Weld Procedure Qualification (PQR): Mechanical Testing and ISO 15614-1
Weld procedure qualification under ISO 15614-1 is the formal process by which a manufacturer demonstrates that a proposed welding procedure will consistently produce welds with the mechanical properties and soundness required by the design standard. This article explains every stage of the qualification sequence — from drafting the preliminary WPS through to issuing the qualified WPS — with particular focus on essential variables, test weld geometry, required mechanical tests, acceptance criteria, and ranges of approval.
✅ Key Takeaways
- ISO 15614-1 requires a test weld deposited to a preliminary WPS (pWPS), followed by non-destructive and destructive testing; all parameters and results are recorded in the WPQR.
- Essential variables — material group, process, filler type, heat input, PWHT, joint geometry — define the boundary beyond which a new qualification is required.
- Mandatory mechanical tests for a full-penetration butt weld include transverse tensile, face/root (or side) bend, macro-section, hardness survey (HV10), and Charpy impact when material group demands it.
- Ranges of approval for thickness are 0.5t–2t (multi-run) or 0.7t–1.3t (single-run); filler metal diameter changes are not an essential variable.
- HAZ hardness must not exceed 380 HV10 for Groups 1–4 carbon and low-alloy steels in the absence of a specific design standard limit.
- A qualified WPQR has no inherent expiry under ISO 15614-1, but client or authority requirements often impose periodic revalidation every 3–5 years.
The Qualification Framework: WPS, pWPS, and WPQR
ISO 15614-1:2017 (superseding the 2004 edition) specifies the requirements for the qualification of welding procedures for metallic materials by testing. It forms part of a broader family of standards: ISO 15607 defines the general framework, ISO 15608 provides the material grouping scheme, and ISO 15610 through 15614 address specific qualification routes. For steel and nickel alloys welded by arc and gas processes, ISO 15614-1 is the primary document.
The three documents that underpin any qualification are distinct in purpose:
- pWPS (preliminary Welding Procedure Specification) — the proposed parameter set used to deposit the test weld. It covers all welding conditions but is not yet qualified for production use.
- WPQR (Welding Procedure Qualification Record) — the record of actual parameters measured during the test weld, together with all NDE and destructive test results. Once accepted, this document becomes the evidence of qualification.
- WPS (Welding Procedure Specification) — the production instruction issued to welders, derived from the WPQR, specifying parameters within the qualified ranges of approval.
The standard distinguishes between arc welding processes covered under Part 1 (SMAW, GMAW/FCAW, GTAW, SAW, PAW, ESW/EGW) and other processes addressed in Parts 2 through 13 of the ISO 15614 series.
ISO/TR 15608 Material Grouping
The material group system is central to ISO 15614-1 because it determines the transferability of qualification — a WPQR performed on a material within one group may or may not qualify welding of materials in adjacent groups. The principal groups relevant to ferrous materials are:
| Group | Material Description | Typical Grade Examples |
|---|---|---|
| 1.1 / 1.2 / 1.3 | Steels with Re ≤ 460 MPa | S235, S275, S355, S420, S460 |
| 2 | Thermomechanical rolled fine-grain steels, Re > 360 MPa | S420M, S460M, S355ML |
| 3 | Quenched and tempered steels, Re > 360 MPa | S690Q, S890Q, Hardox grades |
| 4 | Low-vanadium alloy steels | 13CrMo4-5, 10CrMo9-10 (P22) |
| 5 | 5Cr–0.5Mo steels | X12CrMo5 (P5) |
| 6 | High-chromium creep-resistant steels | P91, P92, X10CrMoVNb9-1 |
| 8.1 | Austenitic stainless steels | 304L, 316L, 321, 347 |
| 10 | Nickel and nickel alloys | Alloy 625, Alloy 825, Alloy C-276 |
A qualification on Group 1.2 material does not automatically qualify welding of Group 1.3; a qualification on Group 2 material qualifies Groups 1 and 2 but not Group 3. Table 4 of ISO 15614-1 gives the full transferability matrix.
Essential Variables and Their Significance
An essential variable is any parameter whose change outside defined limits alters the metallurgical character of the weld or HAZ in a manner that cannot be predicted from the existing test data. ISO 15614-1 Clause 8 lists the essential variables applicable to each welding process. A change in an essential variable beyond its range of approval voids the existing WPQR and requires a new test weld to be qualified.
Process-Independent Essential Variables
| Variable | Nature of Change Requiring Re-qualification |
|---|---|
| Parent material group (ISO/TR 15608) | Change to a group not covered by the qualification matrix (Table 4) |
| Filler metal type / AWS or EN designation | Change to a different filler type (e.g., basic to rutile; solid wire to flux-cored) |
| Welding process | Addition, removal, or substitution of a welding process |
| Joint type | Change from butt to fillet (partially; see Clause 8 notes) |
| Post-weld heat treatment | Addition or omission of PWHT; change in PWHT temperature range >15°C |
| Preheat temperature | Reduction below qualified minimum by more than 25°C |
| Interpass temperature | Increase above qualified maximum by more than 25°C (per test record) |
| Heat input | Increase more than 25% above or decrease more than 25% below the qualified range |
| Shielding gas type / mixture | Change in gas type or change in mixture ratio outside tolerance |
| Material thickness | Outside range 0.5t–2t (multi-run) or 0.7t–1.3t (single-run) |
| Welding position | Change to a position not covered by Table 12 transferability rules |
Heat Input Calculation
Heat input is one of the most consequential essential variables because it governs HAZ grain growth, peak temperature, and cooling rate through the martensite start temperature, all of which determine HAZ toughness and hardness. The arc energy Qarc and net (corrected) heat input Qnet are:
Q_arc = (U × I) / v [kJ/mm] where: U = arc voltage (V) I = welding current (A) v = travel speed (mm/s) Q_net = Q_arc × η Thermal efficiency factors η: SMAW : η = 0.80 GMAW : η = 0.80 GTAW : η = 0.60 SAW : η = 1.00 FCAW-G : η = 0.80
Test Weld Assembly and Execution
Test Piece Dimensions
The test weld geometry must be representative of the intended production joint. ISO 15614-1 Clause 7.3 specifies minimum test piece dimensions:
- Butt weld in plate: minimum length 350 mm (or 150 mm either side of weld); width such that full specimens can be extracted after weld quality checks remove end zones of 25 mm each.
- Butt weld in pipe: full circumference or at minimum a quarter-circumference arc, ensuring at least one face-bend, one root-bend, one tensile, and one macro specimen can be extracted.
- Fillet weld (Clause 8.3 qualification): T-joint assembly minimum 300 mm long; specimen extraction for macro and hardness only.
Welding Conditions
The test weld must be performed in the same manner as intended for production. Conditions that must be recorded and reproduced within the essential variable tolerances include:
- Joint preparation geometry (included angle, root face, root gap) within ±2° and ±0.5 mm of nominal
- Base material grade, heat, and batch reference (for traceability)
- Filler metal trade name, classification, and batch certificate
- Preheat temperature measured by contact thermocouple or Tempilstik at least 75 mm from the joint line
- Interpass temperature measured with calibrated contact pyrometer immediately before each pass deposition
- Travel speed measured or derived from weld length divided by arc time per pass
- Current, voltage, and polarity recorded per pass
Non-Destructive Examination of the Test Weld
Before destructive specimens are cut, the test weld must pass NDE to ISO 5817:2014 Level B acceptance criteria (Level C for specific fillet weld qualifications). The required NDE methods are:
| NDE Method | Standard | Coverage Required | Acceptance Level |
|---|---|---|---|
| Visual examination (VT) | ISO 17637 | 100% of weld length | ISO 5817 Level B |
| Radiographic testing (RT) | ISO 17636-1/-2 | Full length of test weld | ISO 10675-1 Level 1 |
| Ultrasonic testing (UT) | ISO 17640 | Full weld (alternative to RT for t ≥ 8 mm) | ISO 11666 Level 2 |
| Penetrant testing (PT) | ISO 3452-1 | Root side (pipe welds, austenitic) | ISO 23277 Level 1 |
| Magnetic particle (MT) | ISO 17638 | Weld + HAZ surfaces (ferritic only) | ISO 23278 Level 1 |
NDE is typically completed at least 16 hours after welding for ferritic steels susceptible to hydrogen cracking (Groups 2, 3, 4, 5, 6), and 24 hours for hydrogen-sensitive steels welded with high hydrogen potential processes. Phased array UT (PAUT) per ISO 13588 is an acceptable alternative to conventional UT provided the technique is validated for the weld geometry.
See the hydrogen-induced cracking article for the metallurgical basis of delayed hydrogen cracking and its relevance to NDE timing.
Destructive Test Requirements and Specimen Extraction
Once NDE is passed, a cutting plan is prepared. End zones (25 mm each end) are discarded. The destructive test specimens are extracted in the sequence shown in Figure 2. Table 1 of ISO 15614-1 specifies the required number of each specimen type as a function of test piece thickness.
Transverse Tensile Test
Two transverse tensile specimens are required. Specimens are machined to remove the weld cap flush with the plate surface; the weld root reinforcement is also removed. The gauge length spans the full weld width plus HAZ. Tests are conducted to ISO 4136 at ambient temperature (23 ±5 °C).
Acceptance criterion: Tensile strength Rm of the specimen must be ≥ the minimum specified Rm of the parent material. If the weld metal has a specified strength exceeding the parent material (overmatching filler), fracture in the weld metal is acceptable at any strength. Fracture at the fusion boundary below the parent material minimum is a failure.
Bend Test
Bend tests assess ductility and detect planar flaws in the weld cross-section. For t < 12 mm, two face bends and two root bends are required; for t ≥ 12 mm, four side bends replace face and root bends (ISO 5173). The mandrel diameter is specified in ISO 15614-1 Table 4a as a function of elongation A and thickness t:
Mandrel diameter d = 100t / A − t where: t = specimen thickness (mm) A = minimum elongation (%) from parent material specification For A ≥ 20% (e.g., structural steels): d ≈ 4t typical For A < 20% (e.g., high-strength steel): d is larger per formula
Acceptance criterion: No single imperfection exceeding 3 mm in any direction, measured after bending, visible on the outer surface of the bent specimen. Total cumulative length of cracks <6 mm. Corner cracks up to 6 mm are not cause for rejection unless they originate from a visible slag inclusion or lack of fusion.
Macro-Section Examination
One macro-section cut transversely through the weld and prepared to a 1µm finish, etched with 2–5% Nital (for steels), and examined at magnification 1× to 10×. The section must reveal:
- Full fusion to both sidewalls and inter-run boundaries
- Complete root penetration or root fusion (for one-sided welds)
- Absence of cracks in weld metal, HAZ, and parent metal
- Absence of inter-run porosity exceeding ISO 5817 Level B limits
- Correct pass sequence and number of runs consistent with the pWPS
Macro-section acceptance is to ISO 5817 Level B. The macro also provides confirmation of the actual throat thickness for fillet welds and the actual weld bead geometry for correlation with the hardness traverse.
Hardness Survey (HV10)
A Vickers hardness survey (10 kg load, HV10) is performed on the macro section per ISO 9015-1. Three traverse lines are specified:
- Top traverse: approximately 2 mm below the weld cap surface
- Middle traverse: at mid-thickness (for t ≥ 20 mm)
- Root traverse: approximately 2 mm above the root
Each traverse covers parent metal (at least 4 mm from fusion boundary), HAZ at 0.5 mm, 1 mm, 2 mm, 5 mm from the fusion line, weld centre-line, and the mirror positions on the opposite HAZ and parent metal.
Acceptance criterion: Maximum 380 HV10 in HAZ for steels in Groups 1–4, in the absence of a specific material standard requirement. Groups 5 and 6 (Cr-Mo and P91/P92) require PWHT, and hardness limits post-PWHT are set by the relevant material standard (typically ≤250–265 HV for P91 after PWHT at 745–760 °C).
The hardness testing methods article provides a comprehensive background on the Vickers test principle, indenter geometry, and conversion factors relevant to this application.
Charpy V-Notch Impact Testing
Charpy testing is required when the base material standard mandates impact properties, or when the design code specifies a minimum absorbed energy requirement. ISO 15614-1 specifies testing to ISO 148-1 at the temperature required by the material specification or design code.
Notch positions and specimen orientations:
| Notch Position | Abbreviation | Notch Location | Purpose |
|---|---|---|---|
| Weld centre-line | WC | Notch root at weld centreline | Weld metal toughness |
| Fusion line | FL | Notch root tangent to fusion line | Coarse-grained HAZ toughness |
| FL + 2 mm | FL+2 | 2 mm from fusion line into HAZ | Partially transformed / ICHAZ |
| FL + 5 mm | FL+5 | 5 mm from fusion line into HAZ | Outer HAZ / subcritical zone |
Acceptance criterion: Mean of three specimens ≥ the minimum specified energy. No individual value below 70% of the minimum (i.e., ≥0.7 × minimum); one value may be between 70% and 100% of the minimum provided the mean is met. Specimens are transverse to the weld direction and positioned to ensure the notch root samples the intended microstructural zone.
For the metallurgical interpretation of HAZ toughness, see the Charpy impact testing guide and the HAZ microstructure article covering coarse-grained HAZ grain growth and its effect on impact energy.
Ranges of Approval
The range of approval defines the production welding conditions that are legitimately covered by a given WPQR. ISO 15614-1 Clauses 8 and 9 define ranges of approval for each essential variable. Key ranges for commonly encountered variables are:
| Variable | Qualified Range | Notes |
|---|---|---|
| Material thickness (multi-run) | 0.5t to 2t (max 150 mm) | t = test piece thickness |
| Material thickness (single-run) | 0.7t to 1.3t | Single-pass butt or fillet |
| Pipe outside diameter | ≥ 0.5 D (min 25 mm) | D = test pipe OD |
| Heat input | 0.75 Q to 1.25 Q | Q = mean heat input of test weld |
| Preheat temperature | ≥ (Tp − 25°C) | Lower limit only; higher preheat is acceptable |
| Interpass temperature | ≤ (Ti + 25°C) | Upper limit only; lower interpass is acceptable |
| Filler wire diameter | Not an essential variable | Any diameter of same classification is acceptable |
| Welding position (plate) | PA qualifies PA, PC, PF; PG qualifies PG only | Table 12 transferability matrix |
Thickness Range for Multi-Process Qualifications
When a test weld is deposited using two processes (e.g., GTAW root + SMAW fill), each process is qualified only for the thickness it deposited in the test. If the GTAW root run deposited 4 mm and the SMAW fill deposited 16 mm, the GTAW process is qualified for root applications up to 2 × 4 = 8 mm, while the SMAW is qualified for fill passes 0.5 × 16 = 8 mm to 2 × 16 = 32 mm. This distinction is critical for complex joint configurations on heavy wall piping.
Post-Weld Heat Treatment (PWHT) and Its Role in Qualification
PWHT is an essential variable. A WPQR qualified with PWHT does not cover production welding without PWHT, and vice versa. This is because PWHT fundamentally changes the microstructure of both the weld metal and HAZ — tempering martensite, precipitating carbides, reducing residual stress, and altering hardness and toughness profiles. For hydrogen-susceptible steels (Groups 3, 4, 5, 6), PWHT is not optional and must be part of the qualification record.
The PWHT parameters recorded on the WPQR — temperature range, holding time, heating and cooling rates — define the qualification. Changes in temperature of more than ±15 °C or holding time of more than −25% require re-qualification. This tight control is particularly important for P91 (Group 6) steels, where the tempered martensite microstructure and creep rupture properties are critically sensitive to PWHT conditions.
Refer to the quenching and tempering article for the metallurgical principles of tempering as they apply to PWHT of alloy steels, and to the martensite formation article for the microstructural basis of HAZ hardness.
Common Qualification Failures and Corrective Actions
Transverse Tensile Failure at the Fusion Boundary
The most common tensile failure mode in procedure qualification is fracture at the fusion boundary with strength below the parent material minimum. Root causes include: lack of fusion arising from incorrect arc gap or travel speed; excessive dilution of low-strength filler with high-strength parent metal at the root; or weld metal hydrogen embrittlement in inadequately preheated joints. Corrective action typically involves revising the pWPS to increase preheat temperature, reduce travel speed, or change to a higher-strength matching filler.
Excessive HAZ Hardness
HAZ hardness exceeding 380 HV10 in carbon and low-alloy steels (Groups 1–4) indicates an as-deposited martensite-dominated HAZ microstructure. This arises from rapid cooling through the martensite transformation range — a consequence of low heat input, low preheat, or high carbon equivalent material. Carbon equivalent (IIW formula) predicts susceptibility:
CE(IIW) = %C + %Mn/6 + (%Cr + %Mo + %V)/5 + (%Ni + %Cu)/15 CE < 0.40 : low susceptibility, preheat generally not required CE 0.40–0.50 : moderate susceptibility, preheat 50–100°C typical CE > 0.50 : high susceptibility, preheat >100°C, potentially PWHT
Corrective actions: increase preheat, increase heat input within the allowable range, add PWHT to the procedure. See hydrogen-induced cracking for the relationship between HAZ hardness and cold cracking risk.
Charpy Impact Failure in the Coarse-Grained HAZ
The coarse-grained HAZ (CGHAZ) consistently presents the lowest Charpy values in the qualification test. The CGHAZ undergoes grain coarsening above approximately 1100 °C; in multi-pass welds, local reheating can produce a partially retransformed zone between two adjacent beads where a mixture of MA constituents (martensite-austenite islands) forms, further degrading toughness. Corrective actions include: reducing peak heat input to limit grain growth; using fine-grain normalised parent material; specifying controlled interpass temperature to promote fine-grained microstructure between passes.
For a full treatment of the microstructural zones in the HAZ and their properties, see the HAZ microstructure article.
Bend Test Cracks from Lack of Fusion
Lack of fusion defects aligned parallel to the weld axis, invisible to RT in some orientations, are readily detected by bending. A crack >3 mm originating at a fusion boundary or an entrapped slag stringer constitutes failure. Corrective pWPS changes: increase arc energy, widen joint preparation angle (reduce sidewall angle), improve interpass cleaning.
Qualification Under EN 15614-1 vs. ASME Section IX
ISO 15614-1 and ASME BPVC Section IX are the two most widely encountered weld procedure qualification standards globally. While their underlying philosophy is similar — qualify the procedure by testing, define essential variables, specify ranges of approval — there are significant differences that prevent direct cross-acceptance:
| Aspect | ISO 15614-1 | ASME Section IX |
|---|---|---|
| Document nomenclature | pWPS → WPQR → WPS | WPS → PQR → WPS |
| Material grouping | ISO/TR 15608 groups | P-numbers (ASME material tables) |
| Mandatory Charpy testing | Required when material standard demands it | Required only if specified by design code (e.g., ASME VIII Div.1 UG-84) |
| Hardness requirement | 380 HV10 max (Groups 1–4) | No mandatory HAZ hardness limit in Sec. IX (set by design code) |
| Bend mandrel diameter | Function of elongation and thickness | Fixed at 4t (standard metals); 6t (reduced ductility) |
| Heat input as essential variable | Yes (±25%) | Not a supplementary essential variable for most processes |
| NDE of test weld | Required (RT/UT + VT to ISO 5817 Level B) | Not mandatory in Sec. IX itself; may be required by referencing code |
| Fillet weld qualification | Clause 8 of ISO 15614-1 | Separate groove and fillet PQRs required |
Many fabricators operating across both European and North American markets maintain dual qualification sets — one per ISO 15614-1, one per ASME Section IX — for the same welding procedure. Some third-party inspection bodies accept cross-qualification where the more conservative test program covers both standards’ requirements, but this must be verified case by case with the relevant notified body or authorised inspection agency.
Industrial Applications and Standards Context
ISO 15614-1 is invoked by — or directly incorporated into — a wide range of product standards, design codes, and customer requirements across pressure equipment, structural steel, offshore, pipeline, and nuclear sectors:
| Sector / Code | Reference to ISO 15614-1 | Additional Requirements |
|---|---|---|
| Pressure Equipment Directive (PED) / EN 13445 | Direct invocation for unfired pressure vessels | Notified body witnessing of test weld; full HAZ toughness data required |
| EN 1090 (Structural Steelwork) | Required for EXC3/EXC4 structures | Impact tests required for steels ≥ S420 and t ≥ 25 mm |
| ISO 3834-2 (Comprehensive quality level) | Mandatory where ISO 3834 is invoked | WPQR must be validated by examiner or examination body |
| DNVGL-OS-C101 (Offshore structures) | Acceptable qualification route | HAZ toughness at −40 °C or −60 °C often required |
| EN 13480 (Industrial piping) | Primary qualification route | Charpy on all Groups 1–6 where t ≥ 6 mm |
| Railway EN 15085 | Required at CL1/CL2 | Full WPQR review by certification body |
Understanding the requirements of the specific design standard — not merely ISO 15614-1 itself — is essential before commencing qualification. Design codes frequently impose additional essential variables, lower hardness limits, stricter impact requirements, or mandatory PWHT that are not required by ISO 15614-1 in isolation.
Frequently Asked Questions
What is the difference between a WPS, pWPS, and WPQR?
Which mechanical tests are mandatory under ISO 15614-1 for a butt weld?
What are essential variables in ISO 15614-1?
How is the range of approval for material thickness determined?
What acceptance criteria apply to the transverse tensile test?
What hardness limits apply in the HAZ under ISO 15614-1?
How many Charpy specimens are required and at what locations?
Does ISO 15614-1 cover fillet welds?
Can one test weld qualify multiple welding processes?
How long does a WPQR remain valid?
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