*The coil has a strong heat dissipation capacity

*The coil can be wound by equipment

*Minimize the DC resistance

*The height contrast is relatively lower

*Initial inductance:115uH~335uH

*DC BIAS：

Current：@20A~105A

Inductance：48uH~156uH

*The cost of magnetic core ferrite is relatively low

*Inductance：60uH

*Provide a path with high magnetic permeability to guide magnetic leakage

*Suppress eddy current loss and local heating to optimize EMI performance

*Initial inductance:200uH~380uH

*DC BIAS：

Current：@50A

Inductance：60uH~140uH

*The coil has a strong heat dissipation capacity

*Can be produced automatically

*Minimize DC resistance

*The cost of mold pressing is low

*Initial inductance:180uH~335uH

*DC BIAS：

Current：@40A~85A

Inductance：60uH~140uH

*Air cooling scheme

*Power density improvement

*Volume reduction

*Cost reduction

*Initial inductance:300uH

*DC BIAS：

Current：@25A

Inductance：185uH

*The coil has a strong heat dissipation capacity

*Coils can be wound by equipment

*Minimize DC resistance

*The anti-saturation ability is enhanced

*Initial inductance:170uH~335uH

*DC BIAS：

Current：@20A~85A

Inductance：60uH~156uH

*Air cooling scheme

*The magnetic core has a strong heat dissipation capacity

*The cost of mold pressing is low

*Ultimate high-frequency loss control

*EMI suppression design with relatively high space utilization

*Initial inductance:170uH~335uH

*DC BIAS：

Current：@20A~85A

Inductance：60uH~156uH

*Higher thermal conductivity

*Higher power density

*Higher reliability and longer lifespan

*Significantly reduce noise

*Comply with the requirements of the CLASS F insulation system

*Initial inductance:480uH

*DC BIAS：

Current：@67A~81A

Inductance：180uH~270uH