VI-JNM-IW-S

Due to market price fluctuations, if you need to purchase or consult the price. You can contact us or emial to us:   sales@allicdata.com

DC DC converters are electrical components used in AC to DC, DC to DC, or other electrical engineering applications. They are widely used in power systems such as telecommunications, industrial motor control, electrical grid interconnection, and defence systems.

VI-JNM-IW-S Converters are the latest generation of DC DC converters. It stands for Variable Isolated, Junctionless, Nanoscale MOSFET, and Isolated Wafer Stack converter topologies. VI-JNM-IW-S converters offer several key advantages over the older and more established topologies. They provide higher power density, improved power conversion efficiency, lower voltage conversion ratios, and better electrical isolation.

In the application field, VI-JNM-IW-S converters are most suitable for DC to DC conversion, especially when the input and output DC voltages are in very different ranges compared to previous converter topologies. They are highly efficient in converting low voltage signals (down to 0.8V) into much higher voltages that can go up to 200V and beyond, and can effectively handle a very wide range of input and output parameters. This makes them suitable for powering components such as microprocessors, ASICs, and DSPs.

At the same time, VI-JNM-IW-S converters also have a number of advantages in the industrial motor control sector as well. They are capable of handling changes in input power while maintaining steady output voltages, eliminating long start-up times and power cycling. They can also provide increased current capacity while reducing overall energy losses, resulting in improved efficiency and better temperature control.

The VI-JNM-IW-S converter works by using four different power conversion stages. The first stage is the voltage isolation stage, which is used to prevent high voltage transients and enable isolation between the input voltage and the output voltage. This is done by using insulated, cascaded metal oxide semiconductor field-effect transistors (MOSFETs).

The second stage is the junctionless MOSFET stage, which is used to minimize the voltage drops and increase efficiency. In this stage, two MOSFETs are connected back to back, and a voltage star is used to regulate the current flow. By minimizing the amount of voltage loss, the MOSFETs are able to effectively transfer energy from the input to the output.

The third stage is the nanoscale MOSFET stage, which is used to provide the highest efficiency of conversion. This is done by using very small MOSFETs, which are also extremely resistant to electric fields and radiation. This greatly reduces power losses, increases efficiency, and provides the highest DC-to-DC conversion ratio possible.

Finally, the fourth stage is the isolated wafer stack stage, which is used to increase the current efficiency and power density. Wafer stacking involves stacking multiple layers of semiconductor material together, which provides a much more efficient way of dissipating heat and increasing power density. This increases the converter’s current efficiency and power density, resulting in improved performance.

VI-JNM-IW-S converters offer a number of key benefits for both industrial and consumer DC DC conversion applications. They provide higher power density, improved efficiency, lower voltage conversion ratios, and better electrical isolation. These advantages have enabled VI-JNM-IW-S converters to replace the older topologies in many different power conversion applications.

The specific data is subject to PDF, and the above content is for reference