Design and Test of a High-Performance Wireless Sensor Network for Irradiance Monitoring
Manuel Jesús Espinosa-Gavira,
Agustín Agüera-Pérez,
José María Sierra-Fernández,
Juan José González de-la-Rosa,
José Carlos Palomares-Salas,
Olivia Florencias-Oliveros
Affiliations
Manuel Jesús Espinosa-Gavira
Research Group PAIDI-TIC-168, Computational Instrumentation and Industrial Electronics (ICEI), University of Cadiz, ETSI of Algeciras, Av. Ramonn Puyol S/N, Algeciras, 11202 Cadiz, Spain
Agustín Agüera-Pérez
Research Group PAIDI-TIC-168, Computational Instrumentation and Industrial Electronics (ICEI), University of Cadiz, ETSI of Algeciras, Av. Ramonn Puyol S/N, Algeciras, 11202 Cadiz, Spain
José María Sierra-Fernández
Research Group PAIDI-TIC-168, Computational Instrumentation and Industrial Electronics (ICEI), University of Cadiz, ETSI of Algeciras, Av. Ramonn Puyol S/N, Algeciras, 11202 Cadiz, Spain
Juan José González de-la-Rosa
Research Group PAIDI-TIC-168, Computational Instrumentation and Industrial Electronics (ICEI), University of Cadiz, ETSI of Algeciras, Av. Ramonn Puyol S/N, Algeciras, 11202 Cadiz, Spain
José Carlos Palomares-Salas
Research Group PAIDI-TIC-168, Computational Instrumentation and Industrial Electronics (ICEI), University of Cadiz, ETSI of Algeciras, Av. Ramonn Puyol S/N, Algeciras, 11202 Cadiz, Spain
Olivia Florencias-Oliveros
Research Group PAIDI-TIC-168, Computational Instrumentation and Industrial Electronics (ICEI), University of Cadiz, ETSI of Algeciras, Av. Ramonn Puyol S/N, Algeciras, 11202 Cadiz, Spain
Cloud-induced photovoltaic variability can affect grid stability and power quality, especially in electricity systems with high penetration levels. The availability of irradiance field forecasts in the scale of seconds and meters is fundamental for an adequate control of photovoltaic systems in order to minimize their impact on distribution networks. Irradiance sensor networks have proved to be efficient tools for supporting these forecasts, but the costs of monitoring systems with the required specifications are economically justified only for large plants and research purposes. This study deals with the design and test of a wireless irradiance sensor network as an adaptable operational solution for photovoltaic systems capable of meeting the measurement specifications necessary for capturing the clouds passage. The network was based on WiFi, comprised 16 pyranometers, and proved to be stable at sampling periods up to 25 ms, providing detailed spatial representations of the irradiance field and its evolution. As a result, the developed network was capable of achieving comparable specifications to research wired irradiance monitoring network with the advantages in costs and flexibility of the wireless technology, thus constituting a valuable tool for supporting nowcasting systems for photovoltaic management and control.
