PEMODELAN STATE SPACE MOTOR INDUKSI TIGA FASA SEBAGAI PENGGERAK MOBIL LISTRIK

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Published: Feb 26, 2020
DOI: https://doi.org/10.24853/jurtek.12.1.39-48
Keywords:
State space equation Induction Motor and Electric Vehicle

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Angga Wahyu Aditya
Program Studi Teknologi Listrik - Jurusan Teknik Elektro - Politeknik Negeri Balikpapan
Ihsan Ihsan
Program Studi Teknik Elektronika - Jurusan Teknik Elektro - Politeknik Negeri Balikpapan
Restu Mukti Utomo
Program Studi Teknologi Listrik - Jurusan Teknik Elektro - Politeknik Negeri Balikpapan
Hilmansyah Hilmansyah
Program Studi Teknologi Listrik - Jurusan Teknik Elektro - Politeknik Negeri Balikpapan

Abstract

The use of induction motors in electric cars was developed since vector control technology was discovered and developed. In vector control technology requires dynamic modeling of induction motors on electrical and mechanical sides. Along with the development of controlling system technology, especially controllers based on system modeling, dynamic modeling of induction motors that are simple and easy to process to design a controller is needed. The state space equation is a solution that can be used to simplify induction motor modeling so that it is easier to determine vector control equations and design controllers to get maximum induction motor performance. In addition, the induction motor state space equation can also be used to design and determine the stability of an induction motor control system. The response to the basic characteristics of an induction motor includes the response of the characteristics of the stator current, rotor speed and electromagnetic torque at no-load conditions and at full load.

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How to Cite
Aditya, A. W., Ihsan, I., Utomo, R. M., & Hilmansyah, H. (2020). PEMODELAN STATE SPACE MOTOR INDUKSI TIGA FASA SEBAGAI PENGGERAK MOBIL LISTRIK. Jurnal Teknologi, 12(1), 39–48. https://doi.org/10.24853/jurtek.12.1.39-48
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Vol. 12 No. 1 (2020): Jurnal Teknologi
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Articles

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References

Abu-Rub, H., Iqbal, A., & Guzinski, J. (2012). High Performance Control of AC Drives with MATLAB/Simulink Models. West Sussex: John Wiley & Sons Ltd.

Aditya, A. W., Happyanto, D. C., & Sumantri, B. (2017). Application of Sliding Mode Control in Indirect Field Oriented Control for Model Based Controller. EMITTER International Journal of Engineering Technology, 5(2), 255-269.

Aditya, A. W., Rusli, M. R., Praharsena, B., Purwanto, E., Happyanto, D. C., & Sumantri, B. (2018). The Performance of FOSMC and Boundary - SMC in Speed Controller and Current Regulator for IFOC-Based Induction Motor Drive. International Seminar on Application for Technology of Information and Communication. Semarang.

Berlianti, R. (2015). Analisis Motor Induksi Fasa Tiga Tipe Rotor Sangkar Sebagai Generator Induksi Dengan Variasi Hubungan Kapasitor Untuk Eksitasi. Jurnal Nasional Teknik Elektro, 4(1), 110 - 119.

Bose, B. K. (2001). Modern Power Electronics and AC Drives. Prentice Hall.

Diniardi, E., Syawaluddin, Ramadhan, A. I., Fithriyah, N. H., & Dermawan, E. (2018). Analisis Daya Piezoelektrik Model Hybrid Solar Cell Piezoelectric Skala Rendah. Jurnal Teknologi, 139 - 146.

Djalal, M. R., Pangkung, A., Marhatang, & Sonong. (2018). Field-Oriented Control Permanent Magnet Motor Sinkron Menggunakan Algoritma Kunang-Kunang. Jurnal Teknologi, 10(2), 153 - 160.

Hashernnia, N., & Asaei, B. (2008). Comparative Study of Using Different Electric Motors in the Electric Vehicles. International Conference on Electrical Machines (pp. 1-5). Vilamoura: IEEE.

Hmidet, A., & Hasnaoui, O. (2018). Waijung Blockset-STM32F4 Environment for Real Time Induction Motor Speed Control. International Congress on Information Science and Technology (CiSt). Marrakech.

Jain, S. K., Sharma, F., & Baliwal, M. K. (2014). Modeling and Simulation of an Induction Motor. International Journal of Engineering Research and Development, 10(4), 57 - 61.

Karthik, D., & Chelliah, T. (2016). Analysis of Scalar and Vector Control Based Efficiency-Optimized Induction Motors Subjected to Inverter and Sensor Faults. International Conference on Advanced Communication Control and Computing Technologies (ICACCCT). Ramanathapuram.

Khoury, G., Ghosn, R., Fadel, M., & Tientcheu, M. (2016). Including Core Losses in Induction Motors Dynamic Model. International Conference on Renewable Energies for Developing Countries (REDEC). Zouk Mosbeh.

Kim, J., Cho, E., Lee, Y., Lee, J., & Lee, J. (2016). C++ Based Dynamic Model of AC Induction Motor in Discreate Time Domain. IEEE Transportation Electrification Conference and Expo, Asia-Pacific (ITEC). Busan.

Mahmoudi, M., Madani, N., Benkhoris, M., & Boudjema, F. (1999). Cascade sliding mode control of a field oriented induction machine drive. The European Physical Journal Applied Physics, 7, 217-225.

Oliveira, C. M., Aguiar, M. L., Monteiro, J. B., & Pereira, W. C. (2015). Vector Control of Induction Motor using a Sliding Mode Controller with Chattering Reduction. IEEE Brazillian Electronics Conferrence and 1st Southern Power Electronics Conferrence (COBEP/SPEC). Fortaleza.

Pati, S., Mohanty, S., & Patnaik, M. (2014). Improvement of transient and steady state performance of a scalar controlled induction motor using sliding mode controller. International Conference on Circuits, Power and Computing Technologies [ICCPCT-2014]. Nagercoil.

Pati, S., Patnaik, M., & Panda, A. (2014). Comparative performance analysis of fuzzy PI, PD and PID controllers used in a scalar controlled induction motor drive. International Conference on Circuits, Power and Computing Technologies [ICCPCT-2014]. Nagercoil.

Pavuluri, V. K., Wangy, X., Longz, J., Zhuox, G., & Lian, W. (2015). Field Oriented Control of Induction Motors Using Symmetrical Optimum Method with Applications in Hybrid Electric Vehicles. IEEE Vehicle Power and Propulsion Conference (VPPC). Montreal.

Praharsena, B., Purwanto, E., Jaya, A., Rusli, M. R., Toar, H., Ridwan, . . . Sandhi, N. E. (2018). Evaluation of Hysteresis Loss Curve on 3 Phase Induction Motor by Using Cascade Feed Forward Neural Network. International Electronics Symposium on Engineering Technology and Applications (IES-ETA). Bali.

Quang, N. P., & Dittrich, J.-A. (2015). Vector Control of Three-Phase AC Machines. Berlin: Springer-Verlag Berlin Heidelberg.

Saleki, A., Rezazade, S., & Changizian, M. (2017). Analysis and Simulation of Hybrid Electric Vehicles for Sedan Vehicle. Iranian Conference on Electrical Engineering. Tehran.

Shu-ying, Y., Shu, Y., Zhen, X., Ming-yao, M., & Xing, Z. (2017). A New Vector Control Strategy of Induction Motor based on Iron Loss Model. Chinese Automation Congress. Jinan.

Sieklucki, G. (2018). An Investigation into the Induction Motor of Tesla Model S Vehicle. International Symposium on Electrical Machines (SME). Andrychów.

Slotine, J.-J. E., & Li, W. (1991). Applied Nonlinear Control. New Jersey: Prentice Hall.

Teja, A. V., Verma, V., & Chakraborty, C. (2015). A New Formulation of Reactive Power Based Model Reference Adaptive System for Sensorless Induction Motor Drive. IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS, 62(11), 6797 - 6808.

YAICH, M., HACHICHA, M. R., & GHARIANI, M. (2015). Modeling and Simulation of Electric and Hybrid Vehicles for Recreational Vehicle. International conference on Sciences and Techniques of Automatic control & computer engineering - STA. Monastir.

Yang, Z., Shang, F., Brown, I. P., & Krishnamurthy, M. (2015). Comparative Study of Interior Permanent Magnet, Induction and Switched reluctance Motor Drives for EV and HEV Applications. IEEE Transactions on Transportation Electrification, 245 - 254.

Zaky, M. S., & Metwaly, M. K. (2016). A Performance Investigation of a Four-Switch Three-Phase Inverter-Fed IM Drives at Low Speeds Using Fuzzy Logic and PI Controllers. IEEE Transaction on Power Electronics, 32(5), 3741 - 3753.