Análisis, diseño y optimización del convertidor CC-CC bidireccional reductor-elevador con acoplamiento magnético-Alba Rodríguez Lorente-Ingeniería eléctrica, electrónica y automática Universidad Carlos III de Madrid

Análisis, diseño y optimización del convertidor CC–CC bidireccional reductor–elevador con acoplamiento magnético -Autor-Alba Rodríguez Lorente Tesis depositada en cumplimiento parcial de los requisitos para el grado de Doctor en Ingeniería eléctrica, electrónica y automática Universidad Carlos III de Madrid 

 ABSTRACT Due to their ability to absorb, store, and subsequently deliver electrical energy, Energy Storage Systems (ESS) stand out as a solution to many technical problems arising from the need always to have energy available on demand. Among the different ESS technologies, batteries, within the category of electrochemical ESSs, have gained special relevance in recent times, for their exponential deployment in industry, with a rapid improvement in their performance. Studies predict that their use will continue to grow in the upcoming years and that they will play a major role in applications such as renewable energies and electric transport. In general, all applications that interact with the ESSs need to have power converter circuits that control and transform the energy delivered by the ESSs efficiently, according to the needs of the load demanding that energy. Bidirectional converters are especially useful as an interface with the ESSs, since their versatility allows both the control of the power supply to the load and the conditioning of the surplus or recovered energy from the load to recharge the ESSs after having satisfied the original demand. In this context, the research work carried out in this thesis focuses on those power converters that present non–isolated bidirectional DC–DC topologies with Buck–Boost operation as an interface with batteries and other secondary DC energy storage systems. This subset of topologies provides practical advantages in this context of use in terms of power density, and operating capability regardless of the voltage values demanded by the load and the voltage level at the source. From the topologies analysis in the state–of–the–art that meets these requirements, it is concluded that the highest performances are obtained with topologies that allow greater flexibility in modulation, at the cost of increasing the number of components and the control difficulty. This thesis document proposes a new non–isolated bidirectional DC–DC topology with Buck–Boost operation as an interface to electrical energy storage systems, especially batteries. The new topology is called Magnetically Coupled Bidirectional Buck–Boost converter, or MCB3. The proposal aims to achieve good power density and high modulation flexibility, allowing access to advanced modulations aimed at reducing total losses. Of the proposed converter: the operation is analyzed, the optimization through modulation possibilities is studied for both switching and conduction loss reduction, its magnetic components are designed according to a minimum volume criterion, the power stage is dimensioned based on an established specification and, at each step, the theory is validated with simulation and experimental results. Finally, its performance is compared to topological alternatives with which it shares either behavior or field of application.

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