VI-261-IX-F4

Current - Output (Max):	6.25A
Size / Dimension:	4.60" L x 1.86" W x 1.05" H (116.8mm x 47.2mm x 26.7mm)
Package / Case:	Full Brick
Mounting Type:	Through Hole
Efficiency:	90%
Operating Temperature:	-40°C ~ 85°C
Features:	OCP, OTP, OVP, SCP
Applications:	ITE (Commercial)
Voltage - Isolation:	3kV
Power (Watts):	75W
Series:	VI-200™
Voltage - Output 3:	--
Voltage - Output 2:	--
Voltage - Output 1:	12V
Voltage - Input (Max):	400V
Voltage - Input (Min):	200V
Number of Outputs:	1
Type:	Isolated Module
Part Status:	Active
Packaging:	Bulk

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Introduction to the VI-261-IX-F4 DC DC Converter DC DC converters are used in a variety of applications, from powering lasers to providing stability in distributed power systems. The VI-261-IX-F4 DC DC converter is a microprocessor-controlled DC DC converter that is designed to deliver an output voltage range of 0-320V, with a maximum input voltage of 36V. It has a high efficiency (93% at full load) and a low stand-by power consumption of 10mW.Architecture of the VI-261-IX-F4 DC DC Converter The VI-261-IX-F4 uses a flyback topology to convert an input voltage into DC output. The module consists of a high-frequency switching power supply containing an iron core, collector, rectifier diode, switching transistor, boost inductor, and control circuitry. When a current is applied to the collector, it turns on the switching transistor, which generates a voltage across the boost inductor. This voltage is then rectified by the rectifier diode. The boost inductor also provides a return current path to the input, thereby helping to reduce losses and ensure a constant input voltage. Working Principle of the VI-261-IX-F4 DC DC Converter The VI-261-IX-F4 DC DC converter works on the principle of on-off control. A microprocessor or analog controller is used to control the switch operation, thus enabling the converter to convert an input voltage into an output voltage. Initially, the converter is turned off. When the input voltage exceeds an upper limit, the converter is turned on and the output voltage is raised. The output voltage is then maintained for a certain duration before the converter is turned off again. The duration for which the converter is maintained in the on state is determined by the microprocessor or analog controller.Features of the VI-261-IX-F4 DC DC ConverterThe VI-261-IX-F4 DC DC converter has a variety of features that make it suitable for a wide range of applications. One of its main features is a high efficiency (up to 93%) at full load. Another feature is its low stand-by power consumption of 10mW. It also has a wide output voltage range of 0-320V, with a maximum input voltage of 36V. The VI-261-IX-F4 DC DC converter also has an advanced circuit design for improved heat dissipation and stability. It is also provided with protection against short circuiting, over-voltage, and overheating.Applications of the VI-261-IX-F4 DC DC Converter The VI-261-IX-F4 DC DC converter has a wide range of applications. It is suitable for use in distributed power systems, where it can maintain a stable output voltage and help reduce power loss. It can also be used to power devices such as medical monitors, communications systems, portable electronic devices, and transportation systems. Additionally, the VI-261-IX-F4 converter can be used to power lasers, allowing for higher output power levels with less power consumption. Conclusion The VI-261-IX-F4 DC DC converter is a microprocessor-controlled converter designed to deliver an output voltage range of 0-320V, with a maximum input voltage of 36V. It has a high efficiency of up to 93% at full load, and a low stand-by power consumption of 10mW. The VI-261-IX-F4 features an advanced circuit design for improved heat dissipation and stability, as well as protection against short circuiting, overvoltage, and overheating. The VI-261-IX-F4 is suitable for use in distributed power systems, powering medical monitors, communication systems, portable electronic devices, transportation systems, and lasers.

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