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Fatih Karpat

Uludag University, Mechanical Engineering, Faculty Member

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University of Kragujevac

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Papers by Fatih Karpat

The Effect of Process Parameters on the Microstructure and Mechanical Performance of Fiber Laser-Welded AA5182 Aluminium Alloys

Strojniški vestnik, Sep 15, 2017

Couples of AISI 304L and AISI 1040 steels were welded using the continuous-drive friction-welding... more Couples of AISI 304L and AISI 1040 steels were welded using the continuous-drive friction-welding process. The welded joints were manufactured using three different rotational speeds ((1300, 1500 and 1700) r/min), three different frictional pressures and three different frictional times. To determine microstructural changes, the interface regions of the welded samples were examined by scanning electron microscopy (SEM), X-ray diffraction (XRD) and energy dispersive spectrometry (EDS). Microhardness and tensile tests of the welded samples were conducted. The results show that the properties of the microstructures are significantly changed and the interface temperature increased with the frictional time. An excellent tensile strength was observed for the joint made at a rotational speed of 1700 r/min and a frictional time of 4 s. Keywords: friction welding, AISI 1040 steel, AISI 304L steel Jekli AISI 304L in AISI 1040 sta bili zvarjeni z uporabo kontinuirnega tornega procesa varjenja. Zvarjeni spoji so bili izdelani pri treh razli~nih hitrostih vrtenja ((1300, 1500 in 1700) r/min), treh razli~nih tornih tlakih in treh razli~nih tornih~asih. Za dolo~itev mikrostrukturnih sprememb je bilo sti~no podro~je zvarjenega vzorca preiskano z vrsti~nim elektronskim mikroskopom (SEM), z rentgensko difrakcijo (XRD) in z energijsko disperzijsko rentgensko spektrometrijo (EDS). Izvr{eni so bili preizkusi mikrotrdote in natezni preizkusi varjenih vzorcev. Rezultati ka`ejo, da se mikrostruktura omembe vredno spremeni in da se temperatura stika povi{uje s~asom trenja. Odli~na natezna trdnost stika je bila ugotovljena pri spoju s hitrostjo vrtenja 1700 r/min in pri tornem~asu 4 s. Klju~ne besede: torno varjenje, jeklo AISI 1040, jeklo AISI 304L

Experimental measurement and numerical validation of single tooth stiffness for involute spur gears

Measurement, 2020

Experimental pre-clinical tests associated with numeric models of cemented implants are important... more Experimental pre-clinical tests associated with numeric models of cemented implants are important for screening of new implants in the market. The aim of this study was to measure strain profiles and maximum temperature polymerization inside a cement mantle of an in vitro cemented hip reconstruction using optical fiber Bragg grating (FBG) sensors. For this purpose, a hip femoral prosthesis was instrumented with 12 FBG sensors, three in each aspect of the femur, anterior, posterior, medial and lateral. These were positioned at the proximal, middle and distal part of the cement mantle relatively to the stem. Another sensor was placed in the lateral-proximal region of the mantle to measure the maximum temperature of cement polymerization. The strains measured were compared with those obtained with a Finite Element model, both for quaistatic mechanical loading. The results show that the experimental technique used can measure strains inside the cement mantle with good correlation, R 2 00.970, with the numerical model results. The results present a maximum temperature of polymerization around 110°C inside of cement at proximal region. It was also observed strain concentration in lateral aspect of the femur in polymerization process. The procedure hereby explained can be used to improve experimental pre-clinical tests to measure the strain distribution inside the cement mantle as well as residual strain and temperature variation along with time, as a result of the curing process of cement.

Experimental Verification and Finite Element Analysis of Automotive Door Hinge

In automotive industry, achieving lightweight, low-cost, reliable and more accurate product desig... more In automotive industry, achieving lightweight, low-cost, reliable and more accurate product design are the most important goal. Using Finite Element Analysis (FEA) is an important tool for achieving this since it decreases prototyping cost and time. Cars have different door system and one of the important part of them is door hinge. An automotive door hinge is mainly composed of three elements, fixed part, mobile part and hinge pin that fasten fixed part and mobile parts. Manufacturers have to perform tests and analysis for ensuring international and customer requirements. In this study, FEA results are compared with static and dynamic test results of front door hinge of automotive according to International specifications. The agreement between the computed and measured values is shown.

Influence of Heat Input on Mechanical Properties and Microstructure of Laser Welded Dissimilar Galvanized Steel-Aluminum Joints

Volume 2: Materials; Joint MSEC-NAMRC-Manufacturing USA, 2018

The hybrid structures of aluminum-steel have been increasingly used for body-in-white constructio... more The hybrid structures of aluminum-steel have been increasingly used for body-in-white constructions in order to reduce weight and green gas emissions. Obtaining acceptable joints between steel and aluminum required a better understanding of welding metallurgy and their effects on the resultant mechanical properties as well as the microstructure of the joints. In this research, the fiber laser welding of zero-gap galvanized steel and aluminum alloy in an overlapped configuration was carried out. The influence of heat input on the weld bead dimension, microstructural and mechanical properties of the joints was studied. A detailed study was conducted on the effects of the heat input on the penetration depth, weld width and microstructure of the laser welded dissimilar joints by means of an optical microscopy. A scanning electron microscopy with energy dispersive spectroscopy was carried out to determine the atomic percent of the elements for intermetallic compounds (IMC) occurred at th...

A comparative numerical study of forged bi-metal gears: Bending strength and dynamic response

Mechanism and Machine Theory, 2019

In this paper, an evaluation of the static and dynamic behavior of bimetallic spur gears with dif... more In this paper, an evaluation of the static and dynamic behavior of bimetallic spur gears with different gear parameters is performed numerically. Bimetallic lightweight spur gears working without a decrease in the performance of the gear mechanisms have many potential benefits in automotive and aerospace applications. A bimetallic spur gear consists of two metals which are steel on the gear teeth and aluminum on the hub region. The dynamic performance of these gears is evaluated by using a two degree of freedom (2-DOF) dynamic model. The finite element method is used to calculate maximum root stress for varying ring thicknesses and other gear parameters for gears with symmetric and asymmetric teeth. These stress values and the weight reduction ratios are taken into consideration to optimize the ring thickness. Tooth deflection is also calculated to determine tooth stiffness by finite element analysis (FEA). Dynamic simulations are carried out to investigate the effects of gear parameters on the dynamic force and static transmission error (STE). Sample simulation results are illustrated with numerical examples. The results indicate that, if properly designed, bimetallic gears can provide a high potential to reduce the weight in power transmission systems without adverse effects on stress and dynamic behavior.

Dengeli Gerilmeye Sahip Dişli Çark Çiftleri Üzerine Nümerik bir Araştırma

Uludağ University Journal of The Faculty of Engineering

Involute spur gears are key machine elements for power transmission in various industrial sectors... more Involute spur gears are key machine elements for power transmission in various industrial sectors. During power transmission, the teeth are subjected to high stresses. Many design modifications are used to reduce these stresses, such as increasing the drive side pressure angle and profile shifting factor. These modifications change the contact ratio and center distance of the gear pair. Changing the tooth thickness is another solution to reduce stress. Because there is a difference in the number of teeth between the pinion and the gear, the pinion stress levels are higher than the gear for the same gear parameters. The tooth thickness value in the pitch circle is equal to 0.5xπm for both pinion and gear as standard. Stress compensation can be achieved by increasing this thickness at the pinion and decreasing it at the same rate at the gear. In this study, first of all, 3D designs of gears with non-standard thickness were created in CATIA and finite element analyzes were performed to...

A One-Dimensional Convolutional Neural Network-Based Method for Diagnosis of Tooth Root Cracks in Asymmetric Spur Gear Pairs

Machines

Gears are fundamental components used to transmit power and motion in modern industry. Their heal... more Gears are fundamental components used to transmit power and motion in modern industry. Their health condition monitoring is crucial to ensure reliable operations, prevent unscheduled shutdowns, and minimize human casualties. From this standpoint, the present study proposed a one-dimensional convolutional neural network (1-D CNN) model to diagnose tooth root cracks for standard and asymmetric involute spur gears. A 6-degrees-of-freedom dynamic model of a one-stage spur gear transmission was established to achieve this end and simulate vibration responses of healthy and cracked (25%–50%–75%–100%) standard (20°/20°) and asymmetric (20°/25° and 20°/30°) spur gear pairs. Three levels of signal-to-noise ratios were added to the vibration data to complicate the early fault diagnosis task. The primary consideration of the present study is to investigate the asymmetric gears’ dynamic characteristics and whether tooth asymmetry would yield an advantage in detecting tooth cracks easier to add ...

Effects of tooth root cracks on vibration and dynamic transmission error responses of asymmetric gears: A comparative study

Mechanics Based Design of Structures and Machines

Effect of the cooling process on the mechanical properties and microstructural behavior of extruded AZ31 and AM50 Mg alloys

Materials Testing

During the extrusion of magnesium alloys, temperature change could have a significant effect on t... more During the extrusion of magnesium alloys, temperature change could have a significant effect on the outcome. When this effect is not considered, some commonly known defects might be observed, such as hot cracking. In this study, all samples consist of extruded AZ31 and AM50 magnesium alloys as a solid profile, but the methods by which they are cooled, such as air cooling and water quenching, vary. The effects of cooling methods on tensile-compression behavior and the microstructural properties of the samples were investigated. Test samples were obtained in extrusion direction and perpendicular to the extrusion direction separately for mechanical tests. The main purpose of this study was to investigate the effect of different cooling methods on the mechanical properties and microstructural behavior of AZ31 and AM50 magnesium alloys after extrusion, once different cooling methods were applied. According to the microstructural investigation results, an AM50 magnesium alloy has a finer ...

Numerical Analysis With Physical Test Correlation and Design Optimization of a Rollover Protective Structure (ROPS)

Volume 13: Safety Engineering, Risk, and Reliability Analysis, 2019

In this study, a rollover protective structure design was investigated according to its performan... more In this study, a rollover protective structure design was investigated according to its performance required for product validation. An investigation was performed by using finite element method and the acceptance criteria was taken from the OECD Code 6 standard. After performing finite element analyses in order to simulate ROPS loadings, it was found that the strength of the current ROPS design is good enough and this situation was correlated with physical tests. This situation allows to make some weight reduction studies. Firstly, an analytical optimization study performed on current ROPS design. A new ROPS design was achieved and this design was called as “Design 1”. After that, a parametric optimization study was built and newly achieved ROPS design was called as “Design - 2”. These optimization studies gave some design suggestions but the all changes in studies was not applied to new ROPS design because of some design constraints. The simulation results correlated with tests fo...

Influence of Linear Profile Modifications on the Dynamic Loading of a Spur Gear

Uludağ University Journal of The Faculty of Engineering, Aug 31, 2021

Gear dynamics is one of the most critical subjects in gear design because of its remarkable effec... more Gear dynamics is one of the most critical subjects in gear design because of its remarkable effect on vibration levels, load-carrying capacity, and noise. The tip relief modification is known as a simple method to decrease dynamic loads in the industry. The primary goal of this study is to understand the influence of tip relief modification on the dynamic performance of the spurs gears. In this paper, the meshing process and gear mesh stiffness calculation method are defined. A dynamic model with twodegree-of-freedom is created to find the dynamic response of the spur gear pair. The simulations are carried out with standard and different tip modified spur gear pairs. It is observed that the tip relief modification has an excellent effect on the gear dynamic response. However, this effect is restricted until a certain amount of tip relief modification. After the optimum amount of tip relief modification, the dynamic loads are increased considerably. Thus, a computer program is developed to find the optimum amount of tip relief modification in MATLAB ® for the gear designers. The program outputs are given for two different case studies. As a result of the study, the dynamic factor behaves like a "V form" according to the tip relief modification, and the dynamic force decreased approximately 25% for optimum profile modification.

Structural Analysis of Dental Implants with Various Micro Grove Profiles

The goal of this research was to determine the effect of changing micro-groove profile on an impl... more The goal of this research was to determine the effect of changing micro-groove profile on an implant to the stress transfer to surrounding bone. Different types of parametric groove profiles was designed on the cylindrical implant by using Solidworks and Visual Basic. Finite element analysis was carried out on the designed model by applying pullout test conditions. The boundary condition for the finite element model was generated from an in vivo experimental model. The results showed that implant with square groove profile shows better performance than V-shaped grooves for long-term implant stabilization. Such grooving can be engraved in dental implants in order to obtain long-term stabilization of the implant.

Laser Microgrooving and Nanofiber Membrane Application for Total Knee Replacement Implants Using a Caprine Model

Volume 5: Biomedical and Biotechnology, 2021

Aseptic loosening is a well-recognized phenomenon in cementless total knee replacement (TKR) and ... more Aseptic loosening is a well-recognized phenomenon in cementless total knee replacement (TKR) and often carries severe consequences for the patient. We recently developed and tested in vitro a novel strategy for enhancing osseointegration and acute mechanical stability of orthopedic implants that employ laser-induced microgroove (LIM) and nanofiber membrane (NFM) applications at the bone-implant interface. We report herein investigation of the approach with results from a pilot study employing three skeletally mature female Spanish cross goats (∼4y, 35–45kg) receiving cementless TKR with a commercially available implant system (Biomedrix® Canine Total Knee). Pre-operative radiographs were taken to ensure limb normality and to select the appropriately sized implants for each goat. With the animal under general anesthesia and the limb properly prepped for aseptic surgery, the stifle was approached, and osteotomies of the proximal tibia and distal femur performed in preparation for impl...

Examining Gear Design for Increased Reliability

An Investigation on the Design of Formate and Generate Face Milled Hypoid Gears

Hypoid gears are transmission elements that transfer power and moment between shafts whose axes d... more Hypoid gears are transmission elements that transfer power and moment between shafts whose axes do not intersect. They are similar in structure to spiral bevel gears. However, there are many advantages compared to spiral bevel gears in terms of load carrying capacity and rigidity. Hypoid gear pairs are mostly used as powertrain on the rear axles of cars and trucks. Hypoid gears are manufactured by two essential methods called face-milling and face-hobbing, and there are mainly two relative kinematic movements (Formate® and Generate). In this study, the gears produced with the Face-milling method are discussed. Face milled hypoid gears can be manufactured with both Formate® and Generate, while pinions can only be manufactured with the Generate method. The most crucial factor that determines the performance of hypoid gears is the geometry of hypoid gears. The gear and pinion geometry is directly dependent on the tool geometry, machine parameters, and relative motion between the cradle...

PMMA ve ABS MALZEMELERİN LAZER İLETİM KAYNAĞI İLE BİRLEŞTİRİLMESİNDE PROSES PARAMETRE ETKİLERİNİN İNCELENMESİ

Uludağ University Journal of The Faculty of Engineering, 2021

Stress Analysis of Internal Gear Pairs with Unequal Tooth Thickness

2018 9th International Conference on Mechanical and Aerospace Engineering (ICMAE), 2018

This study aims to increase load carrying capacity of internal spur gear mechanism with making st... more This study aims to increase load carrying capacity of internal spur gear mechanism with making stress balance between pinion and internal gear thanks to changing standard thickness on pitch circle. As standard, this thickness value is half of pitch. Actually, it could be changed provided that total pitch value is constant. To evaluate effect of tooth thickness change on stress, finite element analyses were conducted. As an expected result with increasing thickness on pitch circle, the stress decreases. Specific thickness values which make maximum stress equal was determined. Besides, the total mechanism weight was reduced with this design change.

A Review for Investigation Studies That are Done for Improving Image ProcessingClassification Based on Convolutional Neural Network (CNN) That is Architectural of Deep Learning

International Congress on Human-Computer Interaction, Optimization and Robotic Applications Proceedings, 2019

Effects of Heat Input in Laser Welding of Dissimilar Galvanized Steel to Aluminium Alloy

Proceedings of the 4th World Congress on Mechanical, Chemical, and Material Engineering, Aug 1, 2018

The hybrid structures of aluminum-steel have been increasingly used for body-in-white constructio... more The hybrid structures of aluminum-steel have been increasingly used for body-in-white constructions in order to reduce weight and cost. Obtaining acceptable joints between steel and aluminum required a better understanding of welding metallurgy and their effects on the resultant mechanical properties as well as the microstructure of the joints. In this research, laser welding of galvanized steel and aluminum alloy in an overlapped configuration was carried out. The influence of heat input on the weld bead dimension, microstructural and mechanical properties of the joints was studied. The experimental results showed that the penetration depth and weld width increased with the increase of heat input level. However, in order to limit IMC layer thickness and hardness at the surface of the weld seam and aluminum alloy, iron to aluminum dilution should be restricted by limiting the penetration depth. At lower heat input levels, less brittle IMC formation was formed. Consequently, with limited penetration depths at low heat input levels, tensile shear load increased, with failures located in the interface of the joints.

Laser-Induced Microgrooves Improve the Mechanical Responses of Cemented Implant Systems

Micromachines, 2020

The impact of a laser-induced microgroove (LIM) architecture on mechanical responses of two cemen... more The impact of a laser-induced microgroove (LIM) architecture on mechanical responses of two cemented implant systems was evaluated. One system consisted of two aluminum alloy rods bonded end-to-end by polymethylmethacrylate cement. The second system consisted of a custom-made, aluminum tibial tray (TT) cemented in an artificial canine tibia. Control specimens for each system were polished smooth at the cement interface. For LIM samples in the rod system, microgrooves were engraved (100 µm depth, 200 µm width, 500 µm spacing) on the apposing surface of one of the two rods. For TT system testing, LIM engraving (100 µm spacing) was confined to the underside and keel of the tray. Morphological analysis of processed implant surfaces revealed success in laser microgrooving procedures. For cemented rods tested under static tension, load to failure was greater for LIM samples (279.0 ± 14.9 N vs. 126.5 ± 4.5 N). Neither non-grooved nor grooved TT samples failed under cyclic compression testi...

The Effect of Process Parameters on the Microstructure and Mechanical Performance of Fiber Laser-Welded AA5182 Aluminium Alloys

Strojniški vestnik, Sep 15, 2017

Couples of AISI 304L and AISI 1040 steels were welded using the continuous-drive friction-welding... more Couples of AISI 304L and AISI 1040 steels were welded using the continuous-drive friction-welding process. The welded joints were manufactured using three different rotational speeds ((1300, 1500 and 1700) r/min), three different frictional pressures and three different frictional times. To determine microstructural changes, the interface regions of the welded samples were examined by scanning electron microscopy (SEM), X-ray diffraction (XRD) and energy dispersive spectrometry (EDS). Microhardness and tensile tests of the welded samples were conducted. The results show that the properties of the microstructures are significantly changed and the interface temperature increased with the frictional time. An excellent tensile strength was observed for the joint made at a rotational speed of 1700 r/min and a frictional time of 4 s. Keywords: friction welding, AISI 1040 steel, AISI 304L steel Jekli AISI 304L in AISI 1040 sta bili zvarjeni z uporabo kontinuirnega tornega procesa varjenja. Zvarjeni spoji so bili izdelani pri treh razli~nih hitrostih vrtenja ((1300, 1500 in 1700) r/min), treh razli~nih tornih tlakih in treh razli~nih tornih~asih. Za dolo~itev mikrostrukturnih sprememb je bilo sti~no podro~je zvarjenega vzorca preiskano z vrsti~nim elektronskim mikroskopom (SEM), z rentgensko difrakcijo (XRD) in z energijsko disperzijsko rentgensko spektrometrijo (EDS). Izvr{eni so bili preizkusi mikrotrdote in natezni preizkusi varjenih vzorcev. Rezultati ka`ejo, da se mikrostruktura omembe vredno spremeni in da se temperatura stika povi{uje s~asom trenja. Odli~na natezna trdnost stika je bila ugotovljena pri spoju s hitrostjo vrtenja 1700 r/min in pri tornem~asu 4 s. Klju~ne besede: torno varjenje, jeklo AISI 1040, jeklo AISI 304L

Experimental measurement and numerical validation of single tooth stiffness for involute spur gears

Measurement, 2020

Experimental pre-clinical tests associated with numeric models of cemented implants are important... more Experimental pre-clinical tests associated with numeric models of cemented implants are important for screening of new implants in the market. The aim of this study was to measure strain profiles and maximum temperature polymerization inside a cement mantle of an in vitro cemented hip reconstruction using optical fiber Bragg grating (FBG) sensors. For this purpose, a hip femoral prosthesis was instrumented with 12 FBG sensors, three in each aspect of the femur, anterior, posterior, medial and lateral. These were positioned at the proximal, middle and distal part of the cement mantle relatively to the stem. Another sensor was placed in the lateral-proximal region of the mantle to measure the maximum temperature of cement polymerization. The strains measured were compared with those obtained with a Finite Element model, both for quaistatic mechanical loading. The results show that the experimental technique used can measure strains inside the cement mantle with good correlation, R 2 00.970, with the numerical model results. The results present a maximum temperature of polymerization around 110°C inside of cement at proximal region. It was also observed strain concentration in lateral aspect of the femur in polymerization process. The procedure hereby explained can be used to improve experimental pre-clinical tests to measure the strain distribution inside the cement mantle as well as residual strain and temperature variation along with time, as a result of the curing process of cement.

Experimental Verification and Finite Element Analysis of Automotive Door Hinge

In automotive industry, achieving lightweight, low-cost, reliable and more accurate product desig... more In automotive industry, achieving lightweight, low-cost, reliable and more accurate product design are the most important goal. Using Finite Element Analysis (FEA) is an important tool for achieving this since it decreases prototyping cost and time. Cars have different door system and one of the important part of them is door hinge. An automotive door hinge is mainly composed of three elements, fixed part, mobile part and hinge pin that fasten fixed part and mobile parts. Manufacturers have to perform tests and analysis for ensuring international and customer requirements. In this study, FEA results are compared with static and dynamic test results of front door hinge of automotive according to International specifications. The agreement between the computed and measured values is shown.

Influence of Heat Input on Mechanical Properties and Microstructure of Laser Welded Dissimilar Galvanized Steel-Aluminum Joints

Volume 2: Materials; Joint MSEC-NAMRC-Manufacturing USA, 2018

The hybrid structures of aluminum-steel have been increasingly used for body-in-white constructio... more The hybrid structures of aluminum-steel have been increasingly used for body-in-white constructions in order to reduce weight and green gas emissions. Obtaining acceptable joints between steel and aluminum required a better understanding of welding metallurgy and their effects on the resultant mechanical properties as well as the microstructure of the joints. In this research, the fiber laser welding of zero-gap galvanized steel and aluminum alloy in an overlapped configuration was carried out. The influence of heat input on the weld bead dimension, microstructural and mechanical properties of the joints was studied. A detailed study was conducted on the effects of the heat input on the penetration depth, weld width and microstructure of the laser welded dissimilar joints by means of an optical microscopy. A scanning electron microscopy with energy dispersive spectroscopy was carried out to determine the atomic percent of the elements for intermetallic compounds (IMC) occurred at th...

A comparative numerical study of forged bi-metal gears: Bending strength and dynamic response

Mechanism and Machine Theory, 2019

In this paper, an evaluation of the static and dynamic behavior of bimetallic spur gears with dif... more In this paper, an evaluation of the static and dynamic behavior of bimetallic spur gears with different gear parameters is performed numerically. Bimetallic lightweight spur gears working without a decrease in the performance of the gear mechanisms have many potential benefits in automotive and aerospace applications. A bimetallic spur gear consists of two metals which are steel on the gear teeth and aluminum on the hub region. The dynamic performance of these gears is evaluated by using a two degree of freedom (2-DOF) dynamic model. The finite element method is used to calculate maximum root stress for varying ring thicknesses and other gear parameters for gears with symmetric and asymmetric teeth. These stress values and the weight reduction ratios are taken into consideration to optimize the ring thickness. Tooth deflection is also calculated to determine tooth stiffness by finite element analysis (FEA). Dynamic simulations are carried out to investigate the effects of gear parameters on the dynamic force and static transmission error (STE). Sample simulation results are illustrated with numerical examples. The results indicate that, if properly designed, bimetallic gears can provide a high potential to reduce the weight in power transmission systems without adverse effects on stress and dynamic behavior.

Dengeli Gerilmeye Sahip Dişli Çark Çiftleri Üzerine Nümerik bir Araştırma

Uludağ University Journal of The Faculty of Engineering

Involute spur gears are key machine elements for power transmission in various industrial sectors... more Involute spur gears are key machine elements for power transmission in various industrial sectors. During power transmission, the teeth are subjected to high stresses. Many design modifications are used to reduce these stresses, such as increasing the drive side pressure angle and profile shifting factor. These modifications change the contact ratio and center distance of the gear pair. Changing the tooth thickness is another solution to reduce stress. Because there is a difference in the number of teeth between the pinion and the gear, the pinion stress levels are higher than the gear for the same gear parameters. The tooth thickness value in the pitch circle is equal to 0.5xπm for both pinion and gear as standard. Stress compensation can be achieved by increasing this thickness at the pinion and decreasing it at the same rate at the gear. In this study, first of all, 3D designs of gears with non-standard thickness were created in CATIA and finite element analyzes were performed to...

A One-Dimensional Convolutional Neural Network-Based Method for Diagnosis of Tooth Root Cracks in Asymmetric Spur Gear Pairs

Machines

Gears are fundamental components used to transmit power and motion in modern industry. Their heal... more Gears are fundamental components used to transmit power and motion in modern industry. Their health condition monitoring is crucial to ensure reliable operations, prevent unscheduled shutdowns, and minimize human casualties. From this standpoint, the present study proposed a one-dimensional convolutional neural network (1-D CNN) model to diagnose tooth root cracks for standard and asymmetric involute spur gears. A 6-degrees-of-freedom dynamic model of a one-stage spur gear transmission was established to achieve this end and simulate vibration responses of healthy and cracked (25%–50%–75%–100%) standard (20°/20°) and asymmetric (20°/25° and 20°/30°) spur gear pairs. Three levels of signal-to-noise ratios were added to the vibration data to complicate the early fault diagnosis task. The primary consideration of the present study is to investigate the asymmetric gears’ dynamic characteristics and whether tooth asymmetry would yield an advantage in detecting tooth cracks easier to add ...

Effects of tooth root cracks on vibration and dynamic transmission error responses of asymmetric gears: A comparative study

Mechanics Based Design of Structures and Machines

Effect of the cooling process on the mechanical properties and microstructural behavior of extruded AZ31 and AM50 Mg alloys

Materials Testing

During the extrusion of magnesium alloys, temperature change could have a significant effect on t... more During the extrusion of magnesium alloys, temperature change could have a significant effect on the outcome. When this effect is not considered, some commonly known defects might be observed, such as hot cracking. In this study, all samples consist of extruded AZ31 and AM50 magnesium alloys as a solid profile, but the methods by which they are cooled, such as air cooling and water quenching, vary. The effects of cooling methods on tensile-compression behavior and the microstructural properties of the samples were investigated. Test samples were obtained in extrusion direction and perpendicular to the extrusion direction separately for mechanical tests. The main purpose of this study was to investigate the effect of different cooling methods on the mechanical properties and microstructural behavior of AZ31 and AM50 magnesium alloys after extrusion, once different cooling methods were applied. According to the microstructural investigation results, an AM50 magnesium alloy has a finer ...

Numerical Analysis With Physical Test Correlation and Design Optimization of a Rollover Protective Structure (ROPS)

Volume 13: Safety Engineering, Risk, and Reliability Analysis, 2019

In this study, a rollover protective structure design was investigated according to its performan... more In this study, a rollover protective structure design was investigated according to its performance required for product validation. An investigation was performed by using finite element method and the acceptance criteria was taken from the OECD Code 6 standard. After performing finite element analyses in order to simulate ROPS loadings, it was found that the strength of the current ROPS design is good enough and this situation was correlated with physical tests. This situation allows to make some weight reduction studies. Firstly, an analytical optimization study performed on current ROPS design. A new ROPS design was achieved and this design was called as “Design 1”. After that, a parametric optimization study was built and newly achieved ROPS design was called as “Design - 2”. These optimization studies gave some design suggestions but the all changes in studies was not applied to new ROPS design because of some design constraints. The simulation results correlated with tests fo...

Influence of Linear Profile Modifications on the Dynamic Loading of a Spur Gear

Uludağ University Journal of The Faculty of Engineering, Aug 31, 2021

Gear dynamics is one of the most critical subjects in gear design because of its remarkable effec... more Gear dynamics is one of the most critical subjects in gear design because of its remarkable effect on vibration levels, load-carrying capacity, and noise. The tip relief modification is known as a simple method to decrease dynamic loads in the industry. The primary goal of this study is to understand the influence of tip relief modification on the dynamic performance of the spurs gears. In this paper, the meshing process and gear mesh stiffness calculation method are defined. A dynamic model with twodegree-of-freedom is created to find the dynamic response of the spur gear pair. The simulations are carried out with standard and different tip modified spur gear pairs. It is observed that the tip relief modification has an excellent effect on the gear dynamic response. However, this effect is restricted until a certain amount of tip relief modification. After the optimum amount of tip relief modification, the dynamic loads are increased considerably. Thus, a computer program is developed to find the optimum amount of tip relief modification in MATLAB ® for the gear designers. The program outputs are given for two different case studies. As a result of the study, the dynamic factor behaves like a "V form" according to the tip relief modification, and the dynamic force decreased approximately 25% for optimum profile modification.

Structural Analysis of Dental Implants with Various Micro Grove Profiles

The goal of this research was to determine the effect of changing micro-groove profile on an impl... more The goal of this research was to determine the effect of changing micro-groove profile on an implant to the stress transfer to surrounding bone. Different types of parametric groove profiles was designed on the cylindrical implant by using Solidworks and Visual Basic. Finite element analysis was carried out on the designed model by applying pullout test conditions. The boundary condition for the finite element model was generated from an in vivo experimental model. The results showed that implant with square groove profile shows better performance than V-shaped grooves for long-term implant stabilization. Such grooving can be engraved in dental implants in order to obtain long-term stabilization of the implant.

Laser Microgrooving and Nanofiber Membrane Application for Total Knee Replacement Implants Using a Caprine Model

Volume 5: Biomedical and Biotechnology, 2021

Aseptic loosening is a well-recognized phenomenon in cementless total knee replacement (TKR) and ... more Aseptic loosening is a well-recognized phenomenon in cementless total knee replacement (TKR) and often carries severe consequences for the patient. We recently developed and tested in vitro a novel strategy for enhancing osseointegration and acute mechanical stability of orthopedic implants that employ laser-induced microgroove (LIM) and nanofiber membrane (NFM) applications at the bone-implant interface. We report herein investigation of the approach with results from a pilot study employing three skeletally mature female Spanish cross goats (∼4y, 35–45kg) receiving cementless TKR with a commercially available implant system (Biomedrix® Canine Total Knee). Pre-operative radiographs were taken to ensure limb normality and to select the appropriately sized implants for each goat. With the animal under general anesthesia and the limb properly prepped for aseptic surgery, the stifle was approached, and osteotomies of the proximal tibia and distal femur performed in preparation for impl...

Examining Gear Design for Increased Reliability

An Investigation on the Design of Formate and Generate Face Milled Hypoid Gears

Hypoid gears are transmission elements that transfer power and moment between shafts whose axes d... more Hypoid gears are transmission elements that transfer power and moment between shafts whose axes do not intersect. They are similar in structure to spiral bevel gears. However, there are many advantages compared to spiral bevel gears in terms of load carrying capacity and rigidity. Hypoid gear pairs are mostly used as powertrain on the rear axles of cars and trucks. Hypoid gears are manufactured by two essential methods called face-milling and face-hobbing, and there are mainly two relative kinematic movements (Formate® and Generate). In this study, the gears produced with the Face-milling method are discussed. Face milled hypoid gears can be manufactured with both Formate® and Generate, while pinions can only be manufactured with the Generate method. The most crucial factor that determines the performance of hypoid gears is the geometry of hypoid gears. The gear and pinion geometry is directly dependent on the tool geometry, machine parameters, and relative motion between the cradle...

PMMA ve ABS MALZEMELERİN LAZER İLETİM KAYNAĞI İLE BİRLEŞTİRİLMESİNDE PROSES PARAMETRE ETKİLERİNİN İNCELENMESİ

Uludağ University Journal of The Faculty of Engineering, 2021

Stress Analysis of Internal Gear Pairs with Unequal Tooth Thickness

2018 9th International Conference on Mechanical and Aerospace Engineering (ICMAE), 2018

This study aims to increase load carrying capacity of internal spur gear mechanism with making st... more This study aims to increase load carrying capacity of internal spur gear mechanism with making stress balance between pinion and internal gear thanks to changing standard thickness on pitch circle. As standard, this thickness value is half of pitch. Actually, it could be changed provided that total pitch value is constant. To evaluate effect of tooth thickness change on stress, finite element analyses were conducted. As an expected result with increasing thickness on pitch circle, the stress decreases. Specific thickness values which make maximum stress equal was determined. Besides, the total mechanism weight was reduced with this design change.

A Review for Investigation Studies That are Done for Improving Image ProcessingClassification Based on Convolutional Neural Network (CNN) That is Architectural of Deep Learning

International Congress on Human-Computer Interaction, Optimization and Robotic Applications Proceedings, 2019

Effects of Heat Input in Laser Welding of Dissimilar Galvanized Steel to Aluminium Alloy

Proceedings of the 4th World Congress on Mechanical, Chemical, and Material Engineering, Aug 1, 2018

The hybrid structures of aluminum-steel have been increasingly used for body-in-white constructio... more The hybrid structures of aluminum-steel have been increasingly used for body-in-white constructions in order to reduce weight and cost. Obtaining acceptable joints between steel and aluminum required a better understanding of welding metallurgy and their effects on the resultant mechanical properties as well as the microstructure of the joints. In this research, laser welding of galvanized steel and aluminum alloy in an overlapped configuration was carried out. The influence of heat input on the weld bead dimension, microstructural and mechanical properties of the joints was studied. The experimental results showed that the penetration depth and weld width increased with the increase of heat input level. However, in order to limit IMC layer thickness and hardness at the surface of the weld seam and aluminum alloy, iron to aluminum dilution should be restricted by limiting the penetration depth. At lower heat input levels, less brittle IMC formation was formed. Consequently, with limited penetration depths at low heat input levels, tensile shear load increased, with failures located in the interface of the joints.

Laser-Induced Microgrooves Improve the Mechanical Responses of Cemented Implant Systems

Micromachines, 2020

The impact of a laser-induced microgroove (LIM) architecture on mechanical responses of two cemen... more The impact of a laser-induced microgroove (LIM) architecture on mechanical responses of two cemented implant systems was evaluated. One system consisted of two aluminum alloy rods bonded end-to-end by polymethylmethacrylate cement. The second system consisted of a custom-made, aluminum tibial tray (TT) cemented in an artificial canine tibia. Control specimens for each system were polished smooth at the cement interface. For LIM samples in the rod system, microgrooves were engraved (100 µm depth, 200 µm width, 500 µm spacing) on the apposing surface of one of the two rods. For TT system testing, LIM engraving (100 µm spacing) was confined to the underside and keel of the tray. Morphological analysis of processed implant surfaces revealed success in laser microgrooving procedures. For cemented rods tested under static tension, load to failure was greater for LIM samples (279.0 ± 14.9 N vs. 126.5 ± 4.5 N). Neither non-grooved nor grooved TT samples failed under cyclic compression testi...