Your search keyword '"Korkmaz, İsmail Hakkı"' showing total 5 results

1. Koyun Ön Çapraz Bağının Hiperelastik Malzeme Özelliklerinin In-Vitro ve 3 Boyutlu Sonlu Elemanlar Analizi ile Değerlendirilmesi.

Author

KORKMAZ, İsmail Hakkı

Subjects

*ANTERIOR cruciate ligament, *STANDARD deviations, *TENSILE tests, *CURVE fitting, *COMPUTER simulation, *STRESS-strain curves

Abstract

Modeling of ligament tissues in computer simulations in biomechanics is important for achieving the simulation anatomically. These are often described as hyperelastic materials in these types of studies. However, in order to be defined as a hyperelastic material, a mathematical material model created with data obtained from tests such as tension, compression, and creep is needed. There are many phenomenological models that can be used as material models. In this study, ligament tissue simulation was created according to Neo-Hookean, Ogden 2nd Order and Yeoh 2nd Order hyperelastic material models. In-vitro uniaxial tensile testing of sheep anterior cruciate ligament was performed for data on the stressstrain curve to be used by the models. According to the data obtained from the tensile test, the material constants required for the material models were calculated. As a result of the analysis, it was determined that Ogden 2nd Order and Yeoh 2nd Order models were close results and Neo-Hookean model gave results with different stress values. The fit of the stress-strain curves obtained from three models and in-vitro test was evaluated according to the Root Mean Square Error(RMSE) values. RMSE values of Neo-Hookean, Ogden 2nd Order and Yeoh 2nd Order hyperelastic material models were obtained as 4.9597, 1.9704 and 2.3644, respectively. As a result, the Ogden 2nd Order hyperelastic material model with a high number of material constants produced results closer to in-vitro test results compared to both normal and von-mises stress values and RMSE values. Among the three models analyzed for simulations of ligament tissue, it was determined that the use of this material model was more appropriate. [ABSTRACT FROM AUTHOR]

Published

2021

2. Application of honeycomb pattern to Ti2AlN MAX phase films by plasma etching.

Author

Duran, Semih, Çiçek, Hikmet, Korkmaz, İsmail Hakkı, and Efeoğlu, İhsan

Subjects

*PLASMA etching, *HONEYCOMB structures, *MAGNETRON sputtering, *SURFACE cracks, *HEAT treatment

Abstract

The honeycomb pattern possesses a distinctive hexagonal structure capable of seamless repetition on a flat surface, leaving no gaps. Moreover, all arm thicknesses and angles are equal to one another. This remarkable configuration is deemed biomimetic, with numerous examples found in nature. Notably, it exhibits remarkably low density and exceptional mechanical strength. MAX phase films have gathered significant attention due to their exceptional capacity to amalgamate the essential properties of both metals and ceramics. Additionally, they possess the unique ability to effectively mend surface cracks that may arise as a result of friction-wear, restoring the material to a certain degree of integrity. In this study, Ti2AlN MAX phase thin films were deposited on M2 steel substrates by a closed field unbalanced magnetron sputtering system (CFUBMS). 750 °C heat treatment was applied to obtain the produced films in crystalline form. In addition, plasma etching parameters suitable for the phase structure of the deposited film were determined. With the inductive coupling plasma etching (ICP) process, the honeycomb pattern was given to the Ti2AlN MAX phase films with a continuous and smooth geometry at a depth of 2 μm. This study gives ideas for the development of multi-coating systems in which patterns of different geometries are included in a single layer. [ABSTRACT FROM AUTHOR]

Published

2024

3. Kişiye Özel ve Geleneksel Tibial Diz Protezi Bileşenlerinin Performans Analizi.

Author

KORKMAZ, İsmail Hakkı, KAYMAZ, İrfan, and YILDIRIM, Ömer Selim

Abstract

Total Knee Arthroplasty (TKA) treatment has been widely used for knee joint, having the most complex motion sequences and shape of the body, in case of loss of motion ability such as gonarthrosis. Lots of failures such as loosening, wear and instability have occurred as a result of increasing usage period. Instability is the most commonly seen failure associated with fixation. Especially loosening of tibial component is more common than that of femoral component. Evaluation of bone in terms of shape related with patient's weight, height and gender is required to increase the success of TKAs comprising traditional tibial components. Most of the current commercially available knee prostheses are designed based on the anthropometric data of Caucasian knees. This means an accordance problem for the people in different regions having different joint size. In this study, a patient specific tibial component has been designed according to cutting surface of tibial bone obtained from the patient's computed tomography images. This proposed design has been comparatively investigated with the traditional cemented tibial component by using the finite element analysis. In conclusion, more uniform stress distribution on the tibial trabecular bone related with stress shielding due to long term use was obtained in the patient specific prosthesis. The results have shown that the compatibility between the tibial bone and its component is better than the traditional model and possibility of loosening failure in the patient specific model is lower. [ABSTRACT FROM AUTHOR]

Published

2014

4. A new porous fixation plate design using the topology optimization.

Author

Murat, Fahri, Kaymaz, Irfan, and Korkmaz, Ismail Hakkı

Subjects

*FRACTURE fixation, *ISOGEOMETRIC analysis, *FINITE element method, *TOPOLOGY, *GEOMETRIC shapes

Abstract

• A pioneering work on developing fixation plates with graded porosity produced by additive manufacturing. • An optimum geometric form for the fixation plate obtained by topological optimization based on the finite element analysis. • A functionally-graded porous structure is created for the optimum bulk plate model. • For maximum stiffness, a gradual change in density of the porous plate is required. Fixation plates are used to accelerate the biological healing process in the damaged area by providing mechanical stabilization for fractured bones. However, they may cause mechanical and biological complications such as aseptic loosening, stress shielding effect and necrosis during the treatment process. The aim of this study, therefore, was to reduce mechanical and biological complications observed in conventional plate models. For this purpose, an optimum plate geometry was obtained using the finite element based topology optimization approach. An optimum and functionally graded porous model were obtained for the plates used for transverse fractures of diaphysis in long bones. This model was combined with a functional graded porous cage structure, and thus a new generation porous implant model was proposed for fixation plates. In order to determine the performance of the optimum plate model, it was produced by additive manufacturing. Three models; i.e. conventional, optimum and porous fixation plates were statically tested, and they were compared experimentally and numerically using the finite element analysis (FEA). The porous model can be considered as the most suitable option since it requires less invasive inputs, and might lead minimum necrosis formation due to having lesser contact surface with the bone. [ABSTRACT FROM AUTHOR]

Published

2021

5. Effects of process parameters on selective laser melting of Ti6Al4V-ELI alloy and parameter optimization via response surface method.

Author

Kaya, Gürkan, Yıldız, Fatih, Korkmaz, İsmail Hakkı, Kaymaz, İrfan, Yetim, Ali Fatih, Ergüder, Tevfik Oğuzhan, and Şen, Çağdaş

Subjects

*SELECTIVE laser melting, *SPECIFIC gravity, *X-ray computed microtomography, *HEAT treatment, *SCANNING electron microscopes, *ALLOYS

Abstract

Selective laser melting (SLM) allows for manufacturing intricate and accurate component designs that are challenging, expensive, or impossible to achieve using traditional methods. To achieve a high-quality final product with SLM, it is necessary to optimize the process parameters carefully. This optimization helps to minimize internal structural defects and control the microstructure. In this study, the optimum production parameters of Ti6Al4V alloy were determined using the Response Surface Method (RSM). The micro-CT analysis was utilized to calculate the relative densities of the samples fabricated using different production parameters. Furthermore, the influence of heat treatment, conducted below and above the β transformation temperature, on the mechanical properties was examined. The results were analyzed by considering the microstructure images obtained from Scanning Electron Microscope (SEM) and X-ray Diffraction (XRD) analysis. The optimum production parameters for the SLM method were found to be 80W laser power, 1125 mm/s scanning speed, 25 μm layer thickness, and 45 μm hatch distance. Samples created with these optimized parameters achieved 99.919% relative density, 1050 MPa ultimate tensile stress, and 13.8% elongation, surpassing the minimum standards outlined in ASTM F3001-14. Additionally, the systematic parameter reduction approach used in the study led to savings in both powder consumption and time in SLM, a method that could be applied to various metallic materials. • Ti6Al4V-ELI alloy was manufactured with selective laser melting method. • The response surface method was used to determine the optimum production parameters. • Micro-CT analysis was performed and density ratios were calculated. • Mechanical properties were improved with post processing operation. [ABSTRACT FROM AUTHOR]

Published

2023