Publications

Mueller, Jacob M.; Kaplar, Robert K.; Flicker, Jack D.; Garcia Rodriguez, Luciano A.; Binder, Andrew B.; Ropp, Michael E.; Gill, Lee G.; Palacios, Felipe N.; Rashkin, Lee; Dow, Andrew R.; Elliott, Ryan T.

Structural modularity is critical to solid-state transformer (SST) and solid-state power substation (SSPS) concepts, but operational aspects related to this modularity are not yet fully understood. Previous studies and demonstrations of modular power conversion systems assume identical module compositions, but dependence on module uniformity undercuts the value of the modular framework. In this project, a hierarchical control approach was developed for modular SSTs which achieves system-level objectives while ensuring equitable power sharing between nonuniform building block modules. This enables module replacements and upgrades which leverage circuit and device technology advancements to improve system-level performance. The functionality of the control approach is demonstrated in detailed time-domain simulations. Results of this project provide context and strategic direction for future LDRD projects focusing on technologies supporting the SST crosscut outcome of the resilient energy systems mission campaign.

Reno, Matthew J.; Jimenez Aparicio, Miguel J.; Wilches-Bernal, Felipe W.; Hernandez Alvidrez, Javier H.; Montoya, Armando Y.; Barba, Pedro; Flicker, Jack D.; Dow, Andrew R.; Bidram, Ali B.; Paruthiyil, Sajay P.; Montoya, Rudy A.; Poudel, Binod P.; Reimer, Benjamin R.; Lavrova, Olga L.; Biswal, Milan B.; Miyagishima, Frank M.; Carr, Christopher L.; Pati, Shubhasmita P.; Ranade, Satish J.; Grijalva, Santiago G.; Paul, Shuva P.

This report is a summary of a 3-year LDRD project that developed novel methods to detect faults in the electric power grid dramatically faster than today’s protection systems. Accurately detecting and quickly removing electrical faults is imperative for power system resilience and national security to minimize impacts to defense critical infrastructure. The new protection schemes will improve grid stability during disturbances and allow additional integration of renewable energy technologies with low inertia and low fault currents. Signal-based fast tripping schemes were developed that use the physics of the grid and do not rely on communication to reduce cyber risks for safely removing faults.