Abstract

Stochastically fluctuating wind power has an escalating impact on the stability of power grid operations. To smooth out short- and long-term fluctuations, this paper presents a coordinated control algorithm using model predictive control (MPC) to manage a hybrid energy storage system (HESS) consisting of ultra-capacitor (UC) and lithium-ion battery (LB) banks. In the HESS-computing period, the algorithm minimizes HESS operating costs in the subsequent prediction horizon by optimizing the time constant of a flexible first-delay filter (FDF) to obtain the UC power output. In the LB-computing period, the algorithm keeps the optimal time constant of the FDF from the previous period to directly obtain the power output of the UC bank to minimize the power output of the LB bank in the next prediction horizon. A relaxation technique is deployed when the problem is unsolvable. Thus, the fluctuation mitigation requirements are fulfilled with a large probability even in extreme conditions. A state-of-charge (SOC) feedback control strategy is proposed to regulate the SOC of the HESS within its proper range. Case studies and quantitative comparisons demonstrate that the proposed MPC-based algorithm uses a lower power rating and storage capacity than other conventional algorithms to satisfy one-minute and 30-min fluctuation mitigation requirements (FMR).

Highlights

  • Wind energy is an inexhaustible and environmentally friendly source of renewable energy.Countries like China, USA, Germany, and Spain have led in the installation capacities of wind energy in global markets

  • In the hybrid energy storage system (HESS)-computing periods, the goal is to minimize the cost of HESS in the prediction horizon, the optimal power output of lithium-ion battery (LB) is obtained, as well as the optimal time constant of first-delay filter for obtaining the power output of UC

  • In the LB-computing period, the optimal time constant in the last HESS-computing period is kept to directly obtain the power output of UC, the goal of this stage is simplified to minimize the cost of LB utilization in the subsequent control horizon

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Summary

Introduction

Wind energy is an inexhaustible and environmentally friendly source of renewable energy. Abbey et al utilized a knowledge-based control approach [14], while Datta et al implemented fuzzy logic to smooth power fluctuations of photovoltaic-diesel hybrid power system [15] These methods are all based on an FDF, and fail to guarantee that the smoothing power output at the point of interconnection of wind farm always fulfills the fluctuation mitigation requirements (FMR). A quadratically-constrained programming (QCP) problem is solved to minimize the cost of HESS or LB in the prediction horizon It effectively mitigates wind power fluctuations in multiple time scales, and with a novel state-of-charge feedback (SOCFB) control scheme, it can effectively restore the SOCs of the HESS to its proper safety range

Composition of Wind Power Signals
Thirty-Minute Fluctuation Mitigation Requirements
Flexible First-Delay-Filter with Variable Time Constant
Capacity Calculation
MPC-Based Coordination Control Model for the HESS
(1) Objective function
MPC-based control model for the LB bank
Transformation of the FMR Constraints
Model Solution
Feasibility and Constraints Handling
State-of-Charge Feedback Control
State-of-Charge Feedback Control of the LB
HESS Capacity and Power Configurations
Methods
Comparison of MPCCC and Conventional Algorithms
Battery Health Index
Equivalent Full Cycle
Verification of the Proposed Control Strategy
Maximal
Findings
Conclusions

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