Classification of inductors/Comparison Table of Magnetic Core Material Properties
Introduction: An inductive coil is made up of wires wound one by one on an insulating tube, which is insulated from each other. The insulating tube can be hollow or contain an iron core or magnetic powder core, abbreviated as an inductor. It is represented by l and has units of Henry (h), milliHenry (mh), and microHenry (uh). 1h=10 ^ 3mh=10 ^ 6uh.
Inductive coil
Inductive coils are made up of wires wound one by one on an insulating tube, which is insulated from each other. The insulating tube can be hollow or contain an iron core or magnetic powder core, abbreviated as inductance. Represented by l, the units include Henry (h), milliHenry (mh), and microHenry (uh), with 1h=10 ^ 3mh=10 ^ 6uh.
1��、 Classification of inductors
Classified by inductance form: fixed inductance, variable inductance.
Classified by the properties of magnetic conductors: hollow core coils, ferrite coils, iron core coils, and copper core coils.
Classified by job nature: antenna coil, oscillation coil, choke coil, notch coil, deflection coil.
Classified by winding structure: single-layer coil, multi-layer coil, honeycomb coil.
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Comparison Table of Material Properties of Inductor Magnetic Core
Click: 29, Article entry date: 2008-05-05 00:15:22, Source: www.xhdz123.cn
Introduction: Performance Comparison Table of Inductor Magnetic Core Materials Iron Powder (Pure) Iron Powder Core Hi flux High flux Magnetic Powder Core Super Mss Iron Silicon Aluminum Magnetic Powder Core MPP Iron Nickel Molybdenum Magnetic Powder Core
Comparison Table of Material Properties of Inductor Magnetic Core
Iron powder
(Pure) iron powder core
Hi flush
High flux magnetic powder core
Super mss
Iron silicon aluminum magnetic powder core
MPP
Mpp Cores
Ferrite
Ferrite core
Basic composition of magnetic core materials
100% iron powder
50% nickel and 50% ferroalloy powder
85% iron, 9% silicon, and 6% aluminum alloy powder
81% nickel, 17% iron, 2% molybdenum alloy powder
Ceramic like composite of manganese zinc oxide and iron oxide
Air gap form
Distributed inside the magnetic core
Distributed inside the magnetic core
Distributed inside the magnetic core
Distributed inside the magnetic core
Discrete, individual air gap openings
The composition of the air gap itself
Organic and inorganic adhesives
Inorganic adhesive
Inorganic adhesive
Inorganic adhesive
air
The value of DC bias magnetic field when the magnetic permeability decreases to 50% under DC bias magnetic field
5600a/m (A/m)
70oe (Auster)
9500A/m (A/m)
120oe (Auster)
7200A/m (A/m)
9oe (Auster)
8000A/m (A/m)
10oe (Auster)
5600a/m (A/m)
70oe (Auster)
Typical Core Loss - Test Conditions at 100 kHz, 0.05 tesla Tesla (500 Gauss)
800
(MW/cm3)
260
(MW/cm3)
200
(MW/cm3)
120
(MW/cm3)
230
(MW/cm3)
Typical percentage change in magnetic permeability - in AC magnetic fields ranging from 0-0.4 Tesla (0-4000 Gauss)
260%
7%
-20%
-6%
-
Magnetic permeability range
3 to 100
14 to 160
26 to 125
14 to 350
Determined by the size of the air gap opening
Typical magnetic core loss, under testing conditions of 50 kHz and 0.05 tesla (MW/cm3)
330 (Permeability 75.)
170
(Permeability -125)
80
(Permeability -125)
55
(Permeability -125) is determined by the size of the air gap opening
Curie temperature (℃)
750 ℃
500 ℃
600 ℃
400 ℃
200 ℃
High working temperature (℃)
75-130 ℃
130 ℃ to 200 ℃
130 ℃ to 200 ℃
Core shape
Circular or ex type, etc
Circular shape
Ring type, e-type, can type, etc
Relative price level
low
high
secondary
high
secondary
Release time:2024-01-22
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