AASHTO/AWS D1.5:2025 · 表12.6/12.7 · 破壊臨界 · H8

M270M HPS345W予熱 — H8、Mid HI、40–60 mm: 300°F

Q: 40–60 mm (1½–2½ in)でのH8を使用したM270M HPS345W / M270 HPS50WのFC予熱は？

H8指定溶接材料を使用して40–60 mm (1½–2½ in)板厚、2.0–2.8 kJ/mm入熱で溶接した破壊臨界M270M HPS345W / M270 HPS50Wの最低予熱は、D1.5 表12.6/12.7に基づき300°F (150°C)です。

Q: M270M HPS345W / M270 HPS50WのFC予熱とNFC予熱の違いは？

非破壊臨界（表6.3）予熱は単純な板厚ベースの検索です。破壊臨界（表12.4〜12.8）は水素レベルと入熱を変数として追加し、通常より高い予熱を必要とします。FC部材では、溶接材料分類の水素指定が直接最低予熱を決定します。

Q: 入熱はFC M270M HPS345W / M270 HPS50Wの予熱にどう影響する？

高い入熱は冷却速度が遅くなることを意味し、水素が溶接ゾーンから拡散する時間が増えます。2.0–2.8 kJ/mmでは、300°F予熱が水素レベルと冷却速度のバランスをとります。同じ水素レベルと板厚で入熱バンドを上げると、通常は必要な予熱が低下します。

Q: What preheat is needed for 50 mm thick bridge plate?

For non-fracture-critical: 65°C (150°F) for Group 1 grades, 80°C (175°F) for Group 2. For fracture-critical: consult Tables 12.4–12.8 based on the specific steel grade, hydrogen designator, and heat input. FC preheat at this thickness is typically 90–200°C (200–400°F) depending on those variables.

AASHTO/AWS D1.5:2025（橋梁溶接規格）に基づく、40–60 mm (1½–2½ in)板厚、水素指定H8でのにおけるM270M HPS345W / M270 HPS50Wの破壊臨界予熱要件。

AWS D1.5:2025に基づく — すべての値は条項に追跡可能。

破壊臨界最低予熱・パス間温度

300°F / 150°C

H8水素 · 2.0–2.8 kJ/mm入熱 · 40–60 mm (1½–2½ in)板厚

AASHTO/AWS D1.5M/D1.5:2025 表12.6/12.7

H8指定: AWS A4.3に基づき溶接材料は≤8 mL/100gの拡散性水素を溶着。水素が低いほど予熱要件も低くなります。

参考ツール。プロジェクト適用版およびエンジニア承認済みWPSで確認すること。

AASHTO M270 Standard Grades

M270M HPS345W / M270 HPS50W

AASHTO M270M HPS345W (M270 HPS50W) is a high-performance weathering bridge steel with enhanced weldability through controlled chemistry — 0.11% max carbon, 0.006% max sulfur with calcium treatment for inclusion shape control. Developed under FHWA-funded research to eliminate the lamellar tearing and inconsistent toughness problems of earlier weathering steel bridge designs. The lower carbon equivalent compared to conventional Gr.345W reduces cracking sensitivity at flange splices. NFC preheat per Table 6.3 Group 1; FC per Tables 12.6/12.7.

この予熱の理由

M270M HPS345W / M270 HPS50WのFC予熱を理解する

High-performance weathering 345 MPa steel with enhanced weldability. Under D1.5 fracture-critical requirements (Clause 12), the combination of H8 hydrogen designation and this heat input band requires 300°F minimum preheat at 40–60 mm (1½–2½ 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.

橋梁への適用

M270M HPS345W / M270 HPS50Wの使用箇所

Preferred over conventional Gr.345W for new unpainted bridge construction. The HPS designation indicates FHWA-developed chemistry with 0.11% max carbon and controlled sulfur for enhanced weldability and lamellar tearing resistance. Flange splice CJP welds benefit from the lower carbon equivalent, reducing reject rates during cold-weather bridge fabrication. Material cost premium over standard Gr.345W is typically 15–25% per ton but eliminates weldability-related rework.

H8 製作の詳細

M270M HPS345W / M270 HPS50WにおけるH8水素管理

HPS345W (HPS50W) with H8 is common practice where the HPS weldability advantage partially compensates for the higher hydrogen level. The controlled chemistry means HPS345W at H8 often has lower total cracking susceptibility than conventional 345W at H4 — illustrating how base metal chemistry and hydrogen control interact.

板厚: 40–60 mm (1½–2½ in)

40–60 mm (1½–2½ in)で予熱が重要な理由

Material from 40 to 65 mm (1-1/2 to 2-1/2 in) covers heavy girder flanges, thick splice plates, and main member plate. This is the critical thickness range for bridge fabrication — preheat reaches 65°C (150°F) for Group 1 and 80°C (175°F) for Group 2. FC preheat at this thickness can exceed 200°C (400°F) depending on hydrogen level and heat input.

製作の詳細

40–60 mm (1½–2½ in)でのM270M HPS345W / M270 HPS50W

HPS345W (HPS50W) at 40–65 mm covers main flange plates on new unpainted highway bridges. The controlled chemistry gives better CVN toughness transition behavior than conventional 345W — 20–30 J higher at -29°C (−20°F) — which improves the fracture resistance of thick flange splices in cold-climate service. Fabricators report 30–40% fewer repair rates on HPS flange splice welds compared to conventional 345W at the same thickness.

鋼材比較

H8 2.0–2.8 kJ/mm · 40–60 mm (1½–2½ in)における他の橋梁鋼材

鋼材	表	予熱
M270M Gr.250 / M270 Gr.36	A	200°F (90°C)
M270M Gr.345 / M270 Gr.50	A	200°F (90°C)
M270M Gr.345S / M270 Gr.50S	A	200°F (90°C)
M270M Gr.345W / M270 Gr.50W	B	300°F (150°C)

他の板厚

H8 2.0–2.8 kJ/mmでのM270M HPS345W / M270 HPS50W

インタラクティブ計算機

別の組み合わせを試す

D1.5橋梁予熱計算機を使用して、AASHTO M270鋼材の水素レベルと入熱の任意の組み合わせを検索できます。構造用鋼にはD1.1予熱計算機もご覧ください。

詳細情報