A Review on Steels for Cryogenic Applications

Anoop, C. R.; Singh, Randhir; Kumar, Ravi Ranjan; Jayalakshmi, M.; Prabhu, T. Antony; Tharian, K. Thomas; Murty, S. V. S. Narayana

doi:10.1520/mpc20200193

Cited by 14 publications

(12 citation statements)

References 111 publications

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“…( E ) Strength and ductility synergy of GDS alloy, compared with other high-performing materials at cryogenic temperature. Uniform elongation versus ultimate tensile strength normalized by Young’s modulus of the GDS alloy, compared with those of the same compositions (with homogeneous, gradient-grained structures) at 293 K and 77 K ( 34 – 36 ), other MPE alloys ( 37 – 42 ), and cryogenic steels ( 21 , 43 , 44 ) tensioned from 4.2 K to 77 K in the literature. The hollow five-pointed star denotes the property of the topmost GDS surface with the use of the strength value estimated from the H v/3 and uniform elongation data from tensile test of GDS layer.…”

Section: Strain Hardening Ability At 77 Kmentioning

confidence: 99%

“…To demonstrate the excellent strength-strain hardening synergy of GDS samples at 77 K, we compare their uniform elongation versus ultimate tensile strength (Fig. 2E) with those of the same compositions with homogeneous and gradient-grained structures at 293 K and 77 K ( 34 – 36 ) and with other MPE alloy systems ( 37 – 42 ) as well as the advanced cryogenic steels ( 21 , 43 , 44 ) at 4.2 K to 77 K, which correspond to various strengthening strategies. We normalized the strength by the Young’s modulus of the material.…”

Section: Strain Hardening Ability At 77 Kmentioning

confidence: 99%

“…When strain hardening is improved in this manner, deformation twinning and phase transformation may act as secondary carriers of crystal plasticity at low temperature (17)(18)(19)(20). This scenario is particularly important for traditional single-principal element alloys with low stacking fault energies (SFEs) (1,11,21) and more recently developed high-to medium-entropy or multi-principal element (MPE) alloy systems (22)(23)(24)(25)(26)(27)(28)(29)(30). The presence of dynamic interactions between newly formed interfaces and dislocations contributes to a reasonable strain hardening capac-ity within a certain strain range.…”

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confidence: 99%

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Atomic faulting induced exceptional cryogenic strain hardening in gradient cell–structured alloy

Pan,

Yang,

Feng

et al. 2023

Science

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Coarse-grained materials are widely accepted to display the highest strain hardening and the best tensile ductility. We experimentally report an attractive strain hardening rate throughout the deformation stage at 77 kelvin in a stable single-phase alloy with gradient dislocation cells, that even surpasses coarse-grained counterparts. Contrary to conventional understanding, the exceptional strain hardening arises from a distinctive dynamic structural refinement mechanism facilitated by the emission and motion of massive multi-orientational tiny stacking faults (planar defects), which are fundamentally distinct from the traditional linear dislocation mediated deformation. The dominance of atomic-scale planar deformation faulting in plastic deformation introduces a different approach for strengthening and hardening metallic materials, offering promising properties and potential applications.

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Section: Strain Hardening Ability At 77 Kmentioning

confidence: 99%

Section: Strain Hardening Ability At 77 Kmentioning

confidence: 99%

mentioning

confidence: 99%

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Atomic faulting induced exceptional cryogenic strain hardening in gradient cell–structured alloy

Pan,

Yang,

Feng

et al. 2023

Science

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“…Material yang biasanya bersifat duktil pada temperatur atmosfer dapat menjadi sangat getas ketika dikondisikan pada temperatur yang sangat rendah, sementara material cryogenic keuletannya lebih meningkat. Beberapa jenis material yang biasa digunakan pada temperatur cryogenic adalah baja stainless steel (SS) 316L (Sas, Weiss dan Jung, 2015), SS 304L (Gupta, 2017), baja 9% Nikel (Hany dkk., 2014), baja Invar (Anoop dkk., 2021), dan aluminium AL 5052 (Gang, Lee dan Nam, 2009).…”

Section: Pendahuluanunclassified

Desain dan Analisis Tanki ISO LNG Kapasitas 40 feet Menggunakan Teknik Finite Element Analysis

Marpaung

Wibowo²,

Harmadi³

2022

ASIIMETRIK

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Development of liquified natural gas (LNG) ISO tank in Indonesia pays significant attention due to this product is still imported and it has high LNG market potential. In addition, this research is in line with national research priorities in the maritime sector to implement energy equality in Indonesia. As a first step in the research, the ISO tank model designed by using CATIA and structural testing using ANSYS software for finite element analysis. This simulation test is carried out to identify areas that receive high stress in the tank shell and the support structure of the tank. In addition, this virtual test was conducted to quantify the stress and safety factor of the ISO tank model. With this simulation, it is hoped that a more efficient and safer ISO tank design that meets existing regulatory standards can be obtained.

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“…[2,[9][10][11][12][13] Ni increases the low-temperature toughness of steel not only by enhancing the intrinsic fracture resistance of tempered martensite matrix but also by stabilizing the austenite phase. [10,14,15] Both the thermal and mechanical stability of austenite (γ), retained in a tempered martensite matrix (α), are equally important to ensure good impact toughness, particularly for low-temperature applications. Notably, the austenite stability depends on the tempering (or, annealing) treatment within the (γ þ α) intercritical region.…”

Section: Introductionmentioning

confidence: 99%

Effect of Austenite Reversion and Its Stability on the Tensile and Impact Transition Behavior of High‐Strength Naval Steel

Biswal,

Sk,

Barik

et al. 2023

steel research int.

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The present investigation correlates the austenite reversion and its stability during intercritical annealing (IA) with the tensile and Charpy impact properties of a low‐C naval grade steel. The as‐received steel is subjected to water quenching after austenitization at 950 °C, followed by IA at 620, 650, and 680 °C for 2 h. DICTRA simulation is used to predict the austenite reversion kinetics during the IA. Incorporation of cementite phase in the simulation correlates well with the experimental dilatometry results on the austenite growth kinetics. DICTRA simulation predicts a continuous rise in the reverted austenite fraction with increasing IA temperature. However, the percentage of reverted austenite, that gets retained after the subsequent quenching, decreases with increasing annealing temperature due to the reduction of austenite stability at elevated IA temperature. In other words, the amount of fresh untempered martensite increases rapidly with increasing IA temperature. Consequently, the sample annealed at an intermediate temperature of 650 °C (IA650) shows the best combination of strength, elongation, and low‐temperature impact properties as compared to the IA620 and IA680 steels due to an optimum balance of mechanically stable austenite and relatively lower untempered martensite fractions.

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A Review on Steels for Cryogenic Applications

Cited by 14 publications

References 111 publications

Atomic faulting induced exceptional cryogenic strain hardening in gradient cell–structured alloy

Atomic faulting induced exceptional cryogenic strain hardening in gradient cell–structured alloy

Desain dan Analisis Tanki ISO LNG Kapasitas 40 feet Menggunakan Teknik Finite Element Analysis

Effect of Austenite Reversion and Its Stability on the Tensile and Impact Transition Behavior of High‐Strength Naval Steel

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