Photovoltaic battery charger with sliding mode control and charging current derivative limitation

Ramos-Paja, Carlos A.; Saavedra-Montes, Andrés J.; Bastidas-Rodríguez, Juan D.

Photovoltaic battery charger with sliding mode control and charging current derivative limitation

dc.creator	Ramos-Paja, Carlos A.
dc.creator	Saavedra-Montes, Andrés J.
dc.creator	Bastidas-Rodríguez, Juan D.
dc.date	2018-05-14
dc.date.accessioned	2025-10-01T23:51:54Z
dc.description	In stand-alone photovoltaic (PV) systems, battery chargers are important to guarantee the energy supply when sunlight is not available. Such chargers need to track the maximum power point (MPPT) and limit the derivative of the batteries’ charging current to extend their lifetime. This paper proposes a battery charging system composed of a Buck converter, a cascade control of the battery current and the PV panel voltage, and the Perturb and Observe (P&O) MPPT technique. P&O generates the reference of the panel voltage for the external loop of the cascade control implemented with a P regulator, whose control action is the reference of the batteries’ charging current. Such current reference passes through a derivative limiter before reaching the internal current control loop, which is implemented by a sliding-mode controller (SMC). This paper includes transversality and reachability analyses of the SMC, as well as the procedure to design the P regulator. The proposed system is validated by simulations in PSIM software to show its capacity to perform MPPT and limit the battery’s charging current derivative at the same time.	en-US
dc.description	En los sistemas fotovoltaicos (PV) aislados, los cargadores de baterías son importantes para garantizar el suministro de energía cuando la luz solar no está disponible. Dichos cargadores necesitan realizar el seguimiento del punto de máxima potencia (MPPT) y limitar la derivada de corriente de carga de las baterías para extender su vida útil. Este artículo propone un sistema cargador de baterías compuesto por un convertidor Buck, un control en cascada de la corriente de las baterías y la tensión del panel PV, y la técnica de MPPT Perturbar y Observar (P&O). El P&O genera la referencia de tensión del panel para el lazo externo del control en cascada, implementado con un regulador P, cuya acción de control es la referencia de la corriente de carga de las baterías. Dicha referencia de corriente pasa por un limitador de derivada antes de llegar al lazo interno de control de corriente de las baterías, el cual es implementado con un control por modos deslizantes (SMC). El artículo incluye el análisis de transversalidad y alcanzabilidad del SMC, así como el procedimiento de diseño del regulador P. El sistema propuesto se valida por medio de simulaciones en el software PSIM mostrando la capacidad de realizar el MPPT y limitar la derivada de corriente de carga de las baterías al mismo tiempo.	es-ES
dc.format	application/pdf
dc.format	text/html
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dc.identifier	https://revistas.itm.edu.co/index.php/tecnologicas/article/view/784
dc.identifier	10.22430/22565337.784
dc.identifier.uri	https://hdl.handle.net/20.500.12622/7652
dc.language	spa
dc.publisher	Instituto Tecnológico Metropolitano (ITM)	es-ES
dc.relation	https://revistas.itm.edu.co/index.php/tecnologicas/article/view/784/913
dc.relation	https://revistas.itm.edu.co/index.php/tecnologicas/article/view/784/984
dc.relation	https://revistas.itm.edu.co/index.php/tecnologicas/article/view/784/1205
dc.relation	https://revistas.itm.edu.co/index.php/tecnologicas/article/view/784/1252
dc.relation	/ref/REN21, “Advancing the global renewable
dc.relation	/ref/energy transition,” 2017.
dc.relation	/ref/IEA-PVPS, “2016 Snapshot of Global Photovoltaic Markets,” 2017.
dc.relation	/ref/IDEAM, “Atlas de radiación solar,
dc.relation	/ref/ultravioleta y ozono de Colombia,” Atlas,
dc.relation	/ref/[Online]. Available:
dc.relation	/ref/html.
dc.relation	/ref/World Bank Group, “Global Solar Atlas,”
dc.relation	/ref/[Online]. Available:
dc.relation	/ref/atlas.
dc.relation	/ref/F. Palmiro, R. Rayudu, and R. Ford,
dc.relation	/ref/“Modelling and simulation of a solar PV
dc.relation	/ref/lithium ion battery charger for energy kiosks
dc.relation	/ref/application,” in 2015 IEEE PES Asia-Pacific
dc.relation	/ref/Power and Energy Engineering Conference
dc.relation	/ref/(APPEEC), 2015, vol. 3, pp. 1–5.
dc.relation	/ref/R. A. Messenger and J. Ventre, Photovoltaics
dc.relation	/ref/Systems Engineering, Second. Boca Raton,
dc.relation	/ref/London, New York, Washigton D.C.: Taylor
dc.relation	/ref/& Francis, 2004.
dc.relation	/ref/Y. E. Abu Eldahab, N. H. Saad, and A.
dc.relation	/ref/Zekry, “Enhancing the design of battery
dc.relation	/ref/charging controllers for photovoltaic
dc.relation	/ref/systems,” Renew. Sustain. Energy Rev., vol.
dc.relation	/ref/58, pp. 646–655, May 2016.
dc.relation	/ref/J. López, S. I. Seleme, P. F. Donoso, L. M. F.
dc.relation	/ref/Morais, P. C. Cortizo, and M. A. Severo,
dc.relation	/ref/“Digital control strategy for a buck converter
dc.relation	/ref/operating as a battery charger for standalone
dc.relation	/ref/photovoltaic systems,” Sol. Energy, vol.
dc.relation	/ref/140, pp. 171–187, Dec. 2016.
dc.relation	/ref/A. M. Gee, F. V. P. Robinson, and R. W.
dc.relation	/ref/Dunn, “Analysis of Battery Lifetime
dc.relation	/ref/Extension in a Small-Scale Wind-Energy
dc.relation	/ref/System Using Supercapacitors,” IEEE Trans.
dc.relation	/ref/Energy Convers., vol. 28, no. 1, pp. 24–33,
dc.relation	/ref/Mar. 2013.
dc.relation	/ref/J. Li, A. M. Gee, M. Zhang, and W. Yuan,
dc.relation	/ref/“Analysis of battery lifetime extension in a
dc.relation	/ref/SMES-battery hybrid energy storage system
dc.relation	/ref/using a novel battery lifetime model,”
dc.relation	/ref/Energy, vol. 86, pp. 175–185, Jun. 2015.
dc.relation	/ref/G. Ning, B. Haran, and B. N. Popov,
dc.relation	/ref/“Capacity fade study of lithium-ion batteries
dc.relation	/ref/cycled at high discharge rates,” J. Power
dc.relation	/ref/Sources, vol. 117, no. 1–2, pp. 160–169, May
dc.relation	/ref/
dc.relation	/ref/J. Li, R. Xiong, Q. Yang, F. Liang, M. Zhang,
dc.relation	/ref/and W. Yuan, “Design/test of a hybrid energy
dc.relation	/ref/storage system for primary frequency control
dc.relation	/ref/using a dynamic droop method in an isolated
dc.relation	/ref/microgrid power system,” Appl. Energy, vol.
dc.relation	/ref/201, pp. 257–269, Sep. 2017.
dc.relation	/ref/J. Li, Q. Yang, F. Robinson, F. Liang, M.
dc.relation	/ref/Zhang, and W. Yuan, “Design and test of a
dc.relation	/ref/new droop control algorithm for a
dc.relation	/ref/SMES/battery hybrid energy storage
dc.relation	/ref/system,” Energy, vol. 118, pp. 1110–1122,
dc.relation	/ref/Jan. 2017.
dc.relation	/ref/Sony Energy Devices Corporation and Device
dc.relation	/ref/Solutions Business Group, “Lithium Ion
dc.relation	/ref/Rechargeable Battery Technical
dc.relation	/ref/Information,” 2012.
dc.relation	/ref/E. A. Jiménez-Brea, E. I. Ortiz-Rivera, A.
dc.relation	/ref/Salazar-Llinás, and J. González-Llorente,
dc.relation	/ref/“Simple photovoltaic solar cell dynamic
dc.relation	/ref/sliding mode controlled maximum power
dc.relation	/ref/point tracker for battery charging
dc.relation	/ref/applications,” in Conference Proceedings -
dc.relation	/ref/IEEE Applied Power Electronics Conference
dc.relation	/ref/and Exposition - APEC, 2010, pp. 666–671.
dc.relation	/ref/A. M. S. S. Andrade, E. Mattos, C. O. Gamba,
dc.relation	/ref/L. Schuch, and M. L. da S. Martins, “Design
dc.relation	/ref/and implementation of PV power zeta
dc.relation	/ref/converters for battery charger applications,”
dc.relation	/ref/in 2015 IEEE Energy Conversion Congress
dc.relation	/ref/and Exposition (ECCE), 2015, pp. 3135–
dc.relation	/ref/
dc.relation	/ref/A. M. S. S. Andrade, L. Schuch, and M. L. da
dc.relation	/ref/S. Martins, “Photovoltaic battery charger
dc.relation	/ref/based on the Zeta converter: Analysis, design
dc.relation	/ref/and experimental results,” in 2015 IEEE
dc.relation	/ref/24th International Symposium on Industrial
dc.relation	/ref/Electronics (ISIE), 2015, pp. 379–384.
dc.relation	/ref/A. M. S. S. Andrade, R. C. Beltrame, L.
dc.relation	/ref/Schuch, and M. L. da S. Martins, “PV
dc.relation	/ref/module-integrated single-switch DC/DC
dc.relation	/ref/converter for PV energy harvest with battery
dc.relation	/ref/charge capability,” in 2014 11th IEEE/IAS
dc.relation	/ref/International Conference on Industry
dc.relation	/ref/Applications, 2014, vol. 1, pp. 1–8.
dc.relation	/ref/D. G. Montoya, C. A. Ramos-Paja, and R.
dc.relation	/ref/Giral, “Improved Design of Sliding-Mode
dc.relation	/ref/Controllers Based on the Requirements of
dc.relation	/ref/MPPT Techniques,” IEEE Trans. Power
dc.relation	/ref/Electron., vol. 31, no. 1, pp. 235–247, Jan.
dc.relation	/ref/
dc.relation	/ref/D. González-Montoya, C. A. Ramos-Paja, and
dc.relation	/ref/R. Giral, “Maximum power point tracking of
dc.relation	/ref/photovoltaic systems based on the sliding
dc.relation	/ref/mode control of the module admittance,”
dc.relation	/ref/Electr. Power Syst. Res., vol. 136, pp. 125–
dc.relation	/ref/134, Jul. 2016.
dc.relation	/ref/R. Haroun, A. El Aroudi, A. Cid-Pastor, G.
dc.relation	/ref/Garica, C. Olalla, and L. Martinez-Salamero,
dc.relation	/ref/“Impedance Matching in Photovoltaic
dc.relation	/ref/Systems Using Cascaded Boost Converters
dc.relation	/ref/and Sliding-Mode Control,” IEEE Trans.
dc.relation	/ref/Power Electron., vol. 30, no. 6, pp. 3185–
dc.relation	/ref/3199, Jun. 2015.
dc.relation	/ref/A. Cid-Pastor, L. Martínez-Salamero, A. El
dc.relation	/ref/Aroudi, R. Giral, J. Calvente, and R. Leyva,
dc.relation	/ref/“Synthesis of loss-free resistors based on
dc.relation	/ref/sliding-mode control and its applications in
dc.relation	/ref/power processing,” Control Eng. Pract., vol.
dc.relation	/ref/21, no. 5, pp. 689–699, May 2013.
dc.relation	/ref/J. Guacaneme, D. González, and C. Trujillo,
dc.relation	/ref/“Controlador difuso inteligente para un
dc.relation	/ref/cargador de baterías de plomo-ácido,”
dc.relation	/ref/Ingeniería, vol. 8, no. 2, pp. 62–67, 2003.
dc.relation	/ref/SMA, “Technical Information Battery
dc.relation	/ref/Management of the Sunny Island,” 2017.
dc.relation	/ref/O. López-Santos, D. A. Zambrano Prada, Y.
dc.relation	/ref/A. Aldana-Rodríguez, H. A. Esquivel-Cabeza,
dc.relation	/ref/G. García, and L. Martínez-Salamero,
dc.relation	/ref/“Control of a Bidirectional Cûk Converter
dc.relation	/ref/Providing Charge/Discharge of a Battery
dc.relation	/ref/Array Integrated in DC Buses of Microgrids,”
dc.relation	/ref/in Applied Computer Sciences in
dc.relation	/ref/Engineering, J. C. Figueroa-García, E. R.
dc.relation	/ref/López-Santana, J. L. Villa-Ramírez, and R.
dc.relation	/ref/Ferro-Escobar, Eds. Cham: Springer
dc.relation	/ref/International Publishing, 2017, pp. 495–507.
dc.relation	/ref/M. E. Sahin, H. I. Okumus, and H. Kahveci,
dc.relation	/ref/“Sliding mode control of PV powered DC/DC
dc.relation	/ref/Buck-Boost converter with digital signal
dc.relation	/ref/processor,” in 2015 17th European
dc.relation	/ref/Conference on Power Electronics and
dc.relation	/ref/Applications (EPE’15 ECCE-Europe), 2015,
dc.relation	/ref/pp. 1–8.
dc.relation	/ref/N. Femia, G. Petrone, G. Spagnuolo, and M.
dc.relation	/ref/Vitelli, “Optimization of Perturb and
dc.relation	/ref/Observe Maximum Power Point Tracking
dc.relation	/ref/Method,” IEEE Trans. Power Electron., vol.
dc.relation	/ref/20, no. 4, pp. 963–973, Jul. 2005.
dc.relation	/ref/G. Petrone and C. A. Ramos-Paja, “Modeling
dc.relation	/ref/of photovoltaic fields in mismatched
dc.relation	/ref/conditions for energy yield evaluations,”
dc.relation	/ref/Electr. Power Syst. Res., vol. 81, no. 4, pp.
dc.relation	/ref/1003–1013, Apr. 2011.
dc.relation	/ref/Y.-C. Chuang and Y.-L. Ke, “Analysis and
dc.relation	/ref/implementation of zero voltage switching
dc.relation	/ref/integrated buck-flyback converter,” IET
dc.relation	/ref/Power Electron., vol. 6, no. 7, pp. 2846–2852,
dc.relation	/ref/
dc.relation	/ref/Siew-Chong Tan, Y. M. Lai, and C. K. Tse,
dc.relation	/ref/“General Design Issues of Sliding-Mode
dc.relation	/ref/Controllers in DC–DC Converters,” IEEE
dc.relation	/ref/Trans. Ind. Electron., vol. 55, no. 3, pp.
dc.relation	/ref/1160–1174, Mar. 2008.
dc.relation	/ref/H. Sira-Ramírez, “Sliding Motions in
dc.relation	/ref/Bilinear Switched Networks,” IEEE Trans.
dc.relation	/ref/Circuits Syst., vol. 34, no. 8, pp. 919–933,
dc.relation	/ref/
dc.relation	/ref/P. A. Ortiz-Valencia and C. A. Ramos-Paja,
dc.relation	/ref/“Sliding-mode controller for maximum power
dc.relation	/ref/point tracking in grid-connected photovoltaic
dc.relation	/ref/systems,” Energies, vol. 8, no. 11, pp. 12363–
dc.relation	/ref/12387, 2015.
dc.relation	/ref/C. A. Ramos-Paja, D. González, and A. J.
dc.relation	/ref/Saavedra-Montes, “Accurate calculation of
dc.relation	/ref/settling time in second order systems: A
dc.relation	/ref/photovoltaic application,” Rev. Fac. Ing.
dc.relation	/ref/Univ. Antioquia, no. 66, pp. 104–117, 2013.
dc.relation	/ref/T. Green, “TI Precision Designs: Reference
dc.relation	/ref/Design - Single Op-Amp Slew Rate Limiter,”
dc.relation	/ref/Texas Instruments Incorporated, 2013.
dc.relation	/ref/Digatron, “Universal Battery Tester ME
dc.relation	/ref/Series,” Digatron. [Online]. Available:
dc.relation	/ref/universal-battery-tester/.
dc.relation	/ref/Bitrode, “MCV-EV/HEV Battery Cell
dc.relation	/ref/Testter,” 2015. [Online]. Available:
dc.source	TecnoLógicas; Vol. 21 No. 42 (2018); 129-145	en-US
dc.source	TecnoLógicas; Vol. 21 Núm. 42 (2018); 129-145	es-ES
dc.source	2256-5337
dc.source	0123-7799
dc.subject	Battery charger	en-US
dc.subject	photovoltaic panel	en-US
dc.subject	Buck converter	en-US
dc.subject	sliding-mode control	en-US
dc.subject	current derivative limitation	en-US
dc.subject	Cargador baterías	es-ES
dc.subject	panel fotovoltaico	es-ES
dc.subject	convertidor Buck	es-ES
dc.subject	control por modos deslizantes	es-ES
dc.subject	limitación derivada de corriente	es-ES
dc.title	Photovoltaic battery charger with sliding mode control and charging current derivative limitation	en-US
dc.title	Cargador de baterías fotovoltaico con control por modos deslizantes y limitación de la derivada de corriente de carga	es-ES
dc.type	info:eu-repo/semantics/article
dc.type	info:eu-repo/semantics/publishedVersion
dc.type	Research Papers	en-US
dc.type	Artículos de investigación	es-ES