Journal of Semiconductor Devices and Circuits

Open Access  Subscription or Fee Access

The review documents contained in the literature are either completely off the non-critical load or forwarded within a convenient time frame based on the resulting satisfaction. In this study, instead of shifting critical loads to other terms, they tried to adjust the energy consumption of non-critical loads with the help of AC. A rule-based energy management algorithm is proposed, which uses electric springs to use AC microgrids.

A new DC/DC converter called ASDC spring is proposed, which is completely different from the converter present in the literature. Like the real-time microgrid test system developed by the laboratory, the new energy control algorithm was developed to operate effectively under the spring. The results show that the energy consumed by microgrid structure from the main power grid is reduced by 10% under the presence of power source.

Finally, an energy management strategy is proposed, using actual storage facilities suitable for electricity AC sources and residential consumers. This review document will attempt to und

Electric Spring,, Micro grids, Energy management, Actual storage units

- Andreotti, A., Carpinelli, G., Motto, F. and Prototype, D. (2012), Optimization Model Review of Connected

Car Names in Smart Grid Part 2: Numerical Applications for Fleets, "IEEE Power and Energy Association Gen-Eral Meeting", IEEE, p.

- Bergen, A.R. (2009), Nutritional Systems Analysis, Pearson Education India.

- Carlson, N., Asgailson, H., Raske, R., Benario, D. and Ennis, M.G., Applik-tion indentation type, repronizer of side-chain field research distribution, at the 2009 IEEE Electric Energy Society Conference, IEEE, p.

- Zhou Douri, N.R., Lee, K.K., Zhou Duli, B. and Hui, S.R. (2014), Dynamic Spring Modeling, IEEE Smart

Grid 5 (5), 2450-2458.

- Chen, T., Liu, H, Li, K.K. Hui, S.R. (2018) "Intelligent Load Broad Controller based on Active and Reactive

Power Compensation", IEEE Power Electronics Emerging Themes and Select Theme Magazine.

- Chen, X., Hou, Y. and Hui, S.R. (2016), "Distributed Control Microgrid Voltage Control for Multiple Electrical Springs", IEEE Processing Smart Grid 8 (3), 1350-1359.

- Chen, H., Howe, J., Tan, S.-K., Lee, K-K. and Hui, S.Y.R. (2014), "Using electric springs to reduce the voltage and vibration of microgrids", Smart Grid 6 (2), IEEE Trading 508-515.

- Chico, G. (2010) Intelligent Distribution System Issues: Data Rendering and Optimization Goals, IEEE, pp. 1236-1244, at the 12th International Conference on Electrical and Electronic Equipment Optimization, 2010.

- Cornell, A.J., Morales, J.M and Baringo, L. (2010), Real-Time Demand Response Model, Smart Grid 1 (3), IEEE Trading 236-242.

- Debunass, Ahmed, I. and Habibib, D. (2014), "Quantitative Economic Benefits of Smart Grid Second Life Battery Network Vehicles", International Journal of Electricity and Energy Systems 63,577-5.