Energy Management of a Fuel Cell Electric Robot Based on Hydrogen Value and Battery Overcharge Control
Abstract
:1. Introduction
2. Literature Review
- A novel state machine function has been established for a fuel cell electric robot that is equipped with a battery, enabling it to discern various states of the robot’s maneuver.
- The reduction in power fluctuations in the fuel cell output has been successfully implemented through the proposed strategy.
- Novel mathematical equations have been developed to express the relationship between the battery formulation and the battery SOC. These equations are derived through statistical analysis, in contrast to previous studies that relied on experimental methods.
- Novel mathematical equations have been suggested to calculate the equivalent hydrogen consumption fuel value (EHCFV) as part of the implementation of the equivalent fuel consumption minimization strategy.
- This project introduces a novel concept called battery overcharge control (BOCC) to effectively prevent the unnecessary and excessive charging of batteries.
3. Materials and Methods
3.1. Fuel Cell Modeling
3.2. Modeling of Non-Isolated Step-Up Converter
3.3. Battery Modeling
4. The Proposed Energy Management Strategy
4.1. Robot Maneuver State Identification Strategy
- Stationary state: OSR = 0;
- Acceleration state: OSR = 3;
- Traction state: OSR = 2;
- Deceleration mode: OSR = 1;
- Regenerative braking state: OSR = −1.
4.2. Battery SOC Zone Classification Based on the Proposed Function
4.3. Formulating Hydrogen Fuel Valuation
4.4. Fuel Cell Operational Modes
4.5. The Proposed Operational Mode Control Strategy
- (1)
- The primary consideration when selecting an operational mode (i) is to obtain the optimal efficiency of the fuel cell with the lowest HCJEH2.
- (2)
- When the FC produces more power than the robot’s demanded power (Pdemand), the excess power charges the LFP battery. This is only allowed if the equivalent hydrogen consumption rate (HCJEH2) for the proposed mode is lower than the hydrogen consumption rate in the next battery operational mode, defined in Equation (27).
- (3)
- Producing an FC power less than the demanded power (Pdemand) results in the discharge of the LFP battery. This discharge is permitted only when the combined value of the equivalent total hydrogen consumption (HCJEbat + HCJEH2) for the proposed mode is lower than the hydrogen rate. The consumption in the subsequent mode of the fuel cell is determined by Equation (28).
- (4)
- Figure 12 calculates the recommended performance modes for different OSR modes and multiple demanded power state scenarios based on the given conditions. Figure 12 identifies 100 distinct scenarios for determining the proposed operational modes. Among the 20 available scenarios, the FC must operate on maximum power to be able to supply the demanded power. In two distinct scenarios, specifically those involving a high battery charge during the stationary state and traction state movement, the fuel cell is deactivated to minimize fuel consumption. Out of the remaining 78 scenarios, it is noted that the fuel cell operates at maximum overall efficiency with the lowest equivalent hydrogen consumption rate (PFC mode = 0.4 pu) in 46 scenarios, which accounts for 59% of the remaining scenarios. The fuel cell electric robot’s battery is charged in 7 different scenarios, and in each of these scenarios, the condition of Equation (27) is met. Additionally, the equivalent hydrogen consumption value is more optimal than the hydrogen consumption value of the subsequent mode. In the remaining 25 scenarios, the fuel cell electric robot’s battery is discharged. In each of these scenarios, the condition of Equation (28) is met and the equivalent hydrogen consumption value is more efficient than the hydrogen consumption value of the subsequent mode.
4.6. Battery Overcharge Control Strategy
5. Simulation Results
Comparison of the Simulation Results
- The method in [3] for the output power of PEMFC has been consistently utilized at various points, whereas the current research’s proposed strategy exhibits fewer generation fluctuations and is only active at specific points.
- The proposed method achieves an SOC difference of 0.4% (ΔSOC = 0.4%) at the end of the robot maneuver, while the method [3] yields an SOC difference of 4.02% (ΔSOC = 4.02%).
- The hydrogen consumption for the power curve of the first study plan in Reference [3] is precisely 0.484 g. The proposed strategy involves the consumption of 0.214 g of hydrogen.
6. Conclusions
- (1)
- The OMC strategy has determined the operating conditions for the LFP battery to optimize its use. These conditions aim to minimize fluctuations in the output power of the PEMFC. Additionally, the strategy allows the battery to absorb energy from regenerative braking and deliver high power density when required.
- (2)
- In this research, a new formulation (HCJEH2) has been presented to solve the challenge of successive changes in the output power of the fuel cell (which leads to a decrease in the performance quality and lifespan of the fuel cell), which, after calculating the value of fuel consumption per joule of energy, the mathematical expectation and its standard deviation have been used to select the optimum points of fuel cell performance in order to reduce the successive fluctuations of the PEMFC generation power and to improve the performance of the ECMS and the operational mode control strategy.
- (3)
- Fuel cell operation at its global optimal point is a highly appealing operational concept in online energy management methods. However, maintaining the stability of the robot’s activity is challenging due to its high level of mobility. In this study, precise monitoring of the conditions (OSR) and the differentiation of operating points for PEMFC, along with the OMC strategy, have been implemented. The objective is to track the global optimum point, which is achieved in more than 59% of cases (as shown in Figure 12), and to utilize a fuel cell operating at the point of maximum efficiency.
- (4)
- Presently, the issue of battery overcharging/discharging poses a significant obstacle in all online energy management strategies. This study introduces a novel approach called battery overcharge control (BOCC) that effectively regulates the change in the state of charge (ΔSOC) of the battery within an optimal range, ensuring a positive (ΔSOC > 0) and preventing the overcharging/discharging of the battery. The implementation of the new function, known as BOCC, has successfully achieved a decrease in hydrogen fuel consumption by effectively preventing the battery from undergoing unnecessary charging and discharging. Occasionally, the output results from previous references have shown a negative range of ΔSOC (ΔSOC < 0), indicating inadequate long-term management and complete discharge of the battery over time.
- (5)
- The results obtained suggest that, primarily, the PEMFC fuel cell consistently operated at its highest level of efficiency, without any fluctuations in power output, in the majority of cases. Additionally, the variation in the state of charge (ΔSOC) of the battery was found to be less than 0.4% across various research protocols. The aforementioned findings demonstrate the superiority of the proposed approach in enhancing energy efficiency, diminishing fuel usage, and prolonging the lifespan of hybrid power sources, such as batteries and fuel cells.
- (6)
- The simulation results of the comparison between the proposed strategy and other approaches demonstrate a decrease in hydrogen consumption and the prevention of battery overcharging.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Abbreviations
BCE | Battery combined efficiency |
BOCC | Battery overcharge control |
EHCFV | Equivalent hydrogen consumption fuel value |
ECM | Equivalent consumption minimization |
ECMS | Equivalent consumption minimization strategy |
EMS | Energy management strategy |
FC | Fuel cell |
LFP | LiFePO4 battery |
OMCS | Operational mode control strategy |
OSR | The operational state of the robot |
PEMFC | Proton exchange membrane fuel cell |
Probability density function | |
SBCE | Square of battery combined efficiency |
SMC | State machine control |
SMCS | State machine control strategy |
SOC | State of charge |
UAV | Unmanned aerial vehicle |
pu | Per unit |
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Items | Value | Unit |
---|---|---|
Rated Power | 500 | W |
Rated Voltage | 14.4 | V |
Rated Current | 35 | A |
Cells Number | 24 | - |
Stack Max Temperature | 65 | °C |
Hydrogen Gas Pressure | 0.45–0.55 | bar |
Items | Value | Unit |
---|---|---|
Rated Power | 5.76 | W |
Rated Voltage | 3.2 | V |
Rated Capacity | 1.8 | Ah |
Series Cells Number | 8 | - |
Parallel Cells Number | 3 | - |
EMS Strategies | Hybrid Rule Strategy via AMPSO [3] | Proposed Strategy |
---|---|---|
Hydrogen Consumption | 0.484 g | 0.214 g |
Initial SOC | 70% | 70% |
Final SOC | 74.2% | 70.4% |
Δ SOC | +4.2% | +0.4% |
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Share and Cite
Radmanesh, H.; Farhadi Gharibeh, H. Energy Management of a Fuel Cell Electric Robot Based on Hydrogen Value and Battery Overcharge Control. World Electr. Veh. J. 2024, 15, 352. https://doi.org/10.3390/wevj15080352
Radmanesh H, Farhadi Gharibeh H. Energy Management of a Fuel Cell Electric Robot Based on Hydrogen Value and Battery Overcharge Control. World Electric Vehicle Journal. 2024; 15(8):352. https://doi.org/10.3390/wevj15080352
Chicago/Turabian StyleRadmanesh, Hamid, and Hamed Farhadi Gharibeh. 2024. "Energy Management of a Fuel Cell Electric Robot Based on Hydrogen Value and Battery Overcharge Control" World Electric Vehicle Journal 15, no. 8: 352. https://doi.org/10.3390/wevj15080352
APA StyleRadmanesh, H., & Farhadi Gharibeh, H. (2024). Energy Management of a Fuel Cell Electric Robot Based on Hydrogen Value and Battery Overcharge Control. World Electric Vehicle Journal, 15(8), 352. https://doi.org/10.3390/wevj15080352