Implementation of Non-Isolated Zeta-KY Triple Port Converter for Renewable Energy Applications

Chandran, Ilambirai Raghavan; Sridhar, R.; Ahsan, Mominul; Haider, Julfikar; Rodrigues, Eduardo M. G.

doi:10.3390/electronics10141681

Cited by 11 publications

(4 citation statements)

References 39 publications

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“…The design and implementation of a non-isolated zeta KY triple port converter for renewable applications has been reported [29]. It was found that the PV system and battery were used as hybrid sources for the same converter to minimize the output voltage ripples.…”

Section: Integration Of Cuk-ky Convertersmentioning

confidence: 99%

“…They also provide a greater potential change extent while decreasing the potential output expansion. This large-progressed-upconverter has found its applications in electric vehicles, persistent or limitless [29] uninterruptible power supplies (UPS), high-intensity discharge (HID) light, energy segment structure, and photovoltaic systems. The joined SEPIC and KY converter with the DC supply driven by the sun-arranged solar cells is analyzed.…”

Section: Integration Of Speic and Kymentioning

confidence: 99%

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Comprehensive Review of KY Converter Topologies, Modulation and Control Approaches With Their Applications

Kumar¹,

Raja²,

Sanjeevikumar

et al. 2022

IEEE Access

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In the current scenario, the challenging task of designing a DC-DC converter has high voltage gain and small output ripple waves, which researchers deal with in highly complicated Because of its topological and continuous conduction mode (CCM), the KY converters have developed a better converter than all the traditional DC-DC converters to overcome this intricacy of voltage transfer gain and output ripple waves. The KY converters had various qualities when compared with the boost converter with Synchronous Rectifier (SR). The KY converter is used in photovoltaic and sustainable power applications, which are examined in this study. For example, the KY converter incorporates mode-1 and mode-2 operation and its types, for example, one plus D and one plus 2D, where the KY can deliver the Nth type of KY converter. This article provides a comprehensive review and investigation of the KY converters, which incorporates their topology with control methodologies, Pulse Width Modulation (PWM) techniques, working activity of KY converters, and types for mode-1 and mode-2; it interprets the few strategies the KY converter executes and its applications.

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Section: Integration Of Cuk-ky Convertersmentioning

confidence: 99%

Section: Integration Of Speic and Kymentioning

confidence: 99%

Comprehensive Review of KY Converter Topologies, Modulation and Control Approaches With Their Applications

Kumar¹,

Raja²,

Sanjeevikumar

et al. 2022

IEEE Access

View full text Add to dashboard Cite

show abstract

“…The single switch non-isolated converter topologies are modified by adding extra diodes and passive elements in order to improve the voltage gain [13][14][15][16][17][18][19]. The researchers have also developed non-isolated topologies with extra power switches, diodes and passive components for enhanced static voltage gain [20,21]. The use of more number of switching and passive devices in the non-isolated topologies proposed in [13][14][15][16][17][18][19][20][21] leads to the complexity of the power circuit and the control strategy.…”

Section: Introductionmentioning

confidence: 99%

“…The researchers have also developed non-isolated topologies with extra power switches, diodes and passive components for enhanced static voltage gain [20,21]. The use of more number of switching and passive devices in the non-isolated topologies proposed in [13][14][15][16][17][18][19][20][21] leads to the complexity of the power circuit and the control strategy. Hence, the researchers concentrated on developing the hybrid non-isolated single switch DC-DC converter topologies with simple control strategy, high voltage gain capability and high power conversion efficiency [22][23][24].…”

Section: Introductionmentioning

confidence: 99%

A Transformerless Boost-Modified Cuk Combined Single-Switch DC-DC Converter Topology with Enhanced Voltage Gain

Duraisamy¹

2023

Braz. arch. biol. technol.

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Recently, the research is towards the development of high static gain DC-DC converters suitable for renewable energy applications. The high voltage gain can be achieved using isolated and non-isolated configurations of the converter. The magnetically coupled inductor based isolated DC-DC converter structures can have improved voltage gain, but they need large size inductors which may lead to increased cost. Thus, the modified structures of non-isolated conventional boost, CUK, and SEPIC topologies with inclusion of additional controlled and uncontrolled switches along with large number of passive components are employed to achieve the improved voltage gain. However, it leads to increased complexity and control. Hence, the researchers concentrated on development of hybrid non-isolated DC-DC converter topologies capable of achieving enhanced static voltage gain, without adding extra controlled switches and passive elements. In this paper, a hybrid non-isolated single-switch DC-DC converter structure is proposed for achieving high voltage gain than that of traditional non-isolated topologies. The proposed hybrid structure operating in continuous inductor current mode is obtained by connecting the conventional boost and the modified CUK converters in parallel. The power switch and the diodes have low voltage-current stress. The operation of the proposed hybrid topology during various modes is explored. The mathematical modeling of the proposed converter is also provided. The MATLAB / SIMULINK study of the suggested hybrid converter has been implemented. The digital simulation study proves the feasibility of the proposed hybrid converter concept and its steady-state behavior.

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Enhancing performance of interleaved KY converter control in single phase grid‐tied PV systems: A hybrid approach

Shobha,

Narmadhai

2024

Optim Control Appl Methods

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This paper proposes a hybrid COA‐QNN approach for an interleaved KY converter with closed‐loop control for a single‐phase grid‐connected photovoltaic (PV) system. The proposed strategy combines both Cheetah Optimizer algorithm (COA) and Quantum Neural Network (QNN), and it is commonly named the COA‐QNN technique. The interleaved KY converter is connected in the converter side. The primary goal of the COA‐QNN technique is to enhance PQ while maximizing PV electricity being transferred to the grid. The proposed COA is utilized to identify the optimal closed‐loop controller enhancements for on‐grid solar photovoltaic systems. The QNN is used to predict the optimal control parameter. The PV‐interleaved KY converter is managed by a predictive control mechanism to carry out both tasks of PQ enhancement. By then the COA‐QNN technique is implemented on the MATLAB platform and compared with existing methods. Finally, the proposed method shows better results in all methods, such as GWO, FF optimization and combined GWO‐FF.

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Implementation of Non-Isolated Zeta-KY Triple Port Converter for Renewable Energy Applications

Cited by 11 publications

References 39 publications

Comprehensive Review of KY Converter Topologies, Modulation and Control Approaches With Their Applications

Comprehensive Review of KY Converter Topologies, Modulation and Control Approaches With Their Applications

A Transformerless Boost-Modified Cuk Combined Single-Switch DC-DC Converter Topology with Enhanced Voltage Gain

Enhancing performance of interleaved KY converter control in single phase grid‐tied PV systems: A hybrid approach

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