VI-BTW-EV-S

Current - Output (Max):	9.09A
Size / Dimension:	4.60" L x 1.80" W x 0.52" H (116.8mm x 45.7mm x 13.2mm)
Package / Case:	Full Brick
Mounting Type:	Through Hole
Efficiency:	88%
Operating Temperature:	-10°C ~ 85°C
Features:	OCP, OTP, OVP, SCP
Applications:	ITE (Commercial)
Voltage - Isolation:	3kV
Power (Watts):	150W
Series:	VI-200™
Voltage - Output 3:	--
Voltage - Output 2:	--
Voltage - Output 1:	5.5V
Voltage - Input (Max):	160V
Voltage - Input (Min):	66V
Number of Outputs:	1
Type:	Isolated Module
Part Status:	Active
Packaging:	Bulk

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DC/DC Converters can provide electrical power conversion from a DC source to another DC voltage source in a wide variety of applications. A typical application is the conversion of low-voltage DC battery power to a higher voltage DC power. DC/DC converters may also be used to convert high-voltage DC power to a lower voltage DC output, or to directly switch AC voltage. DC/DC converters can be used for high efficiency and high precision in many applications, such as in power conditioning, electro-optical and communication systems, automotive and computer electronic systems. The most commonly used DC/DC converter topologies are DC-DC/BTW (Boost, Buck, Boost & Buck), DC-DC/EV (Flip-Flop, Flyback, Push-Pull, Series-Parallel), and DC-DC/S (Simplex, Half-Bridge, Full-Bridge) Converters. In a DC-DC/BTW converter, two main power transistors are used to convert the input DC voltage into a higher or lower output voltage. In the DC-DC/EV Converter, four power transistors are used to control the voltage conversion. Finally, in the DC-DC/S Converter, several switching transistors are used to manipulate the transistor switch operations. The Boost converter is the most common type of DC-DC/BTW converter. It works by switching a series of transistors on and off at certain intervals to increase the output voltage. The Buck converter is basically a reversed version of the Boost converter, where the voltage is decreased instead of increased. The Boost & Buck converter is a combination of the Boost and Buck converter, switching the active transistor in the opposite direction at each interval. The Flip-Flop converter is a DC-DC/EV type and works by controlling two power transistors operating in opposite phase. The voltage is increased during the on-time of the first transistor and decreased during the on-time of the second transistor. The Flyback converter is also a DC-DC/EV type, but with an inductor in the circuit that is used to store energy during the off-time of the transistor and releases the stored energy during the on-time. The Push-Pull converter works similarly to the Flip-Flop converter but uses two power transistors operating in the same phase. The voltage is decreased during the on-time of the first transistor and increased during the on-time of the second transistor. The Series-Parallel converter is a DC-DC/EV type where two power transistors are configured in series to double the voltage conversion capability by utilizing the voltage across each transistor. The Simplex converter is a DC-DC/S type, which uses one transistor for voltage conversion. The Half-Bridge converter is a DC-DC/S type, using two power transistors in series to double the voltage conversion of the Simplex converter. The Full-Bridge converter is also a DC-DC/S type, using four power transistors in series to quadruple the voltage conversion of the Simplex converter. DC/DC converters are essential in the development of modern technology for a wide variety of applications. They provide efficient power conversion from DC sources, allowing for greater flexibility and accuracy in power control. In addition, the different topologies enable a variety of voltage regulation and current control capabilities, making DC/DC converters ideal for any power system requirement.

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