AWS D1.1:2025 · Table 5.11 · Category B

A106 Gr.B Preheat for SMAW (low-hydrogen) — over 2-1/2"

Per AWS D1.1:2025 Table 5.11, the minimum preheat for A106 Gr.B welded with SMAW (low-hydrogen) at over 2-1/2" is 225°F (110°C), Category B. Preheat below this raises hydrogen-cracking risk in the heat-affected zone; the same temperature is the minimum interpass limit maintained through the weld.

Built on AWS D1.1:2025 Table 5.11 — every value traced to the clause.

Minimum Preheat & Interpass Temperature

225°F / 110°C

Category B Low-hydrogen SMAW, SAW, GMAW, or FCAW process

AWS D1.1:2025 Table 5.11, §5.7

Reference tool. Verify against project-applicable edition and Engineer-approved WPS.

Have a preheat question? Ask Flux

About SMAW-LH

SMAW (Low-Hydrogen)

Low-hydrogen SMAW (E7018/E7016) uses basic-coated electrodes requiring rod oven storage, assigned to Category B in Table 5.11.

For pipe butt joints, E7018 fill and cap passes follow the E6010 root. Vertical-down technique is not permitted with low-hydrogen electrodes. Interpass cleaning requires chipping and wire brushing between every pass to remove slag inclusions. Restart craters should be ground to sound metal before striking a new arc.

Practical Tips: SMAW-LH + Pipe and Tube Steels

SMAW-LH Tips for Pipe and Tube Steels

For A106 Grade B seamless pipe (35 ksi yield, high-temperature service), E7018 fill and cap passes follow E6010 root on process piping butt welds per ASME B31.1/B31.3. On thick-wall Schedule 160 and XXH A106 pipe (wall thickness over 1/2"), preheat to 150°F minimum for Category B at the 3/4"–1-1/2" tier. E7018 at 130–160 A (1/8" rod) in vertical-up position handles.

Typical values for reference — always verify against your approved WPS and electrode manufacturer data.

Why This Process?

Why SMAW (low-hydrogen) for A106 Gr.B at over 2-1/2"

Why SMAW (low-hydrogen) for A106 Gr.B at over 2-1/2"? SMAW (low-hydrogen) delivers 3-5 lb/hr deposition — compared to <a href="/welding/preheat-calculator/a106-b/saw/over-2-1-2-inch/">SAW</a> at 15-40 lb/hr. Position capability: all positions. Suitability: field and shop.

Pipe and Tube Steels

A106 Gr.B

ASTM A106 Grade B covers seamless carbon steel pipe for high-temperature service up to about 750°F, with 35 ksi minimum yield and 60 ksi minimum tensile strength. Produced in sizes from 1/4" through 30" NPS, it is the standard pipe material for power plants, refineries, and process piping where elevated temperature and pressure coexist. Chemistry limits (0.30% max carbon, 0.29-1.06% manganese) give it a weldability profile that matches common structural grades with Category A and B preheat requirements. A106 is exclusively seamless, which eliminates the ERW seam concern present in A53. Grade C (40 ksi yield) exists but Grade B handles the vast majority of process piping service.

A106 Gr.B + SMAW-LH

Why This Preheat for A106 Gr.B with SMAW-LH

Seamless pipe rated for high-temperature service up to 750°F. With low-hydrogen SMAW-LH, this combination falls under Category B rather than Category A — E7018 low-hydrogen electrodes produce typically 4-8 mL/100g diffusible hydrogen under proper rod oven conditions. The 225°F minimum preheat is lower than what non-low-hydrogen SMAW would require at the same thickness because SMAW-LH significantly reduces the driving force for hydrogen-induced cracking in the heat-affected zone.

Where A106 Gr.B Is Used

Typical Applications for A106 Gr.B

Used in boiler steam headers, refinery piping racks, process plant branch connections, heat exchanger nozzle welds, power plant main steam lines, petrochemical reactor feed piping, and high-temperature manifolds. A106 Gr.B butt welds in process piping require joint preparation to B31.1 (power piping) or B31.3 (process piping) depending on service classification. Socket welds on small-bore A106 drain lines and instrument take-offs are common in utility stations, typically 1/2" to 2" NPS. Typical wall thicknesses range from Schedule 40 (0.237" wall on 2" NPS) to Schedule 160 (0.500" wall on 4" NPS) in critical high-energy service. Weld procedure qualification often includes side bend tests and tensile tests specific to the pipe diameter and wall thickness being joined. Field welds at pipe-to-flange connections and valve set-on joints require portable preheating equipment when wall thickness exceeds 1/2".

Thickness: over 2-1/2"

Why Preheat Matters at over 2-1/2"

The heaviest sections demand the highest preheat in Table 5.11. Multi-pass sequences require maintaining interpass temperature throughout.

Compare Steels

Other Steels with SMAW (low-hydrogen) at over 2-1/2"

Steel	Category	Preheat
A36	B	225°F (110°C)
A633 Gr.E	C	300°F (150°C)
A709 HPS70W	C	300°F (150°C)
A710 Gr.A	C	300°F (150°C)

Other Thicknesses

A106 Gr.B with SMAW (low-hydrogen)

Application context

A106 Grade B seamless pipe in the over-2-1/2-inch wall range with SMAW low-hydrogen is heavy-wall pipe-support territory — large-diameter refinery and industrial pipe support brackets, primary pipe-to-plate connections on industrial structures, and structural members fabricated from heavy-wall A106-B mechanical pipe where the welding falls under D1.1 (structural) rather than ASME B31.1/B31.3 (process piping). The 225°F minimum is the heavy-wall preheat — real preheat infrastructure is mandatory.

Pre-weld notes

Three constraints layer at the heavy-wall threshold, all binding. First, the 225°F preheat floor at this wall thickness — torch passes alone won't bring a 3-inch pipe wall to soak temperature in production time. Practical methods are induction heating (most controllable), electric resistance pads, or oxy-fuel ring burners. Second, the preheat-extent rule per Clause 7.6 — for base metal 1-1/2 inch and greater, the heated zone shall extend at least equal to the base-metal thickness, but not less than 3 inches. Third, axial heat conduction along the pipe and the heat-sink effect of the heavy-wall section make preheat soak time longer than plate of the same nominal thickness — surface temperature on one side reads above the floor while the through-wall lags by minutes during heat-up.

What a CWI verifies

A CWI on heavy-wall A106-B SMAW-LH structural work first verifies the WPS scope — D1.1 structural vs ASME B31.x pressure piping. For D1.1 structural work, the inspection covers (1) preheat through-wall via thermocouples or contact pyrometer at multiple positions around the circumference after a soak period, (2) the heated-zone extent against Clause 7.6, (3) interpass temperature held above 225°F across multi-pass deposition, (4) the LH electrode handling discipline per Clause 7.3 — heavy-wall slow-deposition work runs a longer atmospheric-exposure clock against Table 7.1 column A, and (5) the welder qualification covers tubular position welding under Clause 6.11.

Interactive Calculator

Try Different Combinations

Use the interactive preheat calculator to look up any steel, process, and thickness combination from D1.1:2025 Table 5.11.

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A106 Gr.B Welding Guides

Primary sources

FAQ

What is the minimum preheat for A106 Gr.B with SMAW-LH at over 2-1/2"?

When welding A106 Gr.B at over 2-1/2" using SMAW-LH, the minimum preheat temperature is 225°F (110°C) per AWS D1.1:2025 Table 5.11, Category B. SMAW-LH places this combination in Category B. This is also the minimum interpass temperature — the joint must not cool below 225°F between passes.

What Table 5.11 category applies to A106 Gr.B with SMAW-LH?

When using SMAW-LH on A106 Gr.B, the combination falls under Category B in AWS D1.1:2025 Table 5.11. Low-hydrogen SMAW, SAW, GMAW, or FCAW process. At over 2-1/2" thickness, Category B with SMAW-LH requires a minimum preheat of 225°F (110°C).

Why is preheat 225°F for A106 Gr.B at over 2-1/2"?

The 225°F preheat for A106 Gr.B at over 2-1/2" when using SMAW-LH reflects the combination of the steel's hardenability and the increased restraint at this thickness. SMAW-LH delivers controlled hydrogen levels, but at this thickness the preheat must slow the cooling rate in the heat-affected zone, giving diffusible hydrogen more time to escape before the steel transforms to a crack-susceptible microstructure.

How do I maintain preheat on very thick plate?

For material over 2-1/2”, preheat is typically applied with oxy-fuel torches or electric resistance blankets and monitored with contact thermometers or temp-sticks. The entire weld zone must reach the minimum temperature before welding begins, and interpass temperature is checked before each new pass. Insulating blankets help retain heat during pauses in multi-pass welding.

Is this preheat the same in D1.1:2020 as D1.1:2025?

Yes — the 225°F (110°C) minimum preheat for A106 Grade B with SMAW low-hydrogen at over 2-1/2 inch wall is unchanged across the 2020 and 2025 editions. Both editions place this combination in Category B per Table 5.11.

Does my joint qualify for prequalified WPS at this preheat?

If the joint is structural — not pressure-piping — and matches a prequalified detail in D1.1:2025 Clause 5, the matching-strength filler is from Table 5.7 Group I, and the WPS holds the 225°F minimum through-wall (not just surface), the procedure is prequalified by Clause 5. Pressure-piping welds fall outside D1.1 and must be qualified under ASME B31.1 or B31.3 with their own preheat rules.

How do I achieve 225°F preheat on heavy-wall pipe without scorching the surface?

Practical methods at this wall thickness are induction heating (most controllable for high-volume production), electric resistance pads (good for fit-up sequences), or oxy-fuel ring burners (used carefully with surface-temperature monitoring). Surface temperature can run higher than the through-wall value during heat-up — soak time matters more than peak surface reading. For pipe specifically, the axial conduction along the pipe and the heat-sink effect of the surrounding wall lengthen soak time relative to plate. Multi-position circumferential sampling catches uneven preheat from one-sided heat application.

D1.1:2025 reference data. Not affiliated with AWS.