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Analysis and Modeling of Electrical Power Systems for Hybrid Maritime Vessels


핵심 개념
This paper presents adaptable electrical power system models for hybrid maritime vessels, including both AC and DC grid architectures, and analyzes their performance through time domain simulations, short-circuit current calculations, and protection & coordination studies.
초록

The paper presents two simulation models in ETAP software based on actual maritime vessels, one with an AC main busbar and the other with a DC main busbar. These models can be adapted for the engineering of future hybrid vessels.

For the AC grid simulation:

  • Time domain analysis is performed, focusing on peak shaving and dynamic positioning (DP) mode. The battery inverter is used to provide power support during peak loads and in case of generator disconnection.
  • Short-circuit current calculations are compared between theoretical values using IEC 61363 and simulated results, with differences discussed.
  • Protection and coordination strategies are outlined, leveraging generator decrement curves and circuit breaker time-current characteristics to ensure selective tripping during faults.

For the DC grid simulation:

  • Limitations in ETAP's time domain analysis capabilities are encountered, particularly in modeling the battery and power balance between AC and DC sections.
  • Short-circuit current calculations are performed for the generators using IEC 61363, with a comparison between theoretical and simulated values.
  • Protection strategies for the DC busbar focus on selecting appropriate fuses that can withstand full load currents but also disconnect quickly during short-circuits, based on I^2t coordination.

The models presented are a step towards developing digital twin systems that can aid in the troubleshooting and prevention of issues, reducing risk and engineering time for future hybrid maritime vessels.

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통계
Generator DG#01 rated power: 1916 kW Generator DG#04 rated power: 2570 kW Generator DG#02 rated power: 1370 kW Generator short-circuit current (calculated): 17.638 kA Generator short-circuit current (simulated): 16.648 kA Capacitor short-circuit peak current: 6.95 kA Capacitor short-circuit time constant: 0.134 ms
인용구
"The maritime industry is undergoing a transformative shift toward decarbonization." "Hybrid ships and vessels play a key role in this transition and it is important to have a comprehensive understanding of hybrid power systems imperative." "This paper uses the ETAP simulation software (version 22.5.0) to design two adaptable electrical hybrid power system models that can be adapted for the engineering of future hybrid vessels."

더 깊은 질문

How can the simulation models be further improved to better represent the dynamic behavior of hybrid maritime power systems, especially in the presence of renewable energy sources and energy storage systems?

To enhance the simulation models for hybrid maritime power systems, particularly in integrating renewable energy sources (RES) and energy storage systems (ESS), several improvements can be made: Incorporation of Advanced Control Algorithms: Implementing sophisticated control strategies, such as Model Predictive Control (MPC) or fuzzy logic controllers, can optimize the interaction between RES, ESS, and traditional generators. These algorithms can dynamically adjust the power output based on real-time demand and generation forecasts, improving the system's responsiveness to fluctuations. Enhanced Battery Management Systems (BMS): The current limitations in the ETAP simulation regarding battery operation can be addressed by developing a more robust BMS that allows for detailed modeling of battery charging and discharging cycles. This includes simulating various states of charge (SoC) and their impact on performance, lifespan, and efficiency. Integration of Renewable Energy Profiles: Utilizing historical and predictive data for renewable energy generation (e.g., solar and wind profiles) can provide a more realistic representation of energy availability. This data can be integrated into the simulation to assess how variations in renewable output affect the overall power system dynamics. Dynamic Load Modeling: Instead of static load assumptions, dynamic load profiles that reflect real-time operational conditions should be incorporated. This includes modeling variable loads such as propulsion systems, thrusters, and auxiliary systems that change based on operational modes (e.g., docking, cruising). Real-Time Data Integration: Incorporating Internet of Things (IoT) technologies can facilitate real-time data acquisition from onboard sensors. This data can be used to adjust simulations dynamically, providing insights into system performance under varying operational conditions. Multi-Physics Simulations: Expanding the simulation to include thermal, mechanical, and electrical interactions can provide a holistic view of the hybrid system's performance. This is particularly important for understanding the thermal management of batteries and the mechanical stresses on generators and motors. By implementing these improvements, the simulation models can better represent the complex interactions and dynamic behavior of hybrid maritime power systems, leading to more effective design and operational strategies.

What are the potential challenges and limitations in implementing the proposed protection and coordination strategies in real-world hybrid maritime vessels, and how can they be addressed?

Implementing protection and coordination strategies in hybrid maritime vessels presents several challenges and limitations: Complexity of Hybrid Systems: The integration of multiple power sources (e.g., diesel generators, batteries, and RES) complicates the protection schemes. Each source may have different fault characteristics and response times, making it difficult to design a unified protection strategy. To address this, a comprehensive system study should be conducted to understand the fault behavior of each component, allowing for tailored protection settings. Selectivity and Coordination: Achieving selectivity in circuit breakers is crucial to ensure that only the affected section of the system is isolated during a fault. However, the presence of multiple power sources can lead to challenges in coordination. Implementing advanced protection relays with communication capabilities can enhance coordination by allowing devices to share information about fault conditions and system status. Dynamic Load Variability: The variable nature of loads in hybrid vessels can lead to challenges in setting appropriate protection thresholds. To mitigate this, adaptive protection schemes that can adjust settings based on real-time load conditions should be developed. This may involve using machine learning algorithms to predict load changes and adjust protection parameters accordingly. Testing and Validation: Real-world testing of protection schemes can be challenging due to the operational environment and safety concerns. Simulation tools can be used to validate protection strategies before implementation. Additionally, conducting controlled tests during vessel trials can help refine protection settings. Regulatory Compliance: Ensuring that protection and coordination strategies comply with maritime safety regulations can be complex. Engaging with regulatory bodies early in the design process can help identify requirements and ensure that the proposed strategies meet safety standards. By addressing these challenges through advanced technologies, thorough system studies, and regulatory engagement, the implementation of effective protection and coordination strategies in hybrid maritime vessels can be achieved.

What are the potential applications of the digital twin concept in the design, operation, and maintenance of hybrid maritime power systems, and how can it be integrated with other emerging technologies like machine learning and predictive analytics?

The digital twin concept offers numerous applications in the design, operation, and maintenance of hybrid maritime power systems: Design Optimization: Digital twins can simulate various design configurations and operational scenarios, allowing engineers to optimize the design of hybrid power systems before physical implementation. This includes assessing the impact of different energy sources, storage capacities, and load profiles on system performance. Real-Time Monitoring and Control: By creating a digital replica of the hybrid power system, operators can monitor real-time performance and health of the system. This enables proactive management of energy flows, load balancing, and fault detection, enhancing operational efficiency. Predictive Maintenance: Integrating machine learning algorithms with digital twins can facilitate predictive maintenance strategies. By analyzing historical performance data and real-time sensor inputs, machine learning models can predict potential failures or maintenance needs, allowing for timely interventions and reducing downtime. Scenario Analysis and Training: Digital twins can be used for scenario analysis, enabling operators to simulate various operational conditions, including emergencies or system failures. This can serve as a training tool for crew members, enhancing their preparedness for real-world situations. Integration with IoT and Big Data: The digital twin can be enhanced by integrating IoT devices that collect data from various components of the hybrid power system. This data can be analyzed using big data analytics to identify trends, optimize performance, and inform decision-making. Regulatory Compliance and Reporting: Digital twins can assist in ensuring compliance with maritime regulations by providing detailed performance data and operational history. This can simplify reporting processes and enhance transparency with regulatory bodies. By leveraging the digital twin concept alongside emerging technologies like machine learning and predictive analytics, hybrid maritime power systems can achieve greater efficiency, reliability, and sustainability, ultimately contributing to the decarbonization goals of the maritime industry.
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