A Novel Frequency Control Scheme for Autonomous Microgrid using Cooperative Application of Supercapacitor-Battery HESS, Photovoltaics, LED lighting loads and TCLs

Abstract Background Automatic generation control (AGC) of multi-area interconnected power system (IPS) is often designed with negligible cross-coupling between the load frequency control (LFC) and automatic voltage regulation (AVR) loops. This is because the AVR loop is considerably faster than that of LFC. However, with the introduction of slow optimal control action on the AVR, positive damping effect can be achieved on the LFC loop thereby improving the frequency control. In this paper, LFC synchronized with AVR in three-area IPS is proposed. Model predictive controller (MPC) configured in a dense distributed pattern, due to its online set-point tacking is used as the supplementary controller. The dynamics of the IPS subjected to multi-area step and random load disturbances are studied. The efficacy of the developed scheme is ascertained by simulating the disturbed system in MATLAB/Simulink. Results Based on the comparative analysis on the system responses, it is established that by cross-coupling the LFC loop with AVR, reductions of 66.45% and 59.09% in the frequency and tie-line power maximum deviations respectively are observed, while the respective settling times are found to be reduced by 29.68% and 22.77% when compared with the uncoordinated control scheme. In addition, the standard deviation and variance of the integral time absolute error of the system’s responses have reduced by 23.21% and 20.83% respectively compared to those obtained in a similar study. Conclusions The reduction in the maximum deviations and settling times in the system states indicates that introducing the voltage control via AVR loop has improved the frequency control significantly. While the lower standard deviation and variance of the integral time absolute error signify improvement in the robustness of the developed algorithm. However, this improvement is at the detriment of the controller size and computational complexity. In the uncoordinated control scheme, the control vector is one-dimensional, while in the coordinated scheme, the control vector is two-dimensional for each CA.

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Coordination of hybrid energy storage system, photovoltaic systems, smart lighting loads, and thermostatically controlled loads for microgrid frequency control

International Transactions on Electrical Energy Systems ◽

10.1002/2050-7038.12976 ◽

2021 ◽

Author(s):

Mehrdad Bagheri‐Sanjareh ◽

Mohammad Hassan Nazari ◽

Seyed Hossein Hosseinian

Keyword(s):

Energy Storage ◽

Frequency Control ◽

Storage System ◽

Energy Storage System ◽

Hybrid Energy ◽

Smart Lighting ◽

Hybrid Energy Storage ◽

Hybrid Energy Storage System ◽

Thermostatically Controlled Loads ◽

Lighting Loads

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5G Poor and Rich Novel Control Scheme Based Load Frequency Regulation of a Two-Area System with 100% Renewables in Africa

Fractal and Fractional ◽

10.3390/fractalfract5010002 ◽

2020 ◽

Vol 5 (1) ◽

pp. 2

Author(s):

Hady H. Fayek

Keyword(s):

Power System ◽

Fractional Order ◽

Packet Loss ◽

Pid Controller ◽

Frequency Control ◽

Operating Conditions ◽

Load Frequency Control ◽

Load Frequency ◽

Control Scheme ◽

Non Linear

Remote farms in Africa are cultivated lands planned for 100% sustainable energy and organic agriculture in the future. This paper presents the load frequency control of a two-area power system feeding those farms. The power system is supplied by renewable technologies and storage facilities only which are photovoltaics, biogas, biodiesel, solar thermal, battery storage and flywheel storage systems. Each of those facilities has 150-kW capacity. This paper presents a model for each renewable energy technology and energy storage facility. The frequency is controlled by using a novel non-linear fractional order proportional integral derivative control scheme (NFOPID). The novel scheme is compared to a non-linear PID controller (NPID), fractional order PID controller (FOPID), and conventional PID. The effect of the different degradation factors related to the communication infrastructure, such as the time delay and packet loss, are modeled and simulated to assess the controlled system performance. A new cost function is presented in this research. The four controllers are tuned by novel poor and rich optimization (PRO) algorithm at different operating conditions. PRO controller design is compared to other state of the art techniques in this paper. The results show that the PRO design for a novel NFOPID controller has a promising future in load frequency control considering communication delays and packet loss. The simulation and optimization are applied on MATLAB/SIMULINK 2017a environment.

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Real Time Monitoring of LED Lighting Loads - A study assessing Power Quality

2020 International Conference on Emerging Trends in Information Technology and Engineering (ic-ETITE) ◽

10.1109/ic-etite47903.2020.280 ◽

2020 ◽

Author(s):

Sangeeta L. Mahaddalkar ◽

Vinayak N. Shet

Keyword(s):

Real Time ◽

Power Quality ◽

Real Time Monitoring ◽

Led Lighting ◽

Lighting Loads

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Frequency control scheme with dynamic droop characteristics of a DFIG for mitigating the frequency fluctuations

International Transactions on Electrical Energy Systems ◽

10.1002/2050-7038.13044 ◽

2021 ◽

Author(s):

Dejian Yang ◽

Taiying Zheng ◽

Enshu Jin ◽

Xingsong Zhang ◽

Liang Hua

Keyword(s):

Frequency Control ◽

Control Scheme ◽

Frequency Fluctuations

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Adaptive SRF-PLL Based Voltage and Frequency Control of Hybrid Standalone WECS with PMSG-BESS

International Journal of Emerging Electric Power Systems ◽

10.1515/ijeeps-2018-0072 ◽

2018 ◽

Vol 19 (6) ◽

Cited By ~ 1

Author(s):

Anjana Jain ◽

R. Saravanakumar ◽

S. Shankar ◽

V. Vanitha

Keyword(s):

Reactive Power ◽

Frequency Control ◽

Storage System ◽

Synchronous Generator ◽

Energy Storage System ◽

Voltage Regulation ◽

Operating Conditions ◽

Voltage Source ◽

Voltage Source Converter ◽

Control Scheme

Abstract The variable-speed Permanent Magnet Synchronous Generator (PMSG) based Wind Energy Conversion System (WECS) attracts the maximum power from wind, but voltage-regulation and frequency-control of the system in standalone operation is a challenging task A modern-control-based-tracking of power from wind for its best utilization is proposed in this paper for standalone PMSG based hybrid-WECS comprising Battery Energy Storage System (BESS). An Adaptive Synchronous Reference Frame Phase-Locked-Loop (SRF-PLL) based control scheme for load side bi-directional voltage source converter (VSC) is presented for the system. MATLAB/Simulink model is developed for simulation study for the proposed system and the effectiveness of the controller for bi-directional-converter is discussed under different operating conditions: like variable wind-velocity, sudden load variation, and load unbalancing. Converter control scheme enhances the power smoothening, supply-load power-matching. Also it is able to regulate the active & reactive power from PMSG-BESS hybrid system with control of fluctuations in voltage & frequency with respect to varying operating conditions. Proposed controller successfully offers reactive-power-compensation, harmonics-reduction, and power-balancing. The proposed scheme is based on proportional & integral (PI) controller. Also system is experimentally validated in the laboratory-environment and results are presented here.

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Coordinated Frequency Control Strategy with the Virtual Battery Model of Inverter Air Conditionings

Applied Sciences ◽

10.3390/app9153052 ◽

2019 ◽

Vol 9 (15) ◽

pp. 3052

Author(s):

Jiafu Yin ◽

Dongmei Zhao

Keyword(s):

Control Strategy ◽

Frequency Control ◽

Hierarchical Control ◽

Frequency Regulation ◽

Consensus Protocol ◽

Consensus Control ◽

Response Characteristics ◽

Battery Model ◽

Control Framework ◽

Control Scheme

Due to the potential of thermal storage being similar to that of the conventional battery, air conditioning (AC) has gained great popularity for its potential to provide ancillary services and emergency reserves. In order to integrate numerous inverter ACs into secondary frequency control, a hierarchical distributed control framework which incorporates a virtual battery model of inverter AC is developed. A comprehensive derivation of a second-order virtual battery model has been strictly posed to formulate the frequency response characteristics of inverter AC. In the hierarchical control scheme, a modified control performance index is utilized to evaluate the available capacity of traditional regulation generators. A coordinated frequency control strategy is derived to exploit the complementary and advantageous characteristics of regulation generators and aggregated AC. A distributed consensus control strategy is developed to guarantee the fair participation of heterogeneous AC in frequency regulation. The finite-time consensus protocol is introduced to ensure the fast convergence of power tracking and the state-of-charge (SOC) consistency of numerous ACs. The effectiveness of the proposed control strategy is validated by a variety of illustrative examples.

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