AASHTO/AWS D1.5:2025 · Table 12.6/12.7 · Fracture-Critical · H16

M270M Gr.345W Preheat — H16, High HI, 20–40 mm: 200°F

Fracture-critical preheat requirement for M270M Gr.345W / M270 Gr.50W at 20–40 mm (3/4–1½ in) thickness with H16 hydrogen designation, per AASHTO/AWS D1.5:2025, the Bridge Welding Code.

Fracture-Critical Minimum Preheat & Interpass

200°F / 90°C

H16 hydrogen · > 2.8 kJ/mm heat input · 20–40 mm (3/4–1½ in) thickness

AASHTO/AWS D1.5M/D1.5:2025 Table 12.6/12.7

H16 designation: consumable deposits ≤ 16 mL/100g diffusible hydrogen per AWS A4.3. Lower hydrogen = lower preheat requirement.

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

AASHTO M270 Standard Grades

M270M Gr.345W / M270 Gr.50W

AASHTO M270M Gr.345W (M270 Gr.50W) is a weathering bridge steel with 345 MPa (50 ksi) yield that forms a protective oxide patina for unpainted bridge service. The copper-chromium-nickel alloying provides atmospheric corrosion resistance, eliminating lifetime repainting costs estimated at $15–25 per square foot per cycle. Weld filler must match the weathering composition (E8018-W2 or equivalent) for exposed joints. NFC preheat per Table 6.3 Group 1; FC per Tables 12.6/12.7 which carry higher preheat than the non-weathering grades.

Why This Preheat

Understanding the FC Preheat for M270M Gr.345W / M270 Gr.50W

Weathering 345 MPa (50 ksi) bridge steel for unpainted service. Under D1.5 fracture-critical requirements (Clause 12), the combination of H16 hydrogen designation and this heat input band requires 200°F minimum preheat at 20–40 mm (3/4–1½ in). Lower hydrogen levels (H4 < H8 < H16) allow lower preheat because less hydrogen enters the weld deposit. Similarly, higher heat input reduces preheat requirements because slower cooling rates give hydrogen more time to diffuse out.

Bridge Applications

Where M270M Gr.345W / M270 Gr.50W Is Used

Deployed in unpainted bridge plate girders across humid, coastal, and high-maintenance-cost environments. The weathering patina eliminates lifetime repainting cycles estimated at $15–25/sq ft per cycle. Weld filler must match the weathering composition (E8018-W2 or ER80S-G-W) for exposed joints to ensure the weld face develops the same protective oxide as the base metal. Conventional Gr.345W is being replaced by HPS345W in new designs due to superior weldability.

H16 Consumables

H16 Hydrogen Control for M270M Gr.345W / M270 Gr.50W

Weathering Gr.345W (50W) at H16 is used for field splices when self-shielded FCAW is the only practical process due to wind exposure on elevated bridge erection. The significantly higher preheat at H16 — often 40–60°F above H4 — makes weather-window scheduling critical for winter field splice operations.

Thickness: 20–40 mm (3/4–1½ in)

Why Preheat Matters at 20–40 mm (3/4–1½ in)

Material from 20 to 40 mm (3/4 to 1-1/2 in) includes many girder web plates, splice plates, and bearing stiffener plates. Preheat increases to 20°C (70°F) for Group 1 and 50°C (125°F) for Group 2 under Table 6.3. The thicker section slows hydrogen diffusion, requiring higher preheat to maintain safe cooling rates.

Fabrication Detail

M270M Gr.345W / M270 Gr.50W at 20–40 mm (3/4–1½ in)

At 20–40 mm, Gr.345W (50W) serves as the primary plate for unpainted bridge girder webs and connection plates. Weathering steel butt splices require the same CJP quality as painted Gr.345 but with compositional matching of the filler metal. Improper filler selection leaves a cosmetically distinct weld face that does not develop the same protective oxide, creating a maintenance concern on exposed bridges.

H16 Hydrogen Level

Higher Preheat at H16 Designation

H16 consumables allow up to 16 mL of diffusible hydrogen per 100g — the highest level permitted for FC bridge welding. At 20–40 mm (3/4–1½ in) with > 2.8 kJ/mm heat input, the 200°F (90°C) preheat compensates for the higher hydrogen potential. Switching to H8 or H4 consumables would reduce the required preheat for this joint.

Compare Steels

Other Bridge Steels at H16 > 2.8 kJ/mm · 20–40 mm (3/4–1½ in)

Steel	Table	Preheat
M270M Gr.250 / M270 Gr.36	A	150°F (70°C)
M270M Gr.345 / M270 Gr.50	A	150°F (70°C)
M270M Gr.345S / M270 Gr.50S	A	150°F (70°C)
M270M HPS345W / M270 HPS50W	B	200°F (90°C)

Other Thicknesses

M270M Gr.345W / M270 Gr.50W at H16 > 2.8 kJ/mm

Interactive Calculator

Try Different Combinations

Use the D1.5 Bridge Preheat Calculator to look up any AASHTO M270 steel, hydrogen level, and heat input combination. Also see the D1.1 Preheat Calculator for structural steel.

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Related Guides

FAQ

What is the FC preheat for M270M Gr.345W / M270 Gr.50W with H16 at 20–40 mm (3/4–1½ in)?

For fracture-critical M270M Gr.345W / M270 Gr.50W welded with H16-designated consumables at 20–40 mm (3/4–1½ in) thickness and > 2.8 kJ/mm heat input, the minimum preheat is 200°F (90°C) per D1.5 Table 12.6/12.7.

What is the difference between FC and NFC preheat for M270M Gr.345W / M270 Gr.50W?

Non-fracture-critical (Table 6.3) preheat is a simple thickness-based lookup. Fracture-critical (Tables 12.4–12.8) adds hydrogen level and heat input as variables, typically requiring higher preheat. For FC members, the hydrogen designator on the consumable classification directly determines the minimum preheat.

How does heat input affect preheat for FC M270M Gr.345W / M270 Gr.50W?

Higher heat input means slower cooling rates, giving hydrogen more time to diffuse out of the weld zone. At > 2.8 kJ/mm, the 200°F preheat balances the hydrogen level and cooling rate. Moving to a higher heat input band would typically reduce the required preheat for the same hydrogen level and thickness.

Why does Group 2 need higher preheat than Group 1 at this thickness?

Group 2 steels (HPS485W, HPS690W) have higher hardenability from their increased alloy content, forming harder microstructures on cooling. The 50°C (125°F) minimum versus Group 1’s 20°C (70°F) compensates for the greater cracking susceptibility of these higher-strength grades.

D1.5:2025 reference data. Not affiliated with AWS or AASHTO.