Abstract
From its introduction to the present day, Cascaded H-Bridge multilevel converters were employed on numerous applications. However, their floating capacitor, while advantageous for some applications (such as photovoltaic) requires the usage of balancing methods by design. Over the years, several such methods were proposed and polished. Some of these methods use optimization techniques or inject a zero-sequence voltage to take advantage of the converter redundancies. This paper describes an optimization-based capacitor balancing method with additional features. It can drive each module DC-Link to a different voltage for independent maximum power point tracking in photovoltaic applications. Moreover, the user can specify the independent active power set points to modules connected to batteries or any other energy storage systems. Finally, DC current ripple can be reduced on some modules, which can extend the lifespan of any connected ultra-capacitors. The method as a whole is tested on real hardware and compared with the state-of-the-art. In its simplest configuration, the presented method shows greater speed, robustness, and current wave quality than the state-of-the-art alternative in spite of producing about 1/3 fewer commutations. Its other characteristics provide additional functionalities and improve the adaptability of the converter to other applications.
Highlights
Cascaded H-Bridge (CHB) converters have supposed a big step forward in the development of Multilevel converters technology
Several tests were made to check the general performance of the proposed method
Each test is described in its own subsection
Summary
Cascaded H-Bridge (CHB) converters have supposed a big step forward in the development of Multilevel converters technology This type of modular converter is increasingly widespread in the industry, due to the great number of advantages compared with the traditional converters [1]. From its introduction, this topology, shown, is mainly used in photovoltaic plants [2,3,4,5,6,7,8], Static Synchronous Compensators (STATCOM) [9,10,11,12,13], and power distribution applications [14,15,16]. Related investigations focus on enhancing the capability and efficiency of this converter [17,18] This can be achieved through improvements in control strategies and in the voltage balance method. Several methods have already been presented to equalize the DC-Link of the modules
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