ABSTRAK

Salah satu energi terbarukan adalah pembangkit listrik tenaga surya (PLTS), yang menggunakan photovoltaic (PV) sebagai sarana konversi energi. Untuk mendapatkan daya maksimal, menggunakan konverter DC-DC beralgoritma maximum power point tracker (MPPT). Sistem di Indonesia menggunakan tiga fasa empat kawat (TFEK), sehingga sistem perlu diintegrasi menjadi satu, dikenal dengan nama konversi dua tahap. Masalah yang muncul adalah konverter TFEK lazim diimplementasi menggunakan konverter daya empat lengan, di mana setiap lengannya terdapat dua buah sakelar daya. Hal ini akan mengakibatkan sistem pensaklaran yang tinggi, tapis dan stress tegangan yang besar untuk mendapatkan THD rendah. Oleh karena itu, telah diteliti inverter TFEK menggunakan 5-level inverter. Metode modulasi lebar pulsa digital sinusoidal (MLPDS) digunakan untuk mengendalikan setiap sakelar (IRFP 460) dengan menggunakan mikrokontrol jenis STM32F407. Verifikasi menggunakan perangkat lunak PSIM dan prototype. Berdasarkan hasil pengujian, metode yang dilakukan mampu menghasilkan arus dan tegangan keluaran inverter TFEK dengan THD tegangan sebesar 4,38%.

Kata kunci: Inverter 5-tingkat, Tiga fasa empat kawat, STM32F407, THD

 

ABSTRACT

One of the renewable energy is solar power plant (PLTS), which uses photovoltaic (PV) as a means of energy conversion. To get maximum power, use a DC-DC converter with a maximum power point tracker (MPPT). The system in Indonesia uses three-phase four-wires (TPFW), the system needs to be integrated into one, as two-stage conversion. The problem is that TPFW converters are commonly implemented using four-leg power converter, where each leg has two power switches. This will result in high switching system, large filters, and stress voltage to get low THD. Hence, the TPFW inverter 5-level inverter has been investigated. The sinusoidal pulse width modulation (SPWM) method is used to control each switch (IRFP 460) using an STM32F407 microcontroller. Verification with PSIM software and prototype. Based on the results, the method used can produce the current and output voltage of the TPFW inverter with a voltage THD of 4.38%.

Keywords: five-level inverter, three-phase four-wire, STM32F407, THD

Aheshri, S., & Khampariya, P. (2014). Simulation of Single Phase SPWM ( Unipolar ) Inverter. International Journal of Innovative Research in Advanced Engineering (IJIRAE), 1(9), 12–18.

Ahmad, A., & Maqbool, S. (2019). Square Wave Inverters – A Performance Comparison with Pure Sine Wave Inverters. International Journal Of Research in Electronics and Computer Engineering, 7(1), 237–39.

Algaddafi, A., Elnaddab, K., Al Ma’Mari A., & Esgiar, A.N. (2017). Comparing the Performance of Bipolar and Unipolar Switching Frequency to Drive DC-AC Inverter. Proceedings of 2016 International Renewable and Sustainable Energy Conference, IRSEC 2016, (pp. 680–85).

Ardin, F., Rahardjo, A., & Hudaya, C. (2017). Electricity Price and Subsidy Scenario for Hybrid Power Generations on Off-Grid System. ICCREC 2017 - 2017 International Conference on Control, Electronics, Renewable Energy, and Communications, (pp. 132–38).

IEEE Standards Association. (2014). IEEE Recommended Practice and Requirements for Harmonic Control in Electric Power Systems.

Hakim, A.R., Handoyo, W.T., & Wullandari, P. (2018). An Energy and Exergy Analysis of Photovoltaic System in Bantul Regency, Indonesia Arif.

Hamid, N. F. A. l, Jalil, M.A.A., & Mohamed, N.S.S. (2019). Design and Simulation of Single Phase Inverter Using SPWM Unipolar Technique. Journal of Physics: Conference Series 1432(1), 1–9.

Neukirchner, L., & Magyar, A. (2017). Modelling a Three-Phase Current Source Inverter. Hungarian Journal of Industry and Chemistry, 44(2), 105–11.

Pratomo, L.H., & Tjokro, C. (2019). Hardware Implementation of an Asymmetrical 11-Level Inverter with Automatic Boost Charge Control in PV Applications. Proceedings - 2019 International Seminar on Application for Technology of Information and Communication: Industry 4.0: Retrospect, Prospect, and Challenges, iSemantic 2019. (pp. 336–41).

Pratomo, L.H., Wijaya, F.D., & Firmansyah, E. (2015). Capacitor Bank Voltage Equilibrium for MPPT in Single-Phase Single-Stage Capacitor Bank Voltage Equilibrium for MPPT in Single- Phase Single-Stage Five-Level Inverter for PV-Grid Application.

Pratomo, L.H., & Riyadi, S. (2020). Desain Dan Implementasi Algoritma Korelasi Daya Dan Tegangan Di Kapasitor Untuk Maximum Power Point Trackking Pada Photovoltaic Menggunakan Arduino Uno. Jurnal Teknik Elektro, 12(1), 9–16.

Rahman, T., Motakabber, S.M.A., & Ibrahimy, M.I. (2016). Design of a Switching Mode Three Phase Inverter. Proceedings - 6th International Conference on Computer and Communication Engineering: Innovative Technologies to Serve Humanity, ICCCE 2016 (pp. 155–60).

Sanadeera, M, & Miller, W. (2015). Residential Electricity Costs-Assessment Of Queensland Electricity Tariffs For Solar Households. IEEE PES Asia-Pacific Power Engineering Conference (APPEC), (pp. 6–9).

Tran, V.R., Nguyen, M.K., Yoo M.H., Choi, Y.O., & Cho, G.B. (2017). A Three-Phase Cascaded H-Bridge Quasi Switched Boost Inverter for Renewable Energy. 2017 20th International Conference on Electrical Machines and Systems, ICEMS 2017.

Trivedi, J., Shah, M,. & Shah, J. (2016). Three Phase 150 Degree Mode of Conduction Voltage Source Inverter Using Arduino. International Journal of Engineering Research And 5(12), 272–75.

Wilson, A.O.M., & Jiménez, J.B. (2016). Electricity Demand Modeling for Rural Residential Housing: A Case Study in Colombia. 2015 IEEE PES Innovative Smart Grid Technologies Latin America, ISGT LATAM 2015. Colombia: IEEE. (pp. 614-618).