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ŞARJ EDİLEBİLİR PİLLERE GENEL BAKIŞ

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dc.creator SEZER, Kadir Can; Mehmet Akif Ersoy Üniversitesi
dc.creator BASMACI, Gültekin; BURDUR MEHMET AKİF ERSOY ÜNİVERSİTESİ, MÜHENDİSLİK-MİMARLIK FAKÜLTESİ, MAKİNE MÜHENDİSLİĞİ BÖLÜMÜ
dc.date 2022-03-23T00:00:00Z
dc.date.accessioned 2022-05-10T10:56:44Z
dc.date.available 2022-05-10T10:56:44Z
dc.identifier https://dergipark.org.tr/tr/pub/jesd/issue/69033/946769
dc.identifier 10.21923/jesd.946769
dc.identifier.uri http://acikerisim.sdu.edu.tr/xmlui/handle/123456789/96131
dc.description Günümüzde insansız hava araçları, insansız su altı araçları, robotik ve otonom cihazlar, hibrit ve elektrikli taşıtlar, taşınabilir bilgisayarlar, ileri teknoloji cep telefonları, küçük dijital kameralar, askeri yenilikler ve kablosuz cihazlar oldukça yaygınlaşmıştır. Bu nedenle, bu teçhizatlar için enerji depolaması sorunu oluşmuştur. Günümüzde en verimli piller arasında yer alan lityum iyon piller, piyasada yadsınamayacak kadar geniş bir alana sahiptir. Lityum iyon piller çok büyük bir kapasiteye sahiptir. Bununla birlikte, dünyadaki lityum kaynağının sınırlı olmasından dolayı, lityum iyon piller neredeyse sınırlarına ulaştı ve yüksek bir maliyetle karakterize edildi. Bu da lityum iyon pilleri gibi şarj edilebilir piller olarak adlandırılan bu tür teknolojilerin daha da geliştirilmesini gerektiriyor. Bu makale geçmişten günümüze geliştirilmiş olan sekonder yani şarj edilebilir pilleri incelemek için derlenmiş bir makaledir, bu piller, lityum hava piller, sodyum iyon piller, lityum sülfür piller gibi lityum iyon sonrası piller ve kurşun asit, nikel kadmiyum, nikel çinko, nikel metal hidrit gibi şarj edilebilir pillerdir.
dc.description Today, unmanned aerial vehicles, unmanned underwater vehicles, robotic and autonomous devices, hybrid and electric vehicles, portable computers, high-tech mobile phones, small digital cameras, military innovations and cordless devices have become widespread. Therefore, energy storage problem has arisen for these equipment. Lithium ion batteries, which are among the most efficient batteries today, have an undeniable wide area in the market. Lithium ion batteries have an enormous capacity. However, due to the limited supply of lithium in the world, lithium-ion batteries have almost reached their limits and are characterized by a high cost. This requires further development of such technologies called rechargeable batteries, such as lithium-ion batteries. This article is a review article to examine secondary rechargeable batteries developed from the past to the present, such as, lithium air batteries, sodium ion batteries, lithium sulfur batteries such as batteries developed on lithium-ion infrastructure and lead acid, nickel cadmium, nickel zinc, nickel metal hydride types of rechargeable batteries.
dc.format application/pdf
dc.language tr
dc.publisher Süleyman Demirel Üniversitesi
dc.publisher Süleyman Demirel University
dc.relation https://dergipark.org.tr/tr/download/article-file/1802345
dc.source Volume: 10, Issue: 1 297-309 en-US
dc.source 1308-6693
dc.source Mühendislik Bilimleri ve Tasarım Dergisi
dc.subject Şarj Edilebilir,Sekonder Pil,Elektrokimyasal,Li-İyon,Na-İyon
dc.subject Rechargeable,Secondary Battery,Electrochemical,Li-Ion,Na-Ion
dc.title ŞARJ EDİLEBİLİR PİLLERE GENEL BAKIŞ tr-TR
dc.title OVERVIEW OF RECHARGEABLE BATTERIES en-US
dc.type info:eu-repo/semantics/article
dc.citation Algül, H., 2015. Lityum Hava Pilleri İçin Ag/Mg Katkılı Anot Malzemelerinin Geliştirilmesi (Development of Increased Corrosion Resistance Anode Materials for Lithium Air Batteries), Yüksek Lisans Tezi, Sakarya Üniversitesi Fen Bilimleri Enstitüsü, 74s, Sakarya.
dc.citation Aras, U.T., 2009. Hibrit Elektrikli Araçların Batarya Sistemlerinin Bilgisayar Destekli Performans Analizi (Computer Aided Performance Analysis of Battery Systems of Hybrid Electrical Vehicles), Yüksek Lisans Tezi, Kocaeli Üniversitesi Fen Bilimleri Enstitüsü, 43s, Kocaeli.
dc.citation Arya, S., Verma, S., 2020. Nickel-Metal Hydride (Ni-MH) Batteries, Rechargeable Batteries, ss.131-176.
dc.citation Ayoub, E., Karami, 2015. Review on The Charging Techniques of a Li-ion Battery, Third Internatiaonal Conference on Technological Advances in Electrical, Electronics and Computer Engineering.
dc.citation Başaran, K., Çetin, N.S., Çelik, H., 2011. Rüzgar-Güneş Hibrit Güç Sistemi Tasarımı ve Uygulaması (Wind-Solar Hybrid Power System Design and Application), Conference: 6th International Advanced Technologies Symposium.
dc.citation Cheng, X.-B., Huang, J.-Q., Zhang, Q., 2018. Review—Li Metal Anode in Working Lithium-Sulfur Batteries, Journal of the Electrochemical Society, 165(1), 6058-6072.
dc.citation Cheng, X.-B., Zhang, R., Zhao, C.-Z., Zhang, Q., 2017. Toward Safe Lithium Metal Anode in Rechargeable Batteries: A Review, Chemical Reviews, 117(15), 10403-10473.
dc.citation Choi, J.W., Aurbach, D., 2016. Promise and Reality of Post-Lithium-Ion Batteries With High Energy Densities, Nature Reviews Materials, 1(4).
dc.citation Conte, F.V., 2006. Battery and Battery Management for Hybrid Electric Vehicles: A Review, e&i Elektrotechnik und Informationstechnik, 123(10), 424-431.
dc.citation Cope, R. C., Podrazhansky ,Y., 1999. The Art of Battery Charging, Fourteenth Annual Battery Conferece
dc.citation Dell, R.M., Rand, D.A.J., 2001. Understanding Batteries, The Royal Society of Chemistry, ss.100-101.
dc.citation Demir, U., Aküner, M.C., 2018. Design and Optimization of In-Wheel Asynchronous Motor for Electric Vehicle, Journal of the Faculty of Engineering and Architecture of Gazi University, 33(4), 1517-1530.
dc.citation Demirci, O., Demirci, B.A., Taşkın, S., 2019. Battery Cell Measurement and Fault Diagnosis System for Detection of Problem in Automotive Batteries, Pamukkale University Journal of Engineering Sciences, 25(5), 546-552.
dc.citation Deng, J., Luo, W.-B., Chou, S.-L., Liu, H.-K., Dou, S.-X., 2017. Sodium-Ion Batteries: From Academic Research to Practical Commercialization, Advanced Energy Materials, 8(4), 17014128.
dc.citation Din, E., Schaef, C., Moffat, K., Stauth, J.T., 2017. A Scalable Active Battery Management System With Embedded Realtime Electrochemical Impedance Spectroscopy, IEEE T. Power Electr., 32 (7), 5688-5698.
dc.citation Disosway, M., 1998. Development of High Power Nickel-Cadmium Batteries for Hybrid Vehicles, In Thirteenth Annual Battery Conference on Applications and Advances, Proceedings of the Conference.
dc.citation Er, M., 2016. Sn-Sb-Cu-C ve Sn-Co-C Sentezi ve Lityum İyon Pil Anot Materyali Olarak Kullanılmalarının İncelenmesi (Synthesis of Sn-Sb-Cu-C and Sn-Co-C and Investigation of Them Using as Anode Material for Lithium Ion Batteries), Yüksek Lisans Tezi, Sakarya Üniversitesi Fen Bilimleri Enstitüsü, 95s, Sakarya.
dc.citation Etacheri, V., Marom, R., Elazari, R., Salitra, G., Aurbach, D., 2011. Challenges in the Development of Advanced Li-Ion Batteries: a Review, Energ. Environ. Sci., 4 (9), 3243-3262.
dc.citation Gençten, M., 2013. Kurşun Asit Akülerin Performanslarının Artırılması (Increasing the Performance of Lead Acid Batteries), Yüksek Lisans Tezi, Anadolu Üniversitesi Fen Bilimleri Enstitüsü, 134s, Eskişehir.
dc.citation Güneş, D., Tekdemir, İ.G., Karaarslan, M.Ş., Alboyacı, B., 2018. Assessment of the Impact of Electric Vehicle Charge Station Loads on Reliability Indices, Journal of the Faculty of Engineering and Architecture of Gazi University, 33(3), 1073-1084.
dc.citation Hatipoğlu, G., 2019. Lityum İyon Piller İçin Metalurjik Silisyum/KNT/Grafen Çok Fonksiyonlu Anotların Geliştirilmesi (Development of Metallurgical Silicon / CNT / Graphene Multifunctional Anodes for Lithium Ion Batteries), Doktora Tezi, Sakarya Üniversitesi Fen Bilimleri Enstitüsü, 242s, Sakarya.
dc.citation https://tap.org.tr/pil-atik-pil/sss/pil-nedir/ Erişim Tarihi: 12.05.2021
dc.citation https://technoluxpro.com/tr/akkumulyatory/batarei/nizn.html Erişim Tarihi: 16.05.2021
dc.citation https://reactual.com/portable-electronics/nizn-batteries.html Erişim Tarihi: 15.05.2021
dc.citation Hung, Y., Yin, L., Wang, J., Wang, C., Tsai, C., Kuo, Y., 2018. Recycling of Spent Nickel–Cadmium Battery Using a Thermal Separation Process, Enviromental Progress and Sustainable Energy, 39 (2), 645-654.
dc.citation Jeyaseelan, C., Jain, A., Khurana, P., Kumar, D., Thatai, S., 2020. Ni-Cd Batteries, Rechargeable Batteries, s.177-194.
dc.citation Kocaman, A.S., 2019. Optimization of Hybrid Energy Systems With Pumped Hydro Atorage- A Case Study for Turkey, Journal of the Faculty of Engineering and Architecture of Gazi University, 34(1), 53-67.
dc.citation Lavety, S., Keshri, R. K., Chaudhari, M. A., 2020. Evaluation of Charging Strategies for Valve Regulated Lead-Acid Batteries, IEEE Access, 8, 164747-164761.
dc.citation Ledovskikh, A., Verbitskiy, E., Ayeb, A., Notten, P.H.L., 2003. Modelling of Rechargeable NiMH Batteries, Journal of Alloys and Compounds, 356-357, 742-745.
dc.citation Ma, Z., Yuan, X., Li, L., Ma, Z.-F., Wilkinson, D.P., Zhang, L., Zhang, J., 2015. A Review of Cathode Materials and Structures for Rechargeable Lithium-Air Batteries, Energy and Environmental Science, 8(8), 2144-2198.
dc.citation Middlemiss, L., Holland, A., 2018. A Review of Post-Lithium-Ion Batteries, EPSRC CDT in Energy Storage & Its Applications.
dc.citation Miller, P., 2015. Automotive Lithium-Ion Batteries, Johson Matthey Technology Review, 59(1), 4-13.
dc.citation Mirzaeian, M., Hall, P.J., 2009. Preparation of Controlled Porosity Carbon Aerogels for Energy Storage in Rechargeable Lithium Oxygen Batteries, Electrochimica Acta, 54(28), 7444-7451.
dc.citation Moralı, U., Erol, S., 2020. Electrochemical Impedance Analysis of 18650 Lithium-Ion and 6HR61 Nickel-Metal Hydride Rechargeable Batteries, Journal of the Faculty of Engineering and Architecture of Gazi University, 35(1), 297-309.
dc.citation Morimoto, K., Nagashima, I., Matsui, M., Maki, H., Mizuhata, M., 2018. Improvement of Electrochemical Properties and Oxidation/Reduction Behavior of Cobalt in Positive Electrode of Ni-Metal Hydride Battery, J. Power Sources, 388, 45-51.
dc.citation Mulder, G., Omar, N., Pauwels, S., Meeus, M., Leemans, F., Verbrugge, B., De Nijs, W., Van den Bossche, P., Six, D., Van Mierlo, J., 2013. Comparison of Commercial Battery Cells in Relation to Material Properties, Electrochim. Acta, 87, 473-488.
dc.citation Nitta, N., Wu, F., Lee, J. T., Yushin G., 2015. Li-ion Battery Materials: Present And Future, Materials Today, 18, 252-264.
dc.citation Omar, N., Firouz, Y., Monem, M.A., Samba, A., Gualous, H., Coosemans, T., Van den Bossche, P., Mierlo J.V., 2014. Analysis of Nickel-Based Battery Technologies for Hybrid and Electric Vehicles, Reference Module in Chemistry, Molecular Sciences and Chemical Engineering, Elsevier.
dc.citation Özduğan, E., 2010. Atık Nikel Kadmiyum Pillerin Geri Kazanımına Yönelik Proses Geliştirilmesi (Development of a Recycling Process for Waste Nickel Cadmium Batteries), Yüksek Lisans Tezi, İstanbul Teknik Üniversitesi Fen Bilimleri Enstitüsü, 102s, İstanbul.
dc.citation Özermiş, M.E., 2010. Kurşun Asit Akülerin Optimum Şarj Olmasını Sağlayan Şarj Devresi (Charging Circuit Providing Optimum Charging of Lead Acid Batteries), Yüksek Lisans Tezi, Pamukkale Üniversitesi Fen Bilimleri Enstitüsü, 80s, Denizli.
dc.citation Palacin, M.R., 2009. Recent Advances in Rechargeable Battery Materials: A Chemist’s Perspective, Chemical Society Reviews, 38(9), 2565-2575.
dc.citation Polat, B.D., Keleş, Ö., 2013. Lityum İyon Pil Teknolojisi (Technology of Lithium Ion Battery), Türk Mühendis ve Mimar Odaları Birliği, Metalurji Mühendisleri Odası, 162, 42-48.
dc.citation Rahman, M.A., Wang, X., Wen, C., 2013. High Energy Density Metal-Air Batteries: A Review, Journal of the Electrochemical Society, 160(10), 1759-1771.
dc.citation Rand, D.A.J., Moseley, P.T., Garche, J., Parker, C.D., 2004. Valve-Regulated Lead-Acid Batteries, Elsevier, s. 1-14, s.121-122.
dc.citation Sakai, T., Uehara, I., Ishikawa, H., 1999. R and D on Metal Hydride Materials and Ni-MH Batteries in Japan, Journal of Alloys and Compounds, 293-295, 762-769.
dc.citation Scrosati, B., Garche, J., 2010. Lithium batteries: Status, Prospects and Future, Journal of Power Sources, 195, 2419–2430.
dc.citation Serhan, H. A., Ahmed, E. M., 2018. Effect of the Different Charging Techniques on Battery Life-time: Review, 2018 International Conference on Innovative Trends in Computer Engineering (ITCE).
dc.citation Slater, M.D., Kim, D., Lee, E., Johnson, C.S., 2012. Sodium-Ion Batteries, Advanced Function Materials, 23(8), 947-958.
dc.citation Turhan, M., 2011. Li-İyon Pil Destekli Yakıt Pili Güç Sisteminin Su Üstü Platforma Uygulanması (Application of a Power Control With a Li-Ion Battery Supported Powerful Fuel Cell to Surface Ship), Doktora Tezi, Kocaeli Üniversitesi Fen bilimleri Enstitüsü, 161s, Kocaeli.
dc.citation Uz, U., 2019. Hexacopter Yapısında Bir İnsansız Hava Aracı İle Elektronik İlaçlama/Sulama Sisteminin Oluşturulması (The Productıon of Electronıc Pharmaceutıcal / Irrıgatıon System With an Unmanned Aerıal Vehıcle ın Hexacopter Structure), Yüksek Lisans Tezi, İstanbul Gelişim Üniversitesi Fen Bilimleri Enstitüsü, 84s, İstanbul.
dc.citation Wang, D.-W., Zeng, Q., Zhou, G., Yin, L., Li, F., Cheng, H.-M., Gentle, I.R., Lu, G.Q.M., 2013. Carbon-Sulfur Composites for Li-S Batteries: Status and Prospects, Journal of Materials Chemistry A, 1, 9382-9394.
dc.citation Warner, J., 2015. The Handbook of Lithium-Ion Battery Pack Design, Elsevier, ss.177-210.
dc.citation Xia, X., Dahn, J.R., 2012. Study of the Reactivity of Na/Hard Carbon with Different Solvents and Electrolytes, Journal of the Electrochemical Society, 159(5), 515-519.
dc.citation Yabuuchi, N., Kajiyama, M., Iwatate, J., Nishikawa, H., Hitomi, S., Okuyama, R., Usui, R., Yamada, Y., Komaba, S., 2012. P2-type Na_x[Fe_(1/2) Mn_(1/2)] O_2 Made From Earth-Abundant Elements for Rechargeable Na Batteries, Nature Materials, 11(6), 512-517.
dc.citation Yabuuchi, N., Kubota, K., Dahbi, M., Komaba, S., 2014. Research Development on Sodium-Ion Batteries, Chemical Reviews, 114(23), 11636-11682.
dc.citation Yan, S., Nei, J., Li, P., Young, K., Simon Ng, K.Y., 2017. Effects of Cs_2 CO_3 Additive in KOH Electrolyte Used in Ni/MH Batteries, Batteries, Nickel Metal Hydride Batteries 2017, 3(4), 41.
dc.citation Ying, T., Gao, X., Hu, W., Wu, F.,Noreus, D., 2006. Studies On Rechargeable NiMH Batteries, International Journal of Hydrogen Energy, 31, 525-530.
dc.citation Yu, J., Lee, H., Lee, P.S., Lee, J., 2000. Effect of Cu Powder as an Additive Material on the Properties of Zr-Based Pasted Alloy Electrodes for Ni/MH Batteries, Journal of The Electrochemical Society, 147 (7), 2494-2497.
dc.citation Yu, Y., Ji, X., Fan, H., 2018. Post Lithium Ion Batteries for Emerging Energy Storage Technologies, Green Energy and Environment, 3, 1.
dc.citation Zhu, W.H., Zhu, Y., Tatarchuk, B.J., 2014. Self-Discharge Characteristics and Performance Degradation of Ni-MH Batteries for Storage Applications, Int. J. Hydrogen Energ., 39 (34), 19789-19798.


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