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

A992 Preheat for SMAW (low-hydrogen) — over 2-1/2"

Minimum preheat and interpass temperature for A992 welded with SMAW (low-hydrogen) at over 2-1/2" thickness, per AWS D1.1:2025 Table 5.11.

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.

E7018 is the default electrode for structural fillet and groove welds on common building steels. Rod ovens should hold at a minimum of 250°F per D1.1 Clause 7.3.2.1; exposure time out of the oven is limited to 4 hours maximum per Table 7.1. For overhead position, use 3/32" diameter rods to control puddle size. Vertical-up stringer beads provide the best fusion on thicker members.

Why This Process?

Why SMAW (low-hydrogen) for A992 at over 2-1/2"

Why SMAW (low-hydrogen) for A992 at over 2-1/2"? SMAW (low-hydrogen) delivers 3-5 lb/hr deposition — compared to SAW at 15-40 lb/hr. Position capability: all positions. Suitability: field and shop.

Recommended Filler Metal

Filler Metal for SMAW-LH

Electrode: E7018 (AWS A5.1) — the universal low-hydrogen structural rod. Diameter: 1/8" (general/out-of-position), 5/32" (production), 3/16" (heavy plate flat only). Storage: 250°F rod oven minimum per D1.1 §7.3.2.1. Exposure limit: 4 hours out of oven per Table 7.1, then re-bake at 500-800°F for minimum 2 hours per §7.3.2.4 (A5.1 classification).

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 + SMAW-LH

Why This Preheat for A992 with SMAW-LH

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 SMAW-LH, E7018 low-hydrogen electrodes produce typically 4-8 mL/100g diffusible hydrogen under proper rod oven conditions. The 225°F minimum preheat balances the steel’s strength level and carbon equivalent against the hydrogen control provided by SMAW-LH. 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: 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

A992 with SMAW (low-hydrogen)

Interactive Calculator

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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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A992 Welding Guides

FAQ

What is the minimum preheat for A992 with SMAW-LH at over 2-1/2"?

When welding A992 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 A992 with SMAW-LH?

When using SMAW-LH 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 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 A992 at over 2-1/2"?

The 225°F preheat for A992 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.

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