Control of High-Energy High-Power Densities Storage Devices by Li-ion Battery and Supercapacitor for Fuel Cell/Photovoltaic Hybrid Power Plant for Autonomous System Applications

Sikkabut, S.; Mungporn, Pongsiri; Ekkaravarodome, Chainarin; Bizon, Nicu; Tricoli, Pietro; Nahid‐Mobarakeh, Babak; Pierfederici, Serge; Davat, Bernard; Thounthong, Phatiphat

doi:10.1109/tia.2016.2581138

Cited by 107 publications

(37 citation statements)

References 40 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Control for high power PV + a fuel cell plant with hybrid energy storage consisting of a battery and the supercapacitor is presented in [17]. Each energy source and energy storing element are connected to a common DC link through independent converters in this configuration.…”

Section: Power Balancing Control Of the Grid Energy Storage System Inmentioning

confidence: 99%

Power Balancing Control for Grid Energy Storage System in Photovoltaic Applications—Real Time Digital Simulation Implementation

et al. 2017

View full text Add to dashboard Cite

A grid energy storage system for photo voltaic (PV) applications contains three different power sources i.e., PV array, battery storage system and the grid. It is advisable to isolate these three different sources to ensure the equipment safety. The configuration proposed in this paper provides complete isolation between the three sources. A Power Balancing Control (PBC) method for this configuration is proposed to operate the system in three different modes of operation. Control of a dual active bridge (DAB)-based battery charger which provides a galvanic isolation between batteries and other sources is explained briefly. Various modes of operation of a grid energy storage system are also presented in this paper. Hardware-In-the-Loop (HIL) simulation is carried out to check the performance of the system and the PBC algorithm. A power circuit (comprised of the inverter, dual active bridge based battery charger, grid, PV cell, batteries, contactors, and switches) is simulated and the controller hardware and user interface panel are connected as HIL with the simulated power circuit through Real Time Digital Simulator (RTDS). HIL simulation results are presented to explain the control operation, steady-state performance in different modes of operation and the dynamic response of the system.

show abstract

Section: Power Balancing Control Of the Grid Energy Storage System Inmentioning

confidence: 99%

Power Balancing Control for Grid Energy Storage System in Photovoltaic Applications—Real Time Digital Simulation Implementation

et al. 2017

View full text Add to dashboard Cite

show abstract

“…Control for high power PV + Fuel cell plant with hybrid energy storage consists of a battery and the super-capacitor is presented in [12]. Each energy source and energy storing element are connected to common DC link through independent converters in this configuration.…”

Section: Power Balancing Control Of Grid Energy Storage System In Pv mentioning

confidence: 99%

“…The systems presented in [11], [12] and [13] are for Off-Grid Applications hence the control during Mode-3 of operation is not covered. System configurations presented in above works require independent converters for each source which may increase the cost of the system and also may increase the complexity of control algorithm.…”

Section: Power Balancing Control Of Grid Energy Storage System In Pv mentioning

confidence: 99%

Power Balancing Control for Grid Energy Storage System in PV Applications—Real Time Digital Simulation Implementation

Sridhar¹,

Padmanaban²,

Subramaniam³

et al. 2017

Preprint

View full text Add to dashboard Cite

Grid energy storage system for PV Applications is connected with three different power sources i.e. PV Array, Battery and the Grid. It is advisable to have Isolation between these three different sources to provide safety for the equipment. The configuration proposed in this paper provides the complete isolation between the three sources. A Power Balancing Control (PBC) for this configuration is proposed to operate the system in three different modes of operation. Control of a dual active bridge (DAB) based battery charger which provides a galvanic isolation between batteries and other sources is explained briefly. Various modes of operation of a Grid energy storage system are also presented in this paper. Hardware-In-Loop (HIL) Simulation is carried out to check the performance of the system and the PBC algorithm. Power circuit (comprises of inverter, dual active bridge based battery charger, grid, PV cell, batteries, contactors and switches) is simulated and the controller hardware and user interface panel are connected as HIL with the simulated power circuit through Real Time Digital Simulator (RTDS). HIL simulation results are presented to explain the control operation, steady state performance in different modes of operation and the dynamic response of the system.

show abstract

“…Sikkabut et al [19] presented a small-scale experimental prototype of a DC-MG with a 60 V bus that uses a photovoltaic array of 800 W, a battery bank of between 11.6 Ah and 24 V, and a 100 F supercapacitor bank. This prototype uses a management system implemented in the card dSPACE DS1104 platform, which includes an FCS to stabilize the DC bus.…”

Section: Introductionmentioning

confidence: 99%

Development and Application of a Fuzzy Control System for a Lead-Acid Battery Bank Connected to a DC Microgrid

Martínez

Padilla-Medina

Cano-Andrade

et al. 2018

International Journal of Photoenergy

View full text Add to dashboard Cite

This study presents the development and application of a fuzzy control system (FCS) for the control of the charge and discharge process for a bank of batteries connected to a DC microgrid (DC-MG). The DC-MG runs on a maximum power of 1 kW with a 190 V DC bus using two photovoltaic systems of 0.6 kW each, a 1 kW bidirectional DC-AC converter to interconnect the DC-MG with the grid, a bank of 115 Ah to 120 V lead-acid batteries, and a general management system used to define the operating status of the FCS. This FCS uses a multiplexed fuzzy controller, normalizing the controller's inputs and outputs in each operating status. The design of the fuzzy controller is based on a Mamdani inference system with AND-type fuzzy rules. The input and output variables have two trapezoidal membership functions and three triangular membership functions. LabVIEW and the NI myRIO-1900 embedded design device were used to implement the FCS. Results show the stability of the DC bus of the microgrid when the bank of batteries is in the charging and discharging process, with the bus stabilized in a range of 190 V ± 5%, thus demonstrating short response times to perturbations considering the microgrid's response dynamics.

show abstract

Control of High-Energy High-Power Densities Storage Devices by Li-ion Battery and Supercapacitor for Fuel Cell/Photovoltaic Hybrid Power Plant for Autonomous System Applications

Cited by 107 publications

References 40 publications

Power Balancing Control for Grid Energy Storage System in Photovoltaic Applications—Real Time Digital Simulation Implementation

Power Balancing Control for Grid Energy Storage System in Photovoltaic Applications—Real Time Digital Simulation Implementation

Power Balancing Control for Grid Energy Storage System in PV Applications—Real Time Digital Simulation Implementation

Development and Application of a Fuzzy Control System for a Lead-Acid Battery Bank Connected to a DC Microgrid

Contact Info

Product

Resources

About

Control of High-Energy High-Power Densities Storage Devices by Li-ion Battery and Supercapacitor for Fuel Cell/Photovoltaic Hybrid Power Plant for Autonomous System Applications

Cited by 107 publications

References 40 publications

Power Balancing Control for Grid Energy Storage System in Photovoltaic Applications—Real Time Digital Simulation Implementation

Power Balancing Control for Grid Energy Storage System in Photovoltaic Applications—Real Time Digital Simulation Implementation

Power Balancing Control for Grid Energy Storage System in PV Applications&mdash;Real Time Digital Simulation Implementation

Development and Application of a Fuzzy Control System for a Lead-Acid Battery Bank Connected to a DC Microgrid

Contact Info

Product

Resources

About

Power Balancing Control for Grid Energy Storage System in PV Applications—Real Time Digital Simulation Implementation