DC Bus Voltage Stabilization and SOC Management Using Optimal Tuning of Controllers for Supercapacitor Based PV Hybrid Energy Storage System
Abstract
:1. Introduction
- A novel TI control scheme is proposed for the DC bus voltage stabilization of the battery and supercapacitor-based HESS.
- Its performance was compared with that of integer-order PI and fractional-order PI controllers to demonstrate the feasibility of the proposed TI controller.
- To present the robustness of the proposed controller by subjecting it to varying input (irradiance and temperature) and load conditions.
- To estimate the amount of SOC consumed in the battery under varying temperature conditions and determine the effectiveness of the controller performance in reducing stress on the battery.
2. Modeling and System Configuration
- A PV panel is the main source of energy.
- A battery is used in the case of a surplus/deficiency of energy harvesting from the PV system.
- A supercapacitor limits the PV/load variation and assists the battery in the case of sudden fluctuations.
3. Proposed Control Scheme for PV Power System
3.1. PI Controller
3.2. FOPI Controller
3.3. TI Controller
3.4. Control Strategy to Stabilize the DC Bus Voltage
3.5. PMS and Control Scheme
3.6. Optimization Based Controller Tuning
4. Results and Discussion
4.1. Dynamic Performance Evaluation of the Controllers
4.2. Robustness Analysis of the Proposed Controller
4.2.1. Analysis with Varying Solar Irradiance and Load
4.2.2. Analysis with Varying Temperature and Estimating the SOC Consumption
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Configuration | Topology | Features | Drawback |
---|---|---|---|
Basic passive parallel Hybrid configuration | Supercapacitor and battery are directly connected with load. Hence it is easy to implement with good reliability | Power sharing between battery and supercapacitor is uncontrolled. Hence the DC bus voltage is not regulated | |
Supercapacitor/battery parallel configuration | Supercapacitor energy is used more efficiently to maintain constant DC bus voltage that changes w.r.t SOC of battery | DC Bus voltage regulation is difficult to obtain and there are chances of load imbalance | |
Battery/supercapacitor parallel configuration | Battery voltage can be higher and lower than the supercapacitor voltage. It costs less with a reduction in complexity due to a single converter used. | Improper DC bus voltage regulation due to the supercapacitor variable voltage | |
Multiple converter | Most efficient configuration is a separate converter for the battery and a supercapacitor is used, which provides the easy control of power | High cost due to complex circuitry and a large number of components |
Devices/Components | Parameters | Value |
---|---|---|
PV module | Maximum power | 120.7 W |
Short circuit current | 8 A | |
Open circuit voltage | 21 V | |
PV array sizing | 2 series and 4 parallel strings | |
Battery | Nominal voltage | 24 V |
Rated capacity | 14 Ah | |
Initial SOC | 50% | |
Supercapacitor | Rated capacitance | 29 F |
Rated voltage | 32 V | |
Initial voltage | 32 V | |
No. of series and parallel capacitors | 1.1 | |
DC bus parameters | DC link capacitance | 300 μF |
Power load | 500 W | |
DC bus voltage | 50 V |
Controller | Kp | KI | N | λ | ITAE |
---|---|---|---|---|---|
PI | 1.424 ± 0.3424 | 3037.9 ± 0.255 | - | - | 0.4881 ± 0.00649 |
FOPI | 1.913 ± 0.098 | 50.908 ± 0.227 | - | 0.504 ± 0.0314 | 0.4203 ± 0.00239 |
TI | 1.015 ± 0.173 | 1039.55 ± 0.358 | 2.558 ± 0.3155 | - | 0.3839 ± 0.00161 |
Controller | Risetime | Undershoot (%) | Settling Time (ms) | Slew Rate |
---|---|---|---|---|
PI | 9.410 ns | 1.340 | 9.149 | 4.229 |
FOPI | 228.427 µs | 1.999 | 5.691 | 173.759 |
TI | 41.071 ps | 0.563 | 5.013 | 966.580 |
Case Study | Temp | Consumption of SOC | % Consumption of SOC in 1 h |
---|---|---|---|
PI | 40 °C | 0.0164 | 29.52 |
25 °C | 0.0146 | 26.28 | |
10 °C | 0.0130 | 22.40 | |
0 °C | 0.0122 | 21.96 | |
−12 °C | 0.0118 | 21.24 | |
FOPI | 40 °C | 0.0158 | 28.44 |
25 °C | 0.0131 | 23.58 | |
10 °C | 0.0130 | 23.4 | |
0 °C | 0.0092 | 16.56 | |
−12 °C | 0.009 | 16.38 | |
TI | 40 °C | 0.0149 | 26.82 |
25 °C | 0.0120 | 21.60 | |
10 °C | 0.0109 | 19.76 | |
0 °C | 0.0091 | 16.38 | |
−12 °C | 0.0088 | 15.84 |
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Pattnaik, S.; Kumar, M.R.; Mishra, S.K.; Gautam, S.P.; Appasani, B.; Ustun, T.S. DC Bus Voltage Stabilization and SOC Management Using Optimal Tuning of Controllers for Supercapacitor Based PV Hybrid Energy Storage System. Batteries 2022, 8, 186. https://doi.org/10.3390/batteries8100186
Pattnaik S, Kumar MR, Mishra SK, Gautam SP, Appasani B, Ustun TS. DC Bus Voltage Stabilization and SOC Management Using Optimal Tuning of Controllers for Supercapacitor Based PV Hybrid Energy Storage System. Batteries. 2022; 8(10):186. https://doi.org/10.3390/batteries8100186
Chicago/Turabian StylePattnaik, Saswati, Mano Ranjan Kumar, Sunil Kumar Mishra, Shivam Prakash Gautam, Bhargav Appasani, and Taha Selim Ustun. 2022. "DC Bus Voltage Stabilization and SOC Management Using Optimal Tuning of Controllers for Supercapacitor Based PV Hybrid Energy Storage System" Batteries 8, no. 10: 186. https://doi.org/10.3390/batteries8100186
APA StylePattnaik, S., Kumar, M. R., Mishra, S. K., Gautam, S. P., Appasani, B., & Ustun, T. S. (2022). DC Bus Voltage Stabilization and SOC Management Using Optimal Tuning of Controllers for Supercapacitor Based PV Hybrid Energy Storage System. Batteries, 8(10), 186. https://doi.org/10.3390/batteries8100186