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Bill Dull | September 27,
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Power inductors can be used to filter the current or convert the Voltage and current to a different Voltage and current. Applications range from small electrical appliances to large power grid systems. Inductors consist of wound conductive metal coils that generate a magnetic field when electricity flows through them. Inductors are essential in any application that needs to carefully control electrical current.
Power Inductor Applications
Inductors have a variety of common applications, such as:
- Power Supply Filter: As one of the most straightforward applications for inductors, power supply filters (also known as chokes) must have a high enough level of inductance to keep current from dipping below the circuit’s minimum Voltage requirement at maximum load. The difficulty of calculating the appropriate inductance for power supply filters will vary based on the details of the intended application.
- EMI Filters in AC Inputs: In power supplies and electronic equipment, an EMI filter helps to keep internally generated noise contained within the device in question. Virtually any electrical equipment can function as a source of EMI. The inductive component of an EMI filter behaves as a low-frequency pass device for AC line frequencies.
- Noise Filters: Noise filters are generally used to remove noise spikes from the low frequency AC or DC currents that are entering or leaving your circuit. They smooth these currents.
- Energy Storage in DC-to-DC or AC-to-DC Converters: The input can be DC or a rectified AC signal that has not been filtered. The inductor stores energy in its magnetic field during the time the inductor input current is on. When the input current is turned off this stored energy is transferred to the output of the circuit. This cycle is repeated as needed to maintain the output. This property makes power supply circuits useful for DC-to-DC or AC-to-DC power converters.
How to Select a Custom Power Inductor
When selecting a custom power inductor, there are ten factors to keep in mind based on the intended use and the electrical specifications of the circuit.
- Application and Circuit: Charging inductors will require analysis of the circuit design/schematics, whereas filter inductors are easier to specify and only require identification of the type of circuit.
- Tolerance and Inductance: While off-the-shelf inductors typically allow a 20% inductance tolerance, a custom inductor should feature a lower tolerance of 10% to account for additional design complexity and demanding application variables.
- AC Frequency and Operating Voltage: AC power supply filters operate only at the AC power switching frequency, while other applications may vary more widely.
- DC Current: Determine the size of the DC current range required by the coil to ensure proper coil selection.
- DC Resistance (DCR): While not all inductors require DCR, any inductor that must operate at or near frequencies of 0 Hz (or if tolerances overlap 0 Hz) will need appropriate specification.
- Max Working Voltage and/or Dielectric Strength: Review application requirements to understand the maximum allowed Voltage of the inductor before dielectric breakdown will occur.
- Case Type: Establish the size and dimensions of the case to ensure the inductor will work within the design.
- Terminals: Take any associated terminals into account, like wire leads, turrets, lugs and more.
- Environmental Requirements: The conditions of the operating environment, such as ambient temperatures, humidity levels, altitude levels, and various other properties will help to specify the appropriate power inductor.
- Industry/Application Specifications: Power inductors are not universal. Select an inductor approved for use in the specific commercial, industrial, or military application of your industry.
Custom Designs Are Made Easy Through Triad's US Design Center
At Triad Magnetics, we've been offering premium magnetics solutions for more than 75 years. We offer more than 1,000 standard part designs in conjunction with advanced customization capabilities. For more information about specifying custom power inductors or any of our other solutions, please don’t hesitate to contact us today or download our eBook, Guide to Inductors.
Topics:
Inductors,
Power Inductor
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Inductors are a crucial component in electronic circuits, playing a vital role in filtering, impedance matching, and energy storage. With so many types of inductors available, selecting the right one for your circuit can be a daunting task. In this guide, we'll walk you through the key factors to consider when choosing an inductor, helping you make an informed decision for your design.
Understanding Inductor Types
Before diving into the selection process, it's essential to understand the different types of inductors available:
1. Air Core Inductors: These inductors have no magnetic core and are often used in high-frequency applications.
2. Ferrite Core Inductors: Ferrite core inductors use a magnetic core to increase inductance and are commonly used in power supplies and filters.
3. Iron Core Inductors: Iron core inductors use a magnetic core made of iron and are often used in high-current applications.
4. Toroidal Inductors: Toroidal inductors have a doughnut-shaped core and are used in applications where a high inductance value is required.
5. Chip Inductors: Chip inductors are surface-mount devices that offer high inductance values in a small package.
Key Factors to Consider
When selecting an inductor, consider the following factors:
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1. Inductance Value: Choose an inductor with the correct inductance value for your application. Inductance values range from a few nanohenries (nH) to several henries (H).
2. Current Rating: Select an inductor that can handle the maximum current required by your circuit.
3. Frequency Range: Choose an inductor that operates within the frequency range of your application.
4. DC Resistance: Consider the DC resistance of the inductor, as it can affect the overall efficiency of your circuit.
5. Physical Size: Select an inductor that fits within the physical constraints of your design.
6. Temperature Range: Choose an inductor that operates within the temperature range of your application.
7. Cost and Availability: Consider the cost and availability of the inductor, as well as any potential lead-time issues.
Additional Considerations
1. Saturation Current: Be aware of the saturation current of the inductor, as it can affect the overall performance of your circuit.
2. Shielding: Consider the shielding requirements of your inductor, as it can affect the overall electromagnetic compatibility (EMC) of your design.
3. Mounting: Select an inductor with a suitable mounting option, such as through-hole or surface-mount.
Conclusion
Choosing the right inductor for your circuit requires careful consideration of several factors. By understanding the different types of inductors available and considering key factors such as inductance value, current rating, and frequency range, you can select the optimal inductor for your design. Remember to also consider additional factors such as saturation current, shielding, and mounting to ensure the best possible performance.
Recommended Products
- Ferrite Core Inductors: Our ferrite core inductors offer high inductance values and are suitable for a wide range of applications.
- Chip Inductors: Our chip inductors are surface-mount devices that offer high inductance values in a small package.