Power networks are deeply changing in recent years due to the rapid deployment of renewable energies and a growing worldwide energy demand. Energy storage systems are promising technologies to provide electric networks with ancillary services. Currently, only few data referred to batteries operation in power network ancillary services utilization are available. This could limit the evaluation of battery technologies in relation to those applications. Li-Titanate technology is characterized by a high specific power, long lifetime, and it guarantees high safety in stressful conditions. In this framework, the performance of a Li-Titanate battery module, subjected to a Primary Frequency Control (PFC) cycle, was studied. This paper reports the results coming from the testing campaign, where Li-Titanate battery demonstrated no degradation after 250 test days. Due to the module low energy content with respect the PFC profile, the battery resulted discharged two times per day. Therefore, a numerical tool was developed in order to obtain a valid instrument for optimal design in relation to PFC application and for simulating Li-Titanate battery module behavior.
Evaluation of a Li-Titanate battery module in primary frequency control ancillary service conditions
Sergi F;Brunaccini G;Aloisio D;Randazzo N;Ferraro M;Antonucci V
2019
Abstract
Power networks are deeply changing in recent years due to the rapid deployment of renewable energies and a growing worldwide energy demand. Energy storage systems are promising technologies to provide electric networks with ancillary services. Currently, only few data referred to batteries operation in power network ancillary services utilization are available. This could limit the evaluation of battery technologies in relation to those applications. Li-Titanate technology is characterized by a high specific power, long lifetime, and it guarantees high safety in stressful conditions. In this framework, the performance of a Li-Titanate battery module, subjected to a Primary Frequency Control (PFC) cycle, was studied. This paper reports the results coming from the testing campaign, where Li-Titanate battery demonstrated no degradation after 250 test days. Due to the module low energy content with respect the PFC profile, the battery resulted discharged two times per day. Therefore, a numerical tool was developed in order to obtain a valid instrument for optimal design in relation to PFC application and for simulating Li-Titanate battery module behavior.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.