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ELEKTROMANYETİK FIRLATICILAR

Year 2018, Volume: 7 Issue: 1, 97 - 106, 28.06.2018

Abstract

Bu çalışmada Elektromanyetik Fırlatıcı’ların
çalışma prensibi, yapısı, türleri, bu tür fırlatıcılar için güç kaynakları
incelenmiştir.

References

  • [1]. Harry Fair, 2003: The Electromagnetic Launch Technology Revolution, University of Texas at Austin, USA.
  • [2]. Akyazı, Ö. ve Akpınar, A. S. 2008: Elektromanyetik Fırlatıcılar, Fen ve Mühendislik Bilgisi Dergisi, Fırat Üniversitesi, Türkiye, 29 Ocak, sf. 117-126..
  • [3]. https://www.rappinstruments.de/accelerator/Coilgun/coilgun.html.
  • [4]. https://www.sfwar.com/pyodogi/pyodogi0001b.html.
  • [5]. https://www.nas.nasa.gov/.../Nowicki/SPBI112.html.
  • [6]. http://members.home.nl/yja.wolters/Coilgun/Coilgun1.html.
  • [7]. http://www.physics4u.gr/articles/2006/electromagnetic_propulsion.html.
  • [8]. http://www.global-defence.com/1997/High-speed.html.
  • [9]. H.D. Fair, “Electromagnetic Launch Science and Technology in the United States Enters a New Era”, IEEE Transaction on Magnetics, Vol. 41, No. 1, pp. 158–164, January 2005.
  • [10]. M.Liao, Z.Zabar, D.Czarkowski, E.Levi and L.Birenbaum, “On the Design of as a Rapid- Fire Grenade Launcher” IEEE Transaction on Magnetics, Vol.35, No.1, January 1999.
  • [11]. http://www.coilgun.eclipse.co.uk/electromagnetic_pistol.html.
  • [12]. Y. Shirong, W. Ying, C. Shanbao, P. Guohua, L. Xuquiong, W. Wei, “A Novel Type Rail- Coil Hybrid Electromagnetic Launcher“, IEEE Transaction on Magnetics, Vol. 41, No. 1, pp. 266–267, 2005.
  • [13]. A.Balikci, “Flywheel Motor/Generator Set as an Energy Source for Coil Launchers”, Ph. D. Dissertation, Polytechnic University, June 2003.
  • [14]. E. Bicak, “Elektromagnetik Fırlatıcı“, Lisans bitirme tezi, Gebze Yüksek Teknoloji Enstitüsü, Gebze, Kocaeli, Haziran 2005.
  • [15]. Zhang, C., Wu, P., Tseng, K.J. 2005. “FEM Analyses for the Design and Modeling of a Novel Flywheel Energy Storage System Assisted by Integrated Magnetic Bearing”, Electric Machines and Drives International Conference IEEE, 1157-1164.
  • [16]. Nguyen, T.D., Tseng, K.J., Zhang, S., Nguyen, H.T. 2011. “A Novel Axial Flux Permanent Magnet Machine for Flywheel Energy Storage System: Design and Analysis”, IEEE Transaction on Industrial Electroninc”, vol.(58), No.9, September, 3784-3794.
  • [17]. Zhou, L., Qi, Z. 2009. “Modeling and Simulation of Flywheel Energy Storage Ssytem with IPMSM for Voltage Sags in Distributed Power Network”, International Conference on Mechatronics and Automation, August, China, 5046-5051.
  • [18]. Abdel-Khalik, A., Elserougi, A., Massoud, A., Ahmed, S. 2013. “A Power Control Strategy for Flywheel Doubly-Fed Induction Machine Storage System Using Artificial Neural Network”, Electric Power System Research, Vol.(96), March, 267-276.
  • [19]. Kato, K., Ishigma, S., Nakajima, Y., Arai, H., Ueda, T., Iwata, T., Ito, Y., Sugao, K. 2014. “10MW, 3.3MWh Energy Storage System consisting of 4000 Flywheels controlled by ICT network for Short Cycle Power Fluctuation Compensation”, The 2014 International Power Electronics Conference IEEE, 403-408.
  • [20]. Zhang, C., Tseng, K.J., Nguyen, T.D. 2010. “Design and Loss Analysis of a High Speed Flywheel Energy Storage System Based on Axial Flux Flywheel Rotor Electric Machines”, IPEC Conference IEEE, October, Singapore, 886-891.
  • [21]. Fu, X. 2010. “A Novel Design for Flywheel Battery of Electric Vehicles”, IEEE International Conference on Intelligent System Design and Engineering Application”, 107- 111.
  • [22]. Chu, H.Y., Fan, Y., Zhang, C.S. 2005. “A Novel Design for the Flywheel Energy Storage System”, Electrical Machines and Systems ICEMS Proceedings of the Eighth International Conference on”, Vol.(2), September, 1583-1587.
  • [23]. Zhang, C., Tseng, K.J. 2004. “Design and FEM Analysis of a Flywheel Energy Storage System Assisted by Integrated Magnetic Bearings”, IECON Industrial Electronics Society 30th Annual Conference IEEE, Vol.(2), November, Busan, Korea, 1634-1639.
  • [24]. Zhang, C., Tseng, K.J. 2007. “A Novel Flywheel Energy Storage System With Partially- Self-Bearing Flywheel Rotor”, IEEE Transactions on Energy Conversion, Vol.(22), No.2, 477-487.
  • [25]. Dong, J., Huang, Y., Shen, P., Jin, L., Ge, B. 2012. “An Axial Flux Flywheel Motor/Generator for Pulsed Power Application”, IEEE Energy Conversion Congress and Exposition(ECCE), Raleigh, NC, September, 678-683.
  • [26]. Junfeng, W. 2012. “Design of a Miniature Axial Flux Flywheel Motor with PCB Winding for Nanosatellites”, Optoelectronics and Microelectronics ICOM International Conference, 544-548.
  • [27]. Yi, J., Lee, K.W., Kim, B., Ko, J., Jeong, S., Noh, M.D., Lee, S.S. 2007. “Micro Flywheel Energy Storage System with Axial Flux Machine”, Advanced Intelligent Mechatronics IEEE/ASME International Conference on, September, Zurich, 1-6.
  • [28]. Qian, X. 2010. “Application Research of Flywheel Battery in the Wind and Solar Complementary Power Generation”, Computer Application and System Modeling International Conference on, Vol.(13), 546-550.
  • [29]. Diaz-Gonzalez, F., Sumper, A., Gomis-Bellmunt, O., Bianchi, F.D. 2013. “Energy Management of Flywheel Based Energy Storage Device for Wind Power Smoothing”, Applied Energy, Vol.(110), 207-219.
  • [30]. Santiago, J., Oliveira, J.G., Lundin, J., Larsson, A., Bernhoff, H. 2008. “Losses in Axial Flux Permanent Magnet Coreless Flywheel Energy Storage Systems”, 18th International Conference on Electric Machines ICEM, 1-5.
  • [31]. Lee, S.J., Kim, J.H., Song, B.S., Kim, J.H. 2013. “Coil Gun Electromagnetic Launcher (EML) System with Multi-Stage Electromagnetic Coils”, Journal of Magnetics, Vol.(18), No.4, 481-486.
  • [32]. Huang, S., Luo, J., Leonardi, F., Lipo, T.A. 1999. “A Comprasion of Power Density for Axial Flux Machines Based on General Purpose Sizing Equations”, IEEE Transactions on Energy Conversion, Vol(14), No.2, 185-192.
  • [33]. Huner, E., Akuner, C. 2012. “Axial-Flux Synchronous Machines Compared with Different Stator Structures for Use in Working”, Prezeglad Elektrotechniczny.
  • [34]. Aydın, M., Qu, R., Lipo, T.A. 2003. “Cogging Torque Minimization Technique for Multiple-Rotor, Axial-Flux, Surface-Mounted-PM Motors : Alternating Magnet Pole-Arcs in Facing Rotors”, IEEE Transactions on Energy Conversion, Vol(14), No.2, 185-192.
  • [35]. Zabar, Z., Naot, Y., Birenbaum, L., Levi, E., Joshi, P. N. 1989. “Design and power conditioning for the coilgun”, IEEE Transactions on Magnetics, 25(1), 627-631.
  • [36]. Hasirci, U., Balikci, A. 2009. “Design, implementation and test of a coilgun-type electromagnetic launcher prototype”, in Proc. 6th International Conference on Recent Advances in Space Technologies, RAST’13, 815-820, Istanbul, Turkey.
  • [37]. Hasirci, U., Balikci, A. 2013. “Design, fabrication and test of a 250 m/s generator-driven coil launcher”, in Proc. 4th International Conference on Recent Advances in Space Technologies, RAST’09, 237-240, Istanbul, Turkey.
  • [38]. Hasirci, U., Balikci, A., Zabar, Z., Birenbaum, L. 2011. “Concerning the design of a novel electromagnetic launcher for earth-to-orbit micro- and nanosatellite systems”, IEEE Transactions on Plasma Science, 39(1), 498-503.
  • [39]. Hasirci, U., Balikci, A., Zabar, Z., Birenbaum, L. 2013. “Experimental performance investigation of a novel magnetic levitation system”, IEEE Transactions on Plasma Science, 41(5), 1174-1181.
  • [40]. Hasirci, U. 2014. “Nonlinear control of axial flux flywheel motor/generator set of coil launchers”, in Proc. 17th International Symposium on Electrmagnetic Launch Technology, 1-5, San Diego, CA, USA.
Year 2018, Volume: 7 Issue: 1, 97 - 106, 28.06.2018

Abstract

References

  • [1]. Harry Fair, 2003: The Electromagnetic Launch Technology Revolution, University of Texas at Austin, USA.
  • [2]. Akyazı, Ö. ve Akpınar, A. S. 2008: Elektromanyetik Fırlatıcılar, Fen ve Mühendislik Bilgisi Dergisi, Fırat Üniversitesi, Türkiye, 29 Ocak, sf. 117-126..
  • [3]. https://www.rappinstruments.de/accelerator/Coilgun/coilgun.html.
  • [4]. https://www.sfwar.com/pyodogi/pyodogi0001b.html.
  • [5]. https://www.nas.nasa.gov/.../Nowicki/SPBI112.html.
  • [6]. http://members.home.nl/yja.wolters/Coilgun/Coilgun1.html.
  • [7]. http://www.physics4u.gr/articles/2006/electromagnetic_propulsion.html.
  • [8]. http://www.global-defence.com/1997/High-speed.html.
  • [9]. H.D. Fair, “Electromagnetic Launch Science and Technology in the United States Enters a New Era”, IEEE Transaction on Magnetics, Vol. 41, No. 1, pp. 158–164, January 2005.
  • [10]. M.Liao, Z.Zabar, D.Czarkowski, E.Levi and L.Birenbaum, “On the Design of as a Rapid- Fire Grenade Launcher” IEEE Transaction on Magnetics, Vol.35, No.1, January 1999.
  • [11]. http://www.coilgun.eclipse.co.uk/electromagnetic_pistol.html.
  • [12]. Y. Shirong, W. Ying, C. Shanbao, P. Guohua, L. Xuquiong, W. Wei, “A Novel Type Rail- Coil Hybrid Electromagnetic Launcher“, IEEE Transaction on Magnetics, Vol. 41, No. 1, pp. 266–267, 2005.
  • [13]. A.Balikci, “Flywheel Motor/Generator Set as an Energy Source for Coil Launchers”, Ph. D. Dissertation, Polytechnic University, June 2003.
  • [14]. E. Bicak, “Elektromagnetik Fırlatıcı“, Lisans bitirme tezi, Gebze Yüksek Teknoloji Enstitüsü, Gebze, Kocaeli, Haziran 2005.
  • [15]. Zhang, C., Wu, P., Tseng, K.J. 2005. “FEM Analyses for the Design and Modeling of a Novel Flywheel Energy Storage System Assisted by Integrated Magnetic Bearing”, Electric Machines and Drives International Conference IEEE, 1157-1164.
  • [16]. Nguyen, T.D., Tseng, K.J., Zhang, S., Nguyen, H.T. 2011. “A Novel Axial Flux Permanent Magnet Machine for Flywheel Energy Storage System: Design and Analysis”, IEEE Transaction on Industrial Electroninc”, vol.(58), No.9, September, 3784-3794.
  • [17]. Zhou, L., Qi, Z. 2009. “Modeling and Simulation of Flywheel Energy Storage Ssytem with IPMSM for Voltage Sags in Distributed Power Network”, International Conference on Mechatronics and Automation, August, China, 5046-5051.
  • [18]. Abdel-Khalik, A., Elserougi, A., Massoud, A., Ahmed, S. 2013. “A Power Control Strategy for Flywheel Doubly-Fed Induction Machine Storage System Using Artificial Neural Network”, Electric Power System Research, Vol.(96), March, 267-276.
  • [19]. Kato, K., Ishigma, S., Nakajima, Y., Arai, H., Ueda, T., Iwata, T., Ito, Y., Sugao, K. 2014. “10MW, 3.3MWh Energy Storage System consisting of 4000 Flywheels controlled by ICT network for Short Cycle Power Fluctuation Compensation”, The 2014 International Power Electronics Conference IEEE, 403-408.
  • [20]. Zhang, C., Tseng, K.J., Nguyen, T.D. 2010. “Design and Loss Analysis of a High Speed Flywheel Energy Storage System Based on Axial Flux Flywheel Rotor Electric Machines”, IPEC Conference IEEE, October, Singapore, 886-891.
  • [21]. Fu, X. 2010. “A Novel Design for Flywheel Battery of Electric Vehicles”, IEEE International Conference on Intelligent System Design and Engineering Application”, 107- 111.
  • [22]. Chu, H.Y., Fan, Y., Zhang, C.S. 2005. “A Novel Design for the Flywheel Energy Storage System”, Electrical Machines and Systems ICEMS Proceedings of the Eighth International Conference on”, Vol.(2), September, 1583-1587.
  • [23]. Zhang, C., Tseng, K.J. 2004. “Design and FEM Analysis of a Flywheel Energy Storage System Assisted by Integrated Magnetic Bearings”, IECON Industrial Electronics Society 30th Annual Conference IEEE, Vol.(2), November, Busan, Korea, 1634-1639.
  • [24]. Zhang, C., Tseng, K.J. 2007. “A Novel Flywheel Energy Storage System With Partially- Self-Bearing Flywheel Rotor”, IEEE Transactions on Energy Conversion, Vol.(22), No.2, 477-487.
  • [25]. Dong, J., Huang, Y., Shen, P., Jin, L., Ge, B. 2012. “An Axial Flux Flywheel Motor/Generator for Pulsed Power Application”, IEEE Energy Conversion Congress and Exposition(ECCE), Raleigh, NC, September, 678-683.
  • [26]. Junfeng, W. 2012. “Design of a Miniature Axial Flux Flywheel Motor with PCB Winding for Nanosatellites”, Optoelectronics and Microelectronics ICOM International Conference, 544-548.
  • [27]. Yi, J., Lee, K.W., Kim, B., Ko, J., Jeong, S., Noh, M.D., Lee, S.S. 2007. “Micro Flywheel Energy Storage System with Axial Flux Machine”, Advanced Intelligent Mechatronics IEEE/ASME International Conference on, September, Zurich, 1-6.
  • [28]. Qian, X. 2010. “Application Research of Flywheel Battery in the Wind and Solar Complementary Power Generation”, Computer Application and System Modeling International Conference on, Vol.(13), 546-550.
  • [29]. Diaz-Gonzalez, F., Sumper, A., Gomis-Bellmunt, O., Bianchi, F.D. 2013. “Energy Management of Flywheel Based Energy Storage Device for Wind Power Smoothing”, Applied Energy, Vol.(110), 207-219.
  • [30]. Santiago, J., Oliveira, J.G., Lundin, J., Larsson, A., Bernhoff, H. 2008. “Losses in Axial Flux Permanent Magnet Coreless Flywheel Energy Storage Systems”, 18th International Conference on Electric Machines ICEM, 1-5.
  • [31]. Lee, S.J., Kim, J.H., Song, B.S., Kim, J.H. 2013. “Coil Gun Electromagnetic Launcher (EML) System with Multi-Stage Electromagnetic Coils”, Journal of Magnetics, Vol.(18), No.4, 481-486.
  • [32]. Huang, S., Luo, J., Leonardi, F., Lipo, T.A. 1999. “A Comprasion of Power Density for Axial Flux Machines Based on General Purpose Sizing Equations”, IEEE Transactions on Energy Conversion, Vol(14), No.2, 185-192.
  • [33]. Huner, E., Akuner, C. 2012. “Axial-Flux Synchronous Machines Compared with Different Stator Structures for Use in Working”, Prezeglad Elektrotechniczny.
  • [34]. Aydın, M., Qu, R., Lipo, T.A. 2003. “Cogging Torque Minimization Technique for Multiple-Rotor, Axial-Flux, Surface-Mounted-PM Motors : Alternating Magnet Pole-Arcs in Facing Rotors”, IEEE Transactions on Energy Conversion, Vol(14), No.2, 185-192.
  • [35]. Zabar, Z., Naot, Y., Birenbaum, L., Levi, E., Joshi, P. N. 1989. “Design and power conditioning for the coilgun”, IEEE Transactions on Magnetics, 25(1), 627-631.
  • [36]. Hasirci, U., Balikci, A. 2009. “Design, implementation and test of a coilgun-type electromagnetic launcher prototype”, in Proc. 6th International Conference on Recent Advances in Space Technologies, RAST’13, 815-820, Istanbul, Turkey.
  • [37]. Hasirci, U., Balikci, A. 2013. “Design, fabrication and test of a 250 m/s generator-driven coil launcher”, in Proc. 4th International Conference on Recent Advances in Space Technologies, RAST’09, 237-240, Istanbul, Turkey.
  • [38]. Hasirci, U., Balikci, A., Zabar, Z., Birenbaum, L. 2011. “Concerning the design of a novel electromagnetic launcher for earth-to-orbit micro- and nanosatellite systems”, IEEE Transactions on Plasma Science, 39(1), 498-503.
  • [39]. Hasirci, U., Balikci, A., Zabar, Z., Birenbaum, L. 2013. “Experimental performance investigation of a novel magnetic levitation system”, IEEE Transactions on Plasma Science, 41(5), 1174-1181.
  • [40]. Hasirci, U. 2014. “Nonlinear control of axial flux flywheel motor/generator set of coil launchers”, in Proc. 17th International Symposium on Electrmagnetic Launch Technology, 1-5, San Diego, CA, USA.
There are 40 citations in total.

Details

Primary Language Turkish
Journal Section Articles
Authors

Çagdas Tunceroğlu

Uğur Hasırcı

Engin Hüner

Zülkif Sarı This is me

Publication Date June 28, 2018
Published in Issue Year 2018 Volume: 7 Issue: 1

Cite

APA Tunceroğlu, Ç., Hasırcı, U., Hüner, E., Sarı, Z. (2018). ELEKTROMANYETİK FIRLATICILAR. İleri Teknoloji Bilimleri Dergisi, 7(1), 97-106.
AMA Tunceroğlu Ç, Hasırcı U, Hüner E, Sarı Z. ELEKTROMANYETİK FIRLATICILAR. İleri Teknoloji Bilimleri Dergisi. June 2018;7(1):97-106.
Chicago Tunceroğlu, Çagdas, Uğur Hasırcı, Engin Hüner, and Zülkif Sarı. “ELEKTROMANYETİK FIRLATICILAR”. İleri Teknoloji Bilimleri Dergisi 7, no. 1 (June 2018): 97-106.
EndNote Tunceroğlu Ç, Hasırcı U, Hüner E, Sarı Z (June 1, 2018) ELEKTROMANYETİK FIRLATICILAR. İleri Teknoloji Bilimleri Dergisi 7 1 97–106.
IEEE Ç. Tunceroğlu, U. Hasırcı, E. Hüner, and Z. Sarı, “ELEKTROMANYETİK FIRLATICILAR”, İleri Teknoloji Bilimleri Dergisi, vol. 7, no. 1, pp. 97–106, 2018.
ISNAD Tunceroğlu, Çagdas et al. “ELEKTROMANYETİK FIRLATICILAR”. İleri Teknoloji Bilimleri Dergisi 7/1 (June 2018), 97-106.
JAMA Tunceroğlu Ç, Hasırcı U, Hüner E, Sarı Z. ELEKTROMANYETİK FIRLATICILAR. İleri Teknoloji Bilimleri Dergisi. 2018;7:97–106.
MLA Tunceroğlu, Çagdas et al. “ELEKTROMANYETİK FIRLATICILAR”. İleri Teknoloji Bilimleri Dergisi, vol. 7, no. 1, 2018, pp. 97-106.
Vancouver Tunceroğlu Ç, Hasırcı U, Hüner E, Sarı Z. ELEKTROMANYETİK FIRLATICILAR. İleri Teknoloji Bilimleri Dergisi. 2018;7(1):97-106.