Abstract
This paper introduces a new framework for optimum design and operation of hybrid renewable energy plants (HREP) augmented with battery energy storage systems (BESS). A new renewable energy management system (REMS) is developed comprising three components: 1) Enhanced joint forecasting of wind and solar outputs based on deep neural networks and also multiplicative weights update (MWU); 2) an advanced optimization model for sizing the HREP-BESS components and the policy of BESS operation; and 3) Augmenting the rolling hourly dispatch for HREP-BESS with a novel dynamic ramping limit and a criterion for reduction of deviations from the hour-ahead dispatch schedule. The proposed REMS tool enables maintaining the inter-hourly ramping of the HREP-BESS output within a threshold. In this context, a novel dynamic ramp limit is proposed to minimize the energy curtailment during operation and maximize energy sales to the power grid. The advantage of the proposed REMS tool over the classical renewable energy systems operation scheme is the mitigation of the volatility of renewable energy sources (RES) by suppressing extreme ramping events with minimum curtailment. Moreover, the costs and revenues of the HREP-BESS design and operation are assessed over a 25 years period. The design problem is solved for different scenarios, and the optimal solution always encloses a hybrid mix of renewables where the share of the PV plant can reach up to 37.1% of the total plant size. With the proposed REMS, the curtailment of RES never exceeds 12.9% even when the HREP is operated without a reserve margin. For the selected design, the optimum BESS capacity is 12.9% of the HREP capacity. The number of hours which observe a ramping violation event is 2.4% of the season's length (2184 hours). 99% of all ramping events fall within the defined ramping limits. The use of the MWU method increases the total profit by 2.53% compared with adopting the average forecast.
Highlights
R ENEWABLE energy (RE) is gaining interest worldwide due to environmental concerns
Most of the design scenarios with a higher penalty πρhave a larger battery energy storage system (BESS) unit CBESS, and a smaller BESS oversizing factor OvFBESS compared to the results with low penalty πρ
A higher penalty πρalso leads to a higher proxy value of BESS stored energy πPBESS
Summary
R ENEWABLE energy (RE) is gaining interest worldwide due to environmental concerns. New policies require grid operators to supply a certain percentage of their load from renewable energy sources (RES), or face high penalties. Partial clouding of photovoltaic (PV) panels can decrease a PV plant’s output by more than 50% within 1 h [7], [8] Against all these findings, European grid codes [9]–[11] define ramping rate limits at the 1-minute time-frame only. The ramping limits are 1%–1.5% of the RES capacity subject to a maximum of 60 MW/min This allows the RES owner to ramp continuously at the maximum rate for extended periods of time, without any legal repercussions. The RES output is allowed within one hour to change by 60%–90% of the RES capacity, subject to a maximum of 3.6 GW This would have a drastic effect on the grid, both technically and economically
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