Nanocrystalline Tape Wound Cores
Iron-Based nanocrystalline materials have enjoyed increased acceptance in modern electronic designs only in the past few years. Nanocrystalline materials have a proven record of high performance, there has been improved reliability in the manufacturing process and this material is now available from multiple sources.
Nanocrystalline soft magnetic materials are now superior to permalloys, ferrites and even amorphous cobalt based alloys in a growing range of applications. The table below identifies different properties of the various soft magnetic materials that are available today.
Click here for recent blog postings tagged "Magnetec"
Click here for datasheets and documentation
Magnetec Information Paper: Smart Grid Technology New!
Cool Blue for Inverter Drive Motor Systems
A primary application is common mode chokes specifically designed to reduce EMI voltage spikes in Inverter Drive Motor Systems. Read more about Cool Blue® Cores for Inverter Drive Motor Systems
Interview with Magnetec's Hans-Joachim Pöss discussing CoolBlue cores and their applications:
Cores for EMI Filters
Another primary application for the nanocrystalline material so far is common mode chokes for EMI Off-line (Mains) filters for any kind of switched mode power converters and inverter drives. Here the most significant design consideration is the reduction of build volume achieved because of both relevant material parameters (permeability and flux swing) are significantly higher then with Ferrite. Read more about Nanoperm® Cores for EMI Filters
For complete details and reference materials, see also: http://magnetec.mhw-intl.com.
| General Specifications: | |
|---|---|
| Saturation Flux Density | 1,200 mT |
| Permeability | 25,000—90,000 @ 10KHz |
| Saturation Magnetostriction | < 0.5 ppm |
| Spec. Electrical Resistivity | 115 µΩcm |
| Density | 7.35 g/cm³ |
| Curie Temperature | 600°C |
| Max. Operating Temperature | 120°C |
| Core Losses (100KHz, 300mT, sine wave) | > 110 W/kg |
| Alloy Composition | Fe:73.5,Cu:1,Nb:3,Si:15.5,B:7 |
| Nanocrystalline vs. other alloys | ||||||
|---|---|---|---|---|---|---|
| Material | Alloy Composition |
Strip Thickness |
Losses | Saturation Bsat |
Magneto- striction |
Permeability |
| µm | 20KHz 200mT W/Kg |
mT | λs 10-6 |
50Hz | ||
| Nanocrystalline Alloys | FE 73 (Si,B) 24 |
20 | 4 | 1,200 | 0.1 | 20,000-200,000 |
| Standard Crystalline Permalloy | Ni 60 Fe 40 |
50 | 45 | 1,200 | 10 | 20,000-30,000 |
| Advanced Crystalline Alloy | Fe 93.5 Si 6.5 |
50 | 40 | 1,300 | 0.1 | 16,000 |
| Amorphous Alloys | FE 76 (Si,B) 24 |
25 | 18 | 1,500 | 25 | 6,500-8,000 |
| High Performance Ferrite | MnZn | - | 17 | 50 | - | 1,000-30,000 |
| Advanced Crystalline Permalloy | NI 80 FE 20 |
30 | 14 | 800 | 1 | 100,000-300,000 |
| Amorphous Alloy IIa | Co 73 (Si,B) 27 |
25 | 5 | 550 | < 0.2 | 100,000-150,000 |
| Amorphous Alloy IIb | Co 77 (Si,B) 23 |
25 | 6.5 | 1,000 | < 0.2 | 2,000-4,500 |
| Amorphous Alloy IIc | Co 80 (Si,B) 20 |
25 | 6.5 | 1,000 | < 0.2 | 1,000-2,500 |
Applications
By variation of the annealing parameters, the required properties such as shape of the B/H-Loop and permeability can be adjusted in a wide range (See figure below). As a result, the spectrum of applications in power electronics ranges from chokes and filters to power transformers.
Benefits
Nanocrystalline over ferrite or permalloy: |
Secondary mainstream applications: |
|---|---|
|
|
For complete details and reference materials, see also: http://magnetec.mhw-intl.com.
