AASHTO/AWS D1.5:2025 · Tabel 12.4/12.5 · Fraktur Kritis · H8

Preheat M270M Gr.250 — H8, Mid HI, > 60 mm: 300°F

Persyaratan preheat fraktur kritis untuk M270M Gr.250 / M270 Gr.36 pada ketebalan > 60 mm (> 2½ in) dengan penunjukan hidrogen H8, sesuai AASHTO/AWS D1.5:2025, Kode Pengelasan Jembatan.

Berdasarkan AWS D1.5:2025 — setiap nilai dilacak ke pasal.

Preheat dan Interpass Minimum Fraktur Kritis

300°F / 150°C

Hidrogen H8 · masukan panas 2.0–2.8 kJ/mm · ketebalan > 60 mm (> 2½ in)

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

Penunjukan H8: bahan habis pakai mengendapkan ≤ 8 mL/100g hidrogen difusibel sesuai AWS A4.3. Hidrogen lebih rendah = preheat lebih rendah.

Alat referensi. Verifikasi terhadap edisi yang berlaku dan WPS yang disetujui Insinyur.

AASHTO M270 Standard Grades

M270M Gr.250 / M270 Gr.36

AASHTO M270M Gr.250 (M270 Gr.36) is the metric/US customary designation for the basic structural bridge steel with 250 MPa (36 ksi) minimum yield. It is the direct bridge equivalent of ASTM A709 Gr.36, procured under AASHTO M270 with mandatory Charpy V-notch testing per temperature zone. Used for secondary bridge members — lateral bracing, diaphragm plates, floor beam stiffeners, and bearing components where Gr.345 strength is not needed. Non-fracture-critical preheat follows Table 6.3 Group 1; fracture-critical follows Tables 12.4/12.5 with hydrogen and heat input as additional variables.

Mengapa Preheat Ini

Memahami Preheat FC untuk M270M Gr.250 / M270 Gr.36

Basic 250 MPa (36 ksi) bridge steel for secondary members. 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 > 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.

Aplikasi Jembatan

Di Mana M270M Gr.250 / M270 Gr.36 Digunakan

Specified for secondary bridge members under AASHTO LRFD — lateral bracing angles, diaphragm plates, floor beam stiffeners, bearing seat components, and railing posts. Gr.250 (36) requires CVN testing per AASHTO temperature zone, distinguishing it from plain ASTM A36 by guaranteeing fracture resistance at the bridge design service temperature. Transverse stiffener fillet welds and floor beam web-to-flange joints are high-frequency fabrication details. Temperature zones (1 through 3) determine CVN test temperature: Zone 1 at 21°C (70°F) for moderate climates, Zone 2 at 4°C (40°F) for cold, Zone 3 at -12°C (10°F) for severe cold.

H8 Detail Fabrikasi

Kontrol Hidrogen H8 untuk M270M Gr.250 / M270 Gr.36

H8 designation (8 mL/100g max) on Gr.250 (36) provides a balanced approach between preheat economy and consumable availability. Most structural SMAW electrodes and FCAW wires carry H8 classification as the standard low-hydrogen tier. For secondary bridge members, H8 is typically the default specification unless the Engineer specifically mandates H4.

Ketebalan: > 60 mm (> 2½ in)

Mengapa Preheat Penting pada > 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.

Detail Fabrikasi

M270M Gr.250 / M270 Gr.36 pada > 60 mm (> 2½ in)

Gr.250 (36) above 65 mm is rare — typically only in large bearing assemblies or rehabilitation projects repairing older bridges where original plate was overspecified. Preheat soak-through at 225°F requires flame heating on both sides for 15–20 minutes on plate this thick. The cost of preheat compliance at this thickness often triggers a design review to consider switching to Gr.345 which achieves the same capacity with thinner, lighter sections.

Bandingkan Baja

Baja Jembatan Lain pada H8 2.0–2.8 kJ/mm · > 60 mm (> 2½ in)

Baja	Tabel	Preheat
M270M Gr.345 / M270 Gr.50	A	300°F (150°C)
M270M Gr.345W / M270 Gr.50W	B	350°F (180°C)
M270M HPS345W / M270 HPS50W	B	350°F (180°C)
M270M HPS485W / M270 HPS70W	B	350°F (180°C)

Ketebalan Lainnya

M270M Gr.250 / M270 Gr.36 pada H8 2.0–2.8 kJ/mm

Kalkulator Interaktif

Coba Kombinasi Berbeda

Gunakan Kalkulator Preheat Jembatan D1.5 untuk mencari baja AASHTO M270, tingkat hidrogen, dan kombinasi masukan panas. Lihat juga Kalkulator Preheat D1.1 untuk baja struktural.

Pelajari Lebih Lanjut

Panduan Terkait

Pertanyaan Umum

Berapa preheat FC untuk M270M Gr.250 / M270 Gr.36 dengan H8 pada > 60 mm (> 2½ in)?

Untuk fraktur kritis M270M Gr.250 / M270 Gr.36 dilas dengan bahan habis pakai bertanda H8 pada ketebalan > 60 mm (> 2½ in) dan masukan panas 2.0–2.8 kJ/mm, preheat minimum adalah 300°F (150°C) sesuai D1.5 Tabel 12.4/12.5.

Apa perbedaan antara preheat FC dan NFC untuk M270M Gr.250 / M270 Gr.36?

Preheat non-fraktur kritis (Tabel 6.3) adalah pencarian sederhana berdasarkan ketebalan. Preheat fraktur kritis (Tabel 12.4–12.8) menambahkan tingkat hidrogen dan masukan panas sebagai variabel, biasanya memerlukan preheat lebih tinggi.

Bagaimana masukan panas mempengaruhi preheat FC M270M Gr.250 / M270 Gr.36?

Masukan panas lebih tinggi berarti laju pendinginan lebih lambat, memberikan hidrogen lebih banyak waktu untuk berdifusi keluar dari zona las. Pada 2.0–2.8 kJ/mm, preheat 300°F menyeimbangkan tingkat hidrogen dan laju pendinginan.

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.

Data referensi D1.5:2025. Tidak berafiliasi dengan AWS atau AASHTO.