Robust Secondary Controller for Islanded Microgrids with Unexpected Electrical Partitions under Fault Conditions
Abstract
:1. Introduction
1.1. Review of Sophisticated Secondary Controllers
1.2. Contribution of the Paper
- ✓
- Easy implementation to real microgrids. The controller is designed using straightforward digital equations, as detailed in Section 3, making it compatible with widely used commercial digital signal processors (DSPs). This compatibility ensures that the proposed control algorithm can be easily adapted and utilized within microgrid central controllers (MGCCs) in centralized infrastructure. Moreover, the simplicity of its design facilitates quick deployment and integration, minimizing potential disruptions and the need for extensive training or system modifications.
- ✓
- Low communication requirements. The proposed controller does not require any communication with the protective devices of the MG, thus reducing the complexity of the overall installation. The only communication infrastructure required is between the MGCC and the DGs of the microgrid.
- ✓
- Topology-independent implementation. The controller is designed to deliver consistent performance without the need for recalibration following network reconfigurations or load changes. It is initially set up based on the number of DGs and maintains its calibration permanently. This one-time setup ensures that the controller can seamlessly adapt to varying operational conditions without additional intervention, simplifying the management of the system.
2. Review of Traditional Secondary Controllers
3. Proposed Centralized Secondary Controller
4. Simulation Results
4.1. Low-Voltage 6-Bus Network
- ▪
- Test 1: Load 2 is doubled at t = 20 s and returned to its initial value at t = 60 s, with no microgrid (MG) partition occurring.
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Resistance of the lines | 0.25 Ω/km |
Self-reactance of the lines | 0.6 mH/km [2] |
Mutual-reactance of the lines | 0.1 mH/km [2] |
Line lengths | 0.1 km [2] |
Lines’ thermal limits | Neglected [2] |
Loads (modeled as constant impedances) | Load 1: R//L = 0.1 Ω//0.001 H Load 2: R//L = 0.2 Ω//0.002 H |
(i = 1, 3) | 1 × 10−6 (Hz/W) |
(i = 2) | 0.5 × 10−6 (Hz/W) |
(i = 1, 2, 3) | 2 × 10−4 (V/VAR) |
Primary droop (i = 1, 2, 3) | 270 V |
Primary droop (i = 1, 2, 3) | 50 Hz |
Ground resistances | 25 Ω [2] |
4.2. Medium-Voltage 13-nus Network
Resistance of the lines | 0.25 Ω /km |
Self-reactance of the lines | 1 mH/km |
Mutual-reactance of the lines | 0.1 mH/km |
Line lengths | 10 km |
Lines’ thermal limits | Neglected |
Loads (modeled as constant impedances) | R//L = 20 Ω//0.25 H |
(i = 1, 2, 3, 4, 5) | 5 × 10−7 (Hz/W) |
(i = 1, 2, 3, 4, 5) | 2 × 10−5 (V/VAR) |
(i = 1, 2, 3, 4, 5) | 7600 V |
(i = 1, 2, 3, 4, 5) | 50 Hz |
Ground resistances | 25 Ω |
5. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Nomenclature
Angular frequency of DG i | |
Reference frequency of DG i | |
Frequency droop gain of DG i | |
Active power of DG i | |
Secondary control signal of the frequency control for DG i | |
Positive-sequency voltage of DG i | |
Reference voltage of DG i | |
Voltage droop gain of DG i | |
Reactive power of DG i | |
Secondary control signal of the voltage control for DG i | |
Proportional gain of secondary frequency controller | |
Integral gain of secondary frequency controller | |
Proportional gain of secondary voltage controller | |
Integral gain of secondary voltage controller | |
Angular frequency measured by the microgrid central controller (MGCC) | |
Voltage measured by the MGCC | |
Desirable angular frequency, i.e., 2⋅π⋅50 rads/sec | |
Desirable voltage, i.e., 230 V | |
Secondary control signal of the proposed method, for DG i, at time instant t | |
Angular frequency of DG i at time instant t |
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Reference | Year | Advances in Secondary Control |
---|---|---|
[7] | 2017 | Treats disturbances and noises in the communication links between the DGs |
[8] | 2016 | Improves the performance under conditions of communication delays |
[9] | 2021 | Improves the performance during a fault in an electric network |
[10] | 2020 | Treats actuation/propulsion faults and disturbances |
[11] | 2017 | Minimization of active power and reactive power oscillations |
[12] | 2020 | Treats failures of central and master controllers in interconnected microgrids |
[13] | 2019 | Reduces the transient voltages during MG reconfiguration |
[14] | 2021 | Reduces the transient voltages during MG reconfiguration |
[15] | 2023 | Reduces the transient voltages during MG reconfiguration |
[16] | 2020 | Treats FDI cyber-attacks on the communication links and controllers |
[17] | 2020 | Treats DoS cyber-attacks on the communication links and controllers |
[18] | 2020 | Treats DoS cyber-attacks on the communication links and controllers |
[19] | 2023 | Treats FDI and DoS cyber-attacks on the communication links and controllers |
[20] | 2019 | Studies the consequences of unexpected electrical and communication MG partitions |
[21] | 2020 | Studies the consequences of unexpected electrical and communication MG partitions |
[22] | 2020 | Improves the performance under unexpected communication MG partitions |
Proposed | 2024 | Improves the performance under unexpected electrical MG partitions |
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Pompodakis, E.E.; Orfanoudakis, G.I.; Yiannis, K.; Karapidakis, E.S. Robust Secondary Controller for Islanded Microgrids with Unexpected Electrical Partitions under Fault Conditions. Energies 2024, 17, 3727. https://doi.org/10.3390/en17153727
Pompodakis EE, Orfanoudakis GI, Yiannis K, Karapidakis ES. Robust Secondary Controller for Islanded Microgrids with Unexpected Electrical Partitions under Fault Conditions. Energies. 2024; 17(15):3727. https://doi.org/10.3390/en17153727
Chicago/Turabian StylePompodakis, Evangelos E., Georgios I. Orfanoudakis, Katsigiannis Yiannis, and Emmanuel S. Karapidakis. 2024. "Robust Secondary Controller for Islanded Microgrids with Unexpected Electrical Partitions under Fault Conditions" Energies 17, no. 15: 3727. https://doi.org/10.3390/en17153727
APA StylePompodakis, E. E., Orfanoudakis, G. I., Yiannis, K., & Karapidakis, E. S. (2024). Robust Secondary Controller for Islanded Microgrids with Unexpected Electrical Partitions under Fault Conditions. Energies, 17(15), 3727. https://doi.org/10.3390/en17153727