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21	Estudo da integridade superficial e seu efeito na fadiga de contato de um aço ferramenta. / The effect of surface integrity on the contact fatigue resistance of a tool steel. John Ferney Alvarez Rosário 19 September 2011 (has links) Os processos de manufatura, bem como os parâmetros de processamento utilizados produzem diferentes resultados com relação à integridade de uma superfície. Estas alterações se refletem em mudança das propriedades da superfície, as quais podem influenciar o desempenho dos componentes. O presente trabalho estuda o efeito da integridade superficial gerada pelos processos de torneamento e retificação na resistência à fadiga de contato do aço ferramenta AISI H13. A influência do processo de usinagem e dos parâmetros de corte no estado da superfície e subsuperfície, e como estas características afetam o desempenho são determinados. Foram geradas quatro condições diferentes para as superfícies torneadas mediante a combinação de parâmetros de corte. As superfícies retificadas foram produzidas empregando as mesmas condições de retificação, com isso, obteve-se a mesma condição para todos os corpos de prova ensaiados. As características medidas da integridade superficial foram: os parâmetros de rugosidade, tensões residuais, microdureza Vickers da seção transversal e ruído magnético de Barkhausen. Foi determinado o desempenho das superfícies por fadiga de contato de rolamento, num equipamento na configuração esfera-plano. Os corpos de prova foram anéis de AISI H13 temperados e revenidos. A totalidade dos ensaios foi realizada até a ocorrência de lascamento (Spalling). Os ensaios foram realizados com lubrificação e com uma máxima pressão de contato de Hertz de 3,6 GPa. Foi observado que dependendo do nível de integridade superficial induzido pelo processo de usinagem e dos parâmetros selecionados, o desempenho da superfície em fadiga de contato de rolamento foi afetado. Contudo, as melhores condições de desempenho foram dos materiais retificados, e para os materiais torneados o melhor desempenho foi obtido com maiores velocidades de corte. / The manufacturing process and the machining parameters selected lead to different integrity of the surface, and these characteristics will influence the functional performance of the components. This study evaluated and analyzed the effect of surface integrity on the contact fatigue resistance of the H13 hot work tool steel. The surfaces were manufactured by hard turning and grinding process. Therefore, the influences of the machining process and the cutting parameters on the surface and on the subsurface layer were studied. Four different turned surfaces were obtained as a combination of cutting parameters selected for the tests. On the other hand, grinding surfaces were generated using the same machining conditions. The characteristics of surface integrity evaluated were: surface roughness parameters, residual stresses, Barkhausen noise, and microhardness of surface and sub-layers in transverse section. It was also evaluated the performance of the samples by rolling contact fatigue tests conducted in a ball on washer machine. The specimens were rings made of AISI H13 steel, which were quenched and tempered. All tests were performed until the occurrence of spalling. The tests were carried out under lubrication and with a maximum Hertz contact pressure of 3.6 GPa. Monitoring and failure detection were carried out by analyzing the changes in the vibration signal of the test machine sensors. It was observed that the performance of the surface in rolling contact fatigue resistance was affected by the level of the surface integrity, related to the machining process and the machining parameters. Fadiga de contato de rolamento Integridade superficial Retificação Torneamento Grinding Rolling contact fatigue Surface integrity Turning
22	Contributions expérimentales et numériques pour la compréhension de l’intégrité des surfaces induite par un outil combiné usinage – galetage / Numerical and experimental contributions for a fundamental understanding of the surface integrity induced by a combined turning burnishing process Rami, Anis 02 October 2017 (has links) Le procédé de tournage galetage (CoTuB) est un traitement d'usinage innovant réalisant les procédés de tournage et de galetage à billes simultanément et sur la même machine-outil. L'objectif du procédé combiné est d'améliorer l'intégrité de surface et en même temps d'augmenter la productivité par rapport aux traitements conventionnels de surface et les procédés d'usinage. En adoptant un plan d’expérience, il a été démontré qu'une amélioration considérable de l’intégrité de surface pourrait être obtenue en utilisant le nouveau procédé combiné et en sélectionnant les paramètres appropriés. Pour effectuer une étude paramétrique, un ensemble d'expériences basées sur un plan d’expérience de type Taguchi complété par une analyse de la variance (ANOVA) a été réalisée. Le but de cette étude expérimentale est d'identifier les paramètres optimaux du tournage / galetage lors du traitement de l'acier 42 Cr Mo 4 permettant de donner une intégrité de surface optimale.Pour une meilleure compréhension des phénomènes impliqués lors du procédé combiné d'usinage / galetage, des approches et méthodologies numériques ont été développées afin de reproduire le procédé combiné. Une nouvelle approche numérique, appelée «Approche Mixte», est développée et utilisée afin de simplifier la simulation du procédé combiné. Cette approche combine des données expérimentales et numériques afin de déterminer la forme et de quantifier les chargements thermiques et mécaniques exercés par l'outil de coupe sur la surface usinée sur chaque zone de cisaillement. Cette nouvelle méthode a permis d'effectuer une simulation 3D du procédé de tournage-galetage combiné et permet de simuler plusieurs passages des outils autour de la surface usinée. La simulation permet de prédire les contraintes résiduelles induites par le procédé combiné et la comparaison révèle un bon accord entre les résultats numériques et expérimentaux. / The Combined Turning-Burnishing (CoTuB) process is an innovative machining treatment that performs turning and ball-burnishing processes simultaneously and on the same machine tool. The aim of performing the combined process is to enhance surface integrity and increase productivity at the same time when compare to conventional surface treatment and machining processes. Based on adopting design of experiments, it has been depicted that a considerable improvement in surface quality could be obtained meaning the new combined process by using the suitable process parameters. In order to carry out a parametric study, a set of experiments based on Taguchi method completed with a statistical analysis of variance (ANOVA) were performed. The aim of this experimental investigation is to identify the optimal turning/burnishing parameters when treating AISI 4140 steel. This helps to get an optimal surface integrity. For a better understanding of the phenomena involved during combined machining / burnishing processes, numerical approaches and methodologies for reproducing the combined turning-burnishing process have been performed. A new approach, called the "Mixed Approach", is developed and used in order to simplify the simulation of the combined process. This approach combines experimental and numerical data in order to determine shape and to quantify thermal and mechanical loadings exerted by the cutting tool on the machined surface on each shear zone. This new method allowed to perform a 3D simulation of combined turning-burnishing and allows to model several tool passages on the machined surface. The simulation allows to predict residual stresses induced by the combined process and the comparison reveals good agreements between numerical and experimental results. Tournage Galetage Intégrité de surface Expérimentation Simulation 3D Turning Burnishing Surface integrity Experimentation 3D simulation
23	Hodnocení povrchových a podpovrchových vlastností obráběného povrchu metodou analýzy Barkhausenova šumu (BNA) / Evaluation of the machined surface and subsurface properties using Barkhausen noise analysis Blažíček, Dominik January 2018 (has links) Master thesis deals with the influence of milling to resulting surface integrity of gear tested by Barkhausen Noise Analysis technique. Two sets of gears milled by different machines by comparable parameters were used to solve the task. The testing of surface integrity was carried out after heat treatment and final grinding. It was experimentaly approved the effected surface/subsurface damage caused by milling remains in the material through the heat treatment. Based on these results, it can be assumed that different milling affects the resulting surface integrity after HT.
24	Analýza vlivu technologických procesů na vlastnosti funkčních ploch ložisek / Analysis of the Impact of Technological Processes on the Properties of the Functional Areas of Bearings Fišerová, Zuzana January 2019 (has links) The dissertation is focused on the bearing production technology issues. The aim of the thesis is to investigate and evaluate the influence of the technological processes on properties of the functional surfaces of an outer bearing ring. The development, rolling, grinding and turning have been selected as basic technological processes. The subject of the surface integrity research on test samples is the measurement and analysis of the quality of the machined surfaces and residual stresses in the surface layers of the bearing rings. The comparison is made in relation to the previous operations - rolling, turning and grinding.
25	IMPACT OF TRIBOSYSTEM COMPATIBILITY ON TOOL WEAR AND SURFACE INTEGRITY Arif, Taib 11 1900 (has links) H13 tool steel is widely used in the mold and die industry. Due to tighter geometric tolerances and higher quality expectations, the use of hard machining has increased over the years. Hard machining refers to the machining of materials in their hardened state. The challenges with hard machining are rapid tool wear and maintaining a high surface integrity of the machined surface. Surface integrity is measured in terms of surface roughness, residual stresses, presence of surface and subsurface cracks, and the quality of the developed microstructure. In order to minimize wear and improve product quality, researchers are working on the development of different tool coatings. Some of the recent tool coatings function by adapting to their environment using heat to form thin layers of oxides, referred to as ―tribo-films‖, on the surface of the tool. If engineered properly, these tribofilms can prolong tool life and improve the surface integrity of a hard machined surface. A titanium based nano multi-layered coating (TiAlCrSiYN/TiAlCrN) has been developed by researchers at the MMRI. The tribological performance of two different coatings TiAlCrSiYN/TiAlCrN and TiAlCrN were tested in a hard machining metal cutting process. The impact of these coatings on tool wear, Cutting process (Chips) and Surface Integrity (Quality of machined surface) was assessed. This research involves characterizing the coating to understand how the formation of different oxide films (tribofilms) effect tool wear and surface integrity. The generation of these tribofilms is sensitive to coating composition and cutting condition (temperature/pressure). Next, an in-depth characterization of the chips produced during machining was carried out as part of studying the effect of different tribological conditions between the tool and workpiece. The chip's hardness, oxidation, chip formation mechanism and topography as the chip slid against the cutting tool surface was studied. Also, the Surface integrity of the machined part was investigated, considering its microstructure, residual stresses and surface roughness. Lastly, tests were performed in an attempt to accelerate the generation of beneficial tribofilms. Results indicate significant improvement in wear life and surface integrity of the machined surface due to the generation of tribo-films in this machining application. / Thesis / Master of Applied Science (MASc) Machining Surface Integrity Tribological compatibility Tool wear PVD coating Ball nose end milling Tribofilms
26	Effects of Processing Parameters on Ultrasonic Nanocrystal Surface Modification (UNSM) of Surface Properties and Residual Stress In 300M Steels Syed, Muhammad Shuja 02 June 2023 (has links) No description available. Mechanical Engineering Surface Modification Residual Stress Surface Integrity Corrosion Brush Electroplating
27	CRYOGENIC MACHINING AND BURNISHING OF AZ31B MAGNESIUM ALLOY FOR ENHANCED SURFACE INTEGRITY AND FUNCTIONAL PERFORMANCE Pu, Zhengwen 01 January 2012 (has links) Surface integrity of manufactured components has a critical impact on their functional performance. Magnesium alloys are lightweight materials used in the transportation industry and are also emerging as a potential material for biodegradable medical implants. However, the unsatisfactory corrosion performance of Mg alloys limits their application to a great extent. Surface integrity factors, such as grain size, crystallographic orientation and residual stress, have been proved to remarkably influence the functional performance of magnesium alloys, including corrosion resistance, wear resistance and fatigue life. In this dissertation, the influence of machining conditions, including dry and cryogenic cooling (liquid nitrogen was sprayed to the machined surface during machining), cutting edge radius, cutting speed and feed rate, on the surface integrity of AZ31B Mg alloy was investigated. Cryogenic machining led to the formation of a "featureless layer" on the machined surface where significant grain refinement from 12 μm to 31 nm occurred due to dynamic recrystallization (DRX), as well as increased intensity of basal plane on the surface and more compressive residual stresses. Dry and cryogenic burnishing experiments of the same material were conducted using a fixed roller setup. The thickness of the processed-influenced layer, where remarkable microstructural changes occurred, was dramatically increased from the maximum value of 20 μm during machining to 3.4 mm during burnishing. The burnishing process also produced a stronger basal texture on the surface than the machining process. Preliminary corrosion tests were conducted to evaluate the corrosion performance of selected machined and burnished AZ31B Mg samples in 5% NaCl solution and simulated body fluid (SBF). Cryogenic cooling and large edge radius tools were found to significantly improve the corrosion performance of machined samples in both solutions. The largest improvement in the material's corrosion performance was achieved by burnishing. A finite element study was conducted for machining of AZ31B Mg alloy and calibrated using the experimental data. A user subroutine was developed and incorporated to predict the grain size changes induced by machining. Good agreements between the predicted and measured grain size as well as thickness of featureless layers were achieved. Numerical studies were extended to include the influence of rake angle, feed rate and cutting speed on the featureless layer formation. Surface Integrity Cryogenic Machining/Burnishing Corrosion Resistance Finite Element Analysis Magnesium Alloys Mechanical Engineering Nanoscience and Nanotechnology Other Materials Science and Engineering
28	Studium účinků pasivních silových složek řezání na obráběný povrch / An experimental study of the impact of passive forces of cutting on a machined surface Slaný, Martin January 2013 (has links) This dissertation thesis focuses on the evaluation of modern machine tools, especially tools for finishing operations, with which the effect of the passive force components on the machining process is evaluated. The thesis will examine the analysis of creating chips and circumstances that accompany this process and substantially involve the formation of a new surface. The analysis of the process of the recording of the power load of the MT3 tool takes place in the experimental part of the thesis. MT3 is a reaming head intended for finishing holes at high cutting speeds (100-200 m.min-1) with removal of small cross section AD (0.024 mm2) chips. Particular attention is paid to the newly created profile from the surface after machining and evaluation of changes in geometry and loading of the cutting edge, which is significantly reflected in the establishment and the development of passive forces.
29	Influence des transformations surfaciques induites par traitements thermomécaniques sur la tenue en fatigue du Ti-10V-2Fe-3Al / Influence of surface transformations induced by thermo-mechanical processes on fatigue limit of Ti-10V-2Fe-3Al titanium allys Dufrenoy, Stephane 24 February 2016 (has links) Les alliages de titane sont largement utilisés dans le secteur de l’aéronautique. Cependant,ces alliages sont très sensibles aux gammes d’élaboration et de mises en forme. Cesdernières ont une grande influence sur l’intégrité de surface des produits finis, ce qui aun impact sur la durée de vie des pièces en service. Il est donc nécessaire de maîtriser lesprocédés afin de pouvoir définir la tenue en service des pièces.Dans ces travaux, les différentes intégrités de surface sont décrites en termes d’évolutionmicrostructurale, de contraintes résiduelles et de micro-géométrie. Des essais de fatigueen flexion 4 points sont réalisés pour tester les performances mécaniques de ces surfaces.Nous avons remarqué une bonne cohérence entre les modèles reliant l’intégrité de surfaceet la tenue en fatigue déterminée expérimentalement.De plus, étant donné que les alliages de titane ont des microstructures complexes etpeuvent être multiphasés, nous nous sommes aussi intéressés au caractère hétérogènede ces matériaux principalement dans l’analyse de contraintes résiduelles déterminées àl’aide de la diffraction des rayons X. Nous avons remarqué que ces hétérogénéités ontun impact sur la détermination des contraintes résiduelles. De fait une méthodologiede détermination de contraintes non standard a été mise en place et validée par dessimulations utilisant un modèle d’homogénéisation auto-cohérent.Ces modèles d’homogénéisation sont intéressants d’un point de vue de la déterminationdes contraintes résiduelles par diffraction des rayons X car ils permettent la prise encompte de l’aspect multiphasé des matériaux ainsi que leur caractère anisotrope. / Titanium alloys are widely used in aeronautics industries. However, these alloys are highlysensitive to the method for elaboration and transformation processes. These processesimpact on the surface integrity of products. Therefore, they have to be controlled inorder to predict life time of structures.In this work, the study of surface integrity is focused on the description of microstructalevolution, residual stresses and micro-geometry. Four points bending tests were performedin order to determined the fatigue limit of the different studied processes. We find outa good consistency between models used to determinate lifetime from surface integrityinvestigation and experimental results.Moreover, microstructures of titanium alloys are highly complex and they often are twophasedmaterials. Consequently, we studied the heterogeneous behaviour of such materialby X-ray diffraction investigation.We found out that these heterogeneities have an impacton residual stresses determination. Therefore, a non-standard methodology was definedand validate by simulation using a micro-mechanic model : a self-consistent model.Micro-mechanical models are interesting for the residual stresses determination using Xraydiffraction because they allow to take into account heterogeneous and anisotropicbehaviours through anisotropic elasticity and anisotropic texture. Modélisation micro-Mécanique Alliages de titane Contraintes résiduelles Intégrité de surface Micro-mechanical model Titanium alloys Residual stresses Surface integrity
30	Caractérisation et modélisation de l'état mécanique et microstructural des sous-couches affectées par l'usinage de finition du cuivre Cu-c2 et impact sur la résistance à la corrosion. / Characterizing and modeling surface integrity induced by finishing machining of OFHC copper and its impact on corrosion resistance Denguir, Lamice 08 December 2016 (has links) La durabilité des composants mécaniques en général et leur résistance à la corrosion en particulier ont une importance primordiale dans l’industrie moderne, qu’elle concerne la production d’énergie, les produits chimiques, le transport, les machines, les matériels médicaux, ou même les composants électroniques. Pour des pièces obtenues par usinage, il est donc nécessaire d’améliorer leur durée de vie et de réduire le risque de défaillance prématurée en améliorant leur intégrité de surface. Ainsi, une compréhension de l’effet du procédé sur l’intégrité de surface induite par usinage et ses conséquences au niveau de sa résistance à la corrosion sont les clés pour relever ces défis.Cette thèse traite le cas particulier de l’usinage de finition du cuivre Cu-c2 et son impact sur la résistance à la corrosion. D’abord, une étude expérimentale comparative du tournage et de la coupe orthogonale est effectuée. Ensuite, vu sa simplicité, la coupe orthogonale fait l’objet de la suite de l’étude. Un modèle numérique est développé pour la prédiction de l’intégrité de surface induite par la coupe. Il utilise une nouvelle loi constitutive du Cu-c2 tenant en compte les transformations microstructurales et l’état des contraintes dans le matériau. Enfin, les résultats issus des études expérimentales ainsi que des simulations numériques concernant l’intégrité de surface sont statistiquement traités dans une analyse multi-physique, dans la perspective d’établir le lien entre la résistance à la corrosion, l’intégrité des surfaces et la physique de la coupe. / The functional performance and life of mechanical components in general and their corrosion resistance in particular are of prime importance in the modern industry, as far as energy production, transportation, machines, medical and even electronic components are concerned. In the case of machined components, it is essential to improve their life and to reduce the premature failure by improving their surface integrity. So, a comprehension of the effect of the machining process mechanics on surface integrity and its consequences on corrosion resistance are essential.This thesis deals with the particular case of finishing machining of oxygen free high conductivity copper (OFHC) and its impact on the surface integrity and corrosion resistance. Firstly, a comparative experimental study between turning and orthogonal cutting is performed. Then, due to its simplicity, orthogonal cutting makes the object of the pursuit of the study. A numerical model is developed to predict the surface integrity induced by the cutting process. It uses a new constitutive model for OFHC copper taking into account microstructural transformations and the state of stress in the work material. Finally, the results issued from experimental studies and the numerical simulations are statistically treated in a multi-physical analysis with the objective of establishing the relationship between corrosion resistance, surface integrity and cutting physics. Cuivre Cu-C2 Usinage de finition Intégrité de surface Modélisation Électrochimie et corrosion Surface integrity Corrosion Constitutive modelling FE modelling OFHC copper Machining

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