DOI:
https://doi.org/10.14483/22484728.15829Publicado:
2020-08-31Número:
Vol. 14 Núm. 2 (2020)Sección:
Visión InvestigadoraDuty cycle and radiation estimates using maximum load transfer point for optimization of a 100KVA photovoltaic system
Estimaciones de ciclo de trabajo y radiación utilizando máximo punto de transferencia de carga para la optimización de un sistema fotovoltaico de 100KVA
Palabras clave:
Duty cycle, MPPT, Photovoltaic, Power, Radiation, Temperature (en).Palabras clave:
Duty cycle, MPPT, Fotovoltaico, Potencia, Radiación, Temperatura (es).Descargas
Resumen (en)
In this document, the variation of temperature and radiation in a 100 kW photovoltaic assembly is connected to a 25 kV network through a DC-DC booster converter and a three-phase three-phase voltage source converter (VSC). Maximum power point tracking (MPPT) is implemented in the elevator converter using a Simulink® model that uses the technique of 'Incremental Conductance + Integral Regulator'.
The switching duty cycle is optimized by an MPPT controller that uses the technique of 'Incremental Conductance + Integral Regulator'. This MPPT system automatically modifies the duty cycle to generate the voltage required to extract the maximum power.
Resumen (es)
En este documento, se describen la variación de la temperatura y radiación en un conjunto fotovoltaico de 100 kW está conectado a una red de 25 kV a través de un convertidor de refuerzo CC-CC y un convertidor de fuente de voltaje trifásico de tres niveles (VSC). El seguimiento del punto de máxima potencia (MPPT) se implementa en el convertidor elevador mediante un modelo Simulink® que utiliza la técnica de 'Conductancia incremental + Regulador integral'.
El ciclo de trabajo de conmutación está optimizado por un controlador MPPT que utiliza la técnica de 'Conductancia incremental + Regulador integral'. Este sistema MPPT varía automáticamente el ciclo de trabajo para generar el voltaje requerido para extraer la potencia máxima.
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