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1	Corrosion fatigue crack propagation behaviour of a high strength low alloy steel in a synthetic sea water environment Millar, Peter G. January 1986 (has links) The corrosion fatigue crack propagation behaviour of a high strength low alloy steel, N-A-XTRA 70, in a synthetic sea water solution was tested using S. E. N. specimens subjected to a loading frequency of 0.1 Hz and a load ratio of 0.6. In order to simulate the conditions encountered by a thumbnail type crack several specimens from each of the microstructural types tested, namely parent plate, heat affected zone and heat treated material, had their crack sides covered by transparent plastic covers. Severe overprotection and slight underprotection conditions were produced using cathodic protection potentials of -1400, -1300, -1200 and -700 mV (S. C. E. ). The Paris relationship da/dN = CLKm was found to be a useful tool in describing the crack propagation rate data. Results obtained, presented in the form of plots of log da/dN against log AK, show that for parent plate, H. A. Z. and heat treated material, covering the crack sides of specimens produces enhanced corrosion fatigue crack propagation rates, at cathodic protection potentials of -1400 and -1300 mV (S. C. E. ), when compared to non covered specimens. This trend was also true for H. A. Z. specimens at a potential of -700 mV (S. C. E. ). For parent plate specimens, however, covering the crack sides at a potential of -700 mV (S. C. E. ) produced reduced crack propagation rates over non covered specimens. It is believed restriced oxygen access may account for these results. Plots of the Paris exponent m and constant C for the three microstructures tested produced three lines of the form m= alnC +b where a and b were found to be dependent upon material parameters. Comparison of results with BS 4360: 50D revealed that N-A-XTRA 70 exhibited superior fatigue performance when tested in air but behaved worse under conditions of free corrosion. 669 Corrosion of low alloy steels
2	Bainitic steels for railway applications Callender, William Robert January 1983 (has links) No description available. 669
3	Dependence of Strength on Corrosion-Fatigue Resistance of AISI 4130 Steel Evins, Joseph Lee 09 April 2004 (has links) Automobile components are often exposed to aggressive environments as a result of aqueous salts from the road coming into contact with unprotected steel. This situation greatly reduces both the life and the appearance of the affected parts. Ultra-high strength steel parts are suspected to exhibit poor corrosion-fatigue properties and be more susceptible to corrosion in general. In this study, the effect of strength level on the decrease in fatigue life of AISI 4130 steel when exposed to an aqueous salt solution is quantified. The observed mechanical properties including corrosion-fatigue behavior are examined with consideration to different microstructural characteristics resulting from heat treatments to the steel. The hardness and tensile properties of the test material were characterized before fatigue testing. Fatigue tests were completed in both air and salt solution to determine the effect on fatigue life of the latter environment. Following fatigue testing, the fracture surface was examined using a scanning electron microscope (SEM) to determine the failure mode. Six strength levels of AISI 4130 steel were investigated ranging from 837 to 1846 MPa (121 268 ksi). The frequency of loading used for corrosion-fatigue tests was 1 Hz and the stress ratio for each test was constant at R = 0.1. The corrosion-fatigue tests consisted of the specimen being submerged in an aqueous solution of sodium chloride, calcium chloride, and sodium bicarbonate and fatigued until failure. The solution was maintained at room temperature with constant aeration to ensure constant oxygen levels. The parameters of interest were the applied loads and the cycles to failure. There were four primary findings of the study. First, decreases in fatigue life of the material caused by the corrosive environment ranged from 100% in the lowest strength level to 190% in the higher strength levels. This result showed that higher strength in this steel corresponds to increasing detriment to fatigue life when the material is exposed to an aqueous salt environment. Second, evidence was found that the salt solution lowered the fatigue limit for each strength level studied in this material. All specimens that were tested in the corrosive environment failed in less than 150,000 cycles, while some specimens fatigued in the air environment experienced run-outs at over 106 cycles. Third, the decrease in fatigue life was attributed to the presence of martensite in the structure of the steel. It was noted that the higher the martensite content, the larger the decrease in fatigue life when exposed to the corrosive environment. Finally, the fracture surfaces of fatigued specimens revealed that a similar cracking mode was present for each strength level in both environments. Enhanced crack initiation was, therefore, assumed to be the cause of the decrease in fatigue life between the air and aqueous salt environments. Corrosion Fatigue AISI 4130 Low alloy steel
4	Microstructural characterisation and remanent creep life evaluation of a 12CrMoVNb steel Chikwanda, Hilda Kundai January 1994 (has links) No description available. 669
5	Etude et optimisation de la solidification d’aciers faiblement alliés lors du process de fonderie par inoculation. / Study and optimization of the solidification of low-alloy steels during the process of foundery by inoculation. Nicoli, Cécile 17 May 2019 (has links) L’objectif de ce travail consiste à améliorer les propriétés mécaniques d’un acier faiblement allié à bas carbone (0,2%) sans recours à des procédés de métallurgie secondaire onéreux. Pour cela, un processus d’inoculation, déjà utilisé lors de l’élaboration des fontes, est transposé à notre nuance d’acier. Il consiste à ajouter des éléments en très faible quantité dans l’acier liquide pour en modifier le processus de solidification donc la microstructure et par conséquent les propriétés de l’acier, dont la résilience. L’ajout d’éléments en très faible quantité ne modifie pas la nuance d’acier. Ils doivent être ajoutés en fin de fusion du métal sous forme de poudre dans le jet de coulée. Les effets de ces éléments se verront sur la microstructure notamment au niveau des inclusions et de la taille des grains. Le « bon candidat » est un élément qui conduira à une répartition homogène d’inclusions de petites tailles et de forme sphérique. Il doit aussi permettre de réduire la taille des grains. Ces modifications de structure sont supposées améliorer les propriétés mécaniques de l’acier et notamment la résistance aux chocs. Une pièce de référence est réalisée pour pouvoir en étudier la microstructure. La forme retenue est un lingot parallélépipédique dimensionné à l’aide d’un logiciel de simulation de coulée afin de prévenir des principaux défauts de fonderie. La taille est adaptée à l’échelle laboratoire (capacité four 120 kg). Les charges de fusion correspondant à la nuance étudiée sont fournies par l’entreprise partenaire de la thèse, SAFE Metal. La première étape est d’obtenir un bain convenablement désoxydé ; c’est-à-dire ajouter de l’aluminium afin de piéger l’oxygène dissous pour l’évacuer. Pour mettre en évidence d’éventuels effets significatifs des différents inoculants testés, il faut partir d’un échantillon de référence contenant un nombre d’inclusions relativement élevé. Ceci est obtenu en ajoutant du soufre dans le bain liquide. Cet élément agit directement sur le nombre d’inclusions présentes dans l’acier en formant des sulfures. Pour passer à l’étape d’inoculation il a fallu créer un outillage spécifique pouvant s’adapter à l’échelle du laboratoire. Des essais sont ensuite réalisés avec différents produits à des concentrations variables. Les échantillons obtenus sont analysés par différentes techniques : analyse chimique de l’acier (spectrométrie étincelle et ICP), analyse de microstructure et de la taille de grains (par micrographie optique) et le comptage inclusionnaire. En ce qui concerne ce dernier point qui consiste à détecter les inclusions, à les compter et à les classer par leur nature, leur forme et leur taille, deux possibilités existent. Soit à l’aide d’un microscope optique mais les risques d’erreur sont importants et le processus est long et fastidieux, soit à l’aide d’un logiciel spécifique (AZtec) couplé à un microscope électronique à balayage (MEB). C’est ce choix qui a été fait, car outre le fait qu’il permette un gain de temps considérable grâce à une automatisation du processus, il est possible de connaître via une sonde EDS, la composition chimique de chaque particule. Pour tous les produits testés, il a été montré que l’inoculation n’avait que peu d’effet sur la taille des inclusions et qu’elles deviennent plus complexes en contenant plusieurs éléments chimiques. Pour certains produits, on voit apparaître des amas d’inclusions. Ces amas sont susceptibles de favoriser la fragilité de l’acier en formant des amorces de fissuration. Pour d’autres, les inclusions diminuent nettement, ont une forme globulaire et la taille des grains est affinée. Ces effets ont tendance à améliorer les propriétés mécaniques de ces aciers. La teneur d’introduction de l’inoculant est aussi déterminée pour un maximum d’efficacité. L’inoculant le plus important pourra être utilisé pour une possible industrialisation. / The objective of this work is to improve the mechanical properties of a low-carbon steel (0.2%) without the use of expensive secondary metallurgy processes. For this, a method of inoculation, already used during the development of the cast iron, is transposed to our steel grade. It consists in adding very small quantities in liquid steel in order to modify the solidification process, thus the microstructure and consequently the properties of the steel, especially resilience. The addition of elements in very small quantities does not modify the grade of steel. They must be added at the end of melting of the metal in the form of powder in the casting stream. The effects of these elements will be seen on the microstructure, particularly in terms of inclusions and grain size. The "good candidate" is an element that will lead to a homogeneous distribution of inclusions of small size and spherical shape. It must also make it possible to reduce the size of the grains. These structural modifications are supposed to improve the mechanical properties of the steel and in particular the impact resistance. A reference piece is made to study the microstructure. The retained shape is a parallelepiped ingot sized using a casting simulation software to prevent major foundry defects. The size is adapted to the laboratory scale (furnace capacity 120 kg). The load corresponding to the grade studied are provided by the SAFE Metal, the partner company. The first step is to obtain a suitably deoxidized bath; that means adding aluminum in order to trap the dissolved oxygen and to evacuate it. To demonstrate any significant effects of the various inoculants tested, it is necessary to start from a reference sample containing a relatively high number of inclusions. This is achieved by adding sulfur to the liquid bath. This element acts directly on the number of inclusions present in the steel by forming sulphides. For the inoculation stage, it was necessary to create specific tools that could be adapted to the laboratory scale. Trials are then carried out with different products at varying concentrations. The samples obtained are analyzed by various techniques: chemical analysis of steel (spark spectrometry and ICP), microstructure and grain size analysis (optical micrograph) and inclusion counting. In order to detect inclusions, count and classify them by their nature, shape and size, two possibilities exist. Either using an optical microscope but the risks of error are significant and the process is long and tedious, either using a specific software (AZtec) coupled to a scanning electron microscope (SEM). It is this choice that was made, because besides the fact that it allows a considerable saving of time thanks to an automation of the process, it is possible to know via an EDS probe, the chemical composition of each particle. For all the products tested, it was shown that inoculation had little effect on the size of the inclusions and that they became more complex by containing several chemical elements. For some products, clusters of inclusions appear. These clusters are likely to promote the fragility of steel by forming cracking primers. For others, the inclusions decrease sharply, have a globular shape and the grain size is refined. These effects tend to improve the mechanical properties of these steels. The introductory content of the inoculant is also determined for maximum effectiveness. The most efficient inoculant can be used for a possible industrialization. Inoculation Acier Aciers faiblement alliers Inoculation Steels Low-Alloy steels
6	Ab-Initio and Molecular Dynamics Simulations Capturing the Thermodynamic, Kinetics, and Thermomechanical Behavior of Galvanized Low-Alloy Steel Aslam, Imran 14 December 2018 (has links) A seven-element Modified Embedded Atom Method (MEAM) potential comprising Fe, Mn, Si, C, Al, Zn, and O is developed by employing a hierarchical multiscale modeling paradigm to simulate low-alloy steels, inhibition layer, and galvanized coatings. Experimental information alongside first-principles calculations based on Density Functional Theory served as calibration data to upscale and develop the MEAM potential. For calibrating the single element potentials, the cohesive energy, lattice parameters, elastic constants, and vacancy and interstitial formation energies are used as target data. The heat of formation and elastic constants of binary compounds along with substitutional and interstitial formation energies serve as binary potential calibration data, while substitutional and interstitial pair binding energies aid in developing the ternary potential. Molecular dynamics simulations employing the developed potentials predict the thermal expansion coefficient, heat capacity, self-diffusion coefficients, thermomechanical stress-strain behavior, and solid-solution strengthening mechanisms for steel alloys comparable to those reported in the literature. Interfacial energies between the steel substrate, inhibition layer, and surface oxides shed light on the interfacial nanostructures observed in the galvanizing process. first-principles MEAM low-alloy steels inhibition layer galvanized coating
7	Microstructure-Property Relations Throughout The Powder Metallurgy Process Tucker, Laura Arias 15 December 2007 (has links) To produce crack free powder compacts with desirable mechanical properties and uniform densities, a predictive finite element simulation of the powder metallurgy process is necessary (compaction and sintering). The finite element method, through the use of appropriate constitutive material models captures the microstructure-property history after compaction and sintering. A FC-0205 cylinder and FC-0208 automotive main bearing cap were compacted to investigate the microstructure changes at different locations within the parts. Measurements of the pore volume fraction, pore size, pore nearest neighbor, pore aspect ratio, and grain size were performed after compaction for the cylinder after compaction and after compaction and sintering for the MBC. An image analysis methodology was created to measure density in the main bearing cap, and to validate future model results. A comparison between the image analysis and the Archimedes immersion methods demonstrated the reliability of the methods. powder metallurgy microstructure characterization density measurements low alloy steel
8	A Study of the Physical and Chemical Processes Involved in the Electroslag Remelting of a Low Alloy Steel Whittaker, Donald 08 1900 (has links) Low alloy steel electrodes have been electroslag remelted using alternating and direct current power sources. Changes in electrical contact between the furnace mould wall and mould base provided an improved understanding of the thermal ,and chemical processes characteristic of the remelting technique. 1m ion regeneration process has been postulated to account for current flow within the slag phase. Observed changes in furnace heating effects, electrode droplet sizes and in slag and metal compositions have be,en related to overtensions impressed on the slag/electrode and slag/ingot boundaries. The desulfurization reaction has been studied in detail. / Thesis / Doctor of Philosophy (PhD) Electroslag Remelting Low Alloy Steel electrical contact slag phase
9	High Strain Rate Characterization of Advanced High Strength Steels Thompson, Alan January 2006 (has links) The current research has considered the characterization of the high strain rate constitutive response of three steels: a drawing quality steel (DDQ), a high strength low alloy steel (HSLA350), and a dual phase steel (DP600). The stress-strain response of these steels were measured at seven strain rates between 0. 003 s<sup>-1</sup> and 1500 s<sup>-1</sup> (0. 003, 0. 1, 30, 100, 500, 1000, and 1500 s<sup>-1</sup>) and temperatures of 21, 150, and 300 ??C. In addition, the steels were tested in both the undeformed sheet condition and the as-formed tube condition, so that tube forming effects could be identified. After the experiments were performed, the parameters of the Johnson-Cook and Zerilli-Armstrong constitutive models were fit to the results. <br /><br /> In order to determine the response of the steels at strain rates of 30 and 100 s<sup>-1</sup>, an intermediate rate tensile experiment was developed as part of this research using an instrumented falling weight impact facility (IFWI). An Instron tensile apparatus was used to perform the experiments at lower strain rates and a tensile split-Hopkinson bar was used to perform the experiments at strain rates above 500 s<sup>-1</sup> <br /><br /> A positive strain rate sensitivity was observed for each of the steels. It was found that, as the nominal strength of the steel increased, the strain rate sensitivity decreased. For an increase in strain rate from 0. 003 to 100 s<sup>-1</sup>, the corresponding increase in strength at 10% strain was found to be approximately 170, 130, and 110 MPa for DDQ, HSLA350, and DP600, respectively. <br /><br /> The thermal sensitivity was obtained for each steel as well, however no correlation was seen between strength and thermal sensitivity. For a rise in temperature from 21 to 300 ??C, the loss in strength at 10% strain was found to be 200, 225, and 195 MPa for DDQ, HSLA350, and DP600, respectively for the 6 o?clock tube specimens. <br /><br /> For all of the alloys, a difference in the stress ? strain behaviour was seen between the sheet and tube specimens due to the plastic work that was imparted during forming of the tube. For the DP600, the plastic work only affected the work-hardening response. <br /><br /> It was found that both the HSLA350 and DDQ sheet specimens exhibited an upper/lower yield stress that was amplified as the strain rate increased. Consequently the actual strength at 30 and 100 s<sup>-1</sup> was obscured and the data at strain rates above 500 s<sup>-1</sup> to be unusable for constitutive modeling. This effect was not observed in any of the tube specimens or the DP600 sheet specimens <br /><br /> For each of the steels, both the Johnson-Cook and Zerilli-Armstrong models fit the experimental data well; however, the Zerilli-Armstrong fit was slightly more accurate. Numerical models of the IFWI and the TSHB tests were created to assess whether the experimental results could be reproduced using the constitutive fits. Both numerical models confirmed that the constitutive fits were applied correctly. Mechanical Engineering strain rate steel dual phase high strength low alloy characterization
10	Influência da corrente elétrica, da força de recalque e do tratamento térmico de revenimento na soldagem topo-a-topo por centelhamento de serras de fita bimetálica. / Influence of the electrical current, upset force and tempering heat treatment in the flash butt welding of bimetal band saw blades Gomes Filho, Omar 20 August 2007 (has links) O desempenho de serras de fita bimetálica depende principalmente das características da junção de suas extremidades, executada pelo processo de soldagem topo-a-topo por centelhamento. Este é um processo de soldagem por resistência, constituído por um aquecimento elétrico, seguido por um rápido forjamento dos materiais. O presente trabalho tem como objetivo, estudar a influência da variação da corrente elétrica, força de recalque e tratamento térmico de revenimento nas microestruturas e propriedades mecânicas das juntas soldadas topo-a-topo por centelhamento. Neste estudo, foram utilizadas amostras de serras de fita bimetálica de 27 mm de largura e 0,9 mm de espessura. O material é um composto bimetálico constituído por aço rápido M42 para os dentes, soldado a um corpo de aço carbono de baixa liga e alta resistência D-6a. As microestruturas e as propriedades mecânicas das amostras soldadas foram investigadas. Foi observado que os parâmetros de soldagem e o revenimento afetam as propriedades mecânicas. A dureza na seção transversal à linha central da solda apresentou valores levemente superiores à respectiva dureza na seção longitudinal. Amostras não revenidas resultaram em maior resistência à tração, associada ao parâmetro de menor temperatura de revenimento. Ficou evidenciado que o revenimento reduziu a dureza e a resistência à tração de todas as amostras. / The performance of bimetal band saw blades depends mainly on the features of joining their ends, carried out by flash butt welding process. This is a resistance welding method, which consists of electrical heating followed by a fast material forging. The present work has the objective of studying the influence of changing the electrical current, upset force and tempering heat treatment on the microstructures and mechanical properties of the flash butt welded joints. In this study, samples of bimetal band saw blades having width of 27 mm and thickness of 0.9 mm were employed. The material consists of a composite M42 high speed steel for the teeth welded together with a D-6a ultra-high strength carbon low alloy steel for the backer. The microstructure and mechanical properties have been investigated. It is pointed out that welding parameters and tempering affected the mechanical properties. The transversal hardness to the welding center line has shown values slightly higher than the respective longitudinal hardness. Non-tempered samples gave the highest tensile strength with the parameter of lowest tempering temperature. It is also found that the tempering reduces the hardness and the tensile strength of all samples. Aços baixa liga Butt welding Low alloy steels Soldabilidade Soldagem topo-a-topo Weldability

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