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| Place of Origin: | CHINA |
| Brand Name: | IKP |
| Certification: | CE/UL/REACH/ROHS |
| Model Number: | PM27/17 |
| Minimum Order Quantity: | 1000 |
|---|---|
| Price: | 0.09-1.1 |
| Packaging Details: | Carton |
| Delivery Time: | 10-15 days |
| Payment Terms: | L/C, T/T |
| Supply Ability: | 100,000/week |
Advantages:
High Magnetic Permeability: PM-type MnZn power ferrite cores have a high magnetic permeability, which enables more efficient conversion between electrical and magnetic energy.
Low Loss: These cores exhibit low losses during operation, contributing to improved device efficiency.
High Curie Temperature: The Curie temperature of PM-type MnZn power ferrite cores is relatively high, allowing them to maintain stable magnetic properties over a wide temperature range.
High Electrical Resistivity: The higher electrical resistivity helps reduce eddy current losses, especially in high-frequency applications.
Good Frequency Characteristics: They possess a good frequency response range, making them suitable for high-frequency power converters, filters, and isolation transformers in power electronic devices.
Application Areas:
Electronic Products: PM-type MnZn power ferrite cores are widely used in various electronic products such as power supplies for program-controlled exchanges, liquid crystal display (LCD) screens, high-power UPS inverters, computer power supplies, and energy-saving lamps.
Communication Equipment: In communication equipment, they serve as high-frequency transformers, filters, and other components for signal amplification and filtering functions.
Power Electronics: In the field of power electronics, PM-type MnZn power ferrite cores are used in transformers, inductors, and other components to facilitate power transmission and conversion.
New Energy Fields: With the rapid development of new energy vehicles and charging stations, the application of PM-type MnZn power ferrite cores in automotive charging piles is becoming increasingly widespread. Due to their cost advantages and good compatibility, they are being used to replace traditional permanent magnet materials, helping to achieve better component performance.
Fig.1 Fig.2
| Specification | Figure | Dimension(mm) | Effective parameter | Inductor coefficient AL(nH/N2) | Weight | |||||||||
| A | B | C | D | E | F | G | Ae(mm2) | Le(mm) | Ve(mm3) | BP44 | BP95 | (grams/pair) | ||
| PM22.5 | 2 | 22.50±0.40 | 9.10±0.15 | 15.00±0.3 | 9.4±0.20 | 18.30min | 6.0±0.20 | 13.0min | 73.2 | 42.1 | 3081.7 | 3600±25% | 4500±25% | 18.20 |
| PM27/17 | 2 | 27.00±0.40 | 8.85±0.15 | 18.00±0.3 | 11.0±0.20 | 22.0+0.5/-0.3 | 5.85±0.20 | 17.1±0.40 | 95.6 | 43.0 | 4110.8 | 5600±25% | 7000±25% | 24.40 |
| PM62/49 | 1 | 61.00±1.00 | 24.3±0.30 | 25.10±0.6 | 5.55±0.30 | 48.80min | 17.0±0.30 | 29.0min | 570 | 108.8 | 62000.0 | 9700±25% | 14400±25% | 357.0 |
| PM74/59 | 1 | 72.50±1.50 | 29.50±0.30 | 29.00±1.00 | 5.40±0.30 | 57.50min | 20.5±0.30 | 34.0min | 790 | 128.0 | 101120.0 | 11000±25% | 15500±25% | 601.0 |
Note:
The test conditions for AL value are: 1KHz, 0.3V, and 10Ts.
The above are the standard specifications of our company, and they can be designed according to the special requirements of customers.
