASTM A234 / A420

ASTM A234: Piping Fittings of Wrought Carbon Steel and Alloy Steel for Moderate and High Temperature Service — covers carbon steel (WPB Grade) and alloy steel stud ends (WP1, WP11, WP22, WP91). ASTM A420: Piping Fittings of Wrought Carbon Steel and Alloy Steel for Low-Temperature Service — covers low-temperature grades (WPL6 for −46°C). A234 WPB is the material standard for carbon steel stud ends in standard temperature service, and for the carbon steel backing flanges (per ASTM A105N for forged flanges or A234 WPB for wrought fittings). A234 WP11/WP22/WP91 stud ends for alloy steel piping systems at high temperature — same PWHT requirements as A182 F11/F22/F91 weldolet and fittings.

ASME B16.47

Large Diameter Steel Flanges — governs lap-joint backing flanges and stud end lap dimensions for NPS 26″–60″. Series A (formerly MSS SP-44) and Series B (formerly API 605) — both series are used in EPC large-bore piping depending on the applicable company or project piping standard. For stud ends on large-bore piping (NPS 26″ and above): the lap OD and lap height must be matched to the B16.47 Series A or Series B backing flange bore — not to the B16.5 dimensions (which cover only NPS ½”–24″). Specify the B16.47 series explicitly when ordering large-bore stud ends — “B16.47 Series A” and “B16.47 Series B” backing flanges have different bolt hole patterns for the same NPS and pressure class.

ASME B31.3

Process Piping — ASME B31.3 Paragraph 304.2.1 covers lap-joint flanges and stud ends as listed fittings under ASME B16.9. The lap-joint connection (stud end + backing flange) is fully code-compliant for all Normal Fluid service pressure classes. B31.3 Paragraph 304.5.1 notes that the backing flange does not require the same pressure rating as the stud end (the stud end carries the internal pressure), but the backing flange must be rated for the bolt preload and the external structural loads from the piping system. For high-cycle fatigue piping (severe cyclic service per B31.3): the lap-joint connection SIF may be lower than a weld-neck flange — the lap face reduces the bending moment transmitted to the pipe compared to the hub of a weld-neck flange.

EN 10253-4 / EN 13480

EN 10253-4: Butt-Welding Pipe Fittings — Part 4: Wrought Austenitic and Austenitic-Ferritic (Duplex) Stainless Steels with Specific Inspection Requirements. Governs SS and Duplex stud ends for European projects. EN 13480: Metallic Industrial Piping — Part 3 covers the design of lap-joint connections. For CE-marked piping systems under PED 2014/68/EU: stud ends (stub ends) must comply with EN 10253-4 for SS and Duplex grades, or EN 10253-2 for carbon and alloy steel, with the appropriate CE marking and EN 10204 3.1 / 3.2 material certification. ASTM A403 stud ends are accepted on EN 13480-governed projects with an ASTM-to-EN material equivalence statement reviewed by the project piping engineer.

Part 03 / Materials, Manufacturing & Welding
Material Grades,
Lap Face Machining
& Weld Requirements

Stud end material must match the connecting pipe material for the butt weld qualification — the same WPS, preheat, and PWHT requirements apply as for any butt-weld fitting of the same material. RR Hydraulic supplies stud ends in all standard ASTM grades with full EN 10204 3.1 / 3.2 forging heat traceability.

Stud End Materials — RR Hydraulic

3.1 — Material Grade Reference for Stud Ends

Table 3.A — Stud End Material Grades: ASTM Spec, Compatible Pipe, and Service Application
ASTM GradeMaterialTemp RangeNACECompatible PipeService Application
A234 WPBCarbon steel−29 to +427°CCond.A106 Gr.B; A53 Gr.BGeneral EPC; utilities; water; steam
A403 WP304LSS 304L−196 to +538°CGoodA312 TP304LChemical; food; water treatment
A403 WP316LSS 316L−196 to +454°CVery GoodA312 TP316LOffshore; chloride; corrosive chemical; marine
A403 WP317LSS 317L (higher Mo)−196 to +454°CVery GoodA312 TP317LHigh-chloride; bleach; aggressive chemical
A403 WP321SS 321 (Ti-stabilised)−196 to +870°CGoodA312 TP321High-temp SS; sensitisation prevention in service
A403 WP347SS 347 (Nb-stabilised)−196 to +870°CGoodA312 TP347High-temp SS; stabilised weld HAZ
A815 WPS31803Duplex 2205−50 to +315°CVery GoodA790 S31803Offshore sour+Cl⁻; seawater; aggressive chemical
A815 WPS32750Super Duplex 2507−50 to +260°CExcellentA790 S32750Extreme chloride; seawater injection; subsea
A234 WP111¼Cr-½Mo alloy−29 to +593°CNoA335 P11High-temp steam; reformer; FCC piping
A234 WP222¼Cr-1Mo alloy−29 to +649°CNoA335 P22Very high-temp; H₂ service; HHTHP
A234 WP919Cr-1Mo-V (P91)−29 to +649°CNoA335 P91USC steam; advanced power plant piping
A420 WPL6CS low-temp (CV tested)−46 to +260°CCond.A333 Gr.6Cryogenic CS; LPG; −46°C service

3.2 — Lap Face Machining and Surface Finish

The lap face (the raised circular face of the stud end that contacts the gasket and the backing flange bore) is the most critical machined surface on the fitting — it is the sealing surface for the flanged joint. The lap face must be machined to: (1) the correct lap OD per ASME B16.5 / B16.47 ±0.8 mm tolerance, ensuring the backing flange can slide over the lap freely while the lap provides the correct load-bearing area for the gasket; (2) the correct lap height per ASME B16.9 tables — insufficient lap height allows the backing flange bore to bear on the pipe OD rather than on the lap face; (3) the correct surface finish for the specified gasket type — spiral-wound gaskets require a smooth phonographic finish (Ra 3.2– 6.3 µm, 125–250 AARH) on the raised face; metallic ring-type joint (RTJ) requires a smooth Ra ≤ 1.6 µm finish; PTFE full-face gaskets require a smooth Ra ≤ 3.2 µm finish to prevent gasket extrusion under bolt load.

  • Lap OD verification: The lap OD is the dimension that determines whether the backing flange will slide over the lap face to its correct seated position — verify the lap OD against ASME B16.5 Appendix E before installing any stud end in the piping system. A lap OD that is too large will prevent the backing flange from passing over the lap — an error that requires the stud end to be removed and re-machined or replaced
  • Lap face perpendicularity: The lap face must be machined perpendicular to the fitting bore axis to within 0.5° — a tilted lap face creates an uneven gasket load when the backing flange bolt is tightened, causing the gasket to fail on the low-load side of the joint. Perpendicularity verified by CMM on sampled lot
  • Lap face surface finish: The raised face of the lap must be machined to the gasket manufacturer’s specified surface finish (phonographic serrated finish for spiral wound gaskets; smooth finish for soft gaskets and RTJ grooves). Ra measurement by contact profilometer on 100% of SS and alloy stud end lots where the lap face finish is specified in the project piping specification
  • Bore match to pipe: The stud end bore ID must match the branch pipe bore ID within ASME B16.9 mismatch tolerance (±1.6 mm) — a bore mismatch greater than 1.6 mm requires a 1:4 transition taper per ASME B16.25. Verify the pipe schedule bore ID matches the stud end bore before welding — a mismatch that is only discovered after welding requires cutting out and replacing the stud end

3.3 — Butt Weld to Pipe and PWHT Requirements

Butt Weld Preparation and Root Pass

The stud end inlet end is bevelled per ASME B16.25 (standard 37.5° bevel, t ≤ 22 mm; compound bevel for heavier wall) matching the mating pipe end preparation. Root gap per WPS; full-penetration root pass using GTAW for SS, Duplex, and alloy steel stud ends. Back-purge with argon for all SS and Duplex root passes — the inside of the pipe and stud end bore is back-purged to prevent root oxidation that would create a corrosion-initiating oxide notch at the weld root inner surface. For large-bore stud ends (NPS 6″ and above): back-purge using an inflatable purge dam system positioned inside the pipe at the weld location; confirm purge gas purity (O₂ ≤ 50 ppm) before commencing root welding to prevent root oxidation.

Bore Alignment at Lap Face

The stud end must be aligned concentrically with the mating pipe end before tack welding — the bore centreline of the stud end must align with the bore centreline of the pipe within the weld fit-up root gap tolerance. Misalignment of the stud end relative to the pipe creates a stepped bore at the weld root that acts as a turbulence-generating step in the flow path (particularly significant in clean-in-place (CIP) piping systems for food and pharmaceutical applications) and a stress concentration in fatigue-sensitive systems. For large-bore stud ends (NPS 10″ and above): internal alignment clamps (spider dogs) are used to hold the stud end concentrically with the pipe bore during tack welding — the clamp is removed after tack welding before the root pass begins.

Lap Face Protection During Welding

The lap face (gasket contact surface) must be protected from weld spatter and arc strikes during the pipe butt weld — weld spatter on the lap face creates hard raised deposits that prevent proper gasket seating and cause gasket leaks at the flanged joint. Protection methods: wrap the lap face with aluminium foil or heat-resistant tape before welding; position the weld joint so that the welder is working away from the lap face; use spatter-release compound on the lap face before welding commences. After welding and PWHT: inspect the lap face for spatter, arc strikes, and discolouration — clean by light grinding with fine abrasive paper followed by passivation if the fitting is SS.

PWHT for Alloy Stud Ends (WP11 / WP22 / WP91)

ASTM A234 WP11 (1¼Cr-½Mo), WP22 (2¼Cr-1Mo), and WP91 (9Cr-1Mo-V) stud ends require the same PWHT as the equivalent A182 F-grade fittings and the pipe material after butt welding: WP11 (P-No. 5A): 595–725°C × time per B31.3 Table 331.1.1; WP22 (P-No. 5B, Gr.1): 675–750°C; WP91 (P-No. 5C, Gr.1): 760–790°C. The PWHT must cover the butt weld, the weld HAZ, and a sufficient length of the stud end body to relieve all welding-induced residual stresses. Lap face protection during PWHT: the lap face must not be mechanically distorted by the PWHT fixture or thermal gradient — support the stud end horizontally with the lap face clear of any fixture contact during the PWHT soak cycle.

Duplex 2205 / Super Duplex Stud End Welding

ASTM A815 WPS31803 (Duplex 2205) and WPS32750 (Super Duplex 2507) stud end butt welds require the same controlled welding conditions as any Duplex piping butt weld: heat input 0.5–2.0 kJ/mm; max interpass temperature 150°C; over-alloyed filler (ER2209 for 2205; ER2594 for 2507); 100% Ar or 98% Ar/2% N₂ back-purge for root passes. The stud end lap face should be masked from argon purge gas contact during root welding — purge gas condensation on the cold lap face can cause moisture contamination of the weld area. Post-weld ferrite count on the butt weld cross-section from the weld procedure qualification record to verify correct 40–60% ferrite balance.

Crevice at Lap-Backing Flange Interface

The annular crevice between the stud end lap face OD and the backing flange bore — and the crevice on the back of the lap face between the lap OD and the pipe OD — must be assessed for crevice corrosion risk in aggressive service environments. For concentrated chloride service (seawater, offshore process, chloride chemical): the crevice at the back of the stud end lap (between the lap underside and the pipe OD) can concentrate chloride and create crevice corrosion even on Duplex SS. This is the primary reason why some offshore company piping standards prohibit lap-joint connections in high-chloride or NACE sour service piping — the piping engineer must evaluate the crevice corrosion risk explicitly for these services before specifying stud ends.

Part 04 / QC, Applications & Export
Inspection & QC,
Industry Applications
& Documentation

RR Hydraulic maintains full traceability from certified pipe or plate stock to final inspected and packed stud end shipment. Lap OD verification, lap height, bore measurement, lap face finish, material certification, and complete EPC export documentation packages are standard on all project-grade stud end supply.

Stud End QC — RR Hydraulic

4.1 — Inspection & QC Protocol

100%
Dimensional Inspection
All stud end dimensions verified per ASME B16.9 / MSS SP-43 on every piece: lap OD (±0.8 mm per B16.5 Appendix E tolerance — the critical dimension controlling backing flange fit), lap height (±0.8 mm), overall length (±1.6 mm), bore ID (per pipe schedule ±1.6 mm mismatch tolerance vs mating pipe), and pipe OD at the butt-weld inlet end (±0.4 mm). For SS and Duplex stud ends: wall thickness at the butt-weld end verified by ultrasonic measurement on sampled lot. Markings verified: NPS, material grade, schedule/wall thickness, heat number, and manufacturer’s mark per ASME B16.9. Dimensional report on lot certificate.
LAP OD
Lap OD Verification — 100%
The lap OD is the single most critical dimension on a stud end — it controls both whether the backing flange can slide over the lap (too large = backing flange cannot be assembled) and whether the lap provides correct gasket seating area (too small = gasket extends beyond the lap face). Internal calliper or OD micrometer measurement on 100% of stud ends on EPC project supply. Lap OD must conform to ASME B16.5 Appendix E tolerance (typically ±0.8 mm from nominal). Lap OD report on QC certificate. This item is unique to stud ends and distinguishes them from standard butt-weld fittings where the flange OD is not a critical dimension.
Ra
Lap Face Surface Finish
Contact profilometer per ISO 4287 on the lap face of all SS, Duplex, and alloy steel stud ends on EPC project supply: raised face lap surface Ra per the project piping specification (typically Ra 3.2–6.3 µm for spiral-wound gaskets; Ra ≤ 1.6 µm for metal ring gaskets; Ra ≤ 3.2 µm for PTFE gaskets). Phonographic serration (concentric or spiral machining marks) per ASME B16.20 requirements for spiral-wound gaskets — smooth turned finish not acceptable for spiral-wound gaskets (insufficient bite for gasket seating). Surface finish report on lot certificate for all alloy stud ends. Visual inspection for arc strikes, weld spatter, and mechanical damage on the lap face on 100% of all stud ends.
PMI
Positive Material ID
XRF on 100% of SS, Duplex, Super Duplex, and alloy steel stud end lots — WP316L vs WP304L differentiation (critical for corrosive service); WPS31803 Duplex 2205 vs WPS32750 Super Duplex 2507; WP11 vs WP22 vs WP91 alloy steel (identical appearance, different service capabilities). For NACE sour service stud ends: individual piece PMI cross-referenced to heat certificate on lot record. Passivation per ASTM A967 on all SS 316 and Duplex stud end lots; passivation certificate confirming the critical lap face surface has been properly passivated.
FERRITE
Ferrite Count (Duplex / Super Duplex)
Mandatory metallographic ferrite content per ASTM E562 on each Duplex 2205 (WPS31803) and Super Duplex 2507 (WPS32750) stud end lot — WPS31803: 40–60% ferrite; WPS32750: 40–50% ferrite. The lap face of the stud end is the critical corrosion-exposed surface — the ferrite balance in the lap zone must be verified to ensure full corrosion resistance at the sealing face. Ferrite count certificate on lot documentation. For subsea and seawater injection stud ends: individual piece ferrite verification is the project standard.
MECH
Mechanical Testing per Heat
Full mechanical properties per ASTM A403 / A234 / A815 / A420 on each material heat: UTS, yield, elongation, reduction of area, and Charpy CVN impact at design minimum temperature for cryogenic and low-temperature grades (WPL6 at −46°C; WP304L/316L at −196°C for cryogenic service). Results on lot certificate cross-referenced to material heat number on EN 10204 3.1 MTC. For WP91 stud ends: mechanical test in the PWHT condition per ASTM A234 WP91 grade requirements.
PERP
Lap Face Perpendicularity
Perpendicularity of the lap face to the stud end bore axis verified by CMM on sampled lot for all EPC project stud ends — acceptance criterion ≤ 0.5° face tilt per bore axis. A tilted lap face creates an eccentric gasket load when the backing flange bolts are tightened, causing uneven gasket compression. On large-bore stud ends (NPS 10″ and above) the perpendicularity check is particularly important — the long lever arm amplifies the effect of small angular deviations into significant gasket load eccentricity. Perpendicularity report on QC certificate for SS and alloy stud end EPC supply.
FAI
First Article Inspection
Complete dimensional (including lap OD, lap height, bore ID), lap face surface finish (Ra), perpendicularity, PMI, ferrite count (Duplex), mechanical test, visual inspection, and material certification on first stud end of each unique configuration (NPS × schedule × material × facing type) per project order. FAI report released before batch production. For WP91 stud ends: FAI includes PWHT record review. For offshore Duplex/Super Duplex: FAI includes TPI (DNV/Lloyds) witness certificate.

4.2 — EN 10204 Material Test Certificate Requirements

Table 4.A — EN 10204 Certificate Types for Stud End Supply
CertificateContentEPC RequirementWhen Mandatory
2.1 / 2.2Declaration / non-specificNot acceptable for EPC process pipingNever for ASME B31.3 / B31.1 stud ends
3.1Heat-traceable mech + chemMandatory — all EPC stud endsAll process, power, chemical, and offshore stud ends
3.23.1 + TPI countersignOffshore critical; NACE; nuclear; Category MNACE sour; offshore safety-critical; nuclear; lethal service

4.3 — Applications by Industry

SS Piping Systems with CS Backing Flanges Corrosion-Resistant Alloy Process Piping Large-Bore Piping Bolt-Hole Alignment Offshore Topside Process Piping Cryogenic LNG Stud End Connections Chemical Plant Alloy Piping Flanges Pharmaceutical CIP Piping Systems Food Processing Hygienic Flanges Duplex Seawater System Flanges Power Plant Alloy Steam Piping Desalination Plant Process Flanges Semiconductor Ultra-Pure Water Piping Maintenance-Frequent Process Connections Mining Slurry Alloy Piping Flanges Pulp and Paper Bleach Circuit Piping Refinery Alloy Piping Flanged Joints

SS 316L Piping with Carbon Steel Backing Flanges

The dominant stud end application in EPC process plants — ASTM A403 WP316L stud ends welded to ASTM A312 TP316L pipe, with ASTM A105N carbon steel ASME B16.5 backing flanges on all flanged connections. This combination delivers the full corrosion resistance of SS 316L at every pressure-boundary surface (pipe bore, weld, and stud end lap face) while using cost-effective carbon steel for the non-pressure-bearing backing flange structural function. On a large petrochemical facility with 2,000 SS piping flanged connections, the stud end / backing flange combination vs all-SS weld-neck flanges saves millions in flange material procurement cost. EN 10204 3.1 on all WP316L stud end lots; passivation per ASTM A967; PMI on 100% of SS lots.

Duplex 2205 / Super Duplex Offshore Process Piping

ASTM A815 WPS31803 (Duplex 2205) stud ends on offshore platform produced water, sour crude, and chemical injection piping with carbon steel backing flanges — achieving the full corrosion resistance of Duplex 2205 at every pressure boundary surface (most critical: the lap face in contact with the process gasket and the pipe bore in contact with the process fluid) while using cost-effective carbon steel for the backing flange. Note: for offshore piping classes that prohibit lap-joint connections in sour or seawater service (due to crevice corrosion concern at the lap back face), weld-neck Duplex 2205 flanges are specified instead. Verify the project offshore piping specification before ordering Duplex stud ends for applications where crevice corrosion is a concern.

Food, Pharmaceutical, and CIP Hygienic Piping

ASTM A403 WP316L stud ends with electropolished lap faces (Ra ≤ 0.4 µm) for hygienic flanged piping connections in food processing, beverage production, pharmaceutical manufacturing, and ultra-pure water systems. The smooth bore and smooth lap face of the stud end provide a crevice-free, cleanable internal surface — essential for CIP (clean-in-place) systems where the piping interior must be cleaned by circulating CIP solution without disassembly. The free-rotation backing flange allows easy alignment of flange joints without rotating piping spools during maintenance. EN 10204 3.1; FDA 21 CFR 177.2800 material compliance for direct food contact SS 316L fittings; electropolish certificate with Ra measurement.

Large-Bore Alloy Piping — Bolt Hole Alignment

WP316L, WP22, or WP91 stud ends on large-bore alloy piping (NPS 12″–24″) where rotating heavy pipe spools for bolt hole alignment is impractical during installation. Large pipe spools (NPS 16″ SS 316L, schedule 10S, 6 metres long) weigh 300–800 kg — aligning bolt holes by rotating the spool requires a crane and is potentially unsafe. The freely rotating backing flange of the lap-joint connection allows the pipe fitter to align all bolt holes from the backing flange alone without touching the pipe spool. This installation advantage is particularly significant on alloy piping systems (where pipe spool weights are higher than carbon steel equivalents of the same OD and length) and in confined offshore platform piping areas.

P91 / WP91 Steam Piping Stud Ends

ASTM A234 WP91 (9Cr-1Mo-V) stud ends for flanged connections on ultra-supercritical (USC) main steam and hot reheat piping in advanced power plants. WP91 stud ends provide matching creep-strength properties to the A335 P91 pipe at the flanged joint — using a lower-alloy stud end (WP22 or WP11) on a P91 pipe creates a creep-strength mismatch at the flanged connection that accelerates thermal fatigue damage at the dissimilar material interface. WP91 stud ends: full ASME IX WPS qualification matching P91 grade; PWHT 760–790°C × time; post-PWHT hardness survey on all weld HAZs; EN 10204 3.1 mandatory; 100% RT of butt welds. Lap face protected during PWHT to prevent distortion.

Alloy Piping Systems — Economy at Scale

The most compelling economic argument for stud ends arises on EPC projects with large quantities of alloy piping flanges — Titanium Grade 2, Hastelloy C276, Inconel 625, or Duplex 2507 piping systems where weld-neck flanges in the same material would cost 5–10× the cost of the equivalent carbon steel carbon flanges. In these ultra-high-cost alloy systems: titanium, Hastelloy, or Inconel stud ends with carbon steel backing flanges reduce the overall flanged joint cost by 70–85% compared to all-alloy weld-neck flanges. This material split is structurally and code-compliant — the only pressure-retaining alloy required is the stud end lap and the pipe bore. This makes stud ends the only economically viable flanged connection solution for exotic alloy piping at industrial project scale.

4.4 — Export Packaging Specification

  • Stud ends individually wrapped — the lap face (gasket seating surface) is the most critical surface on the fitting and must arrive at the fabrication shop free of rust, scratches, and mechanical damage that would compromise gasket seating. Individually wrap each stud end in VCI poly for carbon steel; clean polyethylene sleeve for SS and Duplex; foam disc over the lap face for protection during transit
  • Lap face protected from contact with other fittings — never bulk-stack stud ends with the lap face of one fitting resting against the pipe OD of another; the resulting contact mark on the lap face creates a leak path at the flanged joint. Individual cell packaging in cardboard trays for small-bore stud ends; individual foam-wrapped stacking for large-bore
  • Heat number marked on every stud end per ASME B16.9 — the traceability link to the EN 10204 3.1 MTC. For alloy stud ends (WP316L, WP22, WP91): the heat number is the only field-visible identification that distinguishes the material from other alloys of identical appearance
  • SS and Duplex stud ends in dedicated SS-labelled polybags; segregated from carbon steel hardware; iron contamination on the passivated SS lap face causes corrosion pitting that compromises the gasket seating surface and the corrosion resistance at the critical sealing interface
  • Backing flanges (if supplied as part of the stud end assembly package) packed separately and clearly labelled — Carbon Steel / A105N / ASME Class 150#-300#-600# etc.; backing flanges are bolt-hole-circle matched to the stud end pressure class; mixing classes creates a non-compliant assembly
  • ISPM-15 timber crates or export cartons; desiccant sachets for ocean freight; documentation in waterproof pocket: EN 10204 3.1/3.2 MTC, mechanical test certificate (including Charpy for cryogenic grades), lap OD inspection report (100%), lap face Ra certificate, perpendicularity report (sampled), PMI report (SS/Duplex/alloy), ferrite count (Duplex/Super Duplex), passivation certificate (SS), FAI report, and backing flange certificates (if included)

4.5 — Complete EPC Project Documentation Package

Table 4.B — Full Documentation Package for Stud End Supply
#DocumentStandard / FormatMandatory / ConditionalNotes
01Material Test Certificate (MTC)EN 10204 3.1 / 3.2Mandatory — all EPC stud endsHeat-traceable; one MTC per material heat lot
02Chemical Composition ReportCertified lab per ASTM A403 / A234 / A815MandatoryAll alloying elements; Cr/Ni/Mo/C limits per grade
03Mechanical Properties ReportUTS, yield, elongation, reduction of areaMandatoryPer ASTM spec; one test per material heat
04Charpy Impact Test ReportASTM A370 at design min tempMandatory — WPL6; cryogenic SS; WP91 PWHTTest temp; CVN J-values per material heat
05Lap OD Inspection ReportASME B16.5 Appendix E ±0.8 mm toleranceMandatory — 100% all EPC stud endsCritical for backing flange assembly and gasket seating
06Dimensional Inspection ReportPer ASME B16.9 / MSS SP-43MandatoryLap height, overall length, bore, OD at BW end
07Lap Face Surface Finish CertificateISO 4287 Ra profilometerMandatory — SS / Duplex / alloy EPC stud endsRa per gasket type; phonographic pattern for SW gaskets
08Lap Face Perpendicularity ReportCMM measurement ≤ 0.5° to bore axisMandatory — large bore (NPS ≥ 6″); SS; alloySampled lot; large bore 100%
09PMI Report (XRF)Per lot — SS / Duplex / alloy steelMandatory — all non-CS lots; individual for NACEWP316L vs WP304L; WPS31803 vs WPS32750
10Ferrite Content ReportASTM E562 metallographicMandatory — WPS31803 Duplex; WPS32750 Super Duplex40–60% (2205); 40–50% (2507); photo of cross-section
11Passivation CertificateASTM A967Mandatory — all SS and Duplex stud endsAcceptance test confirms lap face passivated
12NACE Compliance StatementHardness + heat treatment declarationConditional — sour serviceIndividual Brinell confirmation per piece where required
13First Article Inspection (FAI) ReportProject-specific formatMandatory — new configurationsAll parameters including lap OD, Ra, perpendicularity
14TPI Witness CertificateSGS / BV / DNV / LloydsConditional — EN 10204 3.2; offshore; nuclearCo-witness dimensional + PMI + lap face Ra
15ISO 9001:2015 CertificateThird-party QMS certificationMandatory — EPC projectsScope covers stud end manufacture
16Country of Origin + Packing ListChamber of Commerce / item-levelMandatoryHS tariff code; heat number per line item
17Commercial Invoice + Bill of LadingPer INCOTERMS 2020MandatoryFreight forwarder issued

4.6 — ISO and Quality System Compliance

ISO 9001:2015

Quality Management System covering pipe / forging material procurement and heat traceability, forming and CNC machining process qualification (lap OD machining per B16.5 tolerance; lap height; bore ID; overall length; bevel per B16.25), lap face surface finish process qualification (phonographic turning parameters; profilometer acceptance criteria), lap face perpendicularity measurement procedure (CMM setup, acceptance criteria, reporting), PMI procedure, ferrite count test procedure, passivation process control, and full material traceability from raw material heat to dispatched stud end. Mandatory for all EPC, offshore, chemical, and food/pharma stud end procurement qualification.

ASME B16.9 / B16.5 / B16.25

The three-standard framework for stud end manufacture and installation. ASME B16.9 governs the stud end body dimensions (Type A long pattern: face-to-end, lap OD, lap height, butt-weld inlet bevel); ASME B16.5 Appendix E governs the lap interface dimensions (the lap OD tolerance that ensures correct fit with the backing flange bore); ASME B16.25 governs the butt-weld inlet bevel preparation. All three must be simultaneously satisfied — a stud end with correct B16.9 lap OD but incorrect B16.5 lap OD tolerance will either not assemble with the backing flange or will not provide the correct gasket seating area. The procurement document must reference all three standards to create an unambiguous specification.

ASME B31.3 / B31.1

The governing piping design codes for stud end installation. ASME B31.3 Paragraph 304.2.1 accepts lap-joint connections as listed fittings when the stud end per ASME B16.9 and backing flange per ASME B16.5 are used. B31.3 NDE requirements for the butt weld between the stud end and the pipe are the same as for any other butt-weld fitting (RT/UT per Table 341.3.2 for the applicable service category). ASME B31.1 accepts lap-joint flanges for power piping subject to the same pressure-temperature limitations as other flange types. Stud ends on B31.1 piping: verify that the backing flange pressure-temperature rating per ASME B16.5 meets or exceeds the system design conditions at the flanged connection location.

EN 10253-4 / PED 2014/68/EU

EN 10253-4: Butt-Welding Pipe Fittings — Part 4 (Wrought Austenitic and Austenitic-Ferritic SS with Specific Inspection Requirements) governs SS and Duplex stub ends / stud ends on European CE-marked piping systems. The standard covers the material grades, dimensional tolerances, and mechanical testing requirements equivalent to ASTM A403 and A815 for European project supply. PED 2014/68/EU category applies to the piping system — for stud ends on Category III / IV pressure equipment: notified body approval is required. For NORSOK M-650 (Norwegian offshore qualification of manufacturers for special materials): ASTM A403 WP316L and A815 WPS31803 stud end manufacturers must demonstrate compliance with the relevant NORSOK MDS (Material Data Sheet) requirements for offshore piping fittings.


Ready to source stud ends for your EPC, corrosion-resistant alloy, offshore, or hygienic piping project?
Submit your NPS, pipe schedule, material grade, lap facing type, and quantity to RR Hydraulic for a complete, certified commercial offer.