AASHTO/AWS D1.5:2025 · Table 12.4/12.5 · Fracture-Critical · H16

M270M Gr.345S Preheat — H16, Mid HI, > 60 mm: 325°F

Fracture-critical preheat requirement for M270M Gr.345S / M270 Gr.50S at > 60 mm (> 2½ in) thickness with H16 hydrogen designation, per AASHTO/AWS D1.5:2025, the Bridge Welding Code.

Fracture-Critical Minimum Preheat & Interpass

325°F / 160°C

H16 hydrogen · 2.0–2.8 kJ/mm heat input · > 60 mm (> 2½ in) thickness

AASHTO/AWS D1.5M/D1.5:2025 Table 12.4/12.5

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.345S / M270 Gr.50S

AASHTO M270M Gr.345S (M270 Gr.50S) is the structural shape variant of Gr.345, intended for rolled W-shapes and channels used in bridge framing. The "S" suffix indicates the shape-specific chemistry and mechanical property requirements. Used in cross-frame angles, diaphragm members, and built-up sections where rolled shapes are specified rather than plate. Preheat requirements match Gr.345 — Table 6.3 Group 1 for NFC, Tables 12.4/12.5 for FC applications.

Why This Preheat

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

Shape-grade 345 MPa (50 ksi) steel for rolled bridge members. Under D1.5 fracture-critical requirements (Clause 12), the combination of H16 hydrogen designation and this heat input band requires 325°F minimum preheat at > 60 mm (> 2½ 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.345S / M270 Gr.50S Is Used

Used as rolled W-shapes and channels in bridge cross-frames, diaphragm members, and built-up sections. The "S" shape designation indicates procurement under AASHTO M270 with shape-specific chemistry and mandatory CVN testing. Common applications include WT sections for cross-frame members, MC channels for diaphragms, and W-shapes for floor beams on shorter spans. Weld details are primarily fillet welds at gusset connections and clip angles.

H16 Consumables

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

Gr.345S (50S) at H16 applies primarily to field-erected cross-frame connections using self-shielded FCAW. The higher preheat requirement at H16 can be challenging to maintain on thin shape flanges that lose heat rapidly to the surrounding air — electric resistance heating pads help maintain uniform temperature.

Thickness: > 60 mm (> 2½ in)

Why Preheat Matters at > 60 mm (> 2½ in)

Material over 65 mm (2-1/2 in) includes the heaviest bridge girder flanges and box-section walls. Table 6.3 requires 110°C (225°F) for both groups at this thickness. Extended preheat soak time is necessary to achieve uniform through-thickness temperature. FC preheat for the heaviest sections reaches 180–200°C (350–400°F) at the H16 hydrogen level.

Fabrication Detail

M270M Gr.345S / M270 Gr.50S at > 60 mm (> 2½ in)

Gr.345S (50S) above 65 mm flange thickness is limited to the heaviest jumbo W-shapes (W14×730 or similar) used in critical transfer structures. These sections have significant residual stress from the rolling process that compounds with welding stresses. Full 225°F preheat plus controlled cooling is essential — some fabricators specify post-weld hydrogen release holds at 400°F for 2 hours on jumbo section connections.

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 > 60 mm (> 2½ in) with 2.0–2.8 kJ/mm heat input, the 325°F (160°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 2.0–2.8 kJ/mm · > 60 mm (> 2½ in)

Steel	Table	Preheat
M270M Gr.250 / M270 Gr.36	A	325°F (160°C)
M270M Gr.345W / M270 Gr.50W	B	375°F (190°C)
M270M HPS345W / M270 HPS50W	B	375°F (190°C)
M270M HPS485W / M270 HPS70W	B	375°F (190°C)

Other Thicknesses

M270M Gr.345S / M270 Gr.50S at H16 2.0–2.8 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.

Learn More

Related Guides

FAQ

What is the FC preheat for M270M Gr.345S / M270 Gr.50S with H16 at > 60 mm (> 2½ in)?

For fracture-critical M270M Gr.345S / M270 Gr.50S welded with H16-designated consumables at > 60 mm (> 2½ in) thickness and 2.0–2.8 kJ/mm heat input, the minimum preheat is 325°F (160°C) per D1.5 Table 12.4/12.5.

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

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.345S / M270 Gr.50S?

Higher heat input means slower cooling rates, giving hydrogen more time to diffuse out of the weld zone. At 2.0–2.8 kJ/mm, the 325°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 is preheat the same for both groups above 65 mm?

Table 6.3 converges at 110°C (225°F) for both groups at this thickness because the dominant factor becomes hydrogen diffusion distance through the thick section rather than the steel’s hardenability. Even Group 1 steels need substantial preheat at 65+ mm to keep cooling rates slow enough for safe hydrogen escape.

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