Your search keyword '"Austenitic stainless steel"' showing total 9,611 results

1. Effect of Cyclic Load Frequency on the Fatigue Crack Nucleation and Growth of Annealed and Prestrained Austenitic SS 304.

Author

Nascimento, Brenno L., Santos, Iris S., Santos, Luiara L., Reis, Matheus M. S., Jesus, Ihana G. C., and Griza, Sandro

Subjects

*FATIGUE limit, *FATIGUE crack growth, *STAINLESS steel fatigue, *AUSTENITIC stainless steel, *FRACTURE mechanics

Abstract

ABSTRACT The austenitic stainless steels are widely used in several engineering fields due to their high ductility, corrosion and high temperature performance. Despite its noble properties, components manufactured in austenitic stainless steel are subject to fatigue failure. Studies indicate that loading frequency can impact the austenitic stainless steel fatigue performance. In this scenario, the present study aims to evaluate the effect of frequencies of 3 and 30 Hz on the fatigue behavior of SS 304 alloy under load control in order to identify in which fatigue stage the effect is outstanding. Therefore, fatigue and fracture mechanics tests were evaluated on the alloy annealed at 1000°C. Furthermore, fatigue tests were also applied to the alloy after previous tensile plastic strain of 0.5. The analyses denoted a significant reduction in fatigue strength with increasing frequency, especially for the strained alloy. Fatigue crack nucleation is encouraged with greater load frequency. This behavior may be attributed to strain‐induced martensite and other strain mechanisms such as twinning and slip bands that are encouraged by lower strain rates but are relieved by auto‐heating achieved in higher frequencies, as mentioned in the literature, which decrease the strength to fatigue nucleation. [ABSTRACT FROM AUTHOR]

Published

2024

2. Investigation of Scaling and Materials' Performance in Simulated Geothermal Brine.

Author

Martelo, David, Holmes, Briony, Kale, Namrata, Scott, Samuel Warren, and Paul, Shiladitya

Subjects

*AUSTENITIC stainless steel, *GEOTHERMAL brines, *GEOTHERMAL resources, *CONSTRUCTION materials, *CARBON steel, *EPOXY coatings

Abstract

Geothermal energy generation faces challenges in efficiency, partly due to restrictions on reinjection temperatures caused by scaling issues. Therefore, developing strategies to prevent scaling is critical. This study aims to simulate the scaling tendencies and corrosion effects of geothermal fluids on various construction materials used in scaling reactor/retention tank systems. A range of materials, including carbon steel, austenitic stainless steel, duplex stainless steel, two proprietary two-part epoxy coatings, and thermally sprayed aluminium (TSA), were tested in a simulated geothermal brine. Experiments were conducted in a laboratory vessel designed to replicate the wall shear stress conditions expected in a scaling reactor. The tests revealed varying scaling tendencies among the materials, with minimal corrosion observed. The dominant scale formed was calcium carbonate, consistent with geochemical modelling. The findings suggest that despite the high operating temperatures, the risk of corrosion remains low due to the brine's low chloride content, while the wettability of materials after immersion may serve as a useful indicator for selecting those that promote scaling. [ABSTRACT FROM AUTHOR]

Published

2024

3. Preventing columnar grains growth during hybrid wire arc additive manufacturing of austenitic stainless steel 316L.

Author

Albannai, Abdulaziz I., León‐Henao, Henry, and Ramirez, Antonio J.

Subjects

AUSTENITIC stainless steel, HEAT conduction, THERMOCYCLING, IMPACT (Mechanics), SUBSTRATES (Materials science)

Abstract

Wire arc additive manufacturing (WAAM) is an efficient technique for producing medium to large‐size components, due to its accessibility and sustainability in fabricating large‐scale parts with high deposition rates, employing low‐cost and simple equipment, and achieving high material efficiency. Consequently, WAAM has garnered attention across various industrial sectors and experienced significant growth, particularly over the last decade, as it addresses and mitigates challenges within production markets. One of the primary limitations of WAAM is its thermal history during the process, which directly influences grain formation and microstructure heterogeneity in the resulting part. Understanding the thermal cycle of the WAAM process is thus crucial for process improvement. Typically, fabricating a part using WAAM results in a microstructure with three distinct zones along the build direction: an upper zone (thin surface layer) with fine grains, a middle zone dominated by undesirably long and large columnar grains covering more than 90% of the produced part, and a lower zone with smaller to intermediate columnar grains closer to the substrate material. These zones arise from variations in cooling rates, with the middle zone exhibiting the lowest cooling rate due to 2D conduction heat transfer. Consequently, producing a component with a microstructure comprising three different zones, with a high fraction of large and long columnar grains, significantly impacts the final mechanical properties. Therefore, controlling the size and formation of these grain zones plays a key role in improving WAAM. The aim of this work is to investigate the formation of undesired columnar grains in austenitic stainless steel 316L during WAAM and propose a simple hybrid technique by combining WAAM with a hot forging process (with or without interlayer cooling time). This approach targets the disruption of the solidification pattern of columnar grain growth during deposition progression and aims to enhance the microstructure of WAAM components. [ABSTRACT FROM AUTHOR]

Published

2024

4. Advanced ultra super critical power plants: role of buttering layer.

Author

Rathore, Saurabh, Kumar, Amit, Sirohi, Sachin, Pandey, Shailesh M., Gupta, Ankur, Fydrych, Dariusz, and Pandey, Chandan

Subjects

*SHIELDED metal arc welding, *AUSTENITIC stainless steel, *GAS tungsten arc welding, *GAS metal arc welding, *STEEL alloys

Abstract

Dissimilar metal welded (DMW) joint plays a crucial role in constructing and maintaining ultra-supercritical (USC) nuclear power plants while presenting noteworthy environmental implications. This research examines different welding techniques utilized in DMWJ, specifically emphasizing materials such as P91. The study investigates the mechanical properties of these materials, the impact of alloying elements, the notable difficulties encountered with industrial materials, and the concept of buttering. The USC nuclear power plants necessitate welding procedures appropriate for the fusion of diverse metal alloys. Frequently employed methodologies encompass shielded metal arc welding (SMAW), gas tungsten arc welding (GTAW), gas metal arc welding (GMAW), and flux-cored arc welding (FCAW). Every individual process possesses distinct advantages and limitations, and the choice of process is contingent upon various factors, including joint configuration, material properties, and the desired weld quality. The steel alloy known as P91, which possesses high strength and resistance to creep, is extensively employed in advanced ultra-supercritical (AUSC) power plants. P91 demonstrates exceptional mechanical characteristics, encompassing elevated-temperature strength, commendable thermal conductivity, and notable resistance against corrosion and oxidation. The presence of alloying elements, namely chromium, molybdenum, and vanadium, in P91, is responsible for its improved characteristics and appropriateness for utilization in (AUSC) power plant applications. Nevertheless, the utilization of industrial materials in DMW joint is accompanied by many noteworthy concerns, such as the propensity for stress corrosion cracking (SCC), hydrogen embrittlement, and creep deformation under high temperatures. The challenges mentioned above require meticulous material selection, process optimization, and rigorous quality control measures to guarantee the dependability and sustained effectiveness of DMW joint. To tackle these concerns, a commonly utilized approach referred to as buttering is frequently employed. When forming DMW joint in nuclear facilities, it is customary to place a buttering coating on ferritic steel. This facilitates the connection between pressure vessel components of ferritic steel and pipes of austenitic stainless steel. The primary difficulty in DMW joint manufacturing is in mitigating the significant disparity in material characteristics resulting from carbon migration and metallurgical alterations along the fusion interface between ferritic steel and austenitic stainless steel. The process of buttering entails the application of a compatible filler material onto the base metal before the deposition of the desired weld metal. The intermediate layer serves as a mediator, enhancing the metallurgical compatibility, diminishing the probability of fracture, and enhancing the overall integrity of the joint. Buttering is still a new research area with a wide scenario of scope in terms of development, which could revolutionize developing high-temperature. These long-term sustainable joints could serve under critical conditions like AUSC power plants and reduce CO2 emissions by increasing the overall efficiencies of the systems. [ABSTRACT FROM AUTHOR]

Published

2024

5. Microstructure, Mechanical Properties, and Surface Integrity of Austenitic-Martensitic Stainless Steel Functionally Graded Materials Prepared by Laser Additive Manufacturing.

Author

Qu, Huaizhi, Chen, Hui, Zhang, Jingjie, Xiao, Guangchun, Yi, Mingdong, Chen, Zhaoqiang, Wang, Guidong, and Xu, Chonghai

Subjects

AUSTENITIC stainless steel, STRAIN hardening, STAINLESS steel, TENSILE strength, MICROSTRUCTURE

Abstract

This study used laser additive manufacturing technology to fabricate austenitic–martensitic stainless steel functionally graded materials (ASS-MSS FGM). The microstructure and mechanical properties of ASS-MSS FGM were characterized, and the surface integrity after milling experiments of the ASS-MSS FGM was analyzed. The microstructure of the ASS-MSS FGM exhibited a dense subgrain structure with diverse subgrain types and no fixed growth direction. The microhardness of the ASS-MSS FGM increased from 283 HV to 530 HV due to the increased proportion of the martensitic phase. The ASS-MSS FGM tensile specimens fractured in the austenitic stainless steel region. The tensile strength is 896 MPa, which is increased by 121 MPa compared to ASS. The fracture elongation is 18%, which is increased by 140% compared to MSS. The milling experiments revealed that the degree of work hardening decreased by 8.1% along the building direction of the ASS-MSS FGM. Compared with the austenitic and martensitic layers, the degree and depth of work hardening of the gradient layer were in the transitional zone between them. The microstructure of ASS-MSS FGM after the milling mainly exhibited three deformation phenomena: grain squeezed deformation, grain broken dislodgement, and grain sheared fracture. [ABSTRACT FROM AUTHOR]

Published

2024

6. Role of grain size and anisotropy of neighboring grains in hydrogen‐assisted intergranular fatigue crack initiation in austenitic stainless steel.

Author

Arora, Aman, Singh, Mohit, Nair, Varun, Singh, Harpreet, and Mahajan, Dhiraj K.

Subjects

*CRACK initiation (Fracture mechanics), *STAINLESS steel fatigue, *AUSTENITIC stainless steel, *DIGITAL image correlation, *SHEAR strain

Abstract

This study explores the impact of microstructural features on fatigue crack initiation in poly‐crystalline materials, emphasizing hydrogen‐induced complexities. Grain anisotropy, misorientations, grain size variations, and elastic–plastic inhomogeneities concentrate stress at grain boundaries, making them susceptible to crack initiation during fatigue loading. The presence of hydrogen compounds this process, due to complications of characterization of local hydrogen content and activating embrittling mechanisms. Building upon a model for nickel, this research investigates 316L austenitic stainless steel specimens with varying grain sizes, both uncharged and hydrogen‐charged. In situ low‐cycle fatigue loading experiments establish correlations between fatigue crack initiation and microstructural features. The study reveals specific combinations of features crucial in the initiation process, undergoing alterations in the presence of hydrogen. A proposed qualitative model links microstructural features with accumulated plastic shear strain during fatigue and prevalent hydrogen embrittlement mechanisms like hydrogen‐enhanced local plasticity and hydrogen‐enhanced decohesion. Highlights: The effects of hydrogen on fatigue crack initiation (FCI) sites in stainless steel 316L are studied.Two different grain sizes were analyzed by in‐situ scanning electron microscopy (SEM) and electron back‐scattered diffraction (EBSD) and high‐resolution digital image correlation (HR‐DIC).Hydrogen‐assisted FCI is correlated with initial features of the microstructure.A model is proposed linking FCI with microstructure and accumulated plastic shear strain. [ABSTRACT FROM AUTHOR]

Published

2024

7. A physics‐informed neural network for creep life prediction of austenitic stainless steels in air and liquid sodium.

Author

Mei, Huian, Pan, Lingfeng, Gong, Cheng, and Zheng, Xiaotao

Subjects

*MACHINE learning, *AUSTENITIC stainless steel, *LIQUID sodium, *CREEP (Materials), *FAST reactors

Abstract

Creep life prediction of component materials exposed to air and liquid sodium environments is critical to ensure the safe operation and structural integrity of a sodium‐cooled fast reactor. In this paper, a method for predicting the creep life of a wide range of austenitic stainless steels in air and liquid sodium was proposed based on a physics‐informed neural network. Based on the established datasets for sodium corrosion rates and creep life in air and liquid sodium, the predictive performance of physical equations, conventional machine learning models, and the proposed model were assessed. Subsequently, a data‐driven creep life assessment framework was established, providing insight into the engineering application of machine learning methods in high‐temperature structure assessment. The results show that the creep fracture of austenitic stainless steel is accelerated by liquid sodium corrosion. The proposed physics‐informed neural network exhibits enhanced suitability and accuracy for predicting the sodium corrosion rate and creep life than physical equations and conventional machine learning methods. Highlights: A data‐driven creep life prediction method for metals under corrosion was proposed.New physical constraint and feature have been proposed based on domain knowledge.The excellent predictive performance of proposed method has been validated.Data‐driven creep assessment under environment effects has been proposed. [ABSTRACT FROM AUTHOR]

Published

2024

8. Study on Dynamic Recrystallization under Thermal Cycles in the Process of Direct Energy Deposition for 316 L Austenitic Stainless Steel.

Author

Cheng, Manping, Zou, Xi, Chang, Tengfei, and Liu, Lehui

Subjects

*AUSTENITIC stainless steel, *THERMOCYCLING, *DISLOCATION density, *STEEL manufacture, *STAINLESS steel

Abstract

In the process of directed energy deposition (DED), the grain structure of the deposited samples is determined by two aspects. The first is the initial solidification grain structure; the second is the effect of the upper thermal cycle on the solidified grain structure of the lower layer. Dynamic recrystallization and grain growth can be activated under suitable strain and the temperature resulting from thermal cycles. The evolution of grain size and the geometric dislocation density (GND) of austenitic stainless steel 316 L under different strains and temperatures caused by thermal cycles was investigated. It is found that dynamic recrystallization requires an appropriate level of accumulated strain, temperature, and initial grain size. Under <2% accumulated strain and 400–1200 °C conditions caused by 30 layers of thermal cycles, fully dynamic recrystallization occurs with coarse initial grains (CIG), leading to the complete coarsening of grains. However, relatively fine initial grains (FIG) under the same conditions only display partial dynamic recrystallization. The next 2–4% strain and 400–700 °C by 60 layers of thermal cycles make up the driving force of fully dynamic recrystallization, and the grains coarsen completely. Larger accumulated strain (4–6%) and lower temperature (400–600 °C) by 90 layers of thermal cycles and FIG provide more nucleation sites for dynamic recrystallization, which leads to little coarsening of grains even after fully dynamic recrystallization. Temperature, accumulated strain, and the amount of δ-ferrite promote the formation of sub-grains during dynamic recrystallization caused by thermal cycles, which leads to the increase in GND. [ABSTRACT FROM AUTHOR]

Published

2024

9. Parametrisation of Uniform Deformation in Ductile Metals Using Digital Image Correlation Technology.

Author

Tabin, J. and Brodecki, A.

Subjects

*STRAINS & stresses (Mechanics), *DIGITAL image correlation, *AUSTENITIC stainless steel, *MATERIAL plasticity, *ROOT-mean-squares

Abstract

This paper presents a novel measurement method that aims to qualitatively and quantitatively assess uniform deformation during displacement- and force-controlled tensile tests of ductile metals. The method utilizes digital image correlation technology to record the strain distribution during tensile testing, followed by the calculation of the floating root mean square (RMS) value of the strain amplitude along the specimen axis. By implementing this approach, the RMS-based profiles of strain amplitude are identified in different metals and alloys, including austenitic stainless steels, structural steel, copper, and aluminium alloys. Moreover, the proposed method holds potential for predicting important deformation characteristics such as distribution of intensive plastic zones, necking effect, and delocalization effect. Thus, it establishes a link between macroscale and microscale during the analysis of plastic deformation behaviour. The effectiveness of the new method is compared with existing strain and strain-rate methods. The novel approach demonstrates promising advantages in the context of the identification of metal-forming parameters. [ABSTRACT FROM AUTHOR]

Published

2024

10. Influence of Printing Parameters on the Morphological Characteristics of Plasma Directed Energy-Deposited Stainless Steel.

Author

Segovia-Guerrero, Luis, Gil-Mena, Antonio José, Baladés, Nuria, Sales, David L., Fonollá, Carlota, de la Mata, María, and de Nicolás-Morillas, María

Subjects

PLASMA arcs, SUBSTRATES (Materials science), STAINLESS steel, PLASMA materials processing, PROCESS optimization

Abstract

This study investigated the influence of printing parameters and strategies on the morphological characteristics of austenitic stainless steel beads deposited on carbon steel substrates, using plasma directed energy deposition (DED). The experimental setup varied the welding current, wire feed speed, and torch travel speed, and we analyzed three printing strategies: simple-linear, overlapping, and oscillating. Moreover, advanced 3D scanning and computational analysis were used to assess the key morphological features, including bead width and height. The results showed that the computational model developed by using parabolic assumptions accurately predicted the geometric outcomes of the overlapping beads. The oscillating printing strategy was the one that showed improved morphological uniformity and bead substrate wettability, so these features were used for multi-layer component manufacturing. The use of equivalent wavelength–amplitude values resulted in maximum combinations of bead height and width. Moreover, cost-effective carbon steel substrates were feasibly used in microstructural and elemental analyses, with the latter ones confirming the alignment of the bead composition with the wire-fed material. Overall, this study provides practical insights for optimizing plasma DED processes, thus enhancing the efficiency and quality of metal component manufacturing. [ABSTRACT FROM AUTHOR]

Published

2024

11. Sustainable Diamond Burnishing of Chromium–Nickel Austenitic Stainless Steels: Effects on Surface Integrity and Fatigue Limit.

Author

Maximov, Jordan, Duncheva, Galya, Anchev, Angel, Dunchev, Vladimir, Anastasov, Kalin, and Argirov, Yaroslav

Subjects

STRAINS & stresses (Mechanics), FATIGUE limit, AUSTENITIC stainless steel, AXIAL stresses, RESIDUAL stresses

Abstract

This study aims to evaluate the influence of lubrication and cooling conditions in the diamond burnishing (DB) process on the surface integrity and fatigue limit of chromium–nickel austenitic stainless steels (CNASSs) and, on this basis, identify a cost-effective and sustainable DB process. Evidence was presented that DB of CNASS performed without lubricating cooling liquid satisfies the requirements for a sustainable process: the three key sustainability dimensions (environmental, economic, and social) are satisfied, and the cost/quality ratio is favorable. DB was implemented with the same values of the main governing factors; however, four different lubrication and cooling conditions were applied: (1) flood lubrication (process F); (2) dry without cooling (process D); (3) dry with air cooling at a temperature of −19 °C (process A); and (4) dry with nitrogen cooling at a temperature of −31 °C (process N). Conditions A and N were realized via a device based on the principle of vortex tubes. All four DB processes provide mirror-finished surfaces with Ra roughness parameter values from 0.041 to 0.049 μm, zones with residual compressive stresses deeper than 0.5 mm, and increases in the specimens' fatigue limit (as determined by the accelerated Locati's method) compared to turning and polishing. Processes F and D produce the highest microhardness on the surface and at depth. The process D introduces maximum compressive residual axial and hoop stresses in the surface layer. The dry DB processes (D, A, and N) form a submicrocrystalline structure with high atomic density, which is most strongly developed under process D. When high fatigue strength is required, DB with air cooling should be chosen, as it provides a more favorable cost/quality ratio, whereas dry DB without cooling is the most suitable choice for applications that require increased wear resistance. [ABSTRACT FROM AUTHOR]

Published

2024

12. Advances in Low-Temperature Nitriding and Carburizing of Stainless Steels and Metallic Materials: Formation and Properties.

Author

Borgioli, Francesca, Adachi, Shinichiro, and Lindner, Thomas

Subjects

NONFERROUS alloys, IRON alloys, FERRITIC steel, SURFACE hardening, PLASMA immersion ion implantation, NITRIDING, TOOL-steel, AUSTENITIC stainless steel

Abstract

The document discusses advances in low-temperature nitriding and carburizing of stainless steels and metallic materials to enhance their surface properties. By using low-temperature treatments, expanded phases can be formed in stainless steels, improving surface hardness, wear and fatigue resistance, and corrosion resistance. These treatments have been successful in various stainless steel grades, as well as non-ferrous alloys, and have been applied to additively manufactured parts. The research aims to provide valuable insights for scientists and engineers involved in surface engineering processes for stainless steels and metallic materials. [Extracted from the article]

Published

2024

13. Chitosan and Its Derivatives as a Barrier Anti-Corrosive Coating of 304 Stainless Steel against Corrosion in 3.5% Sodium Chloride Solution.

Author

Aguilar-Ruiz, Ana Alejandra, Sánchez-Duarte, Reyna Guadalupe, Orozco-Carmona, Víctor Manuel, Devora-Isiordia, Germán Eduardo, Villegas-Peralta, Yedidia, and Álvarez-Sánchez, Jesús

Subjects

STAINLESS steel corrosion, FOURIER transform infrared spectroscopy, SURFACE analysis, CORROSION potential, STAINLESS steel, EPOXY coatings, AUSTENITIC stainless steel

Abstract

This study investigates the corrosion resistance of chitosan and its crosslinked form coatings applied on stainless steel as substrate using various analytical techniques. Fourier transform infrared spectroscopy (FTIR-ATR), scanning electron microscopy (SEM), and energy-dispersive X-ray spectroscopy (EDS) were employed for surface characterization. Electrochemical impedance spectroscopy (EIS) and potentiodynamic polarization (PDP) techniques were used to analyze the electrochemical behavior. Four coatings were evaluated along with naked stainless steel (ss): chitosan (Chi), chitosan crosslinked with ammonium paratungstate (Chi/PTA), chitosan crosslinked with polyethylene glycol (Chi/PEG), and chitosan crosslinked with polyvinylpyrrolidone (Chi/PVP). Electrochemical measurement parameters analysis assessed the coating corrosion resistance, such as impedance modulus (|Z|) and corrosion potential (Ecorr). Results indicate varying degrees of corrosion resistance among the coatings. Chi/PTA exhibited notable characteristics in the electrochemical tests, showing promising polarization resistance (Rp) and impedance behavior trends. Conversely, Chi/PEG showed differing electrochemical responses, suggesting higher susceptibility to corrosion under the study conditions. These findings contribute to understanding the electrochemical performance of chitosan-based coatings on stainless steel, highlighting their potential in corrosion protection applications. [ABSTRACT FROM AUTHOR]

Published

2024

14. The impact of loading rate on chloride induced stress corrosion cracking of 304L stainless steel.

Author

Blust, Sarah M. and Burns, James T.

Subjects

STRESS corrosion cracking, AUSTENITIC stainless steel, FRACTURE mechanics, STRAINS & stresses (Mechanics), STAINLESS steel

Abstract

The influence of applied loading rate (dK/dt) on stress corrosion cracking (SCC) behavior in annealed 304L stainless steel immersed in 4.7 M MgCl2 solution was assessed at varying temperatures from 23 °C to 70 °C. Measured crack growth rates obtained under rising K loading (dK/dt > 0) are compared to those obtained during static K testing. A rising K-based loading protocol was found to yield more conservative crack growth rates across all temperatures, with the variation in crack growth rates (and therefore the dependence in loading rate) decreasing with increasing environmental severity. [ABSTRACT FROM AUTHOR]

Published

2024

15. Cold Metal Transfer Welding of Ferritic and Austenitic Stainless Steel: Microstructural, Mechanical, and Electrochemical Studies.

Author

Gupta, Santosh K., Patil, Awanikumar P., Rathod, Ramesh C., Gupta, Aman, Methani, Hitesh, and Tandon, Vipin

Subjects

AUSTENITIC stainless steel, FERRITIC steel, ELECTRIC welding, CORROSION resistance, ELECTRON diffraction, FILLER metal, STAINLESS steel

Abstract

In the present study, cold metal transfer arc welding was employed to weld the 304L austenitic stainless steel (ASS) and Ti-stabilized 439 ferritic stainless steel (FSS) using a 309L filler electrode. Dissimilar joints were prepared using low heat input (HI; W1 ~ 247 J/mm) and high HI (W2 ~ 282 J/mm). The solidification mode for both weldments were the ferritic-austenitic mode and the weld zone (WZ) regions of both the weldments consists of columnar austenites, lathy and skeletal ferrite phases. The interfaces between WZ and ASS base metal showed the unmixed zone, whereas a conventional heat-affected zone (HAZ) was formed between the WZ and FSS base metals. The formation of ferrite stringers were observed in the unmixed zone, whereas peppery features of chromium-rich carbides were observed in HAZ. Moreover, electron backscattered diffraction technique was used to distinguish the microstructural differences between W1 and W2 weldments. Increase in the HIs resulted in decreased ferrite fraction in WZ as well as decrease in the mechanical strength of the joints. The W1 weldment depicted higher values of average micro-hardness (WZ ≈ 334.32 HV) than W2 (WZ ≈ 310.92 HV)) weldment. The electrochemical behaviour of the weldments was analysed for both the base metals and WZ of weldments. The higher degree of sensitization (DOS ~ 9.24%) of W1-WZ showed lower intergranular corrosion resistance than W2-WZ (DOS ~ 7.77%), however, the opposite trend was observed for impedance and pitting resistance. [ABSTRACT FROM AUTHOR]

Published

2024

16. A Study on the Liquid Helium Temperature Tensile Property of Fe-21Cr-15Ni-5Mn-2Mo Austenitic Stainless Steel after Solution Treatment.

Author

Zhang, Mengxing, Wang, Changjun, Ma, Dangshen, Liu, Yu, Wang, Weijun, Liang, Jianxiong, Fang, Chao, Chu, Weihan, and Huang, Chuanjun

Subjects

*HIGH strength steel, *AUSTENITIC stainless steel, *TENSILE strength, *SUPERCONDUCTING coils, *LIQUID helium

Abstract

A novel non-magnetic Fe-21Cr-15Ni-5Mn-2Mo austenitic stainless steel with high strength and plasticity has been developed. The microstructure and liquid helium temperature (4.2 K) tensile properties of the top and bottom samples of large-size forged flat steel after solution treatment at 1090 °C were investigated. The results showed that the average grain size of the bottom sample (48.0 ± 6.7 μm) was smaller than that of the top sample (58.8 ± 15.3 μm), and the MX precipitates and Z phases were distributed in the matrix of the samples. The 4.2 K strengths of the samples at the top and bottom were high, and large amounts of annealing twin boundaries played a certain role in strengthening. After cryogenic tensile testing, large amounts of deformation twins, stacking faults, and dislocations were generated inside the austenite grains of both samples, which helped the material to obtain higher plasticity and strength. The top and bottom samples possessed excellent synergies of strength and plasticity at 4.2 K, and the 4.2 K tensile properties of the top sample were as follows: ultimate tensile strength (UTS) of 1850 MPa, yield strength (YS) of 1363 MPa, and elongation (EL) of 26%. The tested steel is thus believed to meet the requirements of combined excellent strength and plasticity within a deep cryogenic environment, and it would be a promising material candidate for manufacturing superconducting coil cases to serve in new generation fusion engineering. [ABSTRACT FROM AUTHOR]

Published

2024

17. Investigations of Metallurgical Differences in AISI 347 and Their Influence on Deformation and Transformation Behaviour and Resulting Fatigue Life.

Author

Veile, Georg, Regitz, Elen, Smaga, Marek, Weihe, Stefan, and Beck, Tillmann

Subjects

*CHEMICAL processes, *AUSTENITIC stainless steel, *FATIGUE life, *MANUFACTURING processes, *MATERIAL fatigue, *HIGH cycle fatigue

Abstract

Due to variations in chemical composition and production processes, homonymous austenitic stainless steels can differ significantly regarding their initial microstructure, metastability, and thus, their fatigue behavior. Microstructural investigations and fatigue tests have been performed in order to evaluate this aspect. Three different batches and production forms of nominally one type of steel AISI 347 were investigated under monotonic tensile tests and cyclic loading under total strain and stress control in low and high cycle fatigue regimes, respectively. The deformation induced α'-martensite formation was investigated globally by means of in situ magnetic measurements and locally using optical light microscopy of color etching of micrographs. The investigation showed that the chemical composition and the different production processes influence the material behavior. In fatigue tests, a higher metastability and thus a higher level of deformation induced α'-martensite pronounced cyclic hardening, resulting in significantly greater endurable stresses in total strain-controlled tests and an increase in fatigue life in stress-controlled tests. For applications of non-destructive-testing, detailed knowledge of a component's metastability is required. In less metastable batches and for lower stress levels, α'-martensite primarily formed at the plasticization zone of a crack. Furthermore, the formation and nucleation points of α'-martensite were highly dependent on grain size and the presence of δ-ferrite. This study provides valuable insights into the different material behavior of three different batches with the same designation, i.e., AISI 347, due to different manufacturing processes and differences in the chemical composition, metastability, and microstructure. [ABSTRACT FROM AUTHOR]

Published

2024

18. Evaluation of near immersion active cooling on the microstructure and mechanical properties of AISI 316L stainless steel obtained with additive manufacturing by DED-Arc.

Author

Costa, Julia Nascimento, de Assis Faria, Geovane, Porcaro, Rodrigo Rangel, and Pereira, Igor Cézar

Subjects

*AUSTENITIC stainless steel, *HARDNESS testing, *STAINLESS steel, *WATER levels, *STRENGTH of materials

Abstract

The directed energy deposition arc (DED-Arc) has been extensively used to develop metallic parts with varying complexities. A major challenge for austenitic stainless steels is managing heat accumulation due to their low thermal conductivity. This study aimed to characterize the microstructure and mechanical properties of AISI 316L preforms manufactured by additive manufacturing (AM) under different deposition paths and cooling conditions. Samples underwent macro- and microstructural analyses, and tensile and hardness tests to evaluate their mechanical behavior. Additionally, the effect of active cooling using near immersion active cooling (NIAC) in water on the microstructure was assessed by examining the secondary interdendritic spacing and ferritic phase fraction. The NIAC technique has shown potential for enhancing productivity by producing preforms with more uniform thickness and consistent solidification/cooling conditions throughout the multiple layers. This approach eliminated deposition idle time, leading to a productivity increase of up to 108%. Microstructures obtained with active cooling were more refined than those resulting from natural cooling, evidenced by a reduction in secondary interdendritic spacing and an increased fraction of delta ferrite. These microstructural changes resulted in higher hardness and mechanical strength in the material processed with the NIAC technique. However, difficulties in precisely controlling the water level resulted in increased apparent porosity when using the NIAC technique. [ABSTRACT FROM AUTHOR]

Published

2024

19. The Role of Dislocation Type in the Thermal Stability of Cellular Structures in Additively Manufactured Austenitic Stainless Steel.

Author

An, Dayong, Xiao, Yao, Yu, Junshi, Zhang, Xu, Li, Zan, Ma, Yan, Li, Rui, Han, Xianhong, Li, Xifeng, Chen, Jun, and Zaefferer, Stefan

Subjects

*AUSTENITIC stainless steel, *DISLOCATION structure, *CELLULAR evolution, *LASER fusion, *CELL anatomy

Abstract

The ultrafine cellular structure promotes the extraordinary mechanical performance of metals manufactured by laser powder‐bed‐fusion (L‐PBF). An in‐depth understanding of the mechanisms governing the thermal stability of such structures is crucial for designing reliable L‐PBF components for high‐temperature applications. Here, characterizations and 3D discrete dislocation dynamics simulations are performed to comprehensively understand the evolution of cellular structures in 316L stainless steel during annealing. The dominance of screw‐type dislocation dipoles in the dislocation cells is reported. However, the majority of dislocations in sub‐grain boundaries (SGBs) are geometrically necessary dislocations (GNDs) with varying types. The disparity in dislocation types can be attributed to the variation in local stacking fault energy (SFE) arising from chemical heterogeneity. The presence of screw‐type dislocations facilitates the unpinning of dislocations from dislocation cells/SGBs, resulting in a high dislocation mobility. In contrast, the migration of SGBs with dominating edge‐type GNDs requires collaborative motion of dislocations, leading to a sluggish migration rate and an enhanced thermal stability. This work emphasizes the significant role of dislocation type in the thermal stability of cellular structures. Furthermore, it sheds light on how to locally tune dislocation structures with desired dislocation types by adjusting local chemistry‐dependent SFE and heat treatment. [ABSTRACT FROM AUTHOR]

Published

2024

20. Influence of organic/inorganic inhibitors on AISI 304 (1.4301) and AISI 314 (1.4841) steels corrosion kinetics in nitric acid solution.

Author

ŠĆEPANOVIĆ, JELENA, ZINDOVIĆ, BOJANA, RADONJIĆ, DRAGAN, PAVLOVIĆ, MARIJANA R. PANTOVIĆ, and PAVLOVIĆ, MIROSLAV M.

Subjects

*AUSTENITIC stainless steel, *STAINLESS steel corrosion, *CORROSION potential, *LINEAR polarization, *STAINLESS steel

Abstract

This study evaluates the effectiveness of KMnO4, MK3 and 1-butanol inhibitors on corrosion of AISI 314 and AISI 304 stainless steels using linear and potentiodynamic polarization in 0.1 M HNO3. The metrics like corrosion potential (Ecorr), current density (jcorr) and polarization resistance (Rp) influence the inhibitor efficacy. The inhibitors improved electrochemical parameters significantly, indicating strong anti-corrosive properties. 1-Butanol had the strongest effect, enhancing corrosion potential and drastically reducing corrosion current density, demonstrating superior protection. The results indicated that without inhibitors, both steels showed higher corrosion rates and more negative potentials, reflecting their susceptibility to corrosion. The introduction of inhibitors markedly improved these parameters, particularly with 1-butanol, which significantly enhanced the polarization resistance and shifted the corrosion potential towards less negative values. The potentiodynamic results highlighted the dynamic effectiveness of inhibitors, reinforcing their role in mitigating corrosion under varied conditions. The study underscores the importance of selecting the appropriate inhibitors to enhance the durability and longevity of stainless steels in acidic environments, with 1-butanol showing the potential for industrial applications requiring high corrosion resistance. This necessitates comprehensive testing to accurately measure inhibitor capabilities in different conditions. [ABSTRACT FROM AUTHOR]

Published

2024

21. Analysis, Assessment, and Mitigation of Stress Corrosion Cracking in Austenitic Stainless Steels in the Oil and Gas Sector: A Review.

Author

Vakili, Mohammadtaghi, Koutník, Petr, Kohout, Jan, and Gholami, Zahra

Subjects

*STRESS corrosion cracking, *AUSTENITIC stainless steel, *STRAINS & stresses (Mechanics), *STRAIN rate, *GAS industry

Abstract

This comprehensive review examines the phenomena of stress corrosion cracking (SCC) and chloride-induced stress corrosion cracking (Cl-SCC) in materials commonly used in the oil and gas industry, with a focus on austenitic stainless steels. The study reveals that SCC initiation can occur at temperatures as low as 20 °C, while Cl-SCC propagation rates significantly increase above 60 °C, reaching up to 0.1 mm/day in environments with high chloride concentrations. Experimental methods such as Slow Strain Rate Tests (SSRTs), Small Punch Tests (SPTs), and Constant-Load Tests (CLTs) were employed to quantify the impacts of temperature, chloride concentration, and pH on SCC susceptibility. The results highlight the critical role of these factors in determining the susceptibility of materials to SCC. The review emphasizes the importance of implementing various mitigation strategies to prevent SCC, including the use of corrosion-resistant alloys, protective coatings, cathodic protection, and corrosion inhibitors. Additionally, regular monitoring using advanced sensor technologies capable of detecting early signs of SCC is crucial for preventing the onset of SCC. The study concludes with practical recommendations for enhancing infrastructure resilience through meticulous material selection, comprehensive environmental monitoring, and proactive maintenance strategies, aimed at safeguarding operational integrity and ensuring environmental compliance. The review underscores the significance of considering the interplay between mechanical stresses and corrosive environments in the selection and application of materials in the oil and gas industry. Low pH levels and high temperatures facilitate the rapid progression of SCC, with experimental results indicating that stainless steel forms passive films with more defects under these conditions, reducing corrosion resistance. This interplay highlights the need for a comprehensive understanding of the complex interactions between materials, environments, and mechanical stresses to ensure the long-term integrity of critical infrastructure. [ABSTRACT FROM AUTHOR]

Published

2024

22. Electrochemical Behavior of Plasma-Nitrided Austenitic Stainless Steel in Chloride Solutions.

Author

Zatkalíková, Viera, Drímalová, Petra, Balin, Katarzyna, Slezák, Martin, and Markovičová, Lenka

Subjects

*AUSTENITIC stainless steel, *STAINLESS steel corrosion, *ELECTROLYTIC corrosion, *PLASMA spectroscopy, *X-ray photoelectron spectroscopy, *NITRIDING

Abstract

The application possibilities of austenitic stainless steels in high friction, abrasion, and sliding wear conditions are limited by their inadequate hardness and tribological characteristics. In order to improve these properties, the thermochemical treatment of their surface by plasma nitriding is suitable. This article is focused on the corrosion resistance of conventionally plasma-nitrided AISI 304 stainless steel (530 °C, 24 h) in 0.05 M and 0.5 M sodium chloride solutions at room temperature (20 ± 3 °C), tested by potentiodynamic polarization and electrochemical impedance spectroscopy. Optical microscopy, scanning electron microscopy, energy-dispersive X-ray spectroscopy, and X-ray photoelectron spectroscopy are used for nitrided layer characterization. The experiment results confirmed the plasma-nitrided layer formation of increased micro-hardness related to the presence of Cr2N chromium nitrides and higher surface roughness compared to the as-received state. Both of the performed independent electrochemical corrosion tests point to a significant reduction in corrosion resistance after the performed plasma nitriding, even in a solution with a very low chloride concentration (0.05 mol/L). [ABSTRACT FROM AUTHOR]

Published

2024

23. A unified creep and fatigue life prediction approach for 316 austenitic stainless steel using machine and deep learning.

Author

Bhardwaj, Harsh Kumar and Shukla, Mukul

Subjects

*ARTIFICIAL neural networks, *AUSTENITIC stainless steel, *FATIGUE life, *CREEP (Materials), *NUCLEAR pressure vessels, *DEEP learning

Abstract

316 Austenitic stainless steel (AusSS) is extensively utilized in high‐temperature industrial applications such as boiler tubes and nuclear reactor pressure vessels. These components commonly experience failure under high‐temperature and high‐pressure conditions, attributed to either creep or fatigue. Existing classical models for creep and fatigue life prediction focus on a singular failure mode (either creep or fatigue) and consider physical features only. This study aims to develop a unified life prediction model for both creep and fatigue phenomena. It synthesizes information from 12 additional unexplored chemical and microstructural features from the National Institute of Materials Science (NIMS), Japan database, and previously published literature. Machine learning (such as decision tree, random forest, and XGBoost) and deep learning (like deep neural network) algorithms are employed in the modeling process. The trained models have been cross‐validated against unseen creep and fatigue life data, demonstrating superior prediction accuracy of 96.1% for deep neural network compared with classical models. Highlights: Unified prediction model for both creep and fatigue life prediction.Investigated the effect of up to 20 physical, chemical, and microstructural features.Multiple ML and DL prediction models were developed and compared with classical ones. [ABSTRACT FROM AUTHOR]

Published

2024

24. Assessment of High-Temperature Oxidation Properties of 316L Stainless Steel Powder and Sintered Porous Supports for Potential Solid Oxide Cells Applications.

Author

Kabir, Ahsanul, Koszelow, Damian, Miruszewski, Tadeusz, Tinti, Victor Buratto, Esposito, Vincenzo, Kern, Frank, and Molin, Sebastian

Subjects

AUSTENITIC stainless steel, MECHANICAL properties of metals, TAPE casting, OXIDATION kinetics, STAINLESS steel

Abstract

In this work, the oxidation properties of austenitic 316L stainless steel powder and sintered porous support were investigated at the temperature range of ~600-750 䨽 for 100 hours in ambient air. Oxidation kinetics was determined by continuous thermogravimetry and analyzed employing parabolic rate law. It was observed that oxidation leads to the formation of an oxide scale, with substantial oxidation occurring at = 650 ℃ in the powder. The porous steel support was fabricated using the tape casting method with two distinct pore former concentrations. The microstructural features of both the powder and support were investigated by X-ray diffractometry and scanning electron microscopy coupled with energy-dispersive X-ray analysis. The mechanical properties of the metal support were examined before and after oxidation via a microhardness test. The effect of porosity on the resulting properties of the metal support was also highlighted. In summary, 316L stainless steel support suits SOCs applications below 600 ℃. [ABSTRACT FROM AUTHOR]

Published

2024

25. Study of selected mild steels for application in vacuum systems of future gravitational wave detectors.

Author

Scarcia, Carlo, Bregliozzi, Giuseppe, Chiggiato, Paolo, Ingrid Michet, Alice, Perez Fontenla, Ana Teresa, Rimoldi, Martino, Taborelli, Mauro, and Wevers, Ivo

Subjects

AUSTENITIC stainless steel, GRAVITATIONAL wave detectors, VACUUM tubes, ULTRAHIGH vacuum, WATER vapor

Abstract

Next-generation gravitational wave detectors (GWDs) like the Cosmic Explorer and Einstein Telescope require extensive vacuum tubing, necessitating cost-effective materials. This study explores the viability of mild steel as an alternative to austenitic stainless steel for ultrahigh vacuum beampipes, focusing on outgassing rates and surface chemistry after low-temperature bakeouts. Mild steels exhibit significantly lower hydrogen outgassing rates, below 10 − 14 mbar l s − 1 cm − 2 after bakeouts at 80 ° C for 48 h. While water vapor is the primary residual gas after such low-temperature bakeouts, repeated treatments reduce its outgassing rate and modify surface conditions so that such benefit is preserved after at least six months of exposure to laboratory air. These findings position mild steel as an economical and efficient material for future GWD beampipes. [ABSTRACT FROM AUTHOR]

Published

2024

26. Analysis of the Relationship Between Process Parameters and Microhardness for the Finishing Process by Wire Arc Additive Manufacturing Combined with the FSB Tool of Austenitic Stainless Steel 316L.

Author

Cordkaew, Teerayut, Kaneko, Jun'ichi, and Abe, Takeyuki

Subjects

GAS metal arc welding, AUSTENITIC stainless steel, MANUFACTURING processes, MATERIAL plasticity, MICROHARDNESS, GRAIN size

Abstract

Wire arc additive manufacturing (WAAM), based on gas metal arc welding, is ideal for fabricating components with sizeable geometries and moderate structural intricacies. However, the electric arc introduces a heat source and directional heat dissipation during deposition, resulting in undesired microstructural characteristics, such as columnar dendritic structures, which lead to variations in hardness across the printed component. Our previous research introduced the friction stir burnishing (FSB) tool integrated with WAAM using a hybrid approach called simultaneous processing. This method suppressed dendrite formation and enhanced the microstructure within WAAM. This approach directly correlates process dynamics, force dynamics, and temperature control, facilitating efficient plastic deformation. This research investigates the relationship between process parameters and microhardness within the combined manufacturing systems of WAAM and FSB tools. The study primarily focuses on using SUS 316L austenitic stainless steel wire material for WAAM and examines how simultaneous operation with the FSB tool impacts microstructure and microhardness. The investigation emphasizes three key parameters: the distance between the welding torch and the FSB tool, tool rotational speed, and machine feed speed. Comprehensive experimentation, including Taguchi analysis, determines optimal values for these parameters. Results indicate that torch-to-tool distance and machine feed speed significantly influence microhardness, while tool rotational speed shows minimal impact. The most effective combination for enhancing microhardness was a torch-to-tool distance of 20 mm, a machine feed speed of 528 mm/min, and a tool rotational speed of 1900 rpm. This combination induced a plastic deformation transformation effect, contributing to the overall improvement in microhardness. Additionally, the optimal parameters for achieving a smaller grain size were a torch-to-tool distance of 17 mm, a machine feed speed of 356 mm/min, and a tool rotational speed of 1900 rpm, as indicated by the average grain size. Furthermore, this study shows significant improvements in microstructure and hardness within 50–200 µm depth from the surface. Comparative analysis between FSB tool-processed and non-processed samples indicates a 22.51% increase in microhardness, with the grain size of the simultaneous process being 7 µm compared to 11.55 µm. Optimizing the process parameters of simultaneous processing achieves superior microhardness and microstructural refinement. Additionally, it highlights the need for further material development to address challenges associated with tool durability, paving the way for advancements in simultaneous processes. [ABSTRACT FROM AUTHOR]

Published

2024

27. Solid-to-Solid Diffusion Bond Between SA508 Low Alloy Steel to 316L Stainless Steel by Hot Isostatic Pressing.

Author

Pan, Qingyu, Lee, Jongkyung, Yang, Jingfan, Samarov, Victor, and Lou, Xiaoyuan

Subjects

LOW alloy steel, AUSTENITIC stainless steel, HEAT treatment, ISOSTATIC pressing, GRAIN refinement

Abstract

Solid-to-solid diffusion bond between ferritic SA508 low alloy steel (LAS) and austenitic 316L stainless steel (SS) via hot isostatic pressing (HIP) was evaluated. This study investigated the microstructural and mechanical evolutions of the bimetallic interface before and after heat treatment. The interfacial region between two materials demonstrated uniform microstructure, no visible manufacturing defects, and higher interfacial hardness and tensile strength. The joint interface was stronger than for both 316L SS and SA508 LAS. The interfacial hardening was attributed to the significant grain refinement at the interface region and dislocation hardening under as-HIP'ed condition. Post-HIP heat treatment considerably reduced the interfacial strength, attributed to dislocation recovery and grain growth. From the mechanical perspective, the work confirmed utilizing HIP capsules during HIP manufacturing provides adequate interfacial strength between 316L SS HIP capsule and SA508 LAS for cladding purposes. The 316L SS HIP capsule may be used as the cladding layer for corrosion protection. [ABSTRACT FROM AUTHOR]

Published

2024

28. Linking Grain Size to Microscopic Hardening Laws in a Phenomenological Crystal Plasticity Model: A Finite Element Simulation Approach for 316L Stainless Steel.

Author

Kouachi, Khalil, Belouchrani, Mohamed El Amine, Bouchedjra, Moussa, Belattar, Adel, Ould Ouali, Mohand, and Kanit, Toufik

Subjects

AUSTENITIC stainless steel, CYCLIC loads, EXPERIMENTAL literature, FINITE element method, CRYSTAL models, GRAIN size

Abstract

This study investigates the relationship between grain size and material parameters defined in the microscopic hardening laws of the phenomenological crystal plasticity model of Méric–Cailletaud. This investigation is essential for accurate cyclic loading simulations, where the grain size effect on kinematic hardening cannot be neglected. The work was carried out through finite element simulations of the macroscopic plastic behavior of six representative volume elements (RVEs), of austenitic stainless steel 316L, varying in grain size, using a model of Méric–Cailletaud, implemented within the Abaqus software. Experimental literature results serve as benchmarks for adjusting grain size-related hardening parameters. The findings reveal that the studied parameters obey the Hall–Petch law and exhibit an inverse relationship with the square root of the grain size. What is noteworthy is the effect of grain size on kinematic hardening, which differs significantly from previous studies where kinematic hardening parameters were kept constant. Additionally, parameter evolution varies notably between microstructures with coarse and fine grains. Finally, determining hardening parameter variation as a function of grain size provides us with an extended model of Méric–Cailletaud capable of predicting the local as well as the global mechanical behavior of stainless steel 316L in both monotonic and cyclic loading cases, considering the grain size effect. [ABSTRACT FROM AUTHOR]

Published

2024

29. Decoupling the Effects of Strain Rate and Temperature Rise on Martensitic Transformation in a 316 Austenitic Stainless Steel.

Author

Shu, Dianqiang, Wang, Huanran, Shen, Yachao, and Yang, Wenshuai

Subjects

AUSTENITIC stainless steel, MARTENSITIC transformations, STRAIN rate, MATERIAL plasticity, ADIABATIC temperature

Abstract

Interrupted and incremental tensile tests have been carried out on 316 austenitic stainless steel at different strain rates, revealing the correlation between the strain, strain rate, and temperature rise of martensitic transformation. The FERITSCOPE FMP ferrite tester and Telops FAST M2K infrared imager measured the martensite content and surface temperature rise at different strain rates, respectively. The effect of adiabatic temperature rise and strain rate on martensitic transformation was isolated by incremental tests. Compared with the incremental tensile test at a low strain rate (0.001 s−1), it has been found that the increase in strain rate has a negative effect on martensitic transformation, and the effect of strain rate on martensitic transformation seems to be more significant than that of adiabatic temperature rise. The formation and evolution mechanism of strain-induced martensitic transformation of 316 austenitic stainless steel were studied by electron backscattered diffraction. During the process of tensile plastic deformation, the nucleation and growth of new martensite mainly occurred near the twin boundary. [ABSTRACT FROM AUTHOR]

Published

2024

30. Effect of Residual Stresses on the Fatigue Stress Range of a Pre-Deformed Stainless Steel AISI 316L Exposed to Combined Loading.

Author

Jagarinec, Darko and Gubeljak, Nenad

Subjects

MECHANICAL behavior of materials, AUSTENITIC stainless steel, RESIDUAL stresses, MATERIAL plasticity, MANUFACTURING processes

Abstract

AISI 316L austenitic stainless steel is utilized in various processing industries, due to its abrasion resistance, corrosion resistance, and excellent properties over a wide temperature range. The physical and mechanical properties of a material change during the manufacturing process and plastic deformation, e.g., bending. During the combined tensile and bending loading of a structural component, the stress state changes due to the residual stresses and the loading range. To characterize the component's stress state, the billet was bent to induce residual stress, but a phase transformation to martensite also occurred. The bent billet was subjected to combined tensile–bending and fatigue loading. The experimentally measured the load vs. displacement of the bent billet was compared with the numerical simulations. The results showed that during fatigue loading of the bent billet, both the initial stress state at the critical point and the stress state during the dynamic loading itself must be considered. Analysis was demonstrated only for one single critical point on the surface of the bent billet. The residual stresses due to the phase transformation of austenite to martensite affected the range and ratio of stress. The model for the stress–strain behaviour of the material was established by comparing the experimentally and numerically obtained load vs. displacement curves. Based on the description of the stress–strain behaviour of the pre-deformed material, guidelines have been provided for reducing residual tensile stresses in pre-deformed structural components. [ABSTRACT FROM AUTHOR]

Published

2024

31. Behaviour of Dissimilar Welded Connections of Mild Carbon (S235), Stainless (1.4404), and High-Strength (S690) Steels under Monotonic and Cyclic Loading.

Author

Ene, Anna, Stratan, Aurel, and Both, Ioan

Subjects

AUSTENITIC stainless steel, CARBON steel, BRITTLE fractures, MILD steel, CYCLIC loads, STEEL framing

Abstract

In the context of an increasing interest in the use of high-performance steels in the construction industry due to their superior mechanical properties, understanding the behaviour and assessing the performance of dissimilar welded connections becomes essential. When several steel grades are adopted for fabrication of the same dissipative element, dissimilar welded connections have a decisive importance regarding the seismic performance of the structural member. This paper presents the experimental results of monotonic and low-cycle fatigue (LCF) tests on dissimilar welded connections. The welded connections are designed to reproduce the loading state that occurs between the web and the flanges of dissipative links in an eccentrically braced frame, and represent combinations of S235 mild carbon steel, 1.4404 austenitic stainless steel, and S690 high-strength steel. The obtained experimental results provide a better understanding of the behaviour of dissimilar welded connections through the evaluation of their strength, ductility, and failure mechanisms, providing a basis for finite element (FE) models' calibration for further numerical simulations. This study contributes to the evaluation of the feasibility of connections between dissimilar steels in seismic-resistant steel structures. [ABSTRACT FROM AUTHOR]

Published

2024

32. Semiconductive Tendency of the Passive Film Formed on Super Austenitic Stainless Steel SR-50A in Acidic or Alkaline Chloride Solutions.

Author

Choi, Seung-Heon, Yoo, Young-Ran, and Kim, Young-Sik

Subjects

AUSTENITIC stainless steel, METALWORK, METALLIC films, THIN films, P-type semiconductors

Abstract

Stainless steel is widely used in various industrial fields due to its excellent corrosion resistance and mechanical properties. The key to this corrosion resistance is the thin passive film that naturally forms on the metal surface. Passive films are characterized by oxide film theory and adsorption theory, each uniquely explaining the structure and mechanism of the protective film on the metal surface. Research on the semiconductive properties of passive films on stainless steel offers diverse viewpoints, classifying theories into the point defect model and the bipolar fixed charge-induced passivity. Specific changes in passive film attributes that lead to degradation, however, are not fully understood. In this study, we analyzed the inner and outer layers of the passive film on super austenitic stainless steel SR-50A under various conditions in acidic and alkaline chloride environments. The interpretations of these results were based on the point defect model and the bipolar model for the passivation mechanism, and correlations between p-type and n-type semiconductor properties and passivation behavior were examined. The surface of the stainless steel forms a passive film comprising two layers with p-type and n-type semiconductive properties, independent of the pH of the solutions. The corrosion resistance increases as the p-type and n-type semiconductive tendencies become more balanced, consequently enhancing the properties of the passive film. [ABSTRACT FROM AUTHOR]

Published

2024

33. Mechanical and Microstructural Characterization of AISI 316L Stainless Steel Superficially Modified by Solid Nitriding Technique.

Author

Guardian-Tapia, Rene, Rosales-Cadena, Isai, Roman-Zubillaga, Jose Luis, and Gonzaga-Segura, Sergio Ruben

Subjects

AUSTENITIC stainless steel, SCANNING electron microscopy, STAINLESS steel, WEAR resistance, NITRIDING, HARDNESS

Abstract

AISI 316L austenitic stainless steel superficially modified by the solid nitriding technique was investigated at different nitriding times (2, 4, 6, 8, 12 and 24 h) and at 450 °C. The microstructural characterization was conducted using scanning electron microscopy (SEM) analysis and X-ray diffraction analyses, finding the presence of Fe2–3N, Fe4N and Cr2N, among others. The mechanical behavior of the modified surfaces was carried out by developing hardness profiles and relating it with the nitride layer thickness evaluated using scanning electron microscopy (SEM), obtaining layers up to 70 µm wide. The nitrogen diffusion produced species above and below the surface sample with a transformation from the austenitic phase to an expanded austenite (γN) phase, which is responsible for producing an increase in hardness of up to 1200 HV in the samples treated at 24 h, which is four times higher than the untreated steels. Wear evaluations of the obtained layers were performed using a pin-on-disk system under zero lubrication, indicating that the samples with 12 and 24 h of treatment present the best wear resistance promoted by an oxidative–adhesive mechanism. The obtained results are positively comparable with those of the ion nitriding technique but with a lower implementation cost. [ABSTRACT FROM AUTHOR]

Published

2024

34. Interpretation of complex x-ray photoelectron peak shapes. II. Case study of Fe 2p3/2 fitting applied to austenitic stainless steels 316 and 304.

Author

Hughes, A. E., Easton, C. D., Gengenbach, T. R., Biesinger, M. C., and Laleh, M.

Subjects

AUSTENITIC stainless steel, BINDING energy, TRANSITION metals, OXIDATION states, PHOTOELECTRONS

Abstract

In this paper, a review of the analysis of Fe 2p3/2 peak and other transition metals in the austenitic stainless steel literature is presented. It reveals the significant shortcomings of the most widely used approaches, based on the principle of "chemistry fitting," where single symmetric peaks are used to represent either individual oxidation states or specific compounds. No meaningful conclusions can be drawn from these commonly employed two- or three-component peak fitting (2C and 3C) approaches; the implication being that a large portion of the literature that relies on this approach is flawed. As a significantly more accurate and reliable alternative to "chemistry fitting," we also assess "envelope fitting" (using empirical multiplet structures) and examine its limitations when applying the approach to austenitic stainless steel data. A detailed comparison of these two fitting approaches is described in Part I. For other elements such as Cr 2p, the problems associated with using single components to represent oxidation states or compounds are not as severe. It was found that it does not impact binding energy measurements, but does influence relative intensities, which will have a flow-on effect for oxide thickness calculations and obtaining a correct understanding of the surface more broadly. [ABSTRACT FROM AUTHOR]

Published

2024

35. Fracture strain improving via structural austenitic stainless steel-coated 22MnB5 plates.

Author

Lv, Jiashun, Yu, Pengchao, Tian, Maoqing, Zhao, Zhuo, and Zhou, Yanwen

Subjects

AUSTENITIC stainless steel, ION bombardment, INTERMETALLIC compounds, SUBSTRATES (Materials science), MAGNETRON sputtering

Abstract

A total of 316 austenitic stainless steel (ASS) coatings were deposited on 22MnB5 press-hardening steel plates by varying the substrate bias voltages using a magnetron sputtering technique and quenched in a flat mold with cooling water. The substrate bias current and ion-bombardment energy densities increased up to 0.5 mA/mm2 and 50 J/mm2 at a high voltage of −100 V, and, therefore, the variations in the coatings' morphologies were owing to the increases in the ion bombardment. The porous bulk pattern appeared in the quenched ASS coating at −100 V, clearly different from the porous columnar structure of the others at −50 and −75 V. The γ-Fe and α-Fe phases were observed from the diffraction peaks, presented the ASS coating and 22MnB5 substrate, respectively. There was no intermetallic compound (IMC) peak detected. In addition, the diffusion layer of the quenched ASS-coated plate was observed, in which its morphology was different from the quenched martensite (M) plate, and proved to be the α-Fe microstructure by the very low α-Fe peak at the standard (110) position. The bright image of TEM and the select area electron diffraction pattern indicated the nanostructure of the quenched ASS coating. The nanohardness of the ASS coating, diffusion layer, and M plate (7.36, 3.60, and 6.25 GPa, respectively) was detected, indirectly proving an α-Fe structure of the diffusion layer. The fracture angles of the 316-coated plates significantly improved from 51.82° at −50 V, 53.77° at −75 V to 57.38° at −100 V, as the ASS structure changed to be porous bulk pattern. The clearance of IMC, coating's porous bulk pattern, and the low hardness α-Fe diffusion layer benefited for the fracture strain by lengthening the pathway of the crack's development and blocking the further crack's propagation, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

36. Qualification of Austenitic Stainless Steels for the Development of Load-Sensitive Material Sensors.

Author

Gansel, René, Quanz, Markus, Lohrengel, Armin, Maier, Hans Jürgen, and Barton, Sebastian

Subjects

AUSTENITIC stainless steel, ELECTROMAGNETIC testing, NONDESTRUCTIVE testing, BENDING stresses, TENSILE tests, EDDY current testing

Abstract

To detect mechanical overloads on the component directly in operation, a metastable material can be used as a load-sensitive sensor when combined with an eddy current testing system. In order to find a suitable metastable sensor material that exhibits microstructural changes at an early stage before fatigue failure, quasi-static tensile tests and cyclic rotating bending tests were carried out with the austenitic stainless steels 1.4301 (2 batches), 1.4305, 1.4541 and 1.4550. For the detection of microstructural changes, electromagnetic testing was used in-situ in the tensile test and ex-situ between the rotating bending test after a pre-defined number of cycles. The investigated materials 1.4301 batch2 and 1.4550 showed the largest signal changes and the lowest austenite stability both in the tensile test and under cyclic bending load. Due to the better mechanical properties, 1.4301 batch2 should be preferred. The order of the austenitic stainless steels tested was similar in terms of transformation behavior in both tests. Thus, the tensile test combined with in-situ electromagnetic testing appears to have potential as a suitable benchmark test for austenite stability. With regard to the cyclic bending stress, an overload of the specimens could be detected for the materials 1.4301 batch2, 1.4305, 1.4541 and for the 1.4550 on the basis of a significant amplitude change. At low bending stresses, uncritical for structural integrity, no increase in amplitude was measured. The results have shown that an early detection of overloads is possible with several materials, however, the potential for detecting overloads varies between materials and also between individual batches. In addition, it has been observed that as the bending stress increases, the gradient of the change in amplitude over the number of cycles increases as well. Thus, with a known number of cycles, it could be possible to classify the previous load spectrum based on the difference in amplitude between two measurements. [ABSTRACT FROM AUTHOR]

Published

2024

37. Effect of Cobalt Addition on the Evolution of Austenite and ε-Martensitic Transformation during Loading of 201 Stainless Steel.

Author

Quyen, H. T. N., Khanh, P. M., and Hai, N. H.

Subjects

AUSTENITIC stainless steel, PERITECTIC reactions, DENDRITES, STAINLESS steel, AUSTENITE

Abstract

In this study, austenite formation in 201 austenitic stainless steel was observed in two steps during solidification. Initially, austenite (γ1) precipitated and grew on δ-ferrite during the peritectic reaction (δ + liquid → γ1) and formed directly from the residual liquid (γ2). With the addition of Co, from 0.09 to 0.51 wt.%, the dendrite morphology of ferrite changed from columnar dendritic to equiaxed dendritic. Primary ferrite phase morphology changes resulted in an austenite microstructure composed of a uniform dispersion of fine grains. Both ε-martensite (hcp) and α′-martensite (bct) were present in the microstructure due to the deformation of austenite particles by the impact force. The impact toughness increased by 33% as the cobalt content increased to 0.51 wt.%. [ABSTRACT FROM AUTHOR]

Published

2024

38. Improvement of Stress Corrosion Cracking Resistance of Shear Cut 304L Stainless Steel through Laser Shock Peening.

Author

Gupta, R. K., Rai, A. K., Nagpure, D. C., Biswal, R., Ganesh, P., Rai, S. K., Ranganathan, K., Bindra, K. S., and Kaul, R.

Subjects

LASER peening, STRESS corrosion cracking, AUSTENITIC stainless steel, RESIDUAL stresses, STAINLESS steel corrosion

Abstract

The present study reports the effect of laser shock peening (LSP) on stress corrosion cracking (SCC) behavior of the shear cut surfaces of type 304L stainless steel. The LSP is carried out on as shear cut surface of SS 304L steel at a fixed laser power density of 3.53 GW cm−2 with multiple passes, i.e., double and triple. The preliminary investigation showed that as shear cut surfaces of SS 304L possess a very high tensile residual stresses of the order of 450-700 MPa and hardness 400 HK0.1. The LSP treatment with double and triple pass led to the generation of high compressive residual stress of the order of − 200, and − 250 MPa as compared to as cut shear surfaces. Microscopic analysis revealed that the shear cut surfaces, after double and triple LSP treatment exhibited significantly reduced susceptibility to the SCC in chloride environment after 8-hour test. The results of the present study recommend that LSP treatment can acts as protector of the product and components of austenitic stainless steel with sheared cut surfaces stored for long time in susceptible corrosive environment. This way a huge loss to the nuclear and process industries can be minimized. [ABSTRACT FROM AUTHOR]

Published

2024

39. Prediction of Surface Microstructure, Grain Size, Martensite Content, and Microhardness of 316L Austenitic Stainless Steel in Surface Mechanical Grinding Treatment Process.

Author

Yang, Chongwen, Jiang, Xinli, Zhang, Wenqian, and Wang, Xuelin

Subjects

AUSTENITIC stainless steel, MARTENSITIC transformations, SURFACE hardening, STRAIN hardening, GRAIN size

Abstract

Surface mechanical grinding treatment (SMGT) is a promising surface strengthening technique by exerting gradient microstructure, phase transformation, and work hardening on the surface layer. However, due to the large strain and high strain rate, it is difficult to evaluate the microstructure attributes of the SMGT-processed surface. In the present work, an analytical model is developed to correlate the SMGT processing parameters to the surface microstructure, grain size, martensite content, and microhardness. Firstly, the processing force and distributions of stress and strain are identified by developing a multi-physics framework for SMGT process. Afterward, the surface grain refinement induced by dynamic recrystallization (DRX) is modeled by cellular automata (CA) method. The grain size along with the depth of cross section is predicted by Johnson–Mehl–Avrami–Kolmogorov (JMAK) DRX model. The martensite content is evaluated according to the strain-induced martensitic transformation kinetics. Ultimately, accounting for both microstructure alteration and phase transformation, the microhardness variation is predicted. To verify the results derived by analytical model, series of confirmatory experiments were carried out on 316L austenitic stainless steel. The SEM was utilized to observe the surface microstructure of the processed samples. The martensitic transformation was characterized by EBSD and XRD methods. The microhardness measurements were taken on an automatic Vickers hardness tester. It was obtained from the results that the surface microstructure, gradient grain size, phase content, and microhardness distribution derived from predictive model were consistent well with the experimental measurements. The confirmed simulation model is further utilized to understand how the process factors, i.e., ball size and penetration depth, influence the evolution of microstructure. It is found that the finer grain structure, higher martensite content, and microhardness can be obtained by adopting smaller ball and larger penetration depth. [ABSTRACT FROM AUTHOR]

Published

2024

40. A critical discussion of elasto-visco-plastic self-consistent (EVPSC) models

Author

Bohye Jeon, Youngung Jeong, and Carlos N. Tomé

Subjects

Elasto-visco-plastic modeling, Crystal plasticity, Austenitic stainless steel, Mining engineering. Metallurgy, TN1-997

Abstract

Two recently proposed elasto-visco-plastic self-consistent (EVPSC) models, based on solving for stress or stress increment, are discussed, and their results are compared with the ones of the visco-plastic self-consistent (VPSC) approach. The advantages and shortcomings of the models are demonstrated, with emphasis on how the grain responses are affected by the time increment and inclusion-medium interaction strength used. Experimental data obtained for an FCC stainless steel is used as the benchmark system for performing the simulations and assessing the reliability of the results. Predictions of stress-strain response of the aggregate, standard deviations in intergranular stress and strain rate, along with the evolution of internal lattice strain are presented and compared, with special focus on their dependence on the incremental approach chosen. We find that the chosen time increment may significantly affect predicted grain responses. To avoid such effect a method based on using two separate time increments is proposed, one for approximating the stress rate and another for actual integration of stress, strain, and state variables. The proposed method successfully eliminates the dependence of results on the time increment used, thus allowing more reliable computations while preserving the computational efficiency of the elasto-visco-plastic model.

Published

2024

41. Stacking fault energy during DRV-DRX competition in high-nitrogen austenitic stainless steel used in orthopedic implants

Author

Joao Marcos da Silva Nunes, Marcelly Cristiny Nunes de Carvalho, Maria Veronica Goncalves Rodrigues, Joao Carlos Ferreira, Kayron Lima Silva, Antonio Enrique Salas Reyes, Marcos Natan da Silva Lima, Fulvio Siciliano, Gedeon Silva Reis, Hamilton Ferreira Gomes de Abreu, Samuel Filgueiras Rodrigues, and Eden Santos Silva

Subjects

Austenitic stainless steel, Thermomechanical processing, Stacking fault energy, Constitutive models, Dynamic softening mechanism, Mining engineering. Metallurgy, TN1-997

Abstract

High-nitrogen (high-N) austenitic stainless steels (ASS) are used in orthopedic implants due to their mechanical properties, human biocompatibility, and affordable cost. However, the high content of (Ni–Nb–N)-rich precipitates can cause allergic reactions and significant challenges in the manufacturing of prostheses. This study investigates the competition between work hardening (WH), dynamic recovery (DRV), and dynamic recrystallization (DRX) during the physical simulation of an ASTM F-1586 steel by thermomechanical processing, using the Kocks-Mecking and Avrami constitutive models. The parameters were obtained through continuous isothermal torsion tests at the temperature range of 900–1200 °C, strain rates between 0.01 and 10 s−1 and a total deformation of 4.0. Determined by compositional-analytical methods, the stacking fault energy (γsfe) was correlated with the stress level (σi) according to the Uesugi and Dai models. Results indicated a high activation energy for hot deformation (Qdef = 587 kJ/mol), affecting the shape of the curves. The γsfe value varied along the curves, delaying the onset of the DRX (σc = 0.928σp). Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) analyses revealed a direct competition between work-hardened and recrystallized grains in the early part of the curves, due to WH-DRV synergy. After the peak stress (σp), the progress of DRX was slow, with the Avrami exponent (n) between 1.1 and 1.9, completing only after large deformations (σss = 0.714σp). The moderate γsfe value (69 mJ/m2) and fine precipitates of the Z-phase (CrNbN) (

Published

2024

42. Breaking the strength-ductility trade-off in austenitic stainless steel at cryogenic temperatures: Mechanistic insights

Author

Digvijay Singh, Fumiyoshi Yoshinaka, Susumu Takamori, Satoshi Emura, and Takahiro Sawaguchi

Subjects

Strength-ductility balance, Austenitic stainless steel, Martensitic transformation, Deformation twinning, Strain-hardening rate, Mining engineering. Metallurgy, TN1-997

Abstract

At cryogenic temperatures, 316L austenitic stainless steel (ASS) exhibits remarkable strength while retaining high ductility, defying the conventional stress-strain trade-off. Despite extensive studies documenting the cryo-tensile properties of ASSs, the underlying mechanisms behind this phenomenon remain largely unexplored. This study systematically re-examines the tensile properties of 316L stainless steel and the associated mechanisms across a range of low temperatures (293 K, 223 K, 123 K, and 77 K). The reasons for the superior stress-strain balance (∼80 % GPa) are discussed using results from electron backscatter diffraction (EBSD) microstructure characteristics. The results undoubtedly suggest that the transformation mechanisms, specifically the shift from deformation twinning to martensitic transformation (γ → ε → α′), play a crucial role in enhancing elongation at cryogenic temperatures. At these temperatures, the Gibbs free energy difference between ε-martensite and γ-austenite approaches zero, resulting in slow martensite growth. The stress-strain curves at low temperatures satisfy the Considère criterion, indicating delayed necking under these conditions. This behavior is ascribed to the presence of various hierarchical microstructures, including ε, α′, γ-twins, ε-twins and their intersections, which act as sources of work hardening. This study provides new insights into deformation behavior of ASSs under cryogenic conditions.

Published

2024

43. Influence of crystallographic textures on the hydrogen embrittlement resistance of austenitic stainless steel

Author

Jeong-Chan Lee, Dae Cheol Yang, Min Young Sung, Nam-Seok Kim, Hyung-Ki Park, Miri Choi, Young Do Kim, Seok Su Sohn, and Chang-Soo Park

Subjects

Austenitic stainless steel, Hydrogen embrittlement, Texture, Slow-strain-rate tensile (SSRT) test, Hydrogen permeation test, Mining engineering. Metallurgy, TN1-997

Abstract

Hydrogen embrittlement (HE) resistance is a significant concern in austenitic stainless steel (ASS) used for hydrogen transportation and storage. While microstructure-controlled methods to enhance HE resistance have been extensively studied in ferritic steels, comprehensive research on microstructure effects in ASS is lacking. In this study, two 316L ASSs with different microstructures were evaluated for HE resistance using electrochemical hydrogen charging. The steel with abundant in + orientations showed a significant elongation reduction after hydrogen charging. It revealed that, from the hydrogen permeation and thermal desorption analysis (TDA) results, effective diffusivity and activation energy of hydrogen were changed along the crystallographic orientation distributions. Also, transformation induced plasticity (TRIP) and twinning induced plasticity (TWIP) behavior affecting to the HE resistance preferentially formed in grains with and orientations rather than in those with orientation during plastic deformation. Therefore, the study suggests that reinforcing the microstructure is advantageous for improving HE resistance in 316L ASS.

Published

2024

44. Clarifying the effect of irradiation and thermal treatment on the austenitic microstructure and austenitic hardening in austenitic stainless steel weld metal

Author

Xiaodong Gao, Xiaodong Lin, Lining Xu, Yaolei Han, Qunjia Peng, and Lijie Qiao

Subjects

Austenitic stainless steel, Proton irradiation, Austenitic hardening, Microstructural evolution, Atom probe tomography, Mining engineering. Metallurgy, TN1-997

Abstract

The weld cladding on the inner surface of nuclear pressure vessels due to irradiation damage and thermal effect presents to a safety issue. Unfortunately, the effect of irradiation and long-term thermal treatment on the austenitic microstructure and austenitic hardening in austenitic stainless steel weld metals (ASSWMs) remains poorly understood. In this study, the effects of irradiation and thermal treatment on the austenitic microstructures and austenitic hardening of 308L ASSWMs were investigated using nanoindentation, atom probe tomography and transmission electron microscopy. The results suggested that irradiation resulted in the formation of Ni/Si-rich clusters, voids, and Frank loops in austenite, thereby inducing austenitic hardening. Subsequently, thermal treatment decreased the size and the number of Frank loops in irradiated austenite, which had a minor effect on austenitic hardening. However, thermal treatment promoted the growth of Ni/Si-rich clusters and void formation, which have a primary effect on austenitic hardening, thereby enhancing the hardening of irradiated austenite. Furthermore, thermal treatment has little effect on the microstructure and hardening of austenite. Then, irradiation promoted the formation of Ni/Si-rich clusters, voids, and Frank loops in thermally treated austenite, resulting in austenitic hardening. The interaction of irradiation and thermal treatment can promote the formation of voids. The austenitic hardening was mainly due to the contribution of Frank loops, voids, and Ni/Si-rich clusters, which acted as short-range barriers by pin-moving dislocations.

Published

2024

45. Selecting Valves for Hydrogen Service: With hydrogen's evolution into an alternative fuel requiring precise production and storage, selecting the right valves has never been more important.

Author

Hayes, Chuck

Subjects

FACE centered cubic structure, FERRITIC steel, AUSTENITIC stainless steel, HYDROGEN as fuel, GREEN fuels, STAINLESS steel

Abstract

The article discusses the importance of selecting the right valves for hydrogen service due to the increasing use of hydrogen as an alternative fuel. Hydrogen molecules are challenging to contain, and leaks can pose safety risks and lead to system failure. The article emphasizes the need for high-performance valves that can withstand pressures, stress, and vibration in hydrogen systems to ensure safety and reliability. Additionally, it highlights the significance of using compatible components designed specifically for hydrogen use to maintain safe and efficient production and storage systems. [Extracted from the article]

Published

2024

46. Behavior, failure analysis, and effectiveness of mechanical stress improvement process in residual stress relaxations in butt-welded austenitic piping using a numerical simulation approach.

Author

Zeghida, Chouaib, Guedri, Abdelmoumene, Allaoui, Abdelhalim, Tlili, Samira, Belyamna, Mohammed Amine, Suleiman, Rami K., and Meliani, Mohammed Hadj

Abstract

The mechanical stress improvement process (MSIP) is a crucial technique employed in nuclear power plants to enhance the reliability and safety of piping systems, which are susceptible to stress corrosion cracking. This study aims to address the significant challenge of preventing such failures by effectively eliminating residual tensile stresses present in weldments. By mitigating these stresses, MSIP helps prevent the formation of new cracks and slows the progression of existing ones in piping systems. This approach induces beneficial compressive stresses along the inner surface of the pipe near the weld, including the molten and heat-affected zones. Multiple cases were analyzed through numerical simulations to assess the efficacy of MSIP in reducing stress concentrations and enhancing structural integrity. Furthermore, the dimensions and placement of the MSIP tool were evaluated, revealing that the optimal position and width of the clamp are 30 mm from the weld line (WL) and 75 mm, respectively. The results indicate that the WL region experiences significantly high compressive stresses, which gradually decrease within a 10-mm distance on each side of the WL. This research contributes valuable insights into the application of MSIP in improving the durability and safety of nuclear piping systems. [ABSTRACT FROM AUTHOR]

Published

2024

47. Bending fatigue behavior of metastable and stable austenitic stainless steels with different surface morphologies.

Author

Zhu, Tong, Smaga, Marek, Bozoglu, Mustafa, Sala, Siva Teja, Kashaev, Nikolai, Antonyuk, Sergiy, and Beck, Tilmann

Subjects

*AUSTENITIC stainless steel, *STAINLESS steel fatigue, *FATIGUE life, *AUSTENITIC steel, *MATERIAL fatigue, *LASER peening

Abstract

The surface morphology has a significant influence on the fatigue behavior of components. For austenitic stainless steels (ASSs), this issue is even more pronounced due to their metastability. Based on the complex deformation mechanisms of metastable ASSs, which include dislocation slip, deformation twinning, and deformation‐induced martensitic phase transformation, the metastable stainless steel AISI 347 was investigated in this study together with the stable AISI 904L as a reference material. Four‐point bending fatigue tests with load ratio R = 0.1 and testing frequency f = 10 Hz at ambient temperature were carried out on specimens with five technically relevant surface morphologies: mechanical polished, milled, microshot peened, laser shock‐peened, and ultrasonic modified. Systematic material characterizations were carried out to elucidate the crucial role of surface roughness and deformation‐induced α′‐martensite in the fatigue behavior of both metastable and stable materials. While surface roughness is a well‐known key factor in conventional fatigue cases, deformation‐induced martensite layers implemented by various surface modification methods were proven to improve the fatigue life in metastable austenitic steels, opening new perspectives to extend the lifetime of ASS components. Highlights: Investigated surface morphology's impact on four‐point bending fatigue in ASSs.Diverse surface treatments to achieve various surface morphologies. [ABSTRACT FROM AUTHOR]

Published

2024

48. Development and Validation of Radiation Embrittlement Prediction Model of Austenitic Stainless Steel

Author

JIA Lixia, WANG Dongjie, HE Xinfu, WU Shi, YANG Wen

Subjects

internal component, austenitic stainless steel, fracture toughness, irradiation embrittlement, prediction model, Nuclear engineering. Atomic power, TK9001-9401, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

Austenitic stainless steels are used as important structural materials in nuclear reactors due to their high fracture toughness. In the process of long-term service, austenitic stainless steel will be subjected to neutron irradiation to cause microstructural changes, such as the formation of dislocation loop and precipitation, which will lead to a decrease in fracture toughness and affect its service behavior. The irradiation embrittlement behavior of austenitic stainless steels, i.e., the reducing of fracture toughness, should be considered in the life extension of the nuclear reactor. According to the relationship between fracture toughness and tensile properties, the prediction of fracture toughness after irradiation can be realized by using the tensile test data after irradiation. In order to predict the irradiation embrittlement bahavior of austenitic stainless steels, firstly, according to the correlation relationship between irradiation hardening and irradiated microstructure information, the post-irradiation microstructure information was used to predict the tensile yield stress after irradiation. Then, according to the correlation relationship of irradiation hardening and fracture toughness, the uniform elongation, yield stress/flow stress and fracture toughness before irradiation, combined with the yield stress/flow stress and uniform elongation obtained after irradiation, the prediction of fracture toughness of austenitic stainless steel after irradiation was realized, that is, the prediction of irradiation embrittlement of austenitic stainless steel was realized. Through the above steps, the fracture toughness of austenitic stainless steel can be directly predicted based on the microstructure information after irradiation. By using the microstructure information from experimental data obtained in the literature, the predicted fracture toughness was basically consistent with the experimental value of fracture toughness of austenitic stainless steel reported in the literature, which verified the effectiveness of the model. The results show that the dislocation loop formed after irradiation are the main microstructures that cause the irradiation embrittlement of austenitic stainless steels. In the future, the irradiation embrittlement of austenitic stainless steel can be predicted based on the microstructure information obtained by experimental test or simulation calculation, which provides a theoretical guidance for reactor life extension.

Published

2024

49. Analysis, Assessment, and Mitigation of Stress Corrosion Cracking in Austenitic Stainless Steels in the Oil and Gas Sector: A Review

Author

Mohammadtaghi Vakili, Petr Koutník, Jan Kohout, and Zahra Gholami

Subjects

stress corrosion cracking, mechanism, mitigation, austenitic stainless steel, Physics, QC1-999

Abstract

This comprehensive review examines the phenomena of stress corrosion cracking (SCC) and chloride-induced stress corrosion cracking (Cl-SCC) in materials commonly used in the oil and gas industry, with a focus on austenitic stainless steels. The study reveals that SCC initiation can occur at temperatures as low as 20 °C, while Cl-SCC propagation rates significantly increase above 60 °C, reaching up to 0.1 mm/day in environments with high chloride concentrations. Experimental methods such as Slow Strain Rate Tests (SSRTs), Small Punch Tests (SPTs), and Constant-Load Tests (CLTs) were employed to quantify the impacts of temperature, chloride concentration, and pH on SCC susceptibility. The results highlight the critical role of these factors in determining the susceptibility of materials to SCC. The review emphasizes the importance of implementing various mitigation strategies to prevent SCC, including the use of corrosion-resistant alloys, protective coatings, cathodic protection, and corrosion inhibitors. Additionally, regular monitoring using advanced sensor technologies capable of detecting early signs of SCC is crucial for preventing the onset of SCC. The study concludes with practical recommendations for enhancing infrastructure resilience through meticulous material selection, comprehensive environmental monitoring, and proactive maintenance strategies, aimed at safeguarding operational integrity and ensuring environmental compliance. The review underscores the significance of considering the interplay between mechanical stresses and corrosive environments in the selection and application of materials in the oil and gas industry. Low pH levels and high temperatures facilitate the rapid progression of SCC, with experimental results indicating that stainless steel forms passive films with more defects under these conditions, reducing corrosion resistance. This interplay highlights the need for a comprehensive understanding of the complex interactions between materials, environments, and mechanical stresses to ensure the long-term integrity of critical infrastructure.

Published

2024

50. Lap-Shear Performance of Weld-Bonded Mg Alloy and Austenitic Stainless Steel in Three-Sheet Stack-Up

Author

Sunusi Marwana Manladan, Mukhtar Fatihu Hamza, Singh Ramesh, and Zhen Luo

Subjects

Weld-bonding, Resistance spot welding, Austenitic stainless steel, Mg alloy, Failure mode, Ocean engineering, TC1501-1800, Mechanical engineering and machinery, TJ1-1570

Abstract

Abstract With the growing interest in utilizing Mg and austenitic stainless steel (ASS) in the automotive sector, joining them together in three-sheet configuration is inevitable. However, achieving this task presents considerable challenges due to the large differences in their physical, metallurgical and mechanical properties. To overcome these challenges, the feasibility of using weld-bonding to join Mg alloy/ASS/ASS was investigated. The nugget formation, interface characteristics, microstructure and mechanical properties of the joints were investigated. The results show that the connection between the Mg alloy and upper ASS was achieved through the combined effect of the cured adhesive and weld-brazing in the weld zone. On the other hand, a metallurgical bond was formed at the ASS/ASS interface. The Mg nugget microstructure exhibited fine columar grains composed predominantly of primary α-Mg grains along with a eutectic mixture of α-Mg and β-Mg17Al12. The nugget formed at the ASS/ASS interface consisted largely of columnar grains of austenite, with some equiaxed dendritic grains formed at the centerline of the joint. The weld-bonded joints exhibited an average peak load and energy absorption of about 8.5 kN and 17 J, respectively (the conventional RSW joints failed with minimal or no load application). The failure mode of the joints changed with increasing welding current from interfacial failure via the Mg nugget/upper ASS interface to partial interfacial failure (part of the Mg nugget was pulled out of the Mg sheet). Both failure modes were accompanied by cohesive failure in the adhesive zone.

Published

2024