Your search keyword '"instrumented indentation test"' showing total 77 results

1. Influence of Mineralogical Characteristics on Mechanical Properties of Montney Tight Formations Using Instrumented Indentation Test and SEM–EDS Analysis.

Author

Yu, Huan, Zheng, Wenbo, Cui, Xiaojun, and Zhou, Jianhui

Subjects

*DIGITAL maps, *DIGITAL mapping, *GAUSSIAN processes, *YOUNG'S modulus, *STATISTICAL correlation

Abstract

This study investigates the influence of mineralogical characteristics on the mechanical properties of tight formations from the Montney Play in Canada. A series of instrumented indentation tests were conducted on rock samples cored at depths of 2068–2037 m. The mineralogical characteristics of the indents from the indentation tests were obtained from scanning electron microscopy (SEM) and energy-dispersive spectroscopy (EDS) analysis. By creating digital mineral maps from EDS elemental maps, the localized mineralogical composition and pore distribution around the indents were quantified, and their variations during indentation tests were correlated to the indentation depth/contact area. This new approach can obtain a unique dataset that directly relates rock indentation to their mineralogical characteristics. Pearson correlation analysis was employed to examine the relationships between mineralogical characteristics and mechanical behaviors, such as elastic, plastic and maximum indentation depths, indentation Young's modulus, and hardness. Furthermore, machine learning models were developed using data from instrumented indentation tests and SEM–EDS analysis to predict indentation behavior. The results indicated albite and porosity both have a positive influence on elastic and maximum indentation depths, while orthoclase and pyrite displayed negative correlations. Gaussian process machine learning models were developed to simulate both the loading and unloading stages of an indentation test, which can accurately forecast the indentation force-depth relation on rocks with different mineralogical characteristics. The findings of this study provide valuable insights into the collective effects of mineralogical characteristics on rock mechanical properties. Highlights: Instrumented indentation and SEM–EDS analysis were used on Montney tight formations. Digital mineral map was created to relate their composition to indentation results. Albite/porosity positively relate to elastic and maximum indentation depth. Orthoclase/pyrite negatively correlate to elastic and maximum indentation depth. Gaussian process model predicts indentation behaviors from mineral characteristic. [ABSTRACT FROM AUTHOR]

Published

2024

2. Application of Instrumented Indentation Test and Neural Networks to determine the constitutive model of in-situ austenitic stainless steel components.

Author

Ma, Quoc-Phu, Basterrech, Sebastián, Halama, Radim, Omacht, Daniel, Měsíček, Jakub, Hajnyš, Jiří, Platoš, Jan, and Petrů, Jana

Abstract

Over the last few decades, Instrumented Indentation Test (IIT) has evolved into a versatile and convenient method for assessing the mechanical properties of metals. Unlike conventional hardness tests, IIT allows for incremental control of the indenter based on depth or force, enabling the measurement of not only hardness but also tensile properties, fracture toughness, and welding residual stress. Two crucial measures in IIT are the reaction force (F) exerted by the tested material on the indenter and the depth of the indenter (D). Evaluation of the mentioned properties from F–D curves typically involves complex analytical formulas that restricts the application of IIT to a limited group of materials. Moreover, for soft materials, such as austenitic stainless steel SS304L, with excessive pile-up/sink-in behaviors, conducting IIT becomes challenging due to improper evaluation of the imprint depth. In this work, we propose a systematic procedure for replacing complex analytical evaluations of IIT and expensive physical measurements. The proposed approach is based on the well-known potential of Neural Networks (NN) for data-driven modeling. We carried out physical IIT and tensile tests on samples prepared from SS304L. In addition, we generated multiple configurations of material properties and simulated the corresponding number of IITs using Finite Element Method (FEM). The information provided by the physical tests and simulated data from FEM are integrated into an NN, to produce a parametric mapping that can predict the parameters of a constitutive model based on any given F–D curve. Our physical and numerical experiments successfully demonstrate the potential of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2024

3. Determining materials yield strength with Lüders behavior of existing steel structures using instrumented indentation approach

Author

Yang Peng, Xiankang Xiong, Yuxiang Tang, Ning Li, and Jun Dong

Subjects

Instrumented indentation test, Strength, Structural steel, Lüders behavior, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The instrumented indentation approach has become popular to characterize the mechanical properties of metals on-site. Although the evaluation of the materials' strength of metal structures is possible using the instrumented indentation approach, a few research studies have been reported to determine the strength of the steels presenting Lüders behavior. This paper presented a series of experiments including instrumented indentation and tensile tests, and proposed a method to evaluate the yield strength of steels presenting Lüders behavior. A steel truss bridge is used in the on-site benchmark experiment to verify the feasibility and reliability of the instrumented indentation approach. Tensile tests in the laboratory were conducted to obtain the accurate strength of steel from the steel truss bridge. The instrumented indentation tests were done on members of the steel truss bridge and the tensile test specimens. The strength from the instrumented indentation tests was compared with those from tensile tests. The comparison results are used to discuss the accuracy and precision of the instrumented indentation approach. The results indicate that the instrumented indentation approach is a feasible and sufficiently accurate method for measuring the strength of steel components. The difference of the yield strength is about 10%, and the difference of the tensile strength is around 5%. A method to improve the measured accuracy of yield strength is proposed. By using the proposed method, the difference of the yield strength for steels presenting Lüders behavior is less than 5%.

Published

2024

4. Data-driven estimation of plastic properties in work-hardening model combining power-law and linear hardening using instrumented indentation test

Author

Ta-Te Chen and Ikumu Watanabe

Subjects

elastic-plastic material, instrumented indentation test, response surface, material database, finite element method, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Instrumented indentation testing is an efficient approach for measuring mechanical properties such as equivalent elastic modulus and hardness. Recently, the indentation-based approach has been extended to estimate the stress–strain curve corresponding to tensile or compression tests. However, estimation performance is decreased in high work-hardening alloys because of the limitation of the functional expressiveness in a simple power-law hardening model containing two material constants. Although a modified constitutive model can be employed to improve the expressiveness, additional experimental data are required to adequately determine these material constants. In this study, a method for determining the additional material constant in a modified work-hardening model combining power-law and linear hardening was proposed without additional experimental data, based on the two stress–plastic strain curves of the power-law and linear hardening models. Consequently, the material constants can be determined using an existing approach. In this study, a data-driven estimation approach using the response surfaces of the loading curvature of a load–depth curve and the pile-up height of an indentation impression is established. The proposed approach was applied to high-work-hardening steel for validation.

Published

2022

5. Calibration of machine platform nonlinearity in Instrumented Indentation Test in the macro range.

Author

Kholkhujaev, Jasurkhuja, Maculotti, Giacomo, Genta, Gianfranco, and Galetto, Maurizio

Subjects

*CREEP (Materials), *CALIBRATION, *LITERARY characters, *NANOMECHANICS, *REFERENCE sources, *NANOINDENTATION

Abstract

Instrumented Indentation Test (IIT) is a non-conventional mechanical characterization technique to evaluate hardness, Young modulus, creep and relaxation of materials. In the macro range, it represents a cheaper and faster alternative to conventional tensile-based tests. IIT is a metrological scale; thus, to establish traceability, calibration is essential. Frame compliance calibration is critical because it is a major contribution to the measurement uncertainty. This work discusses the limits of the current state-of-the-art and proposes a novel methodology for frame compliance calibration. The introduced approach demonstrates the source of common systematic errors in the mechanical characterization reported in the literature, i.e. edge effect, while first highlighting a relevant frame compliance nonlinearity. The proposed procedure is cost-effective and relies upon constitutive spring modelling of IIT and calibration of reference block by nanoindentation. Results show that the novel approach corrects systematic trends in the characterization and yields a relative measurement uncertainty of 5%. • Macro-Instrumented Indentation can conveniently replace conventional tests. • Frame compliance calibration is critical for accurate and precise characterization. • Current calibration methods neglect frame compliance nonlinearity. • A method is proposed and applied to calibrate frame compliance nonlinearity. • An approach to calibrate reference material by nanoindentation is demonstrated. [ABSTRACT FROM AUTHOR]

Published

2023

6. Mechanical Properties of Structural Components in Hastelloy X Joints Brazed with Ni-Pd-Cr-B-Si Alloy.

Author

Baranowski, Michał and Senkara, Jacek

Subjects

*BRAZING alloys, *STRUCTURAL components, *AIRCRAFT engine industry, *NICKEL alloys, *JET engines, *CREEP (Materials), *FILLER metal

Abstract

The brazing of structural high-temperature-resistant nickel alloys is a predominant method in manufacturing jet engines in the aircraft industry. Ni-Cr-base brazing filler metals (BFMs) containing B and Si as the melting point depressants are used for this purpose. The presence of the latter can lead to the formation of brittle constituents in the joints, decreasing their strength, toughness and creep resistance. The structures of Hastelloy X nickel superalloy joints brazed with Palnicro 36M BFM are presented in this paper along with the mechanical properties of their particular phases as a function of brazing time. Indentation hardness, Martens hardness, reduced modulus and creep coefficient were measured using the instrumented indentation method. The elastic part of the indentation work was also calculated. Pd forms an unlimited solution with Ni, but its high content in BFM does not fundamentally change the general joint structure known from other Ni-superalloy–Ni-BFM systems. However, new Pd-containing phases are emerging. The hardest components were Ni-B and Cr-B boride phases and Pd-Ni-Si phase in MZ and the boundary of DAZ and BM. MZ reduces the plasticity of a joint to the highest extent. The hardness of particular parts in the joints and the elastic portion of the indentation work decreased with the increase in brazing time, while the reduced modulus of the indentation contact and indentation creep increased. The results of indentation creep measurements indicate that all structural components of the joints were less susceptible to creep than the parent material at room temperature. [ABSTRACT FROM AUTHOR]

Published

2023

7. Direct calibration of indenter tip geometry by optical surface topography measuring instruments

Author

Maculotti, Giacomo, Kholkhujaev, Jasurkhuja, Genta, Gianfranco, and Galetto, Maurizio

Published

2023

8. Data-driven estimation of plastic properties of alloys using neighboring indentation test

Author

Ta-Te Chen, Ikumu Watanabe, Dayuan Liu, and Kenta Goto

Subjects

elastic-plastic material, finite element method, mechanical testing, response surface, instrumented indentation test, material database, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

A data-driven estimation method for the plastic properties of alloys was proposed using indentations at neighboring positions. An instrumented indentation test is an efficient approach to measure mechanical properties such as equivalent elastic modulus and hardness. In the mechanical test, subsequent experiments are generally performed apart from existing indentations to avoid the interaction effect caused by the dependency on the deformation history of metal plasticity. In this study, the interaction effect was utilized to estimate the plastic properties, based on the difference of load–depth curves between the first and second indentations at neighboring positions. Using finite element simulations of the neighboring indentation tests, the effective experimental conditions were examined, and response surfaces of the loading curvatures were characterized to determine two material constants of a simple constitutive model of plasticity. Finally, the proposed approach was validated for application to aluminum alloys and stainless steel. It can be also applied to various alloys characterized by different elastic moduli.

Published

2021

9. Application of two‐layer viscoplasticity model to predict a semicrystalline polymer response under compression and microindentation.

Author

dos Santos, Bianca Bastos, da Costa, Marysilvia Ferreira, Pasqualino, Ilson Paranhos, and da Costa, Celio Albano

Subjects

VISCOPLASTICITY, CRYSTALLINE polymers, POLYVINYLIDENE fluoride, COMPRESSION loads, STRAIN rate, POLYMERS

Abstract

Polymeric materials are widely used in structural components and systems, and the accurate prediction of their complex time‐dependent behavior is critical. Several constitutive models are available for different types of mechanical behaviors and loading conditions. However, selecting the model and the correct calibration of its parameters is often a challenge. This paper evaluates the applicability of the two‐layer viscoplasticity (TLV) model to predict the viscoplastic behavior of polyvinylidene fluoride (PVDF) in a large range of strain rates and complex states of strain. The setting of parameters and model validation was made by performing experimentally and numerically uniaxial compression tests and relaxation tests. The model parameters were also analyzed in performing microindentation tests. The TLV model using the same set of parameters selected well predicted the PVDF behavior in a wide variety of compressive loading conditions. [ABSTRACT FROM AUTHOR]

Published

2022

10. Data-driven estimation of plastic properties of alloys using neighboring indentation test.

Author

Chen, Ta-Te, Watanabe, Ikumu, Liu, Dayuan, and Goto, Kenta

Abstract

A data-driven estimation method for the plastic properties of alloys was proposed using indentations at neighboring positions. An instrumented indentation test is an efficient approach to measure mechanical properties such as equivalent elastic modulus and hardness. In the mechanical test, subsequent experiments are generally performed apart from existing indentations to avoid the interaction effect caused by the dependency on the deformation history of metal plasticity. In this study, the interaction effect was utilized to estimate the plastic properties, based on the difference of load–depth curves between the first and second indentations at neighboring positions. Using finite element simulations of the neighboring indentation tests, the effective experimental conditions were examined, and response surfaces of the loading curvatures were characterized to determine two material constants of a simple constitutive model of plasticity. Finally, the proposed approach was validated for application to aluminum alloys and stainless steel. It can be also applied to various alloys characterized by different elastic moduli. [ABSTRACT FROM AUTHOR]

Published

2021

11. Methodology to evaluate strength properties of steel by single instrumented indentation test.

Author

Huang, Liyang, Zhong, Jiru, Chen, Guoyao, Xu, Tong, and Guan, Kaishu

Abstract

The instrumented indentation test (IIT) is an attractive non-destructive testing technique. Determining accurate strength properties of steel using IIT is still challenging. In this paper, a new methodology is proposed to acquire the yield and ultimate tensile strength from a single IIT. This method extracts true stress-strain curves from IIT results. Acquired stress-strain curves indicate that the initial yield stress is not repeatable. This is caused by the inhomogeneous deformation of IIT specimens. Based on the obtained true stress-stain curves, corresponding yield strength, and ultimate tensile strength are calculated through theoretical derivation. The results show that the strength has a convergent tendency. On basis of this phenomenon, the strength is determined with an extrapolating method. Finally, the strength properties of Q345R are investigated to verify the reliability of this method. It is found that the strength determined from IIT and conventional tensile tests shows good agreement. The proposed method is effective in predicting strength properties from a single instrumented indentation test. [ABSTRACT FROM AUTHOR]

Published

2021

12. Evaluation of Ballistic Limit Velocity Using Instrumented Indentation Test of 7xxx Aluminum Alloys After Friction Stir Welding.

Author

Cho, Changhyun, Choi, Seunghun, Kwon, Oh Min, Lee, Seungha, Kim, Jong-hwan, and Kwon, Dongil

Abstract

Friction stir welding has the advantages of producing less material deformation and of simple joining of relatively thick materials, but the disadvantages of forming relatively large heat-affected zones around weld areas. In addition, in research on reductions in bulletproof performance in heat-affected zones, it is necessary to evaluate the ballistic limit velocity (V50), which measures bulletproof performance, and this requires specimens of a certain minimum size and has only limited application to local areas such as heat-affected zones. Instrumented indentation testing (IIT), a method of measuring material properties by utilizing load-depth curves measured by a small indenter leaving fine marks on the material, has no specimen size requirements; in addition, it has simple test procedures and is nondestructive. Here a theoretical model is proposed for evaluating V50 of aluminum alloys by ductile hole formation using IIT. Heat-affected zones generated after friction stir welding of for 7000-series aluminum alloys were simulated, and the model was validated through comparison with the conventional V50 test. In addition, there is currently no way to directly evaluate V50 for welded areas in 7000-series aluminum, but here IIT was used to assess V50 for each local part of the welded specimen. The conventional V50 test takes 15 min per shot and cannot be reused of specimens, but the test using IIT takes 1 min to complete one test and has benefits in terms of time, cost and safety. [ABSTRACT FROM AUTHOR]

Published

2021

13. Characterization of the Strain-Rate-Dependent Plasticity of Alloys Using Instrumented Indentation Tests

Author

Ta-Te Chen, Ikumu Watanabe, and Tatsuya Funazuka

Subjects

strain-rate-dependent plasticity, instrumented indentation test, finite elements, mechanical testing, Crystallography, QD901-999

Abstract

Instrumented indentation tests are an efficient approach for the characterization of stress–strain curves instead of tensile or compression tests and have recently been applied for the evaluation of mechanical properties at elevated temperatures. In high-temperature tests, the rate dependence of the applied load appears to be dominant. In this study, the strain-rate-dependent plasticity in instrumented indentation tests at high temperatures was characterized through the assimilation of experiments with a simulation model. Accordingly, a simple constitutive model of strain-rate-dependent plasticity was defined, and the material constants were determined to minimize the difference between the experimental results and the corresponding simulations at a constant high temperature. Finite element simulations using a few estimated mechanical properties were compared with the corresponding experiments in compression tests at the same temperature for the validation of the estimated material responses. The constitutive model and determined material constants can reproduce the strain-rate-dependent material behavior under various loading speeds in instrumented indentation tests; however, the load level of computational simulations is lower than those of the experiments in the compression tests. These results indicate that the local mechanical responses evaluated in the instrumented indentation tests were not consistent with the bulk responses in the compression tests at high temperature. Consequently, the bulk properties were not able to be characterized using instrumented indentation tests at high temperature because of the scale effect.

Published

2021

14. Investigation of the mechanical properties of steel using instrumented indentation test with simulated annealing particle swarm optimization.

Author

Huang, L.Y., Guan, K.S., Xu, T., Zhang, J.M., and Wang, Q.Q.

Subjects

*PARTICLE swarm optimization, *SIMULATED annealing, *MECHANICAL behavior of materials, *STEEL, *MATHEMATICAL optimization

Abstract

• An optimization was used to determine the material mechanical properties. • Mechanical properties were directly extracted from multiple loading–unloading data. • The uniqueness and adequately precision can be assured with the proposed method. A methodology is proposed to obtain mechanical properties of bulk materials from multiple loading-unloading curves of an instrumented indentation test (IIT). The mechanical properties, including strain-hardening exponent (n) and strain-hardening rate (K), were extracted from IIT data using iterative finite element simulation coupled with a simulated annealing swarm particle optimization. A systematical study was carried out to discuss the uniqueness of the identified properties. Results showed that the mechanical properties obtained in this way are unique and accurate adequately. It was found that the maximum errors of K and n generated from the macro indentation tests are 8.2% and 6.3% respectively. The identified mechanical properties from ten loading-unloading curves was compared with those obtained from a single loading-unloading curve. We found that ten loading-unloading cycles of an indentation test will result in more precise mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2019

15. Innovative Geometrical and Mechanical characterization of metallic components

Author

Kholkhujaev, Jasurkhuja

Subjects

technological surface, Mechanical characterization, geometrical characterization, gap and flushness, instrumented indentation test, Settore ING-IND/16 - Tecnologie e Sistemi di Lavorazione

Published

2023

16. Evaluation of Non-Equibiaxial Residual Stresses in Metallic Materials via Instrumented Spherical Indentation

Author

Guangjian Peng, Fenglei Xu, Jianfeng Chen, Huadong Wang, Jiangjiang Hu, and Taihua Zhang

Subjects

instrumented indentation test, finite element simulation, residual stress, residual indentation imprint, metallic materials, Mining engineering. Metallurgy, TN1-997

Abstract

Residual stresses, existed in engineering structures, could significantly influence the mechanical properties of structures. Accurate and non-destructive evaluation of the non-equibiaxial residual stresses in these structures is of great value for predicting their mechanical performance. In this work, investigating the mechanical behaviors of instrumented spherical indentation on stressed samples revealed that non-equibiaxial residual stresses could shift the load-depth curve upwards or downwards and cause the residual indentation imprint to be an elliptical one. Through theoretical, experimental, and finite element (FE) analyses, two characteristic indentation parameters, i.e., the relative change in loading curvature and the asymmetry factor of the residual indentation imprint, were found to have optimal sensitivity to residual stresses at a depth of 0.01R (R is the radius of spherical indenter). With the aid of dimensional analysis and FE simulations, non-equibiaxial residual stresses were quantitatively correlated with these two characteristic indentation parameters. The spherical indentation method was then proposed to evaluate non-equibiaxial residual stress based on these two correlations. Applications were illustrated on metallic samples (AA 7075-T6 and AA 2014-T6) with various introduced stresses. Both the numerical and experimental verifications demonstrated that the proposed method could evaluate non-equibiaxial surface residual stresses with reasonable accuracy.

Published

2020

17. Inverse identification of constitutive parameters with instrumented indentation test considering the normalized loading and unloading P-h curves.

Author

Li, Yu Gang, Kanouté, Pascale, François, Manuel, Chen, Dong, and Wang, Hao Wei

Subjects

*ISOTROPIC properties, *MECHANICAL loads, *HARDNESS, *MULTIDISCIPLINARY design optimization, *INDENTATION (Materials science), *HARDENING (Heat treatment)

Abstract

Abstract The feature of instrumented indentation test (IIT) makes it suitable for the characterization of local constitutive behavior in a small volume of solids. In the present study, the relationship between the shape of the normalized loading P - h curve and the indenter tip rounding radius, and the influences of the constitutive parameters of a Ludwik-type isotropic hardening model on the shape and the initial slope of the normalized unloading P - h curve were investigated by theoretical analysis and sophisticated numerical sensitivity analysis. From the analytical results, a two-stage analytical approach that can inversely identify multiconstitutive parameters simultaneously was proposed. In the first stage, by considering the least-square distance between the experimental and the simulated normalized loading P - h curves (g (h/h max)) as the objective and C 1 in the tip area function as the input variable, the tip rounding was identified by a single-objective optimization procedure. With the optimal tip rounding, a multiobjective optimization procedure was then performed to identify the constitutive parameters of the target materials. The initial slope of the normalized unloading P - h curve (Δ S ' (P / Pmax-h / hmax)), absolute value of the differences between the simulated and the experimental maximum load (Δ P max), initial slope of the unloading P - h curve (Δ S), and contact hardness (Δ H) were set as objectives, while all the material parameters except the Poisson's ratio (v) were considered as input variables. Results of the numerical verification with a set of arbitrarily selected constitutive parameters and the experimental verification on Ti-18 (a near- β high-strength titanium alloy) fit fairly well with uniaxial tensile parameters. With regard to T40, the identified true stress-true plastic strain curve is about 20% higher than the uniaxial tensile curve. One possible explanation is the occurrence of the strength differential and anisotropy effects during the plastic deformation process of α -phase titanium. It is worthy to be noticed that the present study may propose a new way to calibrate the tip area function directly on the target material without any standard indentation sample and improve the quality of the identification of the material constitutive parameters by IIT. [ABSTRACT FROM AUTHOR]

Published

2019

18. Effect of contact stiffness and machine calibration in nano-indentation testing.

Author

Genta, Gianfranco, Maculotti, Giacomo, Barbato, Giulio, Levi, Raffaello, and Galetto, Maurizio

Abstract

Abstract Instrumented indentation tests enable evaluation of several material parameters. Preliminary investigations underlined the influence of contact stiffness in the nano-range. ISO 14577-1 recommends two methods for contact stiffness evaluation, which, however, present shortcomings mainly related to the disregard of actual shape of unloading indentation curve. Given the relevance not only at the extent of material characterization, but also at testing machine calibration, alternative evaluation procedures have been developed, showing better agreement with experimental data and lower uncertainty in the evaluation of contact stiffness. In this work, shortcomings of standard and alternative methods in the evaluation of material parameters are highlighted, and innovative procedures are proposed to overcome them. [ABSTRACT FROM AUTHOR]

Published

2018

19. Stress-strain curve mapping by nanoindentation – a technique to qualify diffusion-bonded window assemblies for ITER.

Author

Pero, Renato, Randall, Nicholas, Frey, Damian, Widmer, Remo N., Darby, Tim, Aucott, Lee, Hardie, Chris, Pak, Sunil, Maquet, Philippe, and Bushby, Andrew

Subjects

*NANOINDENTATION, *STRAIN hardening, *ELASTIC modulus, *YIELD stress, *PLASMA diagnostics, *STRESS-strain curves, *FUSED silica

Abstract

• Methodology to extract bulk equivalent mechanical properties that are usually measured by tensile or compression tests (i.e., yield stress, yield strain, work hardening parameter and elastic modulus) by means of automated large nanoindentation map. • Novel post-processing approach to automatically identify yielding point of materials from stress strain curves assures high throughput analysis. • Outstanding correlation between mechanical properties and microstructural changes across the bonded cross-section, in dissimilar metal/metal and metal/ceramic diffusion bonding joint interfaces. • Qualification protocol for material assemblages of observation windows in the International Thermonuclear Experimental Reactor (ITER) fusion reactor. The International Thermonuclear Experimental Reactor (ITER) is an international nuclear fusion research and engineering project with the aim to prove the feasibility of nuclear fusion as a large-scale carbon-free source of energy. The reactor vessel contains several diagnostic windows that provide a line of sight to the plasma. Design and qualification of such windows is challenging due to severe in-service conditions and the necessity to combine glasses with metals. One specific window is composed of fused silica glass that is connected to an Inconel ferrule via an aluminium bonding layer, where the joint is consolidated through a diffusion bonding process. The optimization of design and production process parameters of the windows is object of continuous improvements via dedicated three-dimensional finite element model (FEM) simulations. Importantly, these FEM simulations necessarily require stress-strain curves as input parameters. Such curves are difficult to obtain, especially from complex systems with dissimilar joints. In the present paper a methodology based on dynamic spherical nanoindentation has been developed and applied to map the stress-strain characteristics across the diffusion bonded joints. The methodology takes inspiration from the well-known theory to extract stress-strain curves from spherical nanoindentation. Here, it is applied to automated large indentation mapping with more than 1000 indentations including fully automated post-processing. The results provide bulk equivalent mechanical properties including yield stress, yield strain, work hardening parameters and elastic modulus at a micrometre resolution. Results show outstanding correlation with microstructural changes across the bonded cross-section, including grain refinement and twinning at the Inconel/aluminium interface. [ABSTRACT FROM AUTHOR]

Published

2023

20. Quantifying Mechanical Properties of Automotive Steels with Deep Learning Based Computer Vision Algorithms

Author

Ehsan Javaheri, Verdiana Kumala, Alireza Javaheri, Reza Rawassizadeh, Janot Lubritz, Benjamin Graf, and Michael Rethmeier

Subjects

deep learning, computer vision, artificial neural network, clustering, mechanical properties, high strength steels, instrumented indentation test, Mining engineering. Metallurgy, TN1-997

Abstract

This paper demonstrates that the instrumented indentation test (IIT), together with a trained artificial neural network (ANN), has the capability to characterize the mechanical properties of the local parts of a welded steel structure such as a weld nugget or heat affected zone. Aside from force-indentation depth curves generated from the IIT, the profile of the indented surface deformed after the indentation test also has a strong correlation with the materials’ plastic behavior. The profile of the indented surface was used as the training dataset to design an ANN to determine the material parameters of the welded zones. The deformation of the indented surface in three dimensions shown in images were analyzed with the computer vision algorithms and the obtained data were employed to train the ANN for the characterization of the mechanical properties. Moreover, this method was applied to the images taken with a simple light microscope from the surface of a specimen. Therefore, it is possible to quantify the mechanical properties of the automotive steels with the four independent methods: (1) force-indentation depth curve; (2) profile of the indented surface; (3) analyzing of the 3D-measurement image; and (4) evaluation of the images taken by a simple light microscope. The results show that there is a very good agreement between the material parameters obtained from the trained ANN and the experimental uniaxial tensile test. The results present that the mechanical properties of an unknown steel can be determined by only analyzing the images taken from its surface after pushing a simple indenter into its surface.

Published

2020

21. A Potential Solution to Mystical Materials in Indentation Test.

Author

Billur, E., Çetin, B., Music, O., Şimşir, C., and Davut, K.

Subjects

INDENTATION (Materials science), ELASTOPLASTICITY, MANUFACTURING processes, SURFACE preparation, INVERSE problems

Abstract

Various methods have been designed to determine the elasto-plastic properties of metals. Instrumented indentation test (IIT) is considered to be a good candidate to determine local properties after manufacturing operations. In order to acquire elastoplastic properties from IIT, either dimensional analysis or inverse analysis of the force-displacement curve is performed. However, the major drawback of those methods is the uniqueness of the solution. Some materials may exhibit almost identical force-depth curves, although they have different elastoplastic properties. Those materials are referred as “mystical materials”. In this contribution, topological features of the indentation surfaces, i.e. indent size, pile-up and sink-in behaviour, are investigated to find a differentiating property. According to the results, indent size, pile-up and sink-in behaviour may help to find the unique solution to the inverse problem. [ABSTRACT FROM AUTHOR]

Published

2017

22. Hot deformation of a Fe-Mn-Al-C steel susceptible of κ-carbide precipitation.

Author

Zambrano, O.A., Valdés, J., Aguilar, Y., Coronado, J.J., Rodríguez, S.A., and Logé, Roland E.

Subjects

*IRON alloys, *CARBIDES, *DEFORMATIONS (Mechanics), *STEEL, *PRECIPITATION (Chemistry)

Abstract

The mechanical properties of Fe-Mn-Al-C steel are significantly enhanced after κ-carbide precipitation via aging; however, most aging treatments are energy demanding because they require relatively high temperatures and extended holding times. This research determined that the precipitation of these carbides can also occur within a few seconds of thermomechanical treatments (TMTs). This behaviour has not been reported post-TMTs for this steel group. Hot compression tests were performed on Fe-21Mn-11Al-1.5C-2Si wt% specimens at test temperatures ranging from 900 °C to 1150 °C and strain rates varying from 0.01 s −1 to 1 s −1 . The effects of strain rate and test temperature on dynamic recrystallization behaviour were evaluated. The microstructures were characterized by scanning electron microscope and electron backscatter diffraction. Hardness tests were performed before and after applying processes studied i.e., TMT and aging treatment to determine the change in hardness induced. Particularly, nanoindentation tests were also used to collect indirect evidence about the deformation mechanisms. The load-displacement curves P-h and (P/h)-h showed the occurrence of several pop-ins and slope changes related to the nucleation of dislocations and strain-induced phase transformations. The occurrence of these phenomena is discussed. [ABSTRACT FROM AUTHOR]

Published

2017

23. Verification of Indentation Parameters Depending on Indentation Speed Based on Representative Stress and Strain Approach.

Author

Oh Min Kwon, Jong Ho Won, Seung gyu Kim, Jun Sang Lee, and Dongil Kwon

Abstract

The instrumented indentation test is widely used for nondestructive evaluation of the mechanical properties of materials. In particular, the uniaxial tensile curve can be estimated through this technique using a spherical indenter with static condition setup. First, to determine the representative stress and strain, the indentation parameters were verified depending on the indentation speed conditions; this was done for the dynamic flow curve estimation using the instrumented indentation test. Multiple load-depth curves were analyzed to determine the maximum load, stiffness, and strain-hardening exponent; the most dominant parameter was verified depending on the indentation speed using the representation model. [ABSTRACT FROM AUTHOR]

Published

2016

24. Instrumented Indentation Test in the Nano-range: Performances Comparison of Testing Machines Calibration Methods

Author

Galetto, Maurizio, Maculotti, Giacomo, Genta, Gianfranco, Barbato, Giulio, and Levi, Raffaello

Published

2019

25. An instrumented spherical indentation study on high purity magnesium loaded nearly parallel to the c-axis.

Author

Nayyeri, G., Poole, W.J., Sinclair, C.W., Zaefferer, S., Konijnenberg, P.J., and Zambaldi, C.

Subjects

*INDENTATION (Materials science), *MAGNESIUM, *MECHANICAL loads, *DISCONTINUOUS precipitation, *DEFORMATIONS (Mechanics), *DISLOCATION density, *CRYSTAL orientation, *ELECTRON backscattering

Abstract

Instrumented spherical indentation has been used to extract information on the deformation behaviour of (0001) oriented grains in commercial purity magnesium. Reproducible discontinuities were found in the loading and the unloading curves and these have been interpreted as the nucleation and growth of { 10 1 ¯ 2 } extension twins during loading and their subsequent retreat during unloading. Detailed three-dimensional electron backscatter diffraction-based orientation microscopy (3D-EBSD) revealed that the presence of residual deformation twins depended on the depth of the indent. Analysis of residual geometrically necessary dislocation density using the EBSD data showed that residual basal 〈a〉 dislocations were dominant in the deformation zone. The crystallographic misorientation observed below the indent can be rationalized by the presence of these basal 〈a〉 dislocations and this is shown to be consistent with crystal plasticity finite element method calculations. Finally, a schematic view of the different stages of deformation during loading and unloading is proposed to rationalize the experimental observations. [ABSTRACT FROM AUTHOR]

Published

2016

26. Instrumented Indentation Test: Contact Stiffness Evaluation in the Nano-range

Author

Maculotti, Giacomo, Genta, Gianfranco, Lorusso, Massimo, Pavese, Matteo, Ugues, Daniele, and Galetto, Maurizio

Published

2019

27. Avaliação de métodos analíticos para determinação de propriedades mecânicas de aços via ensaio de macroindentação instrumentada

Author

Eduardo Ribeiro Nicolosi, Franco, Sinésio Domingues, Oliveira, Sônia Aparecida Goulart de, and Paes, Marcelo Torres Piza

Subjects

ENGENHARIAS::ENGENHARIA MECANICA [CNPQ], Macroindentação instrumentada, Fragilização por hidrogênio, Métodos analíticos, Tensile properties, Chemistry, Aços para a indústria de óleo e gás, Analytical methods, Propriedades mecânicas de tração, Hydrogen embrittlement, Instrumented indentation test, Steels for the oil and gas industry, Nuclear chemistry

Abstract

In situ instrumented indentation tests (IIT) can be used to determine tensile properties as a non-destructive alternative to the destructive tension test, especially when the removal of large amounts of test material from in-service structures implies high cost due to the interruption of operations. The ability of the analytical methods proposed by Haggag et al. and by Ahn and Kwon for determination of yield strength and ultimate tensile strength was assessed by instrumented indentation tests performed on steels for the oil and gas industry. For the analytical method proposed by Haggag et al. , the use of the material parameters Bm= 0.2285 and Xm= 1.200, employed for steels in several studies, proved unable to determine the tensile properties of steels analyzed in the present work. It was found that the indentation results were not in agreement with the tensile data (error up to 35%). Statistical analysis indicated that the empirical parameters Bm and Xm depend on both the indenter diameter and the maximum indentation load. An alternative for determining the tensile properties of steels using Haggag s Model is presented, based on the incorporation of the yield offset parameter, bm, and new values for the parameters Bm, bm and Xm. Use of different empirical correlations for estimating the yield strength and tensile strength from indentation hardness measurements was also investigated. The methodology here proposed validated the instrumented indentation test for determination of tensile properties of steels within a range of error of 10%. Furthermore, tests performed on ABNT 8550 steel specimens, exposed to a high hydrogen pressure, suggest that the instrumented indentation test may be applicable for hydrogen embrittlement detection in steels. O ensaio de macroindentação instrumentada realizado in situ, por ser não destrutivo e utilizar equipamentos portáteis, é uma alternativa na determinação de propriedades mecânicas de tração de materiais de estruturas nas quais a remoção de corpos de prova de grandes dimensões, para realização de ensaios de tração, implica em elevados custos devido à interrupção da operação, como é o caso de dutos de escoamento de petróleo. A capacidade dos modelos analíticos de Haggag et al. e de Ahn e Kwon de estimar os limites de escoamento e de resistência de aços foi avaliada através da realização de ensaios de macroindentação instrumentada em amostras de aços usados na indústria de óleo e gás. Para o Modelo de Haggag et al. , a utilização dos parâmetros de cálculo empíricos Bm= 0,2285 e Xm= 1,200, adotados para aços em vários trabalhos, mostrou-se incapaz de estimar de forma satisfatória os limites de escoamento e de resistência dos aços analisados, pois os erros em relação às propriedades mecânicas determinadas em ensaios de tração atingiram valores de até 35%. Análises estatísticas indicaram que os parâmetros de cálculo Bm e Xm dependem do diâmetro do penetrador e da força máxima usados nos ensaios. Uma metodologia alternativa para calcular o limite de escoamento de aços usando o Modelo de Haggag et al. é apresentada, através da introdução de um novo parâmetro, bm (offset de escoamento), e novos valores de Bm, bm e Xm são propostos. Diversas correlações para o cálculo das propriedades de tração a partir da dureza, determinada via ensaio de macroindentação, também foram avaliadas. A metodologia para realização e análise de ensaios de macroindentação instrumentada apresentada e validada no presente trabalho permite estimar as propriedades mecânicas de tração de aços com erros inferiores a 10%. Além disso, os resultados de ensaios em amostras do aço ABNT 8550, expostas ao gás H2 em alta pressão, sugerem que o ensaio de macroindentação instrumentada pode ser utilizado na detecção da fragilização por hidrogênio em aços. Mestre em Engenharia Mecânica

Published

2021

28. Disturbance induced by surface preparation on instrumented indentation test.

Author

Li, Yugang, Kanouté, Pascale, and François, Manuel

Subjects

*SURFACE coatings, *COATING processes, *SURFACES (Technology), *SURFACE preparation, *SUBSTRATES (Materials science)

Abstract

Surface preparation, which may induce considerable sample disturbance, plays an important role in instrumented indentation test (IIT). In this study, the sample disturbance (mainly divided into residual stresses and plastic strain) induced by the surface preparation process of instrumented indentation test specimens were investigated with both experimental tests and numerical simulations. Grazing incidence X-ray diffractions (GIXRD) and uniaxial tensile tests were conducted for characterizing the residual stresses and high plastic strain in the top surface layers of a carefully mechanically polished indentation sample, which, in the present work, is made of commercially pure titanium. Instrumented indentation tests and the corresponding finite element simulations were performed as well. For comparison, a reference sample (carefully mechanically polished & electrolytically polished) which represents the raw material was prepared and tested. Results showed that a careful mechanical polishing procedure can effectively reduce the level of residual stresses induced by this process. However, the high plastic strain in the surface region imposed by the polishing process is significant. The induced plastic strain can affect a depth up to 5 µm, which is deeper than the maximum penetration depth h max (3 µm) used for the instrumented indentation tests. In the near surface layer (in the range of depth about 350 nm), the plastic strain levels are fairly high. In the very top layer, the plastic strain was even estimated to reach more than 60%. The simultaneous use of indentation tests and numerical simulations showed that the existence of high plastic strain in the surface region will make the load vs depth ( P – h ) curve shift upwards, the contact hardness ( H ) increase and the contact stiffness ( S ) decrease. [ABSTRACT FROM AUTHOR]

Published

2015

29. Using the Instrumented Indentation Technique (IIT) on API Pipe.

Author

Ro, Dongseong, Kim, Kwang-ho, Song, Sung-min, and Kwon, Dongil

Abstract

The article discusses a study that assessed the validity of mechanical properties measurement by instrumented indentation technique (IIT) in an American Petroleum Industry (API) grade steel weldment. It compared the flow strength measured with the results from uniaxial tensile testing. It also discussed the use of the AIS2100 instrumented indentation tester developed by Frontics Co. to the evaluation of compatibility of a weldment of industrial equipment and to the pre-qualification test.

Published

2010

30. Using Instrumented Indentation to Evaluate High-temperature Mechanical Properties.

Author

Chan-Pyoung Park, Seung-Kyun Kang, Won-Je Jo, and Dongil Kwon

Abstract

The article discusses research on the use of instrumented indentation for the analysis of high-temperature mechanical properties. The researchers argued that the evaluation of mechanical properties is essential at high temperatures in order to forecast fracture behavior and deformation. They compared the efficiency of a contact area calibration function with conventional hardness tests.

Published

2010

31. Application of Macro-Instrumented Indentation Test for Superficial Residual Stress and Mechanical Properties Measurement for HY Steel Welded T-Joints

Author

J.J. Lee, Oh Min Kwon, Seong-Min Kim, Hee-Keun Lee, Won-Ki Kang, Jong-Il Lim, Seungha Lee, Kyungyul Lee, and Dongil Kwon

Subjects

Toughness, Technology, Materials science, Bainite, yield strength, residual stress, 02 engineering and technology, Welding, 01 natural sciences, Article, law.invention, law, Residual stress, Indentation, 0103 physical sciences, Ultimate tensile strength, General Materials Science, Composite material, 010302 applied physics, welding, Microscopy, QC120-168.85, QH201-278.5, instrumented indentation test, 021001 nanoscience & nanotechnology, Engineering (General). Civil engineering (General), TK1-9971, Descriptive and experimental mechanics, Martensite, high-yield-strength steel, Arc welding, Electrical engineering. Electronics. Nuclear engineering, TA1-2040, 0210 nano-technology

Abstract

HY-80 and HY-100 steels, widely used in constructing large ocean vessels and submarine hulls, contain mixed microstructures of tempered bainite and martensite and provide high tensile strength and toughness. Weld integrity in HY steels has been studied to verify and optimize welding conditions. In this study, the T-joint weld coupons, HY80 and HY100, were fabricated from HY-80 and HY-100 steel plates with a thickness of 30 mm as base metals by submerged-arc welding. Flux-cored arc welding was performed on an additional welding coupon consisting of HY-100 to evaluate the effect of repair welds (HY100RP). Microstructures in the heat-affected zones (HAZ) were thoroughly analyzed by optical observation. Instrumented indentation testing, taking advantage of local characterization, was applied to assess the yield strength and the residual stress of the HAZ and base regions. The maximum hardness over 400 HV was found in the HAZ due to the high volume fraction of untempered martensite microstructure. The yield strength of the weld coupons was evaluated by indentation testing, and the results showed good agreement with the uniaxial tensile test (within 10% range). The three coupons showed similar indentation residual stress profiles on the top and bottom surfaces. The stress distribution of the HY100 coupon was comparable to the results from X-ray diffraction. HY100RP demonstrated increased tensile residual stress compared to the as-welded coupon due to the effect of the repair weld (323 and 103 MPa on the top and bottom surfaces). This study verifies the wide applicability of indentation testing in evaluating yield strength and residual stress.

Published

2021

32. Uncertainty estimation by bootstrap sampling of area shape function in nano-indentation testing

Author

Maculotti, Giacomo, Genta, Gianfranco, and Galetto, Maurizio

Subjects

Area shape function, Instrumented Indentation Test, Measurement Uncertainty, Bootstrap, Instrumented Indentation Test, Area shape function, Bootstrap, Measurement Uncertainty

Published

2021

33. Evaluation of tensile properties of austenitic stainless steel 316L with linear hardening by modified indentation method.

Author

Wu, S. B. and Guan, K. S.

Subjects

*AUSTENITIC stainless steel, *STRAIN hardening, *STRESS-strain curves, *TENSILE strength, *INDENTATION (Materials science)

Abstract

The instrumented indentation test has been widely used for the non-destructive evaluation of the tensile properties ofmetal materials. The true stress-strain curve, yield strength and tensile strength can be obtained by this method. In the present study, a new modified indentation algorithm was used to determine the tensile properties of austenitic stainless steel 316L by taking into account its linear hardening characteristic. As received 316L was solution treated at four different temperatures in the range of 1223-1473K for 2 h followed by water quenching. The effect of solution treatment temperature on the tensile properties of 316L was investigated by the instrumented indentation test using the modified indentation algorithm. Results reveal that the new modified indentation algorithm can be used to estimate the tensile properties of austenitic stainless steel with linear hardening. [ABSTRACT FROM AUTHOR]

Published

2014

34. Estimating Young's modulus and Poisson's ratio by instrumented indentation test.

Author

Zorzi, J.E. and Perottoni, C.A.

Subjects

*ESTIMATION theory, *YOUNG'S modulus, *POISSON'S ratio, *INDENTATION (Materials science), *INFORMATION storage & retrieval systems, *EMPIRICAL research

Abstract

Abstract: The estimate of Young's modulus from instrumented indentation test results relies on knowing in advance the Poisson's ratio of the sample's material. However, in many cases this information is missing. In this paper we show how an empirical correlation between hardness and elastic moduli, along with the usual instrumented indentation test, allows the estimation of both Young's modulus and Poisson's ratio (and, from them, the bulk and shear moduli) for homogeneous and isotropic samples. The results obtained in this work indicate that the proposed approach represents an improvement over previous practices for the estimation of E and ν from indentation tests, particularly for hard ceramic materials in case no previous information on Poisson's ratio is available. [Copyright &y& Elsevier]

Published

2013

35. Indentation size effect of cortical bones submitted to different soft tissue removals.

Author

Bandini, A., Chicot, D., Berry, P., Decoopman, X., Pertuz, A., and Ojeda, D.

Subjects

INDENTATION (Materials science), ELASTOPLASTICITY, BONE mechanics, ANISOTROPY, HYDRATION, ELASTIC modulus

Abstract

Abstract: Properties of elasticity, hardness and viscosity are determined for the study of the visco-elastoplastic behavior of bones. The mechanical properties are compared in two upright sections of the bone due to their anisotropy. Besides, influence of hydration treatments leading to structural modifications of collagen and ground substance contents of bones on the mechanical properties is studied on a femoral cortical bovine bone. The treatments applied to the bone are used by forensic anthropologists to remove the soft tissue and modifying the hydration degree coupled to the collagen content. From instrumented indentation experiments, the hardness is characterized by the macrohardness and a hardness length-scale factor stating the hardness-load dependence. The elastic modulus results from the application of the methodology of Oliver and Pharr (1992). The coefficient of viscosity is deduced from a rheological model representing the indenter time–displacement observed under the application of a constant load. As a result, all the mechanical properties are found to be lower in the transverse section in an extent depending on the hydration treatment, i.e. the different values are located between 5% and 25% for the hardness around 0.5GPa, between 25% and 40% for the elastic modulus around 20GPa and between 2% and 35% for the coefficient of viscosity around 60GPa.s. Unexpectedly, the elastic modulus to coefficient of viscosity ratio is found to be independent on the hydration treatment. [Copyright &y& Elsevier]

Published

2013

36. Effect and measurement of the machine compliance in the macro range of instrumented indentation test

Author

Ullner, Christian, Reimann, Erhard, Kohlhoff, Harald, and Subaric-Leitis, Andreas

Subjects

*MEASUREMENT, *INDENTATION (Materials science), *MATERIALS testing, *PHYSICAL measurements, *HARDNESS, *CALIBRATION, *ELASTICITY

Abstract

Abstract: The contribution concerns the strong effect of the machine compliance in the upper macro range of the instrumented indentation test on hard materials. To achieve a minimum uncertainty in determination of the machine compliance the measurement and analysis needed for the determination are studied in detail. Based on the assumption that the hardness and/or the indentation modulus are force independent, four methods on the determination of the machine compliance are described. Experimental results of a commercial testing machine up to 2500N and of a standard machine up to 200N are analyzed. The results show that the uncertainty of the compliance is usually higher than requested for a precisely enough determination of hardness and further materials parameters. Especially for the calibration of reference materials with high hardness and/or Young’s modulus, the machine compliance should be limited in ISO 14577 part 3, 2003 . [Copyright &y& Elsevier]

Published

2010

37. A Method for Estimating Uncertainty of Indentation Tensile Properties in Instrumented Indentation Test.

Author

Eun-chae Jeon, Joo-Seung Park, Doo-Sun Choi, Kug-Hwan Kim, and Dongil Kwon

Subjects

*INDENTATION (Materials science), *MECHANICAL behavior of materials, *STRENGTH of materials, *BRINELL test, *TOURNAMENTS (Graph theory), *MODELS & modelmaking, *ESTIMATION theory

Abstract

The instrumented indentation test, which measures indentation tensile properties, has attracted interest recently because this test can replace uniaxial tensile test. An international standard for instrumented indentation test has been recently legislated. However, the uncertainty of the indentation tensile properties has never been estimated. The indentation tensile properties cannot be obtained directly from experimental raw data as can the Brinell hardness, which makes estimation of the uncertainty difficult. The simplifying uncertainty estimation model for the indentation tensile properties proposed here overcomes this problem. Though the influence quantities are generally defined by experimental variances when estimating uncertainty, here they are obtained by calculation from indentation load-depth curves. This model was verified by round-robin test with several institutions. The average uncertainties were estimated as 18.9% and 9.8% for the indentation yield strength and indentation tensile strength, respectively. The values were independent of the materials mechanical properties but varied with environmental conditions such as experimental instruments and operators. The uncertainties for the indentation yield and tensile strengths were greater than those for the uniaxial tensile test. These larger uncertainties were caused by measuring local properties in the instrumented indentation test. The two tests had the same tendency to have smaller uncertain ties for tensile strength than yield strength. These results suggest that the simplified model can be used to estimate the uncertainty in indentation tensile properties. [ABSTRACT FROM AUTHOR]

Published

2009

38. Characterization of the Strain-Rate-Dependent Plasticity of Alloys Using Instrumented Indentation Tests.

Author

Chen, Ta-Te, Watanabe, Ikumu, and Funazuka, Tatsuya

Subjects

HIGH temperatures, TENSILE tests, ALLOYS, STRESS-strain curves

Abstract

Instrumented indentation tests are an efficient approach for the characterization of stress–strain curves instead of tensile or compression tests and have recently been applied for the evaluation of mechanical properties at elevated temperatures. In high-temperature tests, the rate dependence of the applied load appears to be dominant. In this study, the strain-rate-dependent plasticity in instrumented indentation tests at high temperatures was characterized through the assimilation of experiments with a simulation model. Accordingly, a simple constitutive model of strain-rate-dependent plasticity was defined, and the material constants were determined to minimize the difference between the experimental results and the corresponding simulations at a constant high temperature. Finite element simulations using a few estimated mechanical properties were compared with the corresponding experiments in compression tests at the same temperature for the validation of the estimated material responses. The constitutive model and determined material constants can reproduce the strain-rate-dependent material behavior under various loading speeds in instrumented indentation tests; however, the load level of computational simulations is lower than those of the experiments in the compression tests. These results indicate that the local mechanical responses evaluated in the instrumented indentation tests were not consistent with the bulk responses in the compression tests at high temperature. Consequently, the bulk properties were not able to be characterized using instrumented indentation tests at high temperature because of the scale effect. [ABSTRACT FROM AUTHOR]

Published

2021

39. Inverse identification of constitutive parameters with instrumented indentation test considering the normalized loading and unloading P-h curves

Author

Manuel François, Yu Gang Li, Hao Wei Wang, Dong Chen, Pascale Kanouté, Shanghai Jiao Tong University [Shanghai], Laboratoire des Systèmes Mécaniques et d'Ingénierie Simultanée (LASMIS), Institut Charles Delaunay (ICD), Université de Technologie de Troyes (UTT)-Centre National de la Recherche Scientifique (CNRS)-Université de Technologie de Troyes (UTT)-Centre National de la Recherche Scientifique (CNRS), DMAS, ONERA, Université Paris Saclay [Châtillon], and ONERA-Université Paris-Saclay

Subjects

Materials science, Inverse, Absolute value, 02 engineering and technology, Plasticity, Instrumented indentation test, Tip rouding, 0203 mechanical engineering, Indentation, [SPI.MECA.MEMA]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Mechanics of materials [physics.class-ph], General Materials Science, Sensitivity (control systems), Anisotropy, Multiobjective optimization, Applied Mathematics, Mechanical Engineering, Rounding, Mathematical analysis, Constitutive parameter identification, Function (mathematics), 021001 nanoscience & nanotechnology, Condensed Matter Physics, 020303 mechanical engineering & transports, Mechanics of Materials, Modeling and Simulation, 0210 nano-technology, Finite element simulation

Abstract

International audience; The feature of instrumented indentation test (IIT) makes it suitable for the characterization of local constitutive behavior in a small volume of solids. In the present study, the relationship between the shape of the normalized loading P-h curve and the indenter tip rounding radius, and the influences of the constitutive parameters of a Ludwik-type isotropic hardening model on the shape and the initial slope of the normalized unloading P-h curve were investigated by theoretical analysis and sophisticated numerical sensitivity analysis. From the analytical results, a two-stage analytical approach that can inversely identify multiconstitutive parameters simultaneously was proposed. In the first stage, by considering the least-square distance between the experimental and the simulated normalized loading P-h curves (g(h/hmax)) as the objective and C1 in the tip area function as the input variable, the tip rounding was identified by a single-objective optimization procedure. With the optimal tip rounding, a multiobjective optimization procedure was then performed to identify the constitutive parameters of the target materials. The initial slope of the normalized unloading P-h curve (ΔS’( P / Pmax-h / hmax )), absolute value of the differences between the simulated and the experimental maximum load (ΔPmax), initial slope of the unloading P-h curve (ΔS), and contact hardness (ΔH) were set as objectives, while all the material parameters except the Poisson's ratio (v) were considered as input variables. Results of the numerical verification with a set of arbitrarily selected constitutive parameters and the experimental verification on Ti-18 (a near-β high-strength titanium alloy) fit fairly well with uniaxial tensile parameters. With regard to T40, the identified true stress-true plastic strain curve is about 20% higher than the uniaxial tensile curve. One possible explanation is the occurrence of the strength differential and anisotropy effects during the plastic deformation process of α-phase titanium. It is worthy to be noticed that the present study may propose a new way to calibrate the tip area function directly on the target material without any standard indentation sample and improve the quality of the identification of the material constitutive parameters by IIT.

Published

2019

40. Instrumented Indentation Test in the Nano‑range: Performances Comparison of Testing Machines Calibration Methods

Author

Raffaello Levi, Giacomo Maculotti, Gianfranco Genta, Maurizio Galetto, and Giulio Barbato

Subjects

Computer science, Mechanical Engineering, Materials Science (miscellaneous), Frame (networking), Work (physics), Mechanical engineering, Frame compliance, Industrial and Manufacturing Engineering, Instrumented indentation test, Instrumented indentation test, Frame compliance, Indenter area, Indenter area, Compatibility (mechanics), Vickers hardness test, Calibration, Range (statistics), A priori and a posteriori, Effective method

Abstract

In the modern manufacturing industry, dealing with innovative productions and advanced materials, technological surface characterisation is becoming crucial to qualify components and optimise processes. Instrumented indentation test is an effective method for characterising mechanical behaviour of materials through the analysis of the force–displacement curve obtained during the implementation of a predefined loading/unloading cycle. Instrumented indentation test allows for hardness test to be performed at different force ranges, thus enabling bulk to local material characterisation. To guarantee the characterisation accuracy, rigorous procedures for the calibration of testing machines are defined in ISO 14577-2. In particular, calibration of frame compliance and indenter area function may be addressed according to methods which do not require the indenter area function to be known a priori, thus avoiding the need of high-resolution microscopes. The present work aims at comparing performances and compatibility of these methodologies by considering tests performed in the nano-range.

Published

2019

41. Instrumented Indentation Test: Contact Stiffness Evaluation in the Nano‑range

Author

Massimo Lorusso, Giacomo Maculotti, Gianfranco Genta, Matteo Pavese, Daniele Ugues, and Maurizio Galetto

Subjects

0301 basic medicine, Materials science, Materials Science (miscellaneous), nano range, Modulus, Instrumented Indentation Test, Nano-range, Elastic modulus, Contact stiffness, Fitting model, Industrial and Manufacturing Engineering, law.invention, Nano-range, 03 medical and health sciences, 0302 clinical medicine, Instrumented Indentation Test, Contact stiffness, law, Indentation, medicine, Elastic modulus, Instrumented indentation test, elastic modulus, contact stiffness, fitting model, Bearing (mechanical), Mathematical model, business.industry, Fitting model, Mechanical Engineering, Experimental data, Stiffness, Structural engineering, Physics::Classical Physics, 030104 developmental biology, 030220 oncology & carcinogenesis, Vickers hardness test, medicine.symptom, business

Abstract

Instrumented indentation test is a non-conventional hardness test, relevant for performing both hardness measurement and estimating the elastic modulus. The indentation modulus, which depends on the contact stiffness, estimates the elastic modulus. To evaluate contact stiffness, the literature requires fitting force–displacement curve according to mathematical models, which are hardly representative of the curve. This research aims at proposing alternatives, which estimate contact stiffness directly from experimental data. Proposed methods are applied to nano-indentations performed on a reference material and a high-speed bearing steel; indentation modulus is evaluated along with uncertainty contribution of contact stiffness. Comparison with standard methods is provided.

Published

2019

42. Assessment of heat treatment effect on AlSi10Mg by selective laser melting through indentation testing

Author

Maculotti, G., Genta, G., Lorusso, M., and Galetto, M.

Subjects

Macro-indentation, Selective laser melting, Additive manufacturing, Heat treatment, Instrumented indentation test, Nano-indentation

Published

2019

43. Monte Carlo estimation of calibration uncertainty for Instrumented Indentation testing machines

Author

Maculotti, Giacomo, Genta, Gianfranco, and Galetto, Maurizio

Subjects

Instrumented Indentation Test, Instrumented Indentation Test, Calibration, Uncertainty, Monte Carlo, Calibration, Uncertainty, Monte Carlo

Published

2019

44. Application of Macro-Instrumented Indentation Test for Superficial Residual Stress and Mechanical Properties Measurement for HY Steel Welded T-Joints.

Author

Lee, Junsang, Lee, Kyungyul, Lee, Seungha, Kwon, Oh Min, Kang, Won-Ki, Lim, Jong-Il, Lee, Hee-Keun, Kim, Seong-Min, and Kwon, Dongil

Subjects

*STEEL welding, *STRAINS & stresses (Mechanics), *ELECTRIC welding, *RESIDUAL stresses, *STRESS concentration, *SHOT peening, *WELDED joints, *WELDING

Abstract

HY-80 and HY-100 steels, widely used in constructing large ocean vessels and submarine hulls, contain mixed microstructures of tempered bainite and martensite and provide high tensile strength and toughness. Weld integrity in HY steels has been studied to verify and optimize welding conditions. In this study, the T-joint weld coupons, HY80 and HY100, were fabricated from HY-80 and HY-100 steel plates with a thickness of 30 mm as base metals by submerged-arc welding. Flux-cored arc welding was performed on an additional welding coupon consisting of HY-100 to evaluate the effect of repair welds (HY100RP). Microstructures in the heat-affected zones (HAZ) were thoroughly analyzed by optical observation. Instrumented indentation testing, taking advantage of local characterization, was applied to assess the yield strength and the residual stress of the HAZ and base regions. The maximum hardness over 400 HV was found in the HAZ due to the high volume fraction of untempered martensite microstructure. The yield strength of the weld coupons was evaluated by indentation testing, and the results showed good agreement with the uniaxial tensile test (within 10% range). The three coupons showed similar indentation residual stress profiles on the top and bottom surfaces. The stress distribution of the HY100 coupon was comparable to the results from X-ray diffraction. HY100RP demonstrated increased tensile residual stress compared to the as-welded coupon due to the effect of the repair weld (323 and 103 MPa on the top and bottom surfaces). This study verifies the wide applicability of indentation testing in evaluating yield strength and residual stress. [ABSTRACT FROM AUTHOR]

Published

2021

45. Effect of contact stiffness and machine calibration in nano-indentation testing

Author

Giacomo Maculotti, Gianfranco Genta, Giulio Barbato, Maurizio Galetto, and Raffaello Levi

Subjects

0209 industrial biotechnology, Instrumented indentation, Computer science, instrumented indentation test, nano-range, contact stiffness, machine calibration, 02 engineering and technology, 020901 industrial engineering & automation, 0203 mechanical engineering, Indentation, medicine, Calibration, General Environmental Science, Alternative methods, business.industry, Work (physics), nano-range, machine calibration, Stiffness, Experimental data, Structural engineering, instrumented indentation test, Nanoindentation, 020303 mechanical engineering & transports, contact stiffness, General Earth and Planetary Sciences, medicine.symptom, business

Abstract

Instrumented indentation tests enable evaluation of several material parameters. Preliminary investigations underlined the influence of contact stiffness in the nano-range. ISO 14577-1 recommends two methods for contact stiffness evaluation, which, however, present shortcomings mainly related to the disregard of actual shape of unloading indentation curve. Given the relevance not only at the extent of material characterization, but also at testing machine calibration, alternative evaluation procedures have been developed, showing better agreement with experimental data and lower uncertainty in the evaluation of contact stiffness. In this work, shortcomings of standard and alternative methods in the evaluation of material parameters are highlighted, and innovative procedures are proposed to overcome them.

Published

2018

46. Indenter Shape Characterization for the Nanoindentation Measurement of Nanostructured and Other Types of Materials

Author

I.V. Krasnogorov, T. V. Kazieva, A. P. Kuznetsov, A.A. Rusakov, A. S. Useinov, and K. S. Kravchuk

Subjects

Berkovich indenter, Materials science, Atomic force microscopy, indenter area function, instrumented indentation test, Physics and Astronomy(all), Nanoindentation, Laser, hardness, law.invention, Characterization (materials science), Interferometry, law, Calibration, Composite material

Abstract

A review and comparison of different techniques for indenter shape characterization have been carried out. The techniques considered in this study are: a series of indentations in a reference material with known mechanical properties, a direct AFM observation of indenter apex and SPM imaging of calibration gratings supported with laser interferometer. All of the described techniques are analyzed in terms of the factors affecting the indenter shape characterization and the efficiency of obtaining the resulting indenter area function.

Published

2015

47. Characterization of Hardness and Stiffness of Ceramic Matrix Composites through Instrumented Indentation Test

Author

Shi, Yuan and Koch, Dietmar

Subjects

hardness and stiffness, ceramic matrix Composites, instrumented indentation test

Published

2017

48. Evaluation of Non-Equibiaxial Residual Stresses in Metallic Materials via Instrumented Spherical Indentation.

Author

Peng, Guangjian, Xu, Fenglei, Chen, Jianfeng, Wang, Huadong, Hu, Jiangjiang, and Zhang, Taihua

Subjects

DIMENSIONAL analysis, STRUCTURAL engineering, RESIDUAL stresses, MATERIALS

Abstract

Residual stresses, existed in engineering structures, could significantly influence the mechanical properties of structures. Accurate and non-destructive evaluation of the non-equibiaxial residual stresses in these structures is of great value for predicting their mechanical performance. In this work, investigating the mechanical behaviors of instrumented spherical indentation on stressed samples revealed that non-equibiaxial residual stresses could shift the load-depth curve upwards or downwards and cause the residual indentation imprint to be an elliptical one. Through theoretical, experimental, and finite element (FE) analyses, two characteristic indentation parameters, i.e., the relative change in loading curvature and the asymmetry factor of the residual indentation imprint, were found to have optimal sensitivity to residual stresses at a depth of 0.01R (R is the radius of spherical indenter). With the aid of dimensional analysis and FE simulations, non-equibiaxial residual stresses were quantitatively correlated with these two characteristic indentation parameters. The spherical indentation method was then proposed to evaluate non-equibiaxial residual stress based on these two correlations. Applications were illustrated on metallic samples (AA 7075-T6 and AA 2014-T6) with various introduced stresses. Both the numerical and experimental verifications demonstrated that the proposed method could evaluate non-equibiaxial surface residual stresses with reasonable accuracy. [ABSTRACT FROM AUTHOR]

Published

2020

49. Macro instrumented indentation test for structural materials: experimental and numerical methods

Author

Cagliero, Roberto

Subjects

Settore ING-IND/12 - Misure Meccaniche e Termiche, hardness, instrumented indentation test, structural materials, uncertainty

Published

2016

50. Quantifying Mechanical Properties of Automotive Steels with Deep Learning Based Computer Vision Algorithms.

Author

Javaheri, Ehsan, Kumala, Verdiana, Javaheri, Alireza, Rawassizadeh, Reza, Lubritz, Janot, Graf, Benjamin, and Rethmeier, Michael

Subjects

COMPUTER vision, DEEP learning, ALGORITHMS, WELDED steel structures, ARTIFICIAL neural networks, HIGH strength steel

Abstract

This paper demonstrates that the instrumented indentation test (IIT), together with a trained artificial neural network (ANN), has the capability to characterize the mechanical properties of the local parts of a welded steel structure such as a weld nugget or heat affected zone. Aside from force-indentation depth curves generated from the IIT, the profile of the indented surface deformed after the indentation test also has a strong correlation with the materials' plastic behavior. The profile of the indented surface was used as the training dataset to design an ANN to determine the material parameters of the welded zones. The deformation of the indented surface in three dimensions shown in images were analyzed with the computer vision algorithms and the obtained data were employed to train the ANN for the characterization of the mechanical properties. Moreover, this method was applied to the images taken with a simple light microscope from the surface of a specimen. Therefore, it is possible to quantify the mechanical properties of the automotive steels with the four independent methods: (1) force-indentation depth curve; (2) profile of the indented surface; (3) analyzing of the 3D-measurement image; and (4) evaluation of the images taken by a simple light microscope. The results show that there is a very good agreement between the material parameters obtained from the trained ANN and the experimental uniaxial tensile test. The results present that the mechanical properties of an unknown steel can be determined by only analyzing the images taken from its surface after pushing a simple indenter into its surface. [ABSTRACT FROM AUTHOR]

Published

2020