Person: KARAMANGİL, MEHMET İHSAN
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KARAMANGİL
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MEHMET İHSAN
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Publication Investigation of clutch hub strength with various geometries under variable torque conditions(Yildiz Technical Univ, 2020-03-01) Genç, Mehmet Onur; Karaduman, Alper; Aktaşgil, Zübeyir Ramazan; Karamangil, Mehmet İhsan; KARAMANGİL, MEHMET İHSAN; Bursa Uludağ Üniversitesi/Mühendislik Fakültesi/Otomotiv Mühendisliği Bölümü.; 0000-0001-5965-0313; AAH-8619-2019The clutch is a component that performs the duty of transmitting the torque generated by the internal combustion engines to the powertrain. The hub component on disc assembly is one of the most important components in this transmission process. During operation under torque conditions, a hub is supposed to withstand the radial loads. For this purpose, the structural strength analysis of the hub is of importance. In this study, the hub component of the clutch disc assembly is analyzed to simulate real driving conditions. In this analysis, analytical calculations and finite element calculations were made for different hub structures. By comparing the two calculations, the precision of the design and the reasons of failures were determined. According to FEA results, the maximum principal stress occurs in the contact regions where the pressure is applied. With respect to these results, the damage locations are compared to the parts which have been subjected to real bench test, and cracks/breaks occurred. After the tests, damage analysis was performed for fractures. This study enables the assumptions of the hub resistance under the various dynamic conditions with different hub geometry. Furthermore, this novel study provides the cost and time-saving in terms of the design phase in automotive engineering.Publication Development and comparative analysis of a pure fuel cell configuration for a light commercial vehicle(Springer, 2022-11-07) Tekin, Merve; Karamangil, Mehmet İhsan; TEKİN, MERVE; KARAMANGİL, MEHMET İHSAN; Bursa Uludağ Üniversitesi/Mühendislik Fakültesi/Otomotiv Mühendisliği Bölümü; 0000-0003-2831-3175; AAG-8571-2021; AAH-8619-2019Fuel cell electric vehicles help hybrid and battery electric vehicles to reduce vehicle emissions. Fuel cells are more appealing since, like internal combustion engines, they provide energy as long as fuel is supplied while doing so with less energy conversion and little or no emissions. In this study, the energy and fuel consumption values of a vehicle's internal combustion engine and fuel cell configurations were compared on a tank-to-wheel basis. First of all, a fuel consumption model was created for the conventional vehicle with 1.3 diesel engine. Subsequently, the fuel cell configuration of the same vehicle was designed by selecting a suitable fuel cell, electric motor, battery, and transmission. Then, the fuel cell vehicle configuration's hydrogen and energy consumptions were calculated. The equivalent diesel consumption of the fuel cell vehicle was determined to be 3.38 L/100 km at the end of the study, which is 32% better than an Internal Combustion Engine vehicle. Also, with theoretical regenerative braking in the fuel cell electric vehicle, consumed traction energy can be reduced by 27%, while with practical regenerative braking, 55% of the braking energy can be recovered, and the traction energy can be reduced by 15%. On the other hand, since there is no regenerative braking system in the conventional vehicle, all of the braking energy is lost as heat.Publication Electronic driver design of a piezo-actuated valve mechanism for continuously variable valve timing(Ieee, 2019-01-01) Dirim, B.; Sürmen, A.; Karamangil, M. I.; Avcı, A.; İkli, F. I.; Tekin, M.; Türköz, N.; Dirim, Bayazit; SÜRMEN, ALİ; KARAMANGİL, MEHMET İHSAN; AVCI, AYFER; TEKİN, MERVE; Türköz, N.; IŞIKLI, FIRAT; Bursa Uludağ Üniversitesi/Mühendislik Fakültesi/Elektrik-Elektronik Mühendisliği Bölümü.; Bursa Uludağ Üniversitesi/Mühendislik Fakültesi/Otomotiv Mühendisliği Bölümü.; Bursa Uludağ Üniversitesi/Mühendislik Fakültesi/Makine Mühendisliği Bölümü.; 0000-0003-1662-5649; 0000-0003-2831-3175; 0000-0002-9009-8069; AAH-8619-2019; KFR-7212-2024; JCN-8081-2023; AAG-8571-2021; HNS-2001-2023; EBD-3489-2022; EJZ-3309-2022Volumetric efficiency is the main parameter that characterizes the increase in power of an engine at the same speed. A group of design parameters that affects the volumetric efficiency are opening-closing characteristics of the valves (opening and closing times, valve lift and shape of cam lobe). But the same values of these parameters in various speeds yield different volumetric values which make the problem much more difficult. The solution is to develop techniques that change these parameters with changing engine speed. The most ideal one is to achieve this variation continuously together with speed variation which is called continuously variable valve timing (CVVT). To achieve this goal piezo actuator driven hydraulic displacement magnifier has been used. To drive the piezo actuator an electronic control unit and high voltage power amplifier designed and then fully digital solution is developed and explained in this study.Publication Experimental analysis of the volumetric and thermal efficiency performance of a novel direct piezo-acting cvvt mechanism(Taylor & Francis Inc, 2023-06-22) Sürmen, Ali; SÜRMEN, ALİ; Karamangil, M., I; KARAMANGİL, MEHMET İHSAN; Avcı, A.; AVCI, ATAKAN; Dirim, B.; DİRİM, MEHMET SABRİ; Işıklı, F.; IŞIKLI, FIRAT; Tekin, M.; TEKİN, MERVE; Türköz, N.; Bursa Uludağ Üniversitesi/Mühendislik Fakültesi/Otomotiv Mühendisliği Bölümü.; Bursa Uludağ Üniversitesi/Mühendislik Fakültesi/Elektrik Elektronik Mühendisliği Bölümü.; Bursa Uludağ Üniversitesi/Mühendislik Fakültesi/Makine Mühendisliği Bölümü.; 0000-0003-1662-5649; 0000-0003-2831-3175; 0000-0002-9009-8069; AAH-8619-2019; AAG-8571-2021; JCN-8081-2023; HNS-2001-2023In this study, a specifically designed direct-acting continuously variable valve timing mechanism was used to determine speed optimised valve timings for best volumetric efficiency of an engine. This mechanism basically consists of a piezo stack and a hydraulic magnifier integrated into it. To avoid effects of excessive vibrations on the piezo-stack, the engine was operated in a non-combustion mode. An electric motor was used to power the engine. Some system limitations of the hydraulic magnifier and the piezo-stack were the main challenges to a non-stop operation. A valve lift of approximately 4 mm, obtained with maximum applicable voltage of 600V to the piezo-stack, was referred to for comparison instead of the 7.6 mm original value. Tests were conducted for 30 inlet valve timing combinations at four different engine speeds from 1500 to 3000 rpm with 500 rpm increments. Timing pairs for the best VE were determined. They yielded 11.5% to 19.4% better volumetric efficiencies at 4mm lift than those obtained with the original valve timing of the cold engine. We also predicted 5-11.5% overall efficiency improvement, depending on engine type and operating conditions. Despite some practical challenges, better VE values have been obtained for a specific engine at varied speeds.