Your search keyword '"Andrea Reindl"' showing total 3 results

1. Framework to Test DC- DC Converters Developed for a Decentralized Battery Management System

Author

Thomas Singer, Sangyoung Park, Andrea Reindl, Michael Niemetz, and Hans Meier

Subjects

Software framework, Microcontroller, Reliability (semiconductor), Data acquisition, Computer science, Control system, Response time, Control engineering, Converters, computer.software_genre, computer, Power (physics)

Abstract

DC- DC converters control the power flow and thus the power distribution between the components on different voltage levels. They are essential for (dis)charging batteries and influence the safety and stability of the entire battery management system (BMS). Therefore, testing the functionality and the reliability of DC-DC converters is crucial. This is especially true for decentralized battery management systems (DBMS), where multiple nodes communicate to collectively control the system. The used DC-DC converters are modified to parameterize them during operation via microcontroller interfaces. Integrating the communication into the control loop requires an analysis of the control behavior due to additional delays. Therefore, this paper proposes a framework to test DC-DC converters considering the control and communication perspectives. The response time, the control accuracy and stability of these DC-DC converters, e.g., under continuous and abrupt load changes, are measured in automated tests. The dedicated software framework simulates the DBMS and stimulates the hardware components (e.g. electronic loads, data acquisition) via respective interfaces (CAN, RS232). This allows the test of various DC-DC converters with flexibly adaptable load and power generation profiles. An initial application validates the test framework by verifying the aforementioned aspects and thus the applicability of a DC-DC converter within the DBMS.

Published

2021

2. Bidirectional DC-DC Converter with Digital Droop Parameterization

Author

Michael Niemetz, Hans Meier, Andrea Reindl, Michael Jupke, and Pinker, Jiří

Subjects

Battery (electricity), droop control, Computer science, microgrids, kontrola poklesu, DC-DC napájecí měniče, law.invention, law, power stage, sdílení zátěže, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Voltage droop, battery management systems, obousměrný tok energie, systémy pro správu baterií, mikrokontroléry, automatická regulace napětí, Converters, mikrosítě, Microcontroller, automatic voltage control, DC-DC power converters, Operational amplifier, load sharing, bidirectional power flow, Voltage regulation, Resistor, výkonový stupeň, microcontrollers, Voltage

Abstract

The key for decentralized battery systems is a robust and communication-less control strategy for autonomous power sharing of parallel-connected DC-DC converters. Battery systems improve the reliability and quality of power supply in renewable energy systems and enable power supply for off-grid, mobile applications, including islanded grids, home storage, and electric vehicles. In many cases, components with different elec trical properties require different voltage levels. An adaptation is consequently essential and is normally implemented in DC grids for the batteries via bidirectional DC-DC converters. The power flow in both directions can thus be ensured. To achieve a power distribution in parallel connected DC-DC converters, a droop control in the form of a virtual internal resistor can be used. This paper presents a novel approach of a DC DC converter with a digitally parameterizable droop resistor, whose voltage regulation is based on an analog operational amplifier circuit to ensure low delays and robustness. The droop resistor is adjusted with a microcontroller, which offers the possibility to apply a higher-level control for load sharing via an interface. Mathematical correlations are used to clearly define the parameters of the control. Furthermore, the circuit was completely simulated and tested in the hardware setup. The shown results verify the functionality and indicate only minor deviations. Therefore, this circuit is important for future use in distributed battery systems.

Published

2021

3. Software Framework for the Simulation of a Decentralized Battery Management System Consisting of Intelligent Battery Cells

Author

Hans Meier, Andrea Reindl, and Michael Niemetz

Subjects

Battery (electricity), Leader election, business.industry, Computer science, 020209 energy, 020208 electrical & electronic engineering, Distributed management, 02 engineering and technology, computer.software_genre, Decentralised system, Software framework, Microcontroller, Embedded system, 0202 electrical engineering, electronic engineering, information engineering, business, Intelligent control, Uninterruptible power supply, computer

Abstract

Conventional battery management systems typically adopt hierarchical master-slave architectures. With regard to an uninterruptible power supply, the most significant disadvantage of central structures is the dependency of the errorfree function of the superior master board. The decentralized battery management system presented in this paper, consisting of consumers, generators and intelligent battery cells, is controlled without any central coordination authority. For this purpose, an intelligent control algorithm and a leader election algorithm are implemented on the microcontrollers of the battery cells. To test different control and election strategies, a software framework is presented for the complete simulation of the decentralized battery management system consisting of equal participants.

Published

2019