Allicdata Part #: | VI-JNP-IW-B1-ND |
Manufacturer Part#: |
VI-JNP-IW-B1 |
Price: | $ 0.00 |
Product Category: | Power Supplies - Board Mount |
Manufacturer: | Vicor Corporation |
Short Description: | DC DC CONVERTER 13.8V 100W |
More Detail: | Isolated Module DC DC Converter 1 Output 13.8V ... |
DataSheet: | VI-JNP-IW-B1 Datasheet/PDF |
Quantity: | 1000 |
1 +: | 0.00000 |
Current - Output (Max): | 7.25A |
Base Part Number: | VI-JNP |
Size / Dimension: | 2.36" L x 2.28" W x 1.08" H (59.9mm x 57.9mm x 27.4mm) |
Package / Case: | Half Brick |
Mounting Type: | Through Hole |
Efficiency: | 90% |
Operating Temperature: | -40°C ~ 100°C |
Features: | OCP, SCP |
Applications: | ITE (Commercial) |
Voltage - Isolation: | 3kV |
Power (Watts): | 100W |
Series: | VI-J00™ |
Voltage - Output 3: | -- |
Voltage - Output 2: | -- |
Voltage - Output 1: | 13.8V |
Voltage - Input (Max): | 76V |
Voltage - Input (Min): | 36V |
Number of Outputs: | 1 |
Type: | Isolated Module |
Part Status: | Active |
Packaging: | Bulk |
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DC-DC converters are widely used in various applications. They can be used to convert the energy stored in batteries into useful electrical power, to convert DC voltages from one power source to another, and to supply different voltage levels to different systems. VI-JNP-IW-B1 DC-DC converter is a series of advanced, fully regulated DC-DC converters that use Buck, Boost, and Buck-Boost topologies.
VI-JNP-IW-B1 Application Field
VI-JNP-IW-B1 DC-DC converters are mainly used to convert low voltage DC input levels to higher voltage DC output levels. This is especially useful in applications such as distributed power systems, automotive/motor control, solar cell/power supply, and battery-operated systems. VI-JNP-IW-B1 DC-DC converters are also ideal for multi-voltage applications, where multiple outputs are needed from a single input voltage.
Working Principle
VI-JNP-IW-B1 DC-DC converter is based on Buck, Boost, and Buck-Boost topologies. Buck topology is used to drop the input voltage to produce an output voltage that is lower than the input voltage. Boost topology is used to increase the output voltage, while Buck-Boost topology is used to produce an output voltage that is either higher or lower than the input voltage.
Buck topology consists of an inductor, a diode, and a switch. The inductor limits the current flow, while the diode prevents current to flow back into the input. The switch is used to control the current flow and the voltage output. During the first half of the switching cycle, the switch is closed and the current through the inductor increases. When the switch is open, the current stored in the inductor is then used to recharge the output (lower-voltage) capacitor.
Boost topology includes an inductor, a diode, and a switch just like the Buck topology. However, the switch is used to control the current flow in the opposite direction. During the first half of swap cycle, the switch is open, allowing the current to flow through the inductor and capacitor and charging the capacitor at a higher voltage. During the second half of the cycle, the switch is closed, allowing the current to flow to the output. As the current flows through the inductor, the voltage on the capacitor is stepped up to produce a higher output voltage.
Buck-Boost topology has two components that are used to step-up or step-down the voltage while regulating the current. These components are a inductor, a diode, and a switch. When the switch is closed, the current flows through the inductor and diode, and the voltage output is increased or decreased. When the switch is open, the current is stored in the inductor, and the current is then used to recharge the output capacitor.
VI-JNP-IW-B1 converters are used in many applications, ranging from distributed power systems to solar cell power supplies. The Buck, Boost, and Buck-Boost topologies enable the converters to produce higher or lower voltage outputs, while maintaining a constant current. This makes them ideal for constant voltage operation and optimization of energy efficiency.
The specific data is subject to PDF, and the above content is for reference
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