Magnetics Ferrite Cores

Physical Dimensions Part Number Dimension ﹙mm﹚ A B C D E F EC411324-060-XXX 41.0±0.7 30.0MIN 13.1+0/-0.4 12.9±0.2 16.9+0.6 24.2±0.3 EC421521-060-XXX 42.0±0.5 30.5MIN 15.2±0.3 15.2±0.3 15.4±0.3 21.4±0.3 EC441525-060-XXX 44.0±0.6 32.8MIN 14.8±0.3 14.8±0.3 19.7±0.3 25.3±0.3 EC451818-060-XXX 45.0±1.0 33.0+1.6/-0 18.0+0/-0.8 18.0+0/-0.8 10.5+0.5 17.5+0/0.4 EC461523-060-XXX 45.9±0.5 34.5MIN 15.3±0.3 15.3±0.3 17.4±0.2 23.4±0.2 EC471523-060-XXX 47.0±0.4 33.0MIN 15.0±0.3 15.0±0.3 16.4

Type Dimension﹙mm﹚ A B C Dmin Emin F L EE19/8/5 19.3±0.3 8.15±0.1 4.78±0.1 5.5 13.9 4.78±0.1 2.4 EE25/10/7 25.4±0.4 9.53±0.15 6.35±0.1 6.2 18.8 6.35±0.1 3.2 EE30/15/7 30.05±0.45 15.0±0.2 7.06±0.1 9.7 19.5 6.96±0.1 5.1 EE35/14/9 34.5±0.5 14.1±0.2 9.35±0.15 9.6 25.3 9.3±0.15 4.4 EE41/17/13 40.9±0.6 16.5±0.25 12.5±0.2 10.4 28.3 12.5±0.2 6 EE43/21/11 42.85±0.65 21.1±0.3 10.8±0.25 15 30.4 11.9±0.2 5.9 EE43/21/15 42.85±0.65 21.1±0.3 15.4±0.25 15 30.4 11.9±0.2 5.9 EE43/21/20 42.85±0

Type Dimension﹙mm﹚ A B C Dmin Emin F L EE19/8/5 19.3±0.3 8.15±0.1 4.78±0.1 5.5 13.9 4.78±0.1 2.4 EE25/10/7 25.4±0.4 9.53±0.15 6.35±0.1 6.2 18.8 6.35±0.1 3.2 EE30/15/7 30.05±0.45 15.0±0.2 7.06±0.1 9.7 19.5 6.96±0.1 5.1 EE35/14/9 34.5±0.5 14.1±0.2 9.35±0.15 9.6 25.3 9.3±0.15 4.4 EE41/17/13 40.9±0.6 16.5±0.25 12.5±0.2 10.4 28.3 12.5±0.2 6 EE43/21/11 42.85±0.65 21.1±0.3 10.8±0.25 15 30.4 11.9±0.2 5.9 EE43/21/15 42.85±0.65 21.1±0.3 15.4±0.25 15 30.4 11.9±0.2 5.9 EE43/21/20 42.85±0

Type Dimension﹙mm﹚ A B C Dmin Emin F L EE19/8/5 19.3±0.3 8.15±0.1 4.78±0.1 5.5 13.9 4.78±0.1 2.4 EE25/10/7 25.4±0.4 9.53±0.15 6.35±0.1 6.2 18.8 6.35±0.1 3.2 EE30/15/7 30.05±0.45 15.0±0.2 7.06±0.1 9.7 19.5 6.96±0.1 5.1 EE35/14/9 34.5±0.5 14.1±0.2 9.35±0.15 9.6 25.3 9.3±0.15 4.4 EE41/17/13 40.9±0.6 16.5±0.25 12.5±0.2 10.4 28.3 12.5±0.2 6 EE43/21/11 42.85±0.65 21.1±0.3 10.8±0.25 15 30.4 11.9±0.2 5.9 EE43/21/15 42.85±0.65 21.1±0.3 15.4±0.25 15 30.4 11.9±0.2 5.9 EE43/21/20 42.85±0

Type Dimension﹙mm﹚ A B C Dmin Emin F L EE19/8/5 19.3±0.3 8.15±0.1 4.78±0.1 5.5 13.9 4.78±0.1 2.4 EE25/10/7 25.4±0.4 9.53±0.15 6.35±0.1 6.2 18.8 6.35±0.1 3.2 EE30/15/7 30.05±0.45 15.0±0.2 7.06±0.1 9.7 19.5 6.96±0.1 5.1 EE35/14/9 34.5±0.5 14.1±0.2 9.35±0.15 9.6 25.3 9.3±0.15 4.4 EE41/17/13 40.9±0.6 16.5±0.25 12.5±0.2 10.4 28.3 12.5±0.2 6 EE43/21/11 42.85±0.65 21.1±0.3 10.8±0.25 15 30.4 11.9±0.2 5.9 EE43/21/15 42.85±0.65 21.1±0.3 15.4±0.25 15 30.4 11.9±0.2 5.9 EE43/21/20 42.85±0

Type Dimension﹙mm﹚ A B C Dmin Emin F L EE19/8/5 19.3±0.3 8.15±0.1 4.78±0.1 5.5 13.9 4.78±0.1 2.4 EE25/10/7 25.4±0.4 9.53±0.15 6.35±0.1 6.2 18.8 6.35±0.1 3.2 EE30/15/7 30.05±0.45 15.0±0.2 7.06±0.1 9.7 19.5 6.96±0.1 5.1 EE35/14/9 34.5±0.5 14.1±0.2 9.35±0.15 9.6 25.3 9.3±0.15 4.4 EE41/17/13 40.9±0.6 16.5±0.25 12.5±0.2 10.4 28.3 12.5±0.2 6 EE43/21/11 42.85±0.65 21.1±0.3 10.8±0.25 15 30.4 11.9±0.2 5.9 EE43/21/15 42.85±0.65 21.1±0.3 15.4±0.25 15 30.4 11.9±0.2 5.9 EE43/21/20 42.85±0

Advantages 1. High Magnetic Permeability: The EP-type Mn-Zn power core has a high magnetic permeability, which ensures efficient electromagnetic energy conversion under low magnetic field strength. This helps to enhance the performance of electronic devices, especially in high-frequency power converters, filters, and isolation transformers within power electronic equipment. 2. Low Loss: This type of core exhibits low losses, particularly in high-frequency applications,

Advantages 1. High Magnetic Permeability: The EP-type Mn-Zn power core has a high magnetic permeability, which ensures efficient electromagnetic energy conversion under low magnetic field strength. This helps to enhance the performance of electronic devices, especially in high-frequency power converters, filters, and isolation transformers within power electronic equipment. 2. Low Loss: This type of core exhibits low losses, particularly in high-frequency applications,

Advantages 1. High Magnetic Permeability: The EP-type Mn-Zn power core has a high magnetic permeability, which ensures efficient electromagnetic energy conversion under low magnetic field strength. This helps to enhance the performance of electronic devices, especially in high-frequency power converters, filters, and isolation transformers within power electronic equipment. 2. Low Loss: This type of core exhibits low losses, particularly in high-frequency applications,

Type Dimension﹙mm﹚ A B C Dmin Emin F L EE19/8/5 19.3±0.3 8.15±0.1 4.78±0.1 5.5 13.9 4.78±0.1 2.4 EE25/10/7 25.4±0.4 9.53±0.15 6.35±0.1 6.2 18.8 6.35±0.1 3.2 EE30/15/7 30.05±0.45 15.0±0.2 7.06±0.1 9.7 19.5 6.96±0.1 5.1 EE35/14/9 34.5±0.5 14.1±0.2 9.35±0.15 9.6 25.3 9.3±0.15 4.4 EE41/17/13 40.9±0.6 16.5±0.25 12.5±0.2 10.4 28.3 12.5±0.2 6 EE43/21/11 42.85±0.65 21.1±0.3 10.8±0.25 15 30.4 11.9±0.2 5.9 EE43/21/15 42.85±0.65 21.1±0.3 15.4±0.25 15 30.4 11.9±0.2 5.9 EE43/21/20 42.85±0

Advantages High Magnetic Permeability: UYF-type MnZn power cores have a high magnetic permeability, which can effectively convert the conversion efficiency between electrical energy and magnetic energy. This makes them excellent in applications that require efficient energy transmission and conversion. Low Coercivity: These cores have low coercivity, meaning they can quickly achieve magnetization and demagnetization under the action of an external magnetic field. This

Advantages High Magnetic Permeability: UYF-type MnZn power cores have a high magnetic permeability, which can effectively convert the conversion efficiency between electrical energy and magnetic energy. This makes them excellent in applications that require efficient energy transmission and conversion. Low Coercivity: These cores have low coercivity, meaning they can quickly achieve magnetization and demagnetization under the action of an external magnetic field. This

Advantages High Magnetic Permeability: UYF-type MnZn power cores have a high magnetic permeability, which can effectively convert the conversion efficiency between electrical energy and magnetic energy. This makes them excellent in applications that require efficient energy transmission and conversion. Low Coercivity: These cores have low coercivity, meaning they can quickly achieve magnetization and demagnetization under the action of an external magnetic field. This

Advantages High Magnetic Permeability: EEC-type MnZn power cores have high magnetic permeability, which can effectively convert the conversion efficiency between electrical energy and magnetic energy. Low Loss: In high-frequency applications, the loss of EEC-type MnZn power cores is relatively low, which helps to improve the efficiency of the equipment. Good Temperature Stability: EEC-type MnZn power cores have good temperature stability and can maintain stable magnetic

Advantages: High Saturation Magnetic Induction Intensity: The US-type MnZn power magnetic strip has a high saturation magnetic induction intensity, which means that efficient electromagnetic energy conversion can be achieved under the action of a lower magnetic field, enabling more magnetic energy to be stored and converted in a smaller volume and weight. Low Loss: It has relatively low loss, which helps to improve the energy efficiency of the equipment and reduce energy

Advantages: High Saturation Magnetic Induction Intensity: The US-type MnZn power magnetic strip has a high saturation magnetic induction intensity, which means that efficient electromagnetic energy conversion can be achieved under the action of a lower magnetic field, enabling more magnetic energy to be stored and converted in a smaller volume and weight. Low Loss: It has relatively low loss, which helps to improve the energy efficiency of the equipment and reduce energy

Advantages: High Saturation Magnetic Induction Intensity: The US-type MnZn power magnetic strip has a high saturation magnetic induction intensity, which means that efficient electromagnetic energy conversion can be achieved under the action of a lower magnetic field, enabling more magnetic energy to be stored and converted in a smaller volume and weight. Low Loss: It has relatively low loss, which helps to improve the energy efficiency of the equipment and reduce energy

Advantages: High Saturation Magnetic Induction Intensity: The US-type MnZn power magnetic strip has a high saturation magnetic induction intensity, which means that efficient electromagnetic energy conversion can be achieved under the action of a lower magnetic field, enabling more magnetic energy to be stored and converted in a smaller volume and weight. Low Loss: It has relatively low loss, which helps to improve the energy efficiency of the equipment and reduce energy

Advantages: High Saturation Magnetic Induction Intensity: The US-type MnZn power magnetic strip has a high saturation magnetic induction intensity, which means that efficient electromagnetic energy conversion can be achieved under the action of a lower magnetic field, enabling more magnetic energy to be stored and converted in a smaller volume and weight. Low Loss: It has relatively low loss, which helps to improve the energy efficiency of the equipment and reduce energy

Advantages High Saturation Magnetic Flux Density: QP-type manganese-zinc power magnetic strips have a high saturation magnetic flux density, allowing them to generate a strong magnetic field within a smaller volume. This is crucial for enhancing the performance and efficiency of electronic devices. Low Loss: This type of magnetic strip experiences relatively low losses during energy conversion, enabling more effective use of electrical energy and reducing energy loss. This