Welded steel pipe accounts for the majority of the world's pipeline infrastructure — from small-diameter gas distribution mains to 48-inch cross-country transmission corridors. Three distinct manufacturing processes produce three distinct pipe types, each with its own diameter range, pressure capability, cost profile, and appropriate application: ERW (Electric Resistance Welded), LSAW (Longitudinal Submerged Arc Welded), and SSAW (Spiral Submerged Arc Welded). Choosing the wrong type for a project doesn't just affect cost — it can affect code compliance, inspection requirements, and long-term integrity.
ZC Steel Pipe manufactures and exports all three types of welded line pipe to API 5L PSL1 and PSL2, in grades from X52 through X80, with FBE, 3LPE, and 3LPP coating options. We supply pipeline projects across Africa, the Middle East, and South America. This guide explains how each type is made, what it is suited for, and how to select between them for your project.
CONTENTS
The Three Types of Welded Steel Pipe
ERW Pipe — Process, Specs & Applications
LSAW Pipe — Process, Specs & Applications
SSAW Pipe — Process, Specs & Applications
ERW vs LSAW vs SSAW — Full Comparison
Welded vs Seamless Pipe
API 5L Grades for Welded Line Pipe
Coating Options for Welded Line Pipe
How to Choose: Selection by Application
FAQ
1. The Three Types of Welded Steel Pipe
All welded steel pipe starts from flat steel — either coil/strip or heavy plate — which is formed into a cylinder and welded along the seam. The three manufacturing processes differ in how the steel is formed, how the weld seam is oriented, and what diameter and wall thickness range they can produce.
ERW — Electric Resistance Welded
Starting material: Hot-rolled coil / strip
Seam orientation: Longitudinal (straight)
Weld method: High-frequency electrical resistance
OD range: ½" – 24" (21–610 mm)
Wall thickness: Up to ~16 mm
API 5L grades: X42 – X70
LSAW — Longitudinal Submerged Arc Welded
Starting material: Heavy plate
Seam orientation: Longitudinal (straight)
Weld method: Submerged arc welding (SAW) — inside + outside
OD range: 16" – 56" (406–1422 mm)
Wall thickness: 6 – 40 mm
API 5L grades: X52 – X80
SSAW — Spiral Submerged Arc Welded
Starting material: Hot-rolled coil / strip
Seam orientation: Helical (spiral)
Weld method: Submerged arc welding (SAW) — inside + outside
OD range: 16" – 100"+ (406–2540 mm)
Wall thickness: 6 – 25 mm
API 5L grades: X42 – X70
2. ERW Pipe — Process, Specs & Applications
2.1 Manufacturing Process
ERW pipe is produced on a continuous forming mill. Hot-rolled strip steel is uncoiled and progressively formed through a series of roll stands into a circular cross-section. The two edges of the strip are brought together and welded using high-frequency electrical resistance — no filler metal is used. The electrical current creates intense localised heat at the seam interface, and the edges are forged together under mechanical pressure to form the weld.
The weld zone is then heat-treated (normalised or full-body heat treated for higher grades) to restore toughness in the heat-affected zone. For PSL2 and higher grades, the weld seam area is 100% inspected by ultrasonic testing before the pipe leaves the mill.
2.2 Key Specifications
| Parameter | ERW Pipe |
| OD range | ½" – 24" (21.3 – 610 mm) |
| Wall thickness | Typically 2.8 – 16 mm |
| API 5L grades | X42, X46, X52, X56, X60, X65, X70 |
| PSL levels | PSL1 and PSL2 |
| Seam type | Longitudinal — straight seam |
| Standard pipe length | 6 m (R1), 11–12 m (R2/R3) |
| Weld NDE (PSL2) | 100% UT of weld seam mandatory |
| Applicable standard | API 5L / ISO 3183 |
2.3 Applications
Oil and gas gathering lines (2"–12" most common)
Gas distribution mains and laterals
Water supply and irrigation pipelines
ERW casing and tubing for oil wells (API 5CT)
Structural and mechanical tubing
Short-run transmission lines at moderate pressure
Procurement Note — ERW Weld Seam Heat Treatment Is Not Optional for High GradesFor X60 and above, API 5L requires heat treatment of the ERW weld seam area to restore toughness after welding. This is a mill process — it cannot be retrofitted. When sourcing ERW pipe in X60 or X65, always confirm on the MTC that seam normalisation or full-body heat treatment was performed. Untreated weld HAZ in high-grade ERW pipe can be significantly harder and tougher than the pipe body, creating a preferential failure zone in service. See:
Failure Mode Analysis: Preferential Weld Corrosion and ERW Zipper Cracks →
3. LSAW Pipe — Process, Specs & Applications
3.1 Manufacturing Process
LSAW pipe is produced from heavy steel plate — not coil — using one of two forming processes: UOE (U-ing, O-ing, Expansion) or JCOE (J-ing, C-ing, O-ing, Expansion). In both processes, a single plate is progressively formed into a pipe shape and welded along the longitudinal seam using submerged arc welding (SAW) — first on the inside, then on the outside. The pipe is then mechanically expanded to achieve precise dimensional tolerances.
The use of heavy plate as starting material allows LSAW to achieve much greater wall thicknesses than ERW or SSAW. The double-pass SAW process (inside + outside) produces a fully penetrated, high-quality weld that is 100% inspected by UT and radiography.
3.2 Key Specifications
| Parameter | LSAW Pipe |
| OD range | 16" – 56" (406 – 1422 mm) |
| Wall thickness | 6 – 40 mm |
| API 5L grades | X52, X56, X60, X65, X70, X80 |
| PSL levels | PSL1 and PSL2 |
| Seam type | Longitudinal — straight seam |
| Forming process | UOE or JCOE |
| Weld NDE | 100% UT + radiography of weld seam |
| Applicable standard | API 5L / ISO 3183 |
3.3 Applications
High-pressure onshore gas transmission pipelines
Crude oil and product transmission lines (large diameter)
Offshore flowlines and export pipelines
Subsea pipelines (with appropriate coating)
High-yield grade (X70, X80) long-distance pipelines
Sour service pipelines (PSL2 + Annex H)
Engineering Insight — UOE vs JCOE for LSAW PipeUOE and JCOE produce functionally equivalent pipe but differ in capital equipment and forming sequence. UOE is a faster, higher-volume process and is used by the largest LSAW mills globally. JCOE is more flexible — it can produce a wider range of diameters and wall thicknesses on the same equipment, making it the preferred process for specialised orders including very heavy wall or non-standard diameters. For most project specifications, UOE and JCOE are interchangeable and both are accepted under API 5L. If your project specification distinguishes between them, verify the mill's capability before ordering.
Deep dive: LSAW vs Seamless for Large Diameter High-Yield Projects → | LSAW for Offshore and Marine Environments → | LSAW JCOE vs Spiral Pipe for Subsea Risers →
4. SSAW Pipe — Process, Specs & Applications
4.1 Manufacturing Process
SSAW pipe is produced by spirally forming hot-rolled strip steel at a controlled helix angle and welding the resulting helical seam using submerged arc welding — again, inside and outside passes. Because the pipe diameter is determined by the helix angle rather than the strip width, a single strip width can produce a range of pipe diameters by adjusting the forming angle. This flexibility makes SSAW the most economical route to very large diameters.
The spiral seam is longer than a longitudinal seam for the same pipe length, which means more weld length per pipe — and more NDE required per pipe on PSL2 orders. The helical geometry also means that hoop stress in the pipe wall is not perpendicular to the weld seam, which affects fatigue behaviour compared to longitudinal seam pipe.
4.2 Key Specifications
| Parameter | SSAW Pipe |
| OD range | 16" – 100"+ (406 – 2540 mm) |
| Wall thickness | 6 – 25 mm |
| API 5L grades | X42, X46, X52, X56, X60, X65, X70 |
| PSL levels | PSL1 and PSL2 |
| Seam type | Helical (spiral) |
| Weld NDE (PSL2) | 100% UT + radiography of spiral seam |
| Applicable standard | API 5L / ISO 3183 |
4.3 Applications
Water transmission mains (large diameter)
Low to moderate pressure gas distribution
Large diameter onshore oil pipelines
Slurry pipelines
Infrastructure and piling (structural use)
Irrigation and drainage systems
Critical Engineering Point — SSAW Restrictions for High-Pressure GasSome pipeline design codes and IOC project specifications restrict or prohibit SSAW pipe for high-pressure gas transmission — particularly above certain MAOP thresholds or for fatigue-critical applications such as offshore risers and subsea pipelines. The spiral seam geometry means that stress perpendicular to the weld varies around the pipe circumference, which affects fatigue life calculations differently from longitudinal seam pipe. Always check your applicable pipeline code (ASME B31.8, DNV-ST-F101, or company specification) for SSAW restrictions before specifying it for high-pressure gas service. See:
LSAW vs SSAW: Hoop Stress and High-Pressure Transmission →
5. ERW vs LSAW vs SSAW — Full Comparison
| Property | ERW | LSAW | SSAW |
| OD range | ½" – 24" | 16" – 56" | 16" – 100"+ |
| Max wall thickness | ~16 mm | Up to 40 mm | ~25 mm |
| Seam orientation | Longitudinal | Longitudinal | Helical / spiral |
| Starting material | Hot-rolled coil | Heavy plate | Hot-rolled coil |
| Max API 5L grade | X70 | X80 | X70 |
| Dimensional accuracy | Excellent | Excellent (post-expansion) | Good — slight ovality possible |
| High-pressure gas transmission | Yes — small/medium OD | Yes — preferred for large OD | Restricted in some specs |
| Offshore / subsea suitability | Limited — small OD only | Standard choice | Generally not used |
| Sour service (PSL2 + Annex H) | Yes | Yes | Yes — verify project spec |
| Water transmission | Small diameter | Medium–large diameter | Very large diameter — preferred |
| Relative cost (same OD/WT) | Lowest | Higher — heavy plate premium | Moderate |
| Lead time flexibility | Short — coil stock availability | Longer — plate sourcing | Moderate |
6. Welded vs Seamless Pipe
The choice between welded and seamless is one of the most common questions in line pipe procurement. For most pipeline applications above 4" OD, welded pipe is the default — not because seamless is unavailable, but because welded pipe is more economical, more available in large diameters, and fully code-compliant for the application.
| Factor | Seamless | Welded (ERW/LSAW/SSAW) |
| Weld seam risk | None — no seam | Seam present — NDE mandatory (PSL2) |
| Available OD range | Typically up to 24" | Up to 100"+ (SSAW) |
| Heavy wall capability | Superior — up to 60+ mm WT | LSAW up to 40 mm; ERW/SSAW less |
| Dimensional tolerances | Wider WT tolerance than welded | Tighter WT tolerance (esp. LSAW) |
| Cost (same OD, similar WT) | Higher — 20–40% premium typically | Lower |
| Code requirement (some) | Required in certain HPHT / sour specs | Accepted in most pipeline codes |
| Best application | Small OD, thick wall, HPHT, no-seam requirement | Large OD, standard WT, most pipelines |
Related: Seamless vs Welded Line Pipe: How to Choose → | Seamless vs ERW: When Is the Premium Justified? → | Seamless vs LSAW for High-Pressure Gas Transmission →
7. API 5L Grades for Welded Line Pipe
All three welded pipe types are produced to API 5L / ISO 3183 in multiple grades. Grade selection is driven by the required operating pressure, wall thickness economics, and service environment — not by pipe type. The table below shows which grades are available in each welded form.
| API 5L Grade | Min Yield (MPa) | ERW | LSAW | SSAW | Typical Application |
| X52 | 359 | Yes | Yes | Yes | Gathering, water transmission, sour service |
| X56 | 386 | Yes | Yes | Yes | Moderate pressure gathering and transmission |
| X60 | 414 | Yes | Yes | Yes | Gas transmission, offshore flowlines |
| X65 | 448 | Yes | Yes | Yes | Long-distance gas & oil transmission |
| X70 | 483 | Limited mills | Yes | Selected mills | High-pressure long-distance transmission |
| X80 | 552 | Not standard | Yes — PSL2 only | Not standard | Ultra-high-pressure, large diameter transmission |
Grade guides: API 5L X52 Line Pipe → | API 5L X60 Line Pipe → | API 5L X65 Line Pipe → | API 5L X70 Line Pipe → | API 5L X80 Line Pipe →
8. Coating Options for Welded Line Pipe
Most welded line pipe for buried or subsea service is externally coated to prevent corrosion. The three main coating systems are FBE, 3LPE, and 3LPP — each suited to different temperature ranges and service environments.
FBE — Fusion Bonded Epoxy
Thickness: 400–600 μm (single layer)
Max service temp: ~80°C continuous
Mechanical protection: Limited — thin film
Best for: Moderate temp buried pipe; primer for 3LPE/3LPP
Standard: CSA Z245.20, DIN 30670
3LPE — Three-Layer Polyethylene
Thickness: 2.0–3.5 mm (3 layers)
Max service temp: ~80°C continuous
Mechanical protection: Excellent
Best for: Onshore buried pipelines — most common coating globally
Standard: DIN 30670, ISO 21809-1
3LPP — Three-Layer Polypropylene
Thickness: 2.5–4.5 mm (3 layers)
Max service temp: ~110°C continuous
Mechanical protection: Superior
Best for: Offshore, subsea, high-temperature buried pipelines
Standard: DIN 30678, ISO 21809-1
Full coating guide: 3LPE vs FBE vs 3LPP Pipe Coating: How to Choose → | 3LPE Coating Standard DIN 30670 →
9. How to Choose: Selection by Application
| Application | Recommended Type | Typical Grade | PSL Level |
| Gas gathering (2"–12") | ERW | X52 / X60 | PSL2 |
| Sour gas gathering | ERW or Seamless | X52 PSL2 + Annex H | PSL2 |
| Onshore gas transmission (high pressure) | LSAW | X65 / X70 | PSL2 |
| Onshore gas transmission (moderate pressure) | LSAW or SSAW | X60 / X65 | PSL2 |
| Crude oil transmission (large diameter) | LSAW / SSAW | X60 / X65 | PSL1 or PSL2 |
| Offshore flowlines | LSAW or Seamless | X60 / X65 | PSL2 |
| Subsea pipelines | LSAW | X65 / X70 | PSL2 |
| Water transmission (medium diameter) | LSAW or ERW | X52 / X60 | PSL1 |
| Water transmission (large diameter) | SSAW | X52 / X60 | PSL1 |
| Ultra-high-pressure long-distance | LSAW | X70 / X80 | PSL2 |
| Hydrogen blending pipelines | LSAW or Seamless | X52 / X60 PSL2 | PSL2 |
Field Note — Don't Let Pipe Type Drive Grade SelectionA common procurement mistake is to select the pipe type first (e.g., "we want LSAW") and then fit the grade around it. The correct sequence is the reverse: select the grade based on your design MAOP and wall thickness calculation, then select the pipe type based on your OD and the applicable project specification. LSAW and SSAW overlap in the 16"–42" range — the right choice depends on pressure class, project spec restrictions, and whether you're sourcing for gas or water service. Get the engineering right first, then select the manufacturing route.
10. Frequently Asked Questions
What are the types of welded steel pipe?
The three main types are ERW (Electric Resistance Welded), LSAW (Longitudinal Submerged Arc Welded), and SSAW (Spiral Submerged Arc Welded). ERW covers small to medium diameters up to 24". LSAW covers large diameter high-pressure pipe from 16" to 56". SSAW covers very large diameters from 16" to 100"+ for water and moderate-pressure service. All three are produced to API 5L / ISO 3183.
What is the difference between LSAW and SSAW pipe?
LSAW has a straight longitudinal seam, is made from heavy plate, and achieves tighter dimensions and higher wall thicknesses — making it the preferred choice for high-pressure gas transmission and offshore applications. SSAW has a helical seam, is made from coil steel, and can achieve larger diameters more economically — making it the preferred choice for very large diameter water transmission and lower-pressure gas distribution. Some project specifications restrict SSAW for high-pressure gas service.
Can welded pipe be used for high-pressure gas transmission?
Yes. LSAW pipe to API 5L PSL2 is the standard pipe type for high-pressure onshore gas transmission globally. ERW PSL2 is used for smaller diameter high-pressure gas lines. SSAW is used in some gas transmission applications but may be restricted by pipeline codes or project specifications for higher pressure classes — always verify against the applicable code (ASME B31.8, DNV, or company spec) before specifying SSAW for high-pressure gas.
What is the difference between welded and seamless pipe?
Seamless pipe has no weld seam and is produced by piercing a solid billet — giving uniform properties and availability in very thick walls. Welded pipe (ERW, LSAW, SSAW) is more economical for larger diameters and standard wall thicknesses, and is the standard choice for most pipeline applications above 4" OD. For most API 5L pipeline applications, welded PSL2 pipe with full NDE is fully equivalent to seamless in terms of code compliance and service performance.
What coating is used on welded line pipe?
The three main external coatings are FBE (single-layer epoxy, up to ~80°C), 3LPE (three-layer polyethylene, the most common onshore buried pipeline coating), and 3LPP (three-layer polypropylene, for higher temperature and offshore service up to ~110°C). The choice depends on operating temperature, burial depth, soil conditions, and whether the pipeline is onshore or subsea.
What API 5L grades are available in welded pipe?
ERW is available in grades X42 through X70. LSAW is available in grades X52 through X80 — the only welded form that produces X80. SSAW is available in grades X42 through X70. All three are produced to PSL1 or PSL2, with PSL2 required for gas transmission, sour service, and most IOC project specifications.
Source Welded Steel Line Pipe from ZC Steel Pipe
ZC Steel Pipe manufactures and exports ERW, LSAW, and SSAW line pipe to API 5L PSL1 and PSL2, in grades X52 through X80, with FBE, 3LPE, and 3LPP coating options. We supply oil, gas, and water pipeline projects across Africa, the Middle East, and South America with full MTC documentation and third-party inspection.
Sour service pipe (Annex H, HIC tested), high-yield LSAW (X70, X80), and large-diameter SSAW available on order-to-make basis. Custom wall thicknesses, bevelled ends, and project-specific chemistry controls available.
mandy.w@zcsteelpipe.com
WhatsApp: +86-139-1579-1813
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