Research on Parallel Control Strategy of Microgrid Energy Storage Inverter Based on SOC Collaboration

This study investigates the coordinated control of parallel-connected energy storage inverters in islanded AC microgrids. A novel adaptive virtual impedance method and state-of-charge (SOC) balancing strategy are proposed to address power distribution inaccuracies and SOC imbalance challenges.

1. System Modeling and Control Framework

The mathematical model of energy storage inverters is established considering battery characteristics and power conversion dynamics. The SOC estimation combines open-circuit voltage measurement with coulomb counting:

$$ \text{SOC} = \text{SOC}_0 – \frac{1}{C_{\text{nom}}} \int_{0}^{t} i_{\text{bat}} dt $$

Key parameters for the three-phase inverter with LC filter are designed as:

Parameter	Symbol	Value
Filter Inductance	L_f	0.77 mH
Filter Capacitance	C_f	50 μF
Switching Frequency	f_sw	10 kHz

2. Enhanced Droop Control with Adaptive Virtual Impedance

The conventional droop control is improved by introducing adaptive virtual impedance to mitigate line impedance mismatch:

$$ \begin{cases}
f_i = f_{\text{ref}} – mP_i \\
E_i = E_{\text{ref}} – nQ_i – Z_{\text{vir},i}I_{o,i}
\end{cases} $$

Where the adaptive virtual impedance is calculated as:

$$ Z_{\text{vir},i} = \frac{X_{\text{line},j}Q_{\text{ref},j} – X_{\text{line},i}Q_{\text{ref},i}}}{Q_j} $$

3. SOC Coordination Strategy

An exponential SOC balancing algorithm is proposed for energy storage inverters with different capacities:

$$ f_i = f_{\text{ref}} – \frac{mP_i}{C_i} \exp[-\alpha(\text{SOC}_i – \overline{\text{SOC}})] $$

The stability analysis through small-signal modeling reveals:

$$ \Delta \dot{\text{SOC}}_i = -\frac{m\alpha}{C_i^2U_{\text{bat}}} \Delta P_i $$

Control Parameters for SOC Coordination
Parameter	Range	Optimal Value
Droop Coefficient (m)	0.1-1.0 mHz/W	0.5 mHz/W
Coordination Factor (α)	10-50	30
Virtual Impedance Ratio	0.5-2.0 p.u.	1.2 p.u.

4. Multi-Agent Consensus Implementation

A distributed consensus algorithm enables SOC information sharing without central controller:

$$ \text{SOC}_{\text{ave}}^{(k+1)} = \frac{1}{N} \sum_{j\in\mathcal{N}_i} a_{ij}\text{SOC}_j^{(k)} $$

Where the adjacency weights are determined by:

$$ a_{ij} = \frac{1}{n_i + n_j + 1} $$

5. Performance Validation

The proposed strategy demonstrates superior performance in:

Reactive power sharing error reduction (≤3%)
Frequency deviation limitation (±0.15Hz)
SOC convergence time acceleration (2.8s for 90% balance)

$$ \varepsilon_{\text{SOC}} = \frac{\text{max}|\text{SOC}_i – \overline{\text{SOC}}|}{\overline{\text{SOC}}} \times 100\% < 5\% $$

The energy storage inverter coordination scheme effectively addresses the challenges of distributed energy management in modern microgrids, demonstrating remarkable adaptability to various operating conditions and system configurations.