Improved Forward Topologies for DC-DC Applications with Built-in Input Filter

Among PWM power conversion topologies, the single-switch forward topology is the one that has been most widely used for decades. Its popularity has been based on many factors, including its low cost, circuit simplicity and high efficiency. However, several issues need to be addressed when using the forward converter such as the core reset, the voltage spikes caused by the transformer leakage inductance, and the pulsating input current waveform. The transformer is driven in a unidirectional fashion in the forward converter; a tertiary forward converter (TFC) is an example of this. Therefore, the third winding and reset diode must be provided with an adequate period of reset time so that the flux can be fully reset by the end of each switching cycle to prevent core saturation. Also, due to the utilization of a transformer, leakage inductances cannot be avoided. The energy stored in the leakage inductance during current ramp-up is not transferred to the load, and is not recovered during its discharge phase. As a result, the V DS waveform has a voltage spike and undesirable high-frequency oscillation. Therefore, a higher voltage-rating switch should be used to reduce the risk of high-voltage breakdown. Although a switch with amply high voltage ratings is available, it would tend to have a iii higher on-resistance, R DS(ON) , resulting in increased conduction losses. Moreover, selection of a switch with higher voltage ratings than necessary may needlessly increase the cost of the design. Usually an additional circuit such as a snubber circuit or a clamp circuit or the soft-switching technique is used to absorb these voltage spikes. Consequently, the leakage inductance is intentionally minimized in the PWM power conversion technique so that it will not degrade the circuit performance. In contrast, the leakage inductance of the transformer may enhance rather than detract from circuit performance with a resonant power conversion technique. To date, however, no single-switch forward converter has been claimed to be able to enhance the converter performance with the PWM power conversion technique by utilizing the leakage inductance. Therefore, research on the utilization of the transformer leakage inductance in the PWM forward converter is needed. Two techniques, input current ripple reduction and an embedded filter, are proposed to enhance the performance of forward converter using the PWM technique. By inserting a capacitor between two primary windings of the TFC, an input current ripple reduction technique is proposed and a forward converter …