magnetic components
magnetic components
The Conductor
Selection and Use Directions for Magnet Wire
Selection and Use Directions for Magnet Wire
Wire for winding used in electrical equipment is generally called magnet wire. Simply put, "Magnet wire is used for interchanging electrical energy with magnetic energy".
Magnet wires are broadly divided into enamelled wire (coating insulation), covered conductor wire (fiber/film insulation), and combinations thereof.
Both magnet wire types as well as their performance are quite varied.
In electrical conductors, the "skin effect" causes alternating currents (AC) to flow mostly near the surface, or "skin," of the conductor. This happens because, at higher frequencies, the interior of the conductor generates opposing magnetic fields, pushing the current toward the surface. As a result, the effective cross-sectional area through which current flows is reduced, increasing the conductor's effective resistance. In essence, the skin effect makes it harder for the current to flow smoothly through the whole conductor at higher frequencies
With proper Litz wire design, it is possible to minimize both types of skin effect losses. Strand level skin effect losses can be minimized by selecting an individual strand size whose diameter is smaller than two times the skin depth at the operating frequency, or the effective frequency in the case of non-sinusoidal currents. On this page is the calculator for calculating the skin depth.
Use the Litze Calculator to bundle the wires and calculate the fill factor.(OD of bundle litz
Magnet wires are broadly divided into enamelled wire (coating insulation), covered conductor wire (fiber/film insulation), and combinations thereof.
Both magnet wire types as well as their performance are quite varied.
In electrical conductors, the "skin effect" causes alternating currents (AC) to flow mostly near the surface, or "skin," of the conductor. This happens because, at higher frequencies, the interior of the conductor generates opposing magnetic fields, pushing the current toward the surface. As a result, the effective cross-sectional area through which current flows is reduced, increasing the conductor's effective resistance. In essence, the skin effect makes it harder for the current to flow smoothly through the whole conductor at higher frequencies
With proper Litz wire design, it is possible to minimize both types of skin effect losses. Strand level skin effect losses can be minimized by selecting an individual strand size whose diameter is smaller than two times the skin depth at the operating frequency, or the effective frequency in the case of non-sinusoidal currents. On this page is the calculator for calculating the skin depth.
Use the Litze Calculator to bundle the wires and calculate the fill factor.(OD of bundle litz
Technisch Adviesbureau Soetens
Best
info @ tas.industries
Brainport Eindhoven
Best
info @ tas.industries
Brainport Eindhoven
High frequency transformer
CMC DMC and filter inductors.
Power Factor correction.
High-frequency inductors
low-frequency power line inductors
specially designed inductors for decoupling and filter applications.
Ferrite / Nanocrystalline / Powder Material
Application onboard charger for electric Vehicels, line and noise filter exc.
CMC DMC and filter inductors.
Power Factor correction.
High-frequency inductors
low-frequency power line inductors
specially designed inductors for decoupling and filter applications.
Ferrite / Nanocrystalline / Powder Material
Application onboard charger for electric Vehicels, line and noise filter exc.
Technisch Adviesbureau Soetens
Best
info @ tas.industries
Brainport Eindhoven
Best
info @ tas.industries
Brainport Eindhoven