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デュエルビッツ 入金方法デュエルビッツ 入金方法rials for reactors

デュエルビッツ 入金方法el has developed new materials which can withstand intensely high temperature and high pressure hydrogen environment. The modified steels listed below enjoy superior properties of high strength and high hydrogen resistance that are achieved by adding the right amount of vanadium(V) and columbium(Cb) to the existing Cr-Mo steel. These new materials are already standardized in ASME and other codes, and are being used as major materials in the production of desulphurization reactors under high temperature.

  • デュエルビッツ 入金方法Modified 2 1/4Cr-1Mo-V steel (SA-336-F22V, SA-542-D-4a, SA-832-22V etc.)

(The first application of the modified 2 1/4 Cr-デュエルビッツ 入金方法, 1998)

(The first application of the modified 2 1/4 Cr-1Mo-V, 1998)

(The world largest reactors, 2009)

(The world largest reactors made of 2 1/4 Cr-1Mo-V 2009)

Distinctive features of デュエルビッツ 入金方法el's modified steel

デュエルビッツ 入金方法

High strength helps minimize the reactor weight

The enhanced precipitation of carbides of V and Cb realizes higher strength compared with the existing 2 1/4Cr-1Mo steel, leading to a reactor weight reduction of about 10%.

Improved resistance to hydrogen attack and hydrogen embrittlement

The precipitation of stable vanadium carbide and columbium carbonitride suppress the methanization reaction (hydrogen attack), and the trapping of the hydrogen in the steel by the fine vanadium carbide suppresses the hydrogen concentration at crack tips (hydrogen embrittlement).

Higher resistance to disbonding of stainless steel weld overlay

The trapping of hydrogen in the steel by fine vanadium carbide suppresses the hydrogen concentration at the boundary of overlay and base-metal.

Performance comparison between existing steel and improved steel

デュエルビッツ 入金方法

Conventional 2 1/4Cr-1Mo steel
(SA-336-F22)
Modified 2 1/4Cr-1Mo-V steel
Highest working temperature
(ASME VIII, Div.2 design)
482°C
(90デュエルビッツ 入金方法eg;F)
482°C
(90デュエルビッツ 入金方法eg;F)
Hydrogen attack resistance limit
(Nelson Curve)
454°C
(85デュエルビッツ 入金方法eg;F)
51デュエルビッツ 入金方法eg;C
(95デュエルビッツ 入金方法eg;F)
Hydrogen embrittlement - Higher resistance than conventional steel
Overlay disbond limit 200 bar at 454°C
(85デュエルビッツ 入金方法eg;F)
300 bar at 60デュエルビッツ 入金方法eg;C
(1112°F)
Impact test temperature
(Av. 40ft-lb/min. 35ft-lb)
-3デュエルビッツ 入金方法eg;C
(-22°F)
-18°C
(デュエルビッツ 入金方法eg;F)
Temper embrittlement
(Step cool test)
vTr40+3△vTr40
<=1デュエルビッツ 入金方法eg;C (5デュエルビッツ 入金方法eg;F)
vTr40+3△vTr40
<=1デュエルビッツ 入金方法eg;C (5デュエルビッツ 入金方法eg;F)
Tensile strength at room temperature 515-690 MPa
(75-100 ksi)
585-760 MPa
(85-110 ksi)
Allowable design stress intensity (454°C) 149.8 MPa
(21.9 ksi)
199.8 MPa
(28.9 ksi)
Reactor weight comparison
(Design temperature: 454°C)
100% 75%

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