Viper265K Buck Converter Design - 0.5% duty cycle ?

Welcome @shrikantB, to the community!

As you write, you want to implement a high-voltage buck, but you have not specified whether the input voltage is DC or AC.

I will initially assume you mean DC. For your requirements, the buck topology is not suitable, because you would need a duty cycle in the range of 0.005 to 0.0225. A flyback could mitigate the duty-cycle problem through the transformer turns ratio, however you would have to implement it with a PWM device plus an HV MOSFET, because the VIPER265K would not be able to withstand it.

With AC, it would look even worse, because the peak voltage would be about 41% higher.

Hope that helps?

Regards
/Peter

Hi Peter,

Thank you for your reply. For the above requirement share we have decided to go for the 2 Buck.

Wherein first stage would implement 900VDC to 20VDC with Viper267K which seems to be feasible.

Other stage would be 20VDC to 4.5VDC.

Now after doing some simulations with Viper267K switching device there is one query that during start up with 680uH of Buck inductor the initial peak is observed till 2Amps. Later the current is as per the load.

Please can you suggest if this peak can be sustained by the Viper267K as the max current limit seems to be 0.75Amps. Please help for this query.

Thanks and Regards,

Shrikant Bhairavkar

You spoke of a simulation with the VIPER267K, but the VIPER265K is in the schematics. However, I also simulated it again with the VIPER267K and, for the most part, get the same results.

By the way, your simulation refers to an input voltage of around 300Vac, i.e. 424Vdc. As the input voltage increases, the peak current also increases (theoretically), but is limited by the internal current limiting, which makes the peak last longer in order to charge the output capacitance of the system. If the inductor reaches its limit at high start-up currents, the effective inductance drops, so it is inversely proportional to di/dt, which significantly increases the peak currents.

I would advise you that there is really no point in pursuing the idea of a buck for a conversion from an input voltage of up to 900V further, regardless of the output voltage. At that point, you are already too close to the maximum drain voltage of the internal MOSFET. But for a reliable design the limiting factor is not only the MOSFET voltage rating itself, but the combination of:

• very steep inductor current ramp at high input voltage
• start-up dynamics with discharged output capacitor
• current limit behaviour
• inductor saturation or component stress

If you already have two regulators planned, you can also put this material and financial effort into a flyback, which will likely work out cheaper overall. In addition, you won’t be tempted to accidentally connect or mix up the separate input and output GNDs used in the buck converter.

Regards
/Peter