Voltage multiplier applied to boost DC–DC converter: Analysis, design, and performance evaluations

In this paper, a non‐isolated switched inductor cell integrated high step‐up voltage gain DC‐DC converter with a charge pump mechanism is discussed. The continuous conduction mode of the input current is a beneficial aspect of this converter, which is appropriate for electric vehicles, renewable energy, and LED applications. The proposed converter works in two distinct operating modes and provides a flexible range of voltage gain ratios. The performance and small‐signal modeling of the converter in continuous conduction mode are extensively investigated, and voltage gain calculations for the two operational modes are derived. The Markov technique is used to evaluate the converter reliability, component failure rates, and mean time to failures. The proposed converter is evaluated with the existing converters in terms of voltage, and current stress of each component, voltage gain, total component stress factor, component count, and reliability. The proposed converter's hardware prototype has been developed. To validate the theoretical calculations, the converter's simulation and experimental results are discussed. The converter has a maximum output voltage of 110 V and a switching frequency of 50 kHz. The converter's peak efficiency is 94.5%.

Section: Design Of the Capacitorsmentioning

confidence: 99%

“…11,12 These non-isolated converters are classified into coupled inductor converters and non-coupled inductor converters. 13 In previous studies, 14,15 a coupled inductor converter with a high voltage gain was developed. But during the OFF time, coupled inductor leakage caused voltage rise across the switches.…”

Section: Introductionmentioning

confidence: 99%

A non‐isolated switched inductor‐capacitor cell based multiple high voltage gain DC‐DC boost converter

Reddy

Obulesu

2022

“…A PV panel usually supplies a range of 18‐ to 50‐V DC, which commonly results in 100‐ to 600‐W power. Thus, a step‐up converter is needed to increase PV voltage to DC bus voltage (typically >380 V) to interface with the grid tie, load, or microgrid DC 5–8 …”

Section: Introductionmentioning

confidence: 99%

“…Thus, a step-up converter is needed to increase PV voltage to DC bus voltage (typically >380 V) to interface with the grid tie, load, or microgrid DC. [5][6][7][8] Theoretically, the ideal boost and buck-boost converter can achieve high voltage gain when the duty cycle (D) is close to 1. However, this is not feasible experimentally, because boost converter components have parasitic resistances.…”

mentioning

confidence: 99%

High step‐up buck–boost DC–DC converter with coupled inductor and low component count for distributed PV generation systems

Toebe

Faistel

Andrade

2022

Self Cite

This paper presents a non‐isolated high step‐up buck–boost with a coupled inductor DC–DC converter relevant for distributed photovoltaic (PV) generation systems. The proposed topology can reach high voltage gain through the combination of a buck–boost converter with a coupled inductor. The configuration of the proposed converter allows to achieve a natural voltage clamp circuit for the switch, recovering the energy stored in the leakage inductance of the coupled inductor. Moreover, the converter allows soft‐switching conditions, that is, Zero Current Switching (ZCS) for the diodes and nearly ZCS for the active switch. Also, the proposed converter presents a low component count and common ground connection of the input and output. The proposed converter is evaluated theoretically by the principle of operation in continuous‐conduction mode (CCM) and discontinuous‐conduction mode (DCM), voltage gain derivation, external characteristics, semiconductor voltage stress, current stress, and design guidelines. Finally, a 650‐W, 36/380‐V, 50‐kHz prototype was built in the laboratory to experimentally evaluate the proposed converter, which reached a maximum efficiency rate of 96.58%.

“…10 Recent dual active bridge topologies are capable of achieving zero voltage switching by the integration of resonant converters at fixed or variable frequency modulation. Some of the aforementioned demerits in isolated topologies can be overcome by adopting rectifiers, voltage doublers-quadruplers at the secondary side and more over reverse power flow, circulating currents can also completely eliminated as mentioned in Mustafa et al 11 Numerous voltage amplification techniques based on conventional boost converters, 12 switched inductors, [13][14][15] switched capacitors, [16][17][18][19] coupled inductors, [20][21][22][23] cascaded connections, 24,25 quadratic boost, 26 voltage lift, 27,28 voltage multiplier with capacitor-diode combination, 29,30 hybrid switched inductor with intermediate capacitor, 31,32 and quasi Z source type 33 are used for nonisolated converters. The merits of nonisolated converters such as simple in structure and low cost are preferable in applications where galvanic isolation is not necessary.…”

Section: Introductionmentioning

confidence: 99%

Nonisolated high gain hybrid switched‐inductor DC‐DC converter with common switch grounding

Baba

Giridhar

Narasimharaju

2022

This paper presents a methodology that integrates the hybrid switched inductor (HSL) and split duty ratio techniques to synthesize a high gain converter with common switch grounding (HSL‐CSG). The DC‐DC converter's high gain feature is required for microsource power processing in low voltage renewable energy systems. The amplification in voltage gain of the proposed converter is achieved without using transformer, common core coupled inductors, voltage multipliers, intermediate capacitors, and voltage lifting methods so that the topology is simple in construction and operation. Moreover, with a split duty ratio the proposed converter switches are less prone to current stress due to reduction in extreme conducting duty intervals. The topological derivation, operating principle, analysis of both continuous conduction mode (CCM), and discontinuous conduction mode (DCM) are presented. The theoretical analysis is validated with the aid of a laboratory prototype.