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

A992 Preheat for FCAW — 1-1/2" to 2-1/2"

Per AWS D1.1:2025 Table 5.11, the minimum preheat for A992 welded with FCAW at 1-1/2" to 2-1/2" is 150°F (65°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

150°F / 65°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 FCAW

FCAW (Flux Cored Arc Welding)

FCAW uses tubular flux-cored wire, available gas-shielded (E71T-1) or self-shielded (E71T-8) for field work. Category B in Table 5.11.

E71T-1 gas-shielded wire is the workhorse for structural steel erection fillet welds. Self-shielded E71T-8 is preferred for field welding where wind makes gas shielding unreliable. Deposition rates run 8-12 lb/hr depending on wire diameter and position. The flux core provides a protective slag that supports the puddle in vertical-up and overhead positions.

Practical Tips: FCAW + Common Structural Steels

FCAW Tips for Common Structural Steels

For A992 wide-flange shapes (50 ksi yield, Category B), FCAW E71T-1M at 220–260 A is the standard field-erection process for moment-frame beam flange welds, column splice plates, and all-around column base plate fillets. Demand-critical seismic welds per AISC 341 require H8-designated wire and CVN testing at -20°F — confirm wire lot certification before starting seismic connection welds.

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

Recommended Filler Metal

Filler Metal for FCAW

Gas-shielded: E71T-1C (AWS A5.20, requires 100% CO2) or E71T-1M (requires 75/25 Ar/CO2 mixed gas) — the C/M suffix designates the required shielding gas. Self-shielded: E71T-8 (no external gas, field-ready). Diameter: 0.045" standard, 1/16" for high-deposition. Stick-out: 3/4" to 1-1/4" (longer than GMAW due to resistive heating of flux core).

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

Common Structural Steels

A992

ASTM A992 (50 ksi minimum yield, 65 ksi maximum yield, 65 ksi minimum tensile) is the standard specification for W-shapes in building construction — virtually all wide-flange beams and columns in US structural steel buildings are A992. The specification was created in 1998 to address weldability concerns with earlier A36/A572 shapes by imposing tighter chemistry controls: 0.23% max carbon, 0.15% max combined V+Cb+N, and a 0.85 maximum yield-to-tensile ratio to ensure ductile behavior in seismic connections. These controls produce a typical CE-IIW of 0.38-0.44. It falls under Category B in Table 5.11, requiring low-hydrogen welding processes. Most domestic W-shapes are dual-certified A992/A572 Gr.50, with actual mill test yields typically 50-58 ksi. The controlled chemistry makes A992 the most weldable 50 ksi structural shape available.

A992 + FCAW

Why This Preheat for A992 with FCAW

Standard W-shape specification for virtually all US building wide-flanges. This steel is prequalified only with low-hydrogen processes under Table 5.11. With FCAW, flux-cored wire in FCAW provides a combination of deoxidizers and low-moisture flux formulations that control hydrogen. The 150°F minimum preheat balances the steel’s strength level and carbon equivalent against the hydrogen control provided by FCAW. Non-low-hydrogen SMAW is not an option for this grade under D1.1 prequalified WPS.

Where A992 Is Used

Typical Applications for A992

The universal W-shape steel for building frames: beam-to-column moment connections, simple shear tabs, column web doubler plates, continuity plates, collector beams in lateral systems, drag struts, transfer beams, and composite deck stud rails. A992 chemistry control (max 0.23% carbon, max 0.15% V-Cb-N) was specifically designed to improve weldability over earlier A36/A572 shapes after the 1994 Northridge earthquake revealed brittle fracture problems in welded steel moment frames. Flange CJP welds in seismic moment frames are the highest-criticality joints in US building construction. The controlled yield-to-tensile ratio (max 0.85) ensures ductile behavior in seismic connections by guaranteeing sufficient strain hardening capacity. Mill test reports for A992 shapes routinely show actual yield strengths of 50-55 ksi, well above the 50 ksi minimum. The weld access hole geometry per AISC 358 is dimensioned specifically for A992 flanges to reduce stress concentrations at the CJP weld termination.

Thickness: 1-1/2" to 2-1/2"

Why Preheat Matters at 1-1/2" to 2-1/2"

Heavy plate with significant restraint and thermal mass — preheat is critical to maintain slow cooling for hydrogen escape.

Compare Steels

Other Steels with FCAW at 1-1/2" to 2-1/2"

Steel	Category	Preheat
A36	B	150°F (65°C)
A633 Gr.E	C	225°F (110°C)
A709 HPS70W	C	225°F (110°C)
A710 Gr.A	C	225°F (110°C)

Other Thicknesses

A992 with FCAW

Application context

A992 in the 1-1/2 to 2-1/2 inch range with FCAW is the heavy-flange wide-flange shape combination for AISC moment-frame primary fabrication — heavy beam-flange-to-web reinforcement welds on built-up plate girders, splice plates on W14 / W36 column and beam sections, continuity-plate welds at column-to-girder joints, and transfer-girder territory where the higher deposition rate of cored wire and the 150°F preheat floor both bind.

Pre-weld notes

Crossing the 1-1/2 inch threshold changes 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. Real preheat infrastructure is required: induction blankets, electric resistance pads. AISC seismic moment-frame work commonly carries additional notch-toughness and demand-critical-weld requirements per AISC Seismic Provisions that go beyond D1.1 Clause 5 — those move the WPS to qualified under Clause 6 with Table 6.8 supplementary essential-variable controls. The 150°F floor is the prequalified baseline; demand-critical project specifications may set higher.

What a CWI verifies

A CWI on A992 FCAW heavy-section AISC work verifies (1) preheat through-thickness with sampling 3-6 inches from the arc on the back side, (2) the heated-zone extent against Clause 7.6, (3) interpass temperature held above 150°F with a contact pyrometer between pass groups, (4) the FCAW classification on the spool against the WPS-cited variant — for AISC seismic moment-frame demand-critical welds, the FCAW deposit must meet the project-specific CVN requirements which are typically tighter than Table 5.4 prequalified limits. Where CVN is in scope, Clause 6 Table 6.6 + Table 6.8 essential-variable controls layer on top of the prequalified gate.

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A992 Welding Guides

Primary sources

FAQ

What is the minimum preheat for A992 with FCAW at 1-1/2" to 2-1/2"?

When welding A992 at 1-1/2" to 2-1/2" using FCAW, the minimum preheat temperature is 150°F (65°C) per AWS D1.1:2025 Table 5.11, Category B. FCAW places this combination in Category B. This is also the minimum interpass temperature — the joint must not cool below 150°F between passes.

What Table 5.11 category applies to A992 with FCAW?

When using FCAW on A992, the combination falls under Category B in AWS D1.1:2025 Table 5.11. Low-hydrogen SMAW, SAW, GMAW, or FCAW process. At 1-1/2" to 2-1/2" thickness, Category B with FCAW requires a minimum preheat of 150°F (65°C).

Why is preheat 150°F for A992 at 1-1/2" to 2-1/2"?

The 150°F preheat for A992 at 1-1/2" to 2-1/2" when using FCAW reflects the combination of the steel's hardenability and the increased restraint at this thickness. FCAW 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.

What happens if I skip preheat on thick plate?

Without adequate preheat on material in the 1-1/2” to 2-1/2” range, the weld HAZ cools rapidly, trapping diffusible hydrogen in a hardened microstructure. This creates conditions for hydrogen-induced cracking (also called cold cracking or delayed cracking), which may not appear until hours or days after welding. Table 5.11 preheat minimums are set to prevent this failure mode.

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

Yes — the 150°F (65°C) minimum preheat for A992 with FCAW at 1-1/2 to 2-1/2 inch 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 matches a prequalified detail in D1.1:2025 Clause 5, the FCAW classification meets prequalified requirements per Table 5.4, and the WPS holds the 150°F minimum through-thickness, the procedure is prequalified by Clause 5. AISC seismic moment-frame projects commonly carry CVN and demand-critical-weld requirements that elevate the WPS to qualified rather than prequalified.

What does demand-critical-weld status under AISC Seismic mean for the 150°F prequalified floor?

AISC Seismic Provisions identify certain welds — column-to-girder full-penetration joints, continuity-plate welds at the panel zone, base-plate connection welds in seismic moment-frames — as demand-critical, requiring CVN deposit testing and additional supplementary essential-variable controls per AWS D1.8 Structural Welding Code—Seismic Supplement. The 150°F D1.1 Table 5.11 floor is the prequalified baseline; demand-critical welds typically run at higher preheat per the qualified WPS or per the AISC Seismic / D1.8 project requirements. Verify against the WPS as written, not against the Table 5.11 floor — the WPS may be tighter than Table 5.11.

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