VI-BTK-MW

Current - Output (Max):	1.25A
Size / Dimension:	4.60" L x 2.40" W x 0.50" H (116.8mm x 61.0mm x 12.7mm)
Package / Case:	Full Brick
Mounting Type:	Through Hole
Efficiency:	90%
Operating Temperature:	-55°C ~ 85°C
Features:	OCP, OTP, OVP, SCP
Applications:	ITE (Commercial)
Voltage - Isolation:	3kV
Power (Watts):	100W
Series:	VI-200™
Voltage - Output 3:	--
Voltage - Output 2:	--
Voltage - Output 1:	40V
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

DC DC converter technology has been used for many years as a reliable form of power conversion from one voltage level to another. The most common type of DC DC converter is the VI-BTK-MW application field and its working principle. This type of converter is used to step-down a high voltage input to a separate low voltage output. The concept behind it is simple and effective.The VI-BTK-MW application field and working principle involve the use of three primary components. The first component is a transformer, the second is a high-efficiency, high-frequency switch, and the third is a rectifier. Together, these components work together to convert a high voltage input to a lower voltage output. The transformer is the first primary component and plays an important role in the overall power conversion process. At its most basic level, the transformer acts as a buck-boost converter, or an inverter-rectifier. It takes a high voltage input and steps it down to a lower voltage output. The transformer also performs the function of bucking, which is inverting the voltage levels. The second primary component is the high-efficiency, high-frequency switch. This component is responsible for turning the converter on and off, to regulate the amount of power it produces. This is often done by switching the voltage level of the output. This helps to improve the overall efficiency of the converter. The third and final component is the rectifier. The rectifier is designed to convert the AC output of the transformer to a DC output. This is done by rectifying the AC signal, which consists of two flows of power - in and out. The rectifier then converts the AC signal to a DC output, which is then passed through the filter. These three primary components are the key elements in the VI-BTK-MW application field and working principle. Together, these components help to convert a high voltage input to a separate low voltage output. This technology is well established and has been used in a variety of different applications. The VI-BTK-MW application field is a great example of a reliable and efficient DC DC converter.

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