Abstract :

Solar Power Plantsare systems A power plant that utilizes energy from light the sun to produce electrical energy. But often a problem was found, where the resulting output voltage not constant. For this reason, the Buck-Boost circuit is used converter, a piece of equipment that has a converting function the varying DC input voltage becomes a voltage constant DC output. In this research, a simulation was carried out to a buck-boost converter using PID control. Design simulated with Proteus 8.9. Input voltage setting is the main objective in analyzing success simulation series created. Selection of PID control constants the right one will produce a buck-boost output voltage the converter matches the setpoint and gets a response stable output voltage. By using the trial method and error obtained that with the PID constant, namely Kp = 1.0, Ki=0.01, Kd = 0.1 and for an input voltage range of 12 volts up to 40 volts, the simulation results show that the voltage The output is relatively constant, namely 24 volts with a load test fixed and variable loads.

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Keywords :

Buck-boost converter, MOSFET, PID controller, PWM

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References :

1. T. F. Apreka, “Design and implementation of MPPT fuzzy logic control using boost converter for lighting on chicken farm,” Power Electron. J. Electros, vol. 11, no. 1, pp. 69-75, 2022.
2. Komaruddin, “kontrol buck-boost converter,” J. ELTEK, vol. 12, no. 02, pp. 78-89, 2014.
3. B. Pramono, D. A. R. Wati, and M. V. T. Yadaka, “Simulation of Maximum Power Point Tracking on solar panels using simulink matlab,” Pros. Semin. National. 9th ReTII 2014, vol. 1, pp. 176-183, 2015.
4. Utami, “To optimize the output power of solar cell using MPPT,” J. INFOTEL, vol. 9, no. 1, pp. 92-99, 2017.
5. S. Dinniyah, W. Wahab, dan M. Alif, “Simulation buck-boost buck-boost converter for solar panels using a controller PID,” Energy Procedia, vol. 115, pp. 102-113, 2017.
6. F. Prakoso, “PID control for buckboost chopper capacity of 1 kW capacity based on microcontroller,” Thesis, Univ. General Soedirman, 2019
7. D. D. Putri and Aswardi, “Design of buck-boost converter using PID control,” Jtev (Journal of Electrical and Vocational Technology), vol. 06, no. 02, pp. 258-272, 2020.
8. Hermansyah, Soedibyo, and M. Ashari, “Simulation of double buck boost bidirectional DC-DC converter using PID controller. B-1 B-2,” Pros. SENTIA, vol. 7, pp. 1-6, 2015.
9. A. Wibowo, “Design of buck converter as battery charging system,” MSI Transaction on Education, vol. 03, no. 04, 2022.
10. Ali, “Learning to design PID control system with Matlab software,” J. Electrical Education, vol. 1, no. 1, p. 2, 2004. matlab software,” J. Electrical Education, vol. 1, no. 1, p. 2, 2004.
11. Otong and R. M. Bajuri, “Maximum Power Point Tracking (MPPT) on Wind Power Generation system using buck-boost converter,” Setrum System. Control-Power-electronics-telecommunication-computer, vol. 5, no. 2, p. 103, 2017.
12. C. Rachman, “Design of buck boost converter with lab view based monitoring system,” islamic university indonesia. Yogyakarta, vol. 24 no. 1, pp. 29-41, 2018.
13. Budianto, “Solar power generation system for laptop and cell phone chargers at Ist Akprind,” J. Elektr., vol. 3, no. 1, pp. 45-49, 2016.
14. “Solar panels a thousand paths to energy renewal indonesia page all-Kompasiana.com. “https://www.kompasiana.com/kilengser /6204899dbb448626fa675ca2/solar-panel-one-thousand-ways-to-energy-renewal-Indonesia?page=all&page_images=2 (accessed Aug. 01, 2023).
15. W. H. Basri, B. D. Sulo, and M. J. Afroni, “Design and construction of buck-boost converter on Microhydro Power Plant system using PID,” Science Electro, vol. 14, no. 2, pp. 2. system using PID,” Science Electro, vol. 14, no. 2, pp. 1-150, 2022.
16. Taofik, R. M. Imam, A. Zahroh, and R. E. Saputra, “Design and simulation of charging station system by considering the incoming voltage on buck-boost converter,” EJoint (Electronica and Electrical Journal of Innovation Technology), vol. 03, no. 1, pp. 36-41, 2022.
17. “9 Types of Diodes and Their Uses.” https://ajat.xyz/2020/10/17/9- kinds-of-ideas-and uses/ (accessed Aug. 01, 2023).
18. “Explanation of Electrolytic Capacitor Function.” https://www.ruangteknisi.com/electrolytic-capacitor-function-type-ways-of-working / (accessed Aug. 01, 2023).
19. “Resistor Function as a Current Restriction.” https://solderpanas.com/593/function-resistor-as-current-blocker.html (accessed Aug. 01, 2023).
20. “Definition, Functions and Types of Inductors.” https://blog.unnes.ac.id/antosupri/ understanding-functions-and-types-of-inductors/ (accessed Aug. 01, 2023).
21. Usher and D. Pradita, “Design of a multilevel boost converter using PID control with resistive load,” Thesis, university of jember, 2018.
22. Nugraha and K. Krismadinata, “Design of a single-phase inverter with PWM pulse width modulation using an interface. phase inverter with PWM pulse width modulation using computer interface,” JTEV (Journal of Electrical and Vocational Technology), vol. 6, no.1, p. 340, 2020.
23. Malvino dan D. Bates, Electronic principles Eight Edition, McGraw-Hill Education, 2 Penn Plaza, New York, 2016.
24. “IRF5210 MOSFET Equation: Pinout, Specifications & Datasheet.” https:// android news.com/ equation -mosfet-irf5210/ (accessed Aug. 01, 2023).
25. Jayadi, T. Susanto, and F. D. Adhinata, “Proportional control system for pioneer P3-avoidance robot. control system for pioneer P3-x obstacle avoidance robot (Avoider),” Maj. DX,” Maj. Ilm. Technol. Electro, vol. 20, no. 1, p. 47, 2021.
26. Huda and F. Khamami, “Modification of electric bicycle control system,” J. Cahaya Bagaskara, vol. 1, no. 1, pp. 30-35, 2017.
27. Sulthoni, “Design of current limiter on buck,” Thesis, Islamic University of Indonesia,2020.
28. M Sobirin and J. Utama, “Design of multi Computer Numerical Control (CNC) system for plotter and laser engraving,” Komputika, vol. 9, no. 1, pp. 7-25, 2019.
29. T. Putra, “Remote sensing (location & air quality imagery),” Thesis, Univ. of Indonesia. air quality),” Thesis, Univ. August 17, 1945, Surabaya, pp. 7-55, 2018.
30. S. Drajat, “Chapter II theoretical basis 2.1 suspension cable system,” Thesis, Univ. August 17, 1945, Surabaya, pp. 6-30, 2018.
31. S. Drajat, “A suspension cable control system for object locomotion in 3-dimensional space,” Thesis, Univ. Computer. Indonesia., 2019.
32. I. A. Pratama, A. H. Sulasmoro, and I. Pudja, “C++ programming of shallot planting robot using Arduino based on Internet of Things,” Thesis, Polytechnic of Harapan Bersama, 2021.
33. Nuraini, “Design of an automatic chicken feeding robot based on Atmega16 microcontroller using simulator software Proteus 8,” Petir, vol. 11, no. 1, pp. 31-37, 2018.
34. Dewi, “Decision support system for admission selection new employees of nabila cake & bakery with the web-based Simple Additive Weighting (SAW) method based on the web,” Thesis, University of Muhammadiyah Ponorogo, 2016.
35. Ridlo, Flowchart Making Guide. Surabaya: Department of Health Administration and Policy, 2017.