Analysis of Steady-State Characteristics for a Newly Designed High Voltage Gain Switched Inductor Z-Source Inverter

Subhani, Nafis; Kannan, Ramani; Mahmud, M. A.; Roy, T. K.; Romlie, Mohd Fakhizan

doi:10.3390/electronics8090940

Cited by 8 publications

(10 citation statements)

References 41 publications

(55 reference statements)

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“…Most of these topologies follow the extended SL cell structures to improve the gain of the inverter. In [84], the model of an SL strong boost ZSI (SLSB‐ZSI) (see Figure 19) was proposed where the SL cells have been composed on the multiple series impedance networks based on the idea in [85]. Although the SLSB‐ZSI has significantly improved the boost factor and achieved lower voltage stress on capacitors and semiconductor switches, the component count is high enough that shrunk the practical applicability of the inverter.…”

Section: Two Symmetric Impedance Network‐based Sl/sc Zsismentioning

confidence: 99%

“…In the race of improving the voltage boost ability of the SL-ZSI, several other topologies have been studied in [80][81][82][83][84].…”

Section: Similar Structuresmentioning

confidence: 99%

“…In the race of improving the voltage boost ability of the SL‐ZSI, several other topologies have been studied in [80–84]. Most of these topologies follow the extended SL cell structures to improve the gain of the inverter.…”

Section: Two Symmetric Impedance Network‐based Sl/sc Zsismentioning

confidence: 99%

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Z‐source inverter topologies with switched Z‐impedance networks: A review

Subhani

Kannan

Mahmud

et al. 2021

IET Power Electronics

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The Z‐source inverter is one of the most interesting power electronic converters. Over the past decades, research and development have been in high demand to meet the challenges for improving the converter performance with reduced weight and cost while having high efficiency along with high gain or boost factor. Since the inception, tons of resolutions, customizations, and improvements have appeared to achieve these performance goals. To overcome the most common drawback, i.e. the low boost factor of classical Z‐source inverters, the switched inductor/capacitor and switched boost Z‐source inverter topologies have become predominant in the recent epoch. Furthermore, the higher component voltage stress, discontinuous input current, and high inrush start‐up current issues have also been addressed and solved in various literature as part of this topical advancement. In this study, a comprehensive review of various switched impedance network‐based Z‐source inverter topologies has been accomplished for providing a quick report to researchers and engineers so that they can consider this as a one‐stop solution for selecting inverters from this group. The overall study covers the methodology, features, and relevant important results of the latest switched Z‐source inverter models in order to demonstrate the coordination between pitfalls and improvements.

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Section: Two Symmetric Impedance Network‐based Sl/sc Zsismentioning

confidence: 99%

“…In the race of improving the voltage boost ability of the SL-ZSI, several other topologies have been studied in [80][81][82][83][84].…”

Section: Similar Structuresmentioning

confidence: 99%

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Z‐source inverter topologies with switched Z‐impedance networks: A review

Subhani

Kannan

Mahmud

et al. 2021

IET Power Electronics

Self Cite

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“…There are many points of view from which inverters are classified, one of the essential classifications is made according to their power supply. In this way, three types of inverters are established-Voltage Source Inverter (VSI) [15], Current Source Inverter (CSI) [16] and Z-Source Inverter (ZSI) [17]. As a summary, the main classifications of these power converters are presented in Figure 2.…”

Section: Introductionmentioning

confidence: 99%

Leakage Current Reduction in Single-Phase Grid-Connected Inverters—A Review

et al. 2020

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The rise in renewable energy has increased the use of DC/AC converters, which transform the direct current to alternating current. These devices, generally called inverters, are mainly used as an interface between clean energy and the grid. It is estimated that 21% of the global electricity generation capacity from renewable sources is supplied by photovoltaic systems. In these systems, a transformer to ensure grid isolation is used. Nevertheless, the transformer makes the system expensive, heavy, bulky and reduces its efficiency. Therefore, transformerless schemes are used to eliminate the mentioned disadvantages. One of the main drawbacks of transformerless topologies is the presence of a leakage current between the physical earth of the grid and the parasitic capacitances of the photovoltaic module terminals. The leakage current depends on the value of the parasitic capacitances of the panel and the common-mode voltage. At the same time, the common-mode voltage depends on the modulation strategy used. Therefore, by the manipulation of the modulation technique, is accomplished a decrease in the leakage current. However, the connection standards for photovoltaic inverters establish a maximum total harmonic distortion of 5%. In this paper an analysis of the common-mode voltage and its influence on the value of the leakage current is described. The main topologies and strategies used to reduce the leakage current in transformerless schemes are summarized, highlighting advantages and disadvantages and establishing points of comparison with similar topologies. A comparative table with the most important aspects of each converter is shown based on number of components, modes of operation, type of modulation strategy used, and the leakage current value obtained. It is important to mention that analyzed topologies present a variation of the leakage current between 0 to 180 mA. Finally, the trends, problems, and researches on transformerless grid-connected PV systems are discussed.

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“…The substantial progress of modern power inverters is well underway for the penetration of renewable energy sources into power systems and many other industrial applications [1]. The Impedance Source Inverters (also called Z-Source Inverters or ZSIs) form a class of high-performance, highly reliable, and highly efficient yet low-cost inverters equipped with an X-shaped impedance circuit that enables shoot-through state [2,3].…”

Section: Introductionmentioning

confidence: 99%

Optimal Robust LQI Controller Design for Z-Source Inverters

et al. 2020

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This paper investigates the linear quadratic integral (LQI)-based control of Z-source inverters in the presence of uncertainties such as parameter perturbation, unmodeled dynamics, and load disturbances. These uncertainties, which are naturally available in any power system, have a profound impact on the performance of power inverters and may lead to a performance degradation or even an instability of the system. A novel robust LQI-based design procedure is presented to preserve the performance of the inverter against uncertainties while a proper level of disturbance rejection is satisfied. The stability robustness of the system is also studied on the basis of the maximum sensitivity specification. Moreover, the bat algorithm is adopted to optimize the weighting matrices. Simulation results confirm the effectiveness of the proposed controller in terms of performance and robustness.

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Analysis of Steady-State Characteristics for a Newly Designed High Voltage Gain Switched Inductor Z-Source Inverter

Cited by 8 publications

References 41 publications

Z‐source inverter topologies with switched Z‐impedance networks: A review

Z‐source inverter topologies with switched Z‐impedance networks: A review

Leakage Current Reduction in Single-Phase Grid-Connected Inverters—A Review

Optimal Robust LQI Controller Design for Z-Source Inverters

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