Allicdata Part #: | IRF36ER471K-ND |
Manufacturer Part#: |
IRF36ER471K |
Price: | $ 0.07 |
Product Category: | Inductors, Coils, Chokes |
Manufacturer: | Vishay Dale |
Short Description: | IRF-36 470 10% ER E3 |
More Detail: | 470µH Unshielded Inductor 126mA 7.7 Ohm Max Axial |
DataSheet: | IRF36ER471K Datasheet/PDF |
Quantity: | 1000 |
5000 +: | $ 0.06048 |
Q @ Freq: | 60 @ 796kHz |
Height - Seated (Max): | -- |
Size / Dimension: | 0.157" Dia x 0.394" L (4.00mm x 10.00mm) |
Supplier Device Package: | Axial |
Package / Case: | Axial |
Mounting Type: | Through Hole |
Features: | -- |
Inductance Frequency - Test: | 796kHz |
Operating Temperature: | -20°C ~ 105°C |
Ratings: | -- |
Frequency - Self Resonant: | 2.25MHz |
Series: | IRF-36 |
DC Resistance (DCR): | 7.7 Ohm Max |
Shielding: | Unshielded |
Current - Saturation: | -- |
Current Rating: | 126mA |
Tolerance: | ±10% |
Inductance: | 470µH |
Material - Core: | Ferrite |
Type: | -- |
Part Status: | Active |
Packaging: | -- |
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
Fixed inductors are commonly used in electronic circuits to store and release energy in the form of a magnetic field. The IRF36ER471K inductor is a popular component used in modern electronics. It is a surface mountable, three layer capacitive-type inductor with a maximum rated current of 420mA. This component is suitable for a variety of high-frequency applications and can be used in a variety of products. In this article, we will discuss the application field and working principle of the IRF36ER471K inductor.
The primary application of the IRF36ER471K inductor is in high-frequency circuits. It can be used in circuit designs that require high-frequency switching, high-frequency measuring and high-frequency filtering. It is also suitable for high-frequency amplification. The inductor offers excellent input/output performance, excellent reliability and a wide range of DC resistance values. Its low resistance to AC signal helps ensure high efficiency and low power consumption in digital systems.
The working principle of the IRF36ER471K inductor is based on the principle of inductance. Inductance is basically the property of a conductor whereby a voltage is induced in it when it is exposed to a changing magnetic field. The inductor, when connected to an AC voltage, reacts to the electrical current by creating its own magnetic field and thus inducing a voltage in the inductor. This induced voltage creates a current in the circuit which is proportional to the applied voltage.
The construction of the IRF36ER471K inductor is three-layer with a nickel-plated steel core. A dielectric material is then added between the layers in order to provide uniform magnetic field distribution throughout the components. This helps to ensure optimal operation of the component especially when placed in densely populated circuits.
In order to further improve the performance of the IRF36ER471K inductor, it is necessary to use a suitable heat sink depending on the power requirements of the circuit. The heat sink reduces the thermal impedance of the components and improves the inductive efficiency of the device. Additionally, the heat sink helps to increase the lifetime of the inductor.
The IRF36ER471K inductor is highly reliable and can be used in circuits that operate in a wide range of temperature environments. In order to ensure the longevity of the component, it is recommended to keep it within the recommended temperature range. Additionally, the inductor should also be kept away from sources of magnetic interference such as transformers and relay circuits.
The IRF36ER471K inductor is a versatile component that can be used in a variety of different applications such as high-frequency switching, high-frequency measuring, high-frequency filtering, high-frequency amplification, etc. Its high reliability renders it suitable for electronic products that need to operate in a range of different electrical environments. The use of a suitable heat sink helps to further improve its performance and ensure its longevity.
The specific data is subject to PDF, and the above content is for reference
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