An elevated gain DC-DC converter with active switched inductor for PV application

Mahalingam, Kalarathi; Gnanavadivel, J.

doi:10.11591/ijpeds.v14.i2.pp892-897

Cited by 3 publications

(4 citation statements)

References 18 publications

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“…Utilizing the switching average model, with due consideration to the time intervals during which the switch is ON and OFF, we can formulate the voltage equation for the DC-DC boost converter based on ( 2) and ( 4) as follows, denoted as (5).…”

Section: Methods 21 Analysis Of Dc-dc Boost Converter Systemmentioning

confidence: 99%

“…The DC/DC power converter is widely researched and extensively employed in the field of power electronics. The utilization spectrum of DC/DC power converters encompasses various applications such as high-efficiency power supplies [1], [2], high-efficiency battery chargers [3], high voltage gain converters [4], [5], high-efficiency DC motor drives [6], [7], maximum power point tracking (MPPT) applications [8]- [10], and renewable energy conversion systems [11]- [14]. DC-DC converters are frequently employed in the context of inverter systems within photovoltaic systems [15]- [17], alongside wind turbines and other sources of renewable energy.…”

Section: Introductionmentioning

confidence: 99%

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Dynamic evolution control for the DC/DC boost converter design and implementation

Samosir,

Sulistiyanti,

Gusmedi

et al. 2024

IJPEDS

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This paper introduces the design and hardware implementation of the dynamic evolution control for a DC/DC boost converter. The development of the controller aims to effectively regulate the output voltage of the DC/DC boost converter with a high degree of precision. A comprehensive examination of the duty cycle formula for the boost converter is conducted using a non-linear analysis approach. This study introduces a methodology for the synthesis of a converter controller utilizing the principles of dynamic evolution control theory. The converter's output consistently aligns with the target voltage by following the dynamic evolution path determined by the designed controller. The performance evaluation of the proposed boost converter controller utilizing dynamic evolution control is being validated through the utilization of MATLAB/Simulink simulation software. The effectiveness of the proposed controller is further validated through the presentation of hardware results. The performance of the controller was evaluated by varying the values of parameters k and m.

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Section: Methods 21 Analysis Of Dc-dc Boost Converter Systemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dynamic evolution control for the DC/DC boost converter design and implementation

Samosir,

Sulistiyanti,

Gusmedi

et al. 2024

IJPEDS

View full text Add to dashboard Cite

show abstract

“…Furthermore, in [25]- [27] A new approach has been proposed in the DC-DC converter by combining two or more conventional transformers, in [25] has successfully combined flyback and SEPIC topologies, but the profit is still small and requires an increase in the duty cycle, as the result increase loss. The work of [26] shows that the boost converter has been improved and the profit is fairly good, but it requires two keys, which makes controlling it complex and increases costs and losses. Also, in [27] has successfully combined quadratic boost and SEPIC topologies but to increase voltage gain should be increased duty cycle and used to switch.…”

Section: Introductionmentioning

confidence: 99%

Experimental validation of quadratic-boost-zeta converter based on coat circuit

Ali,

Hassan

2023

IJPEDS

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<p>This work proposed a high step-up DC-DC converter with a voltage gain of 12 at a duty cycle of 48.25% with a single active switch. The new design combines the quadratic-boost converter and an isolated zeta converter with a single-stage coat circuit by a transformer with a trans ratio of 2.3. This can result in low voltage stress on switch and diodes with low conduction losses without using an additional clamp circuit, which in turn causes an increase in total efficiency. It has continuous and low ripples in the input and output currents. The voltage conversion ratio and the component voltage stresses are calculated in continuous conduction mode (CCM). The prototype was constructed and tested practically while considering an input voltage of 30 V, an input power of 240 W, an output voltage of 360 V, and a switching frequency of 100 kHz to validate the theoretical evaluations. The maximum efficiency at maximum output power is 94.5%.</p>

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“…There are a number of literature references that describe high gain DC DC converters, both non isolated and isolated. A converter with voltage lift technique is presented in [1], [3]. It is suggested to attain high voltage gain by a hybrid approach where both switches are switched on simultaneously.…”

Section: Introductionmentioning

confidence: 99%

Design and Analysis of Boost Topology Based on Sheppard-Taylor Converter for Renewable Power Integration

2023

IRJMETS

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This paper proposes a novel high step-up converter with an average mode control which is designed for power generation applications. The detailed steady-state analysis for the system is presented. According to the steadystate analysis, transfer functions of input voltage versus output voltage and duty cycle versus output voltage are obtained. In addition, some simplifications and design rules are proposed to facilitate the design of the feedback loop. The Sheppard Taylor Converter was primarily designed to provide non pulsing input and output current similar to the Cuk Converter, The energy of the cuk converter is bidirectional, but the sheppard taylor circuit trand former works is forward. The converter has two inductors that can shape the input current feed the output load, reduce the input and output current ripple. Compare to the cuk converter, the sheppard taylor converter can regulate output voltage with less variation in the duty cycle. Sheppard Taylor converter, state space averge model, high step up converter. High voltage gain DC-DC converters find its applications mainly in renewable energy integration.

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An elevated gain DC-DC converter with active switched inductor for PV application

Cited by 3 publications

References 18 publications

Dynamic evolution control for the DC/DC boost converter design and implementation

Dynamic evolution control for the DC/DC boost converter design and implementation

Experimental validation of quadratic-boost-zeta converter based on coat circuit

Design and Analysis of Boost Topology Based on Sheppard-Taylor Converter for Renewable Power Integration

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