TY - GEN
T1 - Operating a multitasking stationary battery storage system for providing secondary control reserve on low-voltage level
AU - Zeh, Alexander
AU - Müller, Marcus
AU - Hesse, Holger C.
AU - Jossen, Andreas
AU - Witzmann, Rolf
N1 - Publisher Copyright:
© VDE VERLAG GMBH • Berlin • Offenbach.
PY - 2015
Y1 - 2015
N2 - The current debate about the application of storage systems at scientific conferences and symposiums shows the strongly increasing relevance of battery storage systems for a successful completion of the energy transition in Germany and the entire world. Grid operators may be able to substitute grid reinforcement otherwise necessary, electricity utilities can open up new business models and energy customers may become more independent from grid electricity tariffs by using storage systems. However, high investment costs of turnkey storage systems designed for a single storage application do not allow economic operation at present. It is therefore highly desirable to increase cost-effectiveness of storage capacity by combining multiple use-cases. In this paper, a multitasking application for a large-scale stationary battery storage system is presented which allows relieving the grid, storing photovoltaic surplus energy and providing control reserve. An algorithm is presented which allows operation for secondary control reserve on a low-voltage level. Furthermore, the economic benefit of this use-case is calculated for different scenarios. Results show, that providing secondary control reserve and temporary storage for solar systems is a feasible solution to use spare storage capacity especially during night time.
AB - The current debate about the application of storage systems at scientific conferences and symposiums shows the strongly increasing relevance of battery storage systems for a successful completion of the energy transition in Germany and the entire world. Grid operators may be able to substitute grid reinforcement otherwise necessary, electricity utilities can open up new business models and energy customers may become more independent from grid electricity tariffs by using storage systems. However, high investment costs of turnkey storage systems designed for a single storage application do not allow economic operation at present. It is therefore highly desirable to increase cost-effectiveness of storage capacity by combining multiple use-cases. In this paper, a multitasking application for a large-scale stationary battery storage system is presented which allows relieving the grid, storing photovoltaic surplus energy and providing control reserve. An algorithm is presented which allows operation for secondary control reserve on a low-voltage level. Furthermore, the economic benefit of this use-case is calculated for different scenarios. Results show, that providing secondary control reserve and temporary storage for solar systems is a feasible solution to use spare storage capacity especially during night time.
UR - http://www.scopus.com/inward/record.url?scp=85010495797&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:85010495797
T3 - International ETG Congress 2015; Die Energiewende - Blueprints for the New Energy Age
BT - International ETG Congress 2015; Die Energiewende - Blueprints for the New Energy Age
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2015 International ETG Congress on Die Energiewende - Blueprints for the New Energy Age
Y2 - 17 November 2015 through 18 November 2015
ER -