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Implementation of MPPT Solar Charge Controller Using Arduino Nano

Kiron Ghosh1 , Surajit Sahoo2 , Subhadeep Bhadra3 , Rounak Saha4

Section:Survey Paper, Product Type: Journal Paper
Volume-07 , Issue-18 , Page no. 256-258, May-2019

Online published on May 25, 2019

Copyright © Kiron Ghosh, Surajit Sahoo, Subhadeep Bhadra, Rounak Saha . This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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IEEE Style Citation: Kiron Ghosh, Surajit Sahoo, Subhadeep Bhadra, Rounak Saha, “Implementation of MPPT Solar Charge Controller Using Arduino Nano,” International Journal of Computer Sciences and Engineering, Vol.07, Issue.18, pp.256-258, 2019.

MLA Style Citation: Kiron Ghosh, Surajit Sahoo, Subhadeep Bhadra, Rounak Saha "Implementation of MPPT Solar Charge Controller Using Arduino Nano." International Journal of Computer Sciences and Engineering 07.18 (2019): 256-258.

APA Style Citation: Kiron Ghosh, Surajit Sahoo, Subhadeep Bhadra, Rounak Saha, (2019). Implementation of MPPT Solar Charge Controller Using Arduino Nano. International Journal of Computer Sciences and Engineering, 07(18), 256-258.

BibTex Style Citation:
@article{Ghosh_2019,
author = {Kiron Ghosh, Surajit Sahoo, Subhadeep Bhadra, Rounak Saha},
title = {Implementation of MPPT Solar Charge Controller Using Arduino Nano},
journal = {International Journal of Computer Sciences and Engineering},
issue_date = {5 2019},
volume = {07},
Issue = {18},
month = {5},
year = {2019},
issn = {2347-2693},
pages = {256-258},
url = {https://www.ijcseonline.org/full_spl_paper_view.php?paper_id=1374},
publisher = {IJCSE, Indore, INDIA},
}

RIS Style Citation:
TY - JOUR
UR - https://www.ijcseonline.org/full_spl_paper_view.php?paper_id=1374
TI - Implementation of MPPT Solar Charge Controller Using Arduino Nano
T2 - International Journal of Computer Sciences and Engineering
AU - Kiron Ghosh, Surajit Sahoo, Subhadeep Bhadra, Rounak Saha
PY - 2019
DA - 2019/05/25
PB - IJCSE, Indore, INDIA
SP - 256-258
IS - 18
VL - 07
SN - 2347-2693
ER -

           

Abstract

This paper is describing an Arduino based Solar MPPT charge controller. It has features like: LCD display, Led Indication, Wi Fi data logging and provision for charging different USB devices. It is equipped with various protections to protect the circuitry from abnormal condition. The microcontroller used is in this controller is Arduino Nano. This design is suitable for a 50W solar panel to charge a commonly used 12V lead acid battery. You can also use other Arduino board like Pro Mini, Micro and UNO. Now a days the most advance solar charge controller available in the market is Maximum Power Point Tracking (MPPT). The MPPT controller is more sophisticated and more expensive. It has several advantages over the earlier charge controller. It is 30 to 40 % more efficient at low temperature. But making a MPPT charge controller is little bit complex in compare to PWM charge controller. It requires some basic knowledge of power electronics. I put a lot of effort to make it simple, so that anyone can understand it easily. If you are aware about the basics of MPPT charge controller then skip the first few steps. The Maximum Power Point Tracker (MPPT) circuit is based around a synchronous buck converter circuit. It steps the higher solar panel voltage down to the charging voltage of the battery. The Arduino tries to maximize the watts input from the solar panel by controlling the duty cycle to keep the solar panel operating at its Maximum Power Point.

Key-Words / Index Term

MPPT, Arduino Nano, PV Solar Panel,Wifi

References

[1] choudhary, dhananjay and saxena, anmol ratna (2014) ‘DC-DC buck converter for MPPT of PV system’, International Journal of Emerging Technology and Advanced Engineering, 4(7).
[2] Kotak, V.C. and Tyagi, P. (2013) ‘DC To DC Converter in Maximum Power Point Tracker’, International Journal of Advanced Research in Electrical, Electronics and Instrumentation Engineering, 2(12).
[3] radio-electronis.com (no date) Available at: http://http://www.radio-electronics.com/info/power management/switchingmode-power-supply/step-down-buck-regulator-converter-basics.php (Accessed: 10 July 2016).
[4] MicroSystems, A. (2016) Allegro MicroSystems - ACS712: Fully integrated, hall-effectbased linear current sensor IC with 2.1 kVRMS voltage isolation and a low-resistance current conductor. Available at: http://www.allegromicro.com/en/Products/Current-SensorICs/Zero-To-Fifty-Amp-Integrated-Conductor-Sensor-ICs/ACS712.aspx (Accessed: 7 August 2016).
[5]Rahman, S., Sultana, N. and Masud, Q. (2012) Design of a Charge Controller Circuit with Maximum Power Point Tracker (MPPT) for Photovoltaic System. Thesis Report, BRAC University (2012), Available at: http://dspace.bracu.ac.bd/xmlui/bitstream/handle/10361/2389/Design%20of%20a%20Charge %20Controller%20Circuit.pdf.pdf?sequence=1&isAllowed=y (Accessed: 15 May 2016).
[6] Pürschel, M. (2009) Automotive Power. Available at: http://www.infineon.com/dgdl/Reverse-Batery-ProtectionRev2.pdf?fileId=db3a304412b407950112b41887722615 (Accessed: 11 August 2016).
[7] News & analysis (2016) Available at: http://www.globalspec.com/learnmore/optics_optical_components/optoelectronics/optocouplers (Accessed: 12 August 2016).