The Increase of Fracture Toughness with Solution Annealing Temperature in 18Ni Maraging 300 Steel

Filho, Venceslau Xavier de Lima; Lima, Tiago Silva; Griza, Sandro; Saraiva, Breno Rabelo Coutinho; Abreu, Hamilton Ferreira Gomes de

doi:10.1590/1980-5373-mr-2020-0472

Cited by 6 publications

(2 citation statements)

References 30 publications

(34 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…These results regarding grain size are consistent with findings reported by other researchers [66,67]. Lima et al [68] observed that the growth rate of prior austenite grain size is relatively slow between 1133 and 1273 K and increases significantly above 1423 K, with grain size values ranging from approximately 8 µm at 1133 K to 164 µm for the 300-grade maraging steel solution-annealed at 1423 K. Additionally, Lima et al noted that martensitic plates are more equiaxed up to 1133 K and transform into martensitic blocks at a solution annealing temperature of 1237 K, characterized either by the same orientation or blocks separated by high-angle boundaries [69]. The Vickers hardness values for the samples STed at 1123 and 1373 K are identical in this study, both measuring 561 HV.…”

Section: Microstructurementioning

confidence: 99%

“…Regarding the origins of microcracks in the martensitic microstructure of maraging steels, Fanton et al [51] suggested the presence of an oxidized layer formed during welding passes. Lima et al reported the formation of several precipitation particles, such as TiC [69] and Ni 3 Ti [68], at the grain boundary during heat treatment. Viswanathan et al [18,19] observed that maraging material becomes softer due to the occurrence of the retained austenite phase.…”

Section: Crack Propagation Behavior In Hazmentioning

confidence: 99%

See 1 more Smart Citation

Embrittlement Fracture Behavior and Mechanical Properties in Heat-Affected Zone of Welded Maraging Steel

Takahashi,

Toyohiro,

Segawa

et al. 2024

Materials

View full text Add to dashboard Cite

In welded maraging steels, mechanical properties, particularly ductility and toughness, are often compromised in the heat-affected zone (HAZ). This study focuses on 300-grade maraging steel bars, solution annealed at 1123 K for 1.5 h (5.4 ks) and welded using gas tungsten arc welding, followed by a post-weld heat treatment at 753 K for 13.33 h (48 ks). In situ observations during three-point bending tests on HAZ samples featuring coarsened prior austenite grain sizes were conducted to examine damage behavior and the crack path near the crack tip. The main crack initiated at the peak applied load during the bending test and, upon further loading, exhibited significant deflection and extension accompanied by numerous microcracks and localized crack branching. Distinctive damage features, such as transgranular cracking across block regions, intense intergranular cracking along packet boundaries with a pronounced shear component, and crowding of microcracks ahead of the crack tip, were observed in the HAZ sample during the in situ test. The interaction between the main crack tip and microcracks and its influence on the local crack propagation driving force was discussed using fracture mechanics. Experimental results, including tensile fracture surface observations and in situ images, along with analysis of the stress anti-shielding effect by microcracks, suggest that the HAZ sample exhibits embrittlement fracture behavior with lower ductility and toughness compared to the base metal sample.

show abstract

Section: Microstructurementioning

confidence: 99%

Section: Crack Propagation Behavior In Hazmentioning

confidence: 99%

Embrittlement Fracture Behavior and Mechanical Properties in Heat-Affected Zone of Welded Maraging Steel

Takahashi,

Toyohiro,

Segawa

et al. 2024

Materials

View full text Add to dashboard Cite

show abstract

Compromise between Strength and Fracture Resistance

GOURGUES‐LORENZON,

IUNG

2023

New Advanced High Strength Steels

View full text Add to dashboard Cite

Laser-Directed Energy Deposition of Dissimilar Maraging Steels with a Defect-Free Interface: Design for Improved Surface Hardness and Fracture Toughness

Deirmina

Amirabdollahian

Harris³

et al. 2023

Met. Mater. Int.

View full text Add to dashboard Cite

Maraging steels are a class of low-carbon ultra-high-strength martensitic steels. Due to their excellent weldability, these steels have been widely applied for laser-based additive manufacturing (AM). MAR-60HRC is a newly developed maraging grade for AM with a nominal chemical composition of 13.0Ni-15.0Co-10.0Mo-0.2Ti, Fe bal. (wt%), capable of achieving hardness levels of ~ 740 HV. Alternatively, 18Ni300 is a commercialized maraging steel with an excellent combination of strength and toughness at the peak aged hardness (i.e., ~ 590 HV). This work aims to investigate the properties and microstructure of MAR-60HRC fabricated by Laser Directed Energy Deposition (L-DED). Further, the manufacturability of bimetallic parts comprising a tough 18Ni300 core and a hard MAR-60HRC on the surface was evaluated. After proper aging, the multi-layered material showed a surface hardness of ~ 720 HV1 and apparent fracture toughness of 71 MPa m1/2, higher than that of MAR-60HRC (i.e., 60 MPa m1/2), and lower than 18Ni300 (i.e., 90 MPa m1/2). The excellent combination of surface hardness and fracture toughness was discussed, considering the crack arrest at the interface and the flawless interface between the two steels. Graphical Abstract

show abstract

The Increase of Fracture Toughness with Solution Annealing Temperature in 18Ni Maraging 300 Steel

Cited by 6 publications

References 30 publications

Embrittlement Fracture Behavior and Mechanical Properties in Heat-Affected Zone of Welded Maraging Steel

Embrittlement Fracture Behavior and Mechanical Properties in Heat-Affected Zone of Welded Maraging Steel

Compromise between Strength and Fracture Resistance

Laser-Directed Energy Deposition of Dissimilar Maraging Steels with a Defect-Free Interface: Design for Improved Surface Hardness and Fracture Toughness

Contact Info

Product

Resources

About