Publications

Schoenwald, David A.; Roberson, Dakota R.; Borneo, Daniel R.

Abstract not provided.

Schoenwald, David A.; Neely, Jason C.; Elliott, Ryan T.; Byrne, Raymond H.; Roberson, Dakota R.

Abstract not provided.

Elliott, Ryan T.; Byrne, Raymond H.; Schoenwald, David A.; Neely, Jason C.

Abstract not provided.

Elliott, Ryan T.; Schoenwald, David A.; Byrne, Raymond H.; Neely, Jason C.

Abstract not provided.

Ferreira, Summer R.; Rosewater, David M.; Schoenwald, David A.

The U.S. Department of Energys Energy Storage Systems (ESS) Program, through the support of Pacific Northwest National Laboratory (PNNL) and Sandia National Laboratories (SNL), facilitated the development of the protocol provided in this report. The focus of the protocol is to provide a uniform way of measuring, quantifying, and reporting the performance of ESSs in various applications; something that does not exist today and, as such, is hampering the consideration and use of this technology in the market. The availability of an application-specific protocol for use in measuring and expressing performance-related metrics of ESSs will allow technology developers, power-grid operators and other end-users to evaluate the performance of energy storage technologies on a uniform and comparable basis. This will help differentiate technologies and products for specific application(s) and provide transparency in how performance is measured. It also will assist utilities and other consumers of ESSs to make more informed decisions as they consider the potential application and use of ESSs, as well as form the basis for documentation that might be required to justify utility investment in such technologies.

Elliott, Ryan T.; Silva-Monroy, Cesar A.; Neely, Jason C.; Byrne, Raymond H.; Schoenwald, David A.

Abstract not provided.

Ellis, Abraham E.; Elliott, Ryan T.; Neely, Jason C.; Schoenwald, David A.; Silva-Monroy, Cesar A.

Abstract not provided.

Elliott, Ryan T.; Byrne, Raymond H.; Neely, Jason C.; Silva-Monroy, Cesar A.; Schoenwald, David A.

Abstract not provided.

Neely, Jason C.; Elliott, Ryan T.; Silva-Monroy, Cesar A.; Schoenwald, David A.

The goal of this study was to evaluate the small signal and transient stability of the Western Electric- ity Coordinating Council (WECC) under high penetrations of renewable energy, and to identify control technologies that would improve the system performance. The WECC is the regional entity responsible for coordinating and promoting bulk electric system reliability in the Western Interconnection. Transient stability is the ability of the power system to maintain synchronism after a large disturbance while small signal stability is the ability of the power system to maintain synchronism after a small disturbance. Tran- sient stability analysis usually focuses on the relative rotor angle between synchronous machines compared to some stability margin. For this study we employed generator speed relative to system speed as a metric for assessing transient stability. In addition, we evaluated the system transient response using the system frequency nadir, which provides an assessment of the adequacy of the primary frequency control reserves. Small signal stability analysis typically identi es the eigenvalues or modes of the system in response to a disturbance. For this study we developed mode shape maps for the di erent scenarios. Prony analysis was applied to generator speed after a 1.4 GW, 0.5 second, brake insertion at various locations. Six di erent WECC base cases were analyzed, including the 2022 light spring case which meets the renewable portfolio standards. Because of the di culty in identifying the cause and e ect relationship in large power system models with di erent scenarios, several simulations were run on a 7-bus, 5-generator system to isolate the e ects of di erent con gurations. Based on the results of the study, for a large power system like the WECC, incorporating frequency droop into wind/solar systems provides a larger bene t to system transient response than replacing the lost inertia with synthetic inertia. From a small signal stability perspective, the increase in renewable penetration results in subtle changes to the system modes. In gen- eral, mode frequencies increase slightly, and mode shapes remain similar. The system frequency nadir for the 2022 light spring case was slightly lower than the other cases, largely because of the reduced system inertia. However, the nadir is still well above the minimum load shedding frequency of 59.5 Hz. Finally, several discrepancies were identi ed between actual and reported wind penetration, and additional work on wind/solar modeling is required to increase the delity of the WECC models.

Neely, Jason C.; Byrne, Raymond H.; Silva-Monroy, Cesar A.; Elliott, Ryan T.; Schoenwald, David A.

Abstract not provided.

Silva-Monroy, Cesar A.; Neely, Jason C.; Byrne, Raymond H.; Elliott, Ryan T.; Schoenwald, David A.

Abstract not provided.

Neely, Jason C.; Silva-Monroy, Cesar A.; Schoenwald, David A.

Abstract not provided.

Neely, Jason C.; Silva-Monroy, Cesar A.; Schoenwald, David A.

Abstract not provided.

Neely, Jason C.; Silva-Monroy, Cesar A.; Schoenwald, David A.

Abstract not provided.

Ellis, Abraham E.; Schoenwald, David A.

Abstract not provided.

Ellis, Abraham E.; Schoenwald, David A.

Abstract not provided.

Ellis, Abraham E.; Schoenwald, David A.

This report describes an algorithm, implemented in Matlab/Simulink, designed to reduce the variability of photovoltaic (PV) power output by using a battery. The purpose of the battery is to add power to the PV output (or subtract) to smooth out the high frequency components of the PV power that that occur during periods with transient cloud shadows on the PV array. The control system is challenged with the task of reducing short-term PV output variability while avoiding overworking the battery both in terms of capacity and ramp capability. The algorithm proposed by Sandia is purposely very simple to facilitate implementation in a real-time controller. The control structure has two additional inputs to which the battery can respond. For example, the battery could respond to PV variability, load variability or area control error (ACE) or a combination of the three.

Conference Record of the IEEE Photovoltaic Specialists Conference

Johnson, Jay; Schoenwald, David A.; Kuszmaul, Scott S.; Strauch, Jason; Bower, Ward I.

Article 690.11 in the 2011 National Electrical Code® (NEC®) requires new photovoltaic (PV) systems on or penetrating a building to include a listed arc fault protection device. Currently there is little experimental or empirical research into the behavior of the arcing frequencies through PV components despite the potential for modules and other PV components to filter or attenuate arcing signatures that could render the arc detector ineffective. To model AC arcing signal propagation along PV strings, the well-studied DC diode models were found to inadequately capture the behavior of high frequency arcing signals. Instead dynamic equivalent circuit models of PV modules were required to describe the impedance for alternating currents in modules. The nonlinearities present in PV cells resulting from irradiance, temperature, frequency, and bias voltage variations make modeling these systems challenging. Linearized dynamic equivalent circuits were created for multiple PV module manufacturers and module technologies. The equivalent resistances and capacitances for the modules were determined using impedance spectroscopy with no bias voltage and no irradiance. The equivalent circuit model was employed to evaluate modules having irradiance conditions that could not be measured directly with the instrumentation. Although there was a wide range of circuit component values, the complex impedance model does not predict filtering of arc fault frequencies in PV strings for any irradiance level. Experimental results with no irradiance agree with the model and show nearly no attenuation for 1 Hz to 100 kHz input frequencies. © 2011 IEEE.

Kuszmaul, Scott S.; Bower, Ward I.; Schoenwald, David A.

Abstract not provided.

Kuszmaul, Scott S.; Bower, Ward I.; Schoenwald, David A.

Abstract not provided.

Kuszmaul, Scott S.; Bower, Ward I.; Schoenwald, David A.

Abstract not provided.

Schoenwald, David A.; Kuszmaul, Scott S.; Bower, Ward I.

Abstract not provided.

Schoenwald, David A.; Strauch, Jason E.; Kuszmaul, Scott S.

Abstract not provided.

Johnson, Jay; Schoenwald, David A.; Kuszmaul, Scott S.

Article 690.11 in the 2011 National Electrical Code{reg_sign} (NEC{reg_sign}) requires new photovoltaic (PV) systems on or penetrating a building to include a listed arc fault protection device. Currently there is little experimental or empirical research into the behavior of the arcing frequencies through PV components despite the potential for modules and other PV components to filter or attenuate arcing signatures that could render the arc detector ineffective. To model AC arcing signal propagation along PV strings, the well-studied DC diode models were found to inadequately capture the behavior of high frequency arcing signals. Instead dynamic equivalent circuit models of PV modules were required to describe the impedance for alternating currents in modules. The nonlinearities present in PV cells resulting from irradiance, temperature, frequency, and bias voltage variations make modeling these systems challenging. Linearized dynamic equivalent circuits were created for multiple PV module manufacturers and module technologies. The equivalent resistances and capacitances for the modules were determined using impedance spectroscopy with no bias voltage and no irradiance. The equivalent circuit model was employed to evaluate modules having irradiance conditions that could not be measured directly with the instrumentation. Although there was a wide range of circuit component values, the complex impedance model does not predict filtering of arc fault frequencies in PV strings for any irradiance level. Experimental results with no irradiance agree with the model and show nearly no attenuation for 1 Hz to 100 kHz input frequencies.

Schoenwald, David A.; Munoz-Ramos, Karina M.; McLendon, William C.; Russo, Thomas V.

Abstract not provided.