AWS D1.1:2025 · Tabelle 5.11 · Kategorie B

A913 Gr.50/60/65 Vorwärmung für SAW — 3/4" to 1-1/2"

Mindestvorwärm- und Zwischenlagentemperatur für A913 Gr.50/60/65 geschweißt mit SAW bei 3/4" to 1-1/2" Dicke, gemäß AWS D1.1:2025 Tabelle 5.11.

Basierend auf AWS D1.1:2025 Tabelle 5.11 — jeder Wert bis zur Klausel zurückverfolgt.

Mindest-Vorwärm- und Zwischenlagentemperatur

50°F / 10°C

Kategorie B
Niedrigwasserstoff SMAW-, SAW-, GMAW- oder FCAW-Verfahren

AWS D1.1:2025 Tabelle 5.11, §5.7

Referenzwerkzeug. Gegen projektanwendbare Ausgabe und von Ingenieur genehmigte WPS prüfen.

Über SAW

SAW (Submerged Arc Welding)

SAW submerges the arc beneath granular flux for highest deposition rates, flat/horizontal only. Category B in Table 5.11.

SAW on high-strength plate requires careful selection of wire-flux combinations to meet both tensile matching and toughness requirements. F8A4-EA2 or similar high-performance combinations serve Category C steels. Heat input control is particularly important on TMCP grades because SAW naturally deposits high heat input due to the deeply penetrating arc.

Practical Tips: SAW + High-Strength and TMCP Steels

SAW Tips for High-Strength and TMCP Steels

For A913 Grades 50/60/65 TMCP shapes (CE-IIW 0.35–0.42), SAW is limited to flat-position shop fabrication of built-up sections — most A913 work involves W-shape splices welded in positions impractical for SAW. Where flat-position SAW is feasible, use 3/32" EM12K at 400–550 A with neutral flux. D1.1 Clause 7.7 heat input limitations do NOT apply to A913/A913M — SAW high heat.

Typical values for reference — always verify against your approved WPS and electrode manufacturer data.

Why This Process?

Why SAW for A913 Gr.50/60/65 at 3/4" to 1-1/2"

Why SAW for A913 Gr.50/60/65 at 3/4" to 1-1/2"? SAW delivers 15-40 lb/hr deposition — the highest deposition rate among available processes. Position capability: flat and horizontal only. Suitability: shop only.

High-Strength and TMCP Steels

A913 Gr.50/60/65

ASTM A913 Grades 50 (50 ksi yield), 60 (60 ksi yield), and 65 (65 ksi yield) are quenched-and-self-tempered (QST) structural shapes produced by thermo-mechanical controlled processing (TMCP) — an in-line water quench immediately after the final rolling pass, followed by self-tempering from the core heat. This produces a fine-grained bainitic/ferritic microstructure throughout the full cross-section with carbon content typically 0.10-0.16% and CE-IIW of 0.35-0.42. Standard low-hydrogen processes use Category B; H8-certified consumables qualify for the reduced Category D (32°F all thicknesses), reflecting the inherent hydrogen cracking resistance of the TMCP microstructure. Available exclusively as W-shapes (primarily W14 heavy column sections), A913 is not produced as plate or other forms. The QST process eliminates the need for separate mill heat treatment, providing consistent through-thickness properties.

A913 Gr.50/60/65 + SAW

Warum Diese Vorwärmung für A913 Gr.50/60/65 mit SAW

TMCP structural shapes for seismic frames with H8-eligible reduced preheat. This steel is prequalified only with low-hydrogen processes under Table 5.11. With SAW, the submerged arc process with granular flux produces controlled hydrogen levels, with flux condition being the primary variable. The 50°F minimum preheat balances the steel’s strength level and carbon equivalent against the hydrogen control provided by SAW. Non-low-hydrogen SMAW is not an option for this grade under D1.1 prequalified WPS.

Wo A913 Gr.50/60/65 Eingesetzt Wird

Typische Anwendungen für A913 Gr.50/60/65

Specified for seismic moment frame columns, high-rise building corner columns, transfer girder bearing seats, heavy truss chords, stadium cantilever support columns, and parking garage moment frame members. A913 TMCP shapes eliminate the need for post-rolling heat treatment, providing consistent through-thickness properties from flange tip to web center. Column splice CJP welds and beam-to-column continuity plate fillet welds are the critical weld joints. Available in W14 sections from W14x132 through W14x730, these shapes are the backbone of seismic column design in high-rise construction. The TMCP process creates a fine-grained microstructure throughout the full cross-section, unlike conventional heat-treated shapes that may have property gradients. The H8 path to Category D (32°F all thicknesses) offers significant fabrication cost savings on heavy column splices that would otherwise require 150-225°F preheat under Category B. Column flange thicknesses on W14x455 and heavier sections exceed 3".

Dicke: 3/4" to 1-1/2"

Warum Vorwärmung bei 3/4" to 1-1/2" Wichtig ist

Preheat climbs at this range as thicker material slows heat dissipation, trapping hydrogen at crack-susceptible grain boundaries.

Stähle Vergleichen

Andere Stähle mit SAW bei 3/4" to 1-1/2"

Stahl	Kategorie	Vorwärmung
A36	B	50°F (10°C)
A633 Gr.E	C	150°F (65°C)
A709 HPS70W	C	150°F (65°C)
A710 Gr.A	C	150°F (65°C)

Andere Dicken

A913 Gr.50/60/65 mit SAW

Interaktiver Rechner

Verschiedene Kombinationen Ausprobieren

Verwenden Sie den interaktiven Vorwärmrechner für jede Stahl-, Verfahrens- und Dickenkombination aus D1.1:2025 Tabelle 5.11.

Mehr Erfahren

Schweißleitfäden für A913 Gr.50/60/65

Häufige Fragen

Was ist die Mindestvorwärmung für A913 Gr.50/60/65 mit SAW bei 3/4" to 1-1/2"?

Für A913 Gr.50/60/65 geschweißt mit SAW bei 3/4" to 1-1/2" Dicke beträgt die Mindestvorwärmtemperatur 50°F (10°C) gemäß AWS D1.1:2025 Tabelle 5.11, Kategorie B.

Welche Kategorie der Tabelle 5.11 gilt für A913 Gr.50/60/65 mit SAW?

A913 Gr.50/60/65 geschweißt mit SAW fällt unter Kategorie B in AWS D1.1:2025 Tabelle 5.11. Niedrigwasserstoff SMAW-, SAW-, GMAW- oder FCAW-Verfahren. Bei 3/4" to 1-1/2" Dicke erfordert diese Kategorie eine Mindestvorwärmung von 50°F (10°C).

D1.1:2025 Referenzdaten. Nicht mit AWS verbunden.