EE Type Magnets Ferrite Core For Transformer Choke Inductance Inductor Filter

EE Type Magnets Ferrite Core For Transformer Choke Inductance Inductor Filter, PC40/ PC44 Soft Ferrite EE EF Cores, High Magnetic Permeability Ferrite EE EF Core Magnets, Soft Ferrite Transformer Cores w/o Plastic, EE MnZn Ferrite Core Iron Powder Core For Transformer, EE Type Soft Magnetic Core Mn-Zn Ferrite, E Core EE Core, Soft Ferrite Cores China Factory Supplier

EE Type Magnets Ferrite Core For Transformer Choke Inductance Inductor Filter Features
E/EF Ferrite Core
Model:EF Materials:MnZn
Certificate:ISO9001 ROHS CE Factory Location: Zhejiang China
Custom Made: Accepted MOQ: Small Quantity Accepted
Lead Time: Less than 20 days sample can be provided within 3 days
Package: Carton box on the Pallet
Shipment: Sea freight , Air freight, DHL Fedex

Product Name Soft Magnetic Mn-Zn Core EE Core
Type Soft
Serie Ee Serice
Color Black
Sample Free Sample
Tolerance ±1%
Model Number EE10 EE13 EE16 EE19 etc ferrite core
Material PC20/PC30/PC35/PC40,Mn-Zn Ferrite Core
Other Type EE/EC/EF/ETD/EEL/EPC/UU/PQ/EQ/EFD
Service Welding,Moulding,Bending,Cutting,Punching
Condition Brand New and Original
Surface Treatment Smooth
Application Industrial Magnet, high frequency transformer

E and EF ferrite cores are used in power transformers and low signal applications. These cores can be supplied with different air gaps, and AL values. They are made of different ferrite materials, mainly power materials. Two pieces of ferrite cores with or without air gap are set. Inductance factor AL depends on the size of the air gap in the middle leg.

Click to Download MnZn FERRITE CORE EE EF TYPE SIZE PDF

The main component in inductance design is the core structure where to be used for magnetic flux flow is provided. Air cores, iron cores, ferrite and powder cores are known inductance cores. Ferrite and powder cores are preferred for high switching frequency power converters having less loses and saturation. Ferrite cores are cheaper and have low power losses at higher switching frequencies but the flux level is lower. These cores are obtained from Mn-Zn and Ni-Zn alloys and have F, P, R, K types depending on the alloy’s ratios . Also, the air gap in cores makes it preferable against the saturation.
Powder cores have an air gap dispersed in the material due to the nature of the material from which they are produced, and this feature is ideal for switching rectifiers. In addition to a soft saturation characteristic, this feature provides a lot of design convenience, such as small core volume, overcurrent protection, low heat, and powder cores provide high levels of DA magnetic force characteristics without saturation.  EE EF Ferrite Core Transformer Magnet

The energy harvesting from renewables, and also using it more efficient is an important topic for the scientific researchers today. The power electronics circuits and devices are the main parts for renewable energy applications and also to be storable the energy efficiently. The scientific researchers are focused on design and control of the converters, and also increases the efficiency of the power electronic circuit’s components.

One of the main components of the power electronics circuits is inductances. The electrical energy is stored in the inductance temporarily in switch mode power converters. The inductance; which is like the heart in a human which storage and pump the blood, the storage the energy temporarily and pumps the energy from the source to load in switch mode converters, and supply continuously and the circuit current on the load . PC40/ PC44 Soft Ferrite EE EF Cores

The energy efficiency of converters depends of course on the inductance efficiency. So a well-designed inductance is very important for the converter in continuous mode operation and continues the current to flow uninterrupted. The inductance value determines how to operate the converter under load

E cores are more advantageous in terms of core, coil and winding prices and easy to use, also with cross-sectional area and window spacing of different sizes. E cores have a double flux path which reduces their dimensions and this allows for small footprint and easy installation on printed circuits. E cores air gap can be adjusted, but the fringe fluxes formed in cores with air gap lead to flow losses and eddy current (Eddy) losses on winding wires.