Berechnung der Ringkerne

FERRITRINGKERNE - FERRIT - TOROID - CORES

AMIDON-FERRIT-RINGKERNE

Material-Nr.	Intern.Farbe	Perm. µ	Resonanzkreis	Breitband	Drossel
Material 16	Magnetic Balun	120	0,1 bis 10 MHz	9 bis200 MHz	180bis1000MHz
Material 27	Magentbalune z.B. 1:9	2030	0,001 bis 1 MHz	0,5 bis20 MHz	10 bis 50 MHz
Material 31		1500		1-300 MHz
Material 34	*Magnetic-Balun*	820	0,01 bis 1 MHz	1,0-50 MHz	30 bis 600 MHz
Material 43	Grün	850	0,01 bis 1 MHz	1,0 bis 50 MHz	30 bis 600 MHz
Material 61	Rot	125	0,2 bis 10 MHz	10 bis 200 MHz	200 bis 1000 MHz
Material 63	Violett	40	15 bis 25 MHz	50 bis 500 MHz	500 bis 1000 MHz
Material 64	Braun	250	0,05 bis 4 MHz	5 bis 200 MHz	200 bis 1000 MHz
Material 67	Violett	40	10 bis 80 MHz	20 bis 200 MHz	350 bis 1500 MHz
Material 68	Weiß	20	80 bis 180 MHz	200 bis 1000 MHz	1000 bis 5000 MHz
Material 72	Grau	2000	0,001 bis 1 MHz	0,5 bis 25 MHz	5 bis 50 MHz
Material 73	Gelb	2500	0,001 bis 1 MHz	0,5 bis 30 MHz	10 bis 50 MHz
Material 75	Hellblau	5000	0,001 bis 1 MHz	0,2 bis 10 MHz	5 bis 15 MHz
Material 77	Grau	2000	0,001 bis 2 MHz	0,5 bis 30 MHz	1 bis 50 MHz
Material 82	Grau	2050	0,001 bis 2 MHz	0,5 bis 30 MHz	1 bis 50 MHz
Material 85	Hellblau	5000	0,001 bis 1 MHz	0,5 bis 15 MHz	5 bis 15 MHz
Material 86	Weiß	20	80 bis 180 MHz	200 bis 1000 MHz	1000 bis 5000 MHz
Material 93	Orange	3000	0,001 bis 1 MHz	0,5 bis 15 MHz	10 bis 20 MHz
Material 96	-------	290	0,001 bis 30 MHz	50 bis 500 MHz	200 bis 5000MHz
Material 98	-------	10.000	1,0 bis 250 KHz	1 KHz bis 1 MHz	100 Khz bis 1 MHz
Material 99	-------	15.000	1,0 bis 150 KHz	1 KHz bis 1 MHz	1,0 bis 500 KHz

Breitbandtransformatoren

Material J, W,
Geringer Verlust, hoher μ (Permeabilität), guter Frequenzgang

Common Mode Chokes

Material J, W

Gleichtaktdrosseln Sehr hohe μ

Konverter und Inverter Transformatoren

Material F

Geringe Verluste, hohe Sättigung

Schmalband-Transformatoren

Material F und J

Moderate Q, hohe μ, hohe Stabilität

Noise Filters

Material J und W

Hohe μ, guter Frequenzgang

Power Inductors

Material F

Geringe Verluste bei hohen Flussdichten und Temperaturen, Hohe Sättigung, Gute Stabilität unter Lastbedingungen.

Power Transformers

Material F

Hoher μ und geringe Verluste bei hohen Flussdichten und Temperaturen, Hohe Sättigung,

Pulse Transformers

Material J und W

Hohe μ, geringe Verluste, hohe B Sättigung

FT23-16

Burnished to break sharp edges, can contain Parylene C coat at smaller

diameters from the length of 9.5mm (0.375") or a uniform coating of thermo-set

plastic at larger dimensions (if part numbers ends with a C).

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volum A_L : Inductance Factor

Balune von 160m-10m -

Spezialentwicklung für 160m - 10m

MATERIAL 16 (Permeabilität 120)

Ein Nickel-Zink-Material, das mittlere Temperaturstabilität, aber eine hohe Güte bietet (0,2 bis 15 MHz). In erster Linie Ersatz als Ringkern in Spulen hoher Güte. Auch lieferbar in Stabform oder als Breitband-Balunkern.

Ferrit-Ring für Breitbandtransformatoren
Frequenz hohe Güte bis 200 MHz

Features

NiZn ferrite material with a range for inductive applications up to 25 MHz, that

can be used for EMI applications to suppress noise frequencies above 200 MHz.

16 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Reso-nanz

Freq. MHz Breitband

Freq. MHz Dro-ssel

Initial Permeability@ B < 10 gauss

µ_i

120

430

0,1-10

10-200

200-1000

Flux Density @ Field Strength

Gauss
Oersted

B

H

2500

15

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0,02 cm²

Volumen

0.027 cm³

Residual Flux Density

Gauss

B_r

1000

Coercive Force

Oersted

H_c

1.1

Sättigungsflußdichte

10 Oe (Gauß)

2150

Vol.Widerstand Ω/cm

10⁸

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

30

1(Typ)

Remanenzflußdichte

10 Oe (Gauß)

1200

Σl/A(cm^-1)

63.8

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

0.1

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>300

Resistivity

Ohm-cm

Ρ

1×10⁸

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-16

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

25

±25%

NiZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

120

±25%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.1

Typ.

Coercive Force

Hc

oersted

1.8

Typ.

Residual Flux Density

Gauss, Br

N/A

1200

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2350

Typ.

Gauss, H @

@ Field Strength (H), oersted

15

Typ.

Curie temperature

°C

Tc

> 130

Nom.

Resistivity

Ω cm. p

@ Field Strength

10⁸

Typ.

Loss Factor

1×10⁸Tan δ/ µ_i

Initial

30

Typ.

MHz

@ Frequency

1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.8

1.3

0.02

0.027

510

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

-0.10

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

-0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites.

Toroids are tested for A_L values at 10 kHz.

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

FT23-27

Balune von 160m-10m -

Neuer Kern, Spezialentwicklung für 160m - 10m

Dieser Kern ist speziell für Magentbalune, wie z.B. 1:9 usw. entwickelt worden.

Material 27 (Permeabilität 2030)
Ein Mangan-Zink-Material mit großer Sättigungsflußdichte bei hohen Temperaturen. Niedrige Kernverluste im Bereich von 1 kHz bis 1 MHz. Ideal für Transformatoren und Breitbandübertrager bis 30 MHz sowie zur Nebenwellendämpfung zwischen 2 und 40 MHz. Lieferbar in Ring- oder Perlenform sowie als Topf- oder 'E'-Kerne.

Für Breitbandtransformatoren hohe Güte
Frequenz 0,5MHz bis 50MHz

Features

A MnZn ferrite for use in a wide range of high and low flux density inductive designs for frequencies up to 100 kHz.

Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volum A_L : Inductance Factor

27 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Resonanz

Freq. MHz Breitband

Freq. MHz Drossel

Initial Permeability@ B < 10 gauss

µ_i

2030

6000

0.001-1

0.20-20

10-50

Flux Density @ Field Strength

Gauss
Oersted

B

H

5100

5

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02²

Volumen

0.027³

Residual Flux Density

Gauss

B_r

1800

Coercive Force

Oersted

H_c

0.25

Sättigungsflußdichte

10 Oe (Gauß)

4600

Vol.Widerstand Ω/cm

10²

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

15

0.1

Remanenzflußdichte

10 Oe (Gauß)

1150

Σl/A(cm^-1)

63.80

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

1.20

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>200

Resistivity

Ohm-cm

Ρ

100

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-27

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

355

±25%

MnZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

2030

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.7

Typ.

Coercive Force

Hc

oersted

0.30

Typ.

Residual Flux Density

Gauss, Br

N/A

1800

Typ.

Flux Density

Gauss, B

Initial (B), oersted

4900

Typ.

Gauss, H @

@ Field Strength (H), oersted

5

Typ.

Curie temperature

°C

Tc

> 200

Nom.

Resistivity

Ω cm. p

@ Field Strength

10²

Typ.

Loss Factor

10⁶Tan δ/ µ_i

Initial

15

Typ.

MHz

@ Frequency

0.1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.80

1.3

0.02

0.027

355

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

±0.010

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

---

H (Height)/mm

0.060

±0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.
The above quoted properties are typical for Amidon MnZn and NiZn ferrites.

FT23-34

Ein Nickel-Zink Material mit großem Volumenwiderstand. Wird häufig für Spulen mittlerer Frequenz in Ringform und für Breitbandüber¬trager bis 50 MHz benutzt. Wird als Ferritperle besonders zur Dämpfung unerwünschter Oberwellen im Bereich von 50 bis 200 MHz eingesetzt.

Features

NiZn ferrite material with a range for inductive applications up to 25 MHz, that can be used for EMI applications to suppress noise frequencies above 200 MHz.

Burnished to break sharp edges, can contain Parylene C coat at smaller diameters from the length of 9.5mm (0.375") or a uniform coating of thermo-set plastic at larger dimensions (if part numbers ends with a C).

Beschichtungsoptionen:

- Toroide mit einem Außendurchmesser von 9,5 mm (0,375 ") oder kleiner können mit Parylen C beschichtet werden. Die Parylene-Beschichtung erhöht die Abmessungen "A" und "C" und verringert die Abmessung "B" um maximal 0,038 mm (0,0015 "). Die neunte Ziffer einer Parylene-beschichteten Toroid-Teilenummer ist eine "1". Siehe Referenztabellen für die Materialeigenschaften von Parylene C. Parylene C-Beschichtung sind RoHS-konform.
- Thermoplastisch beschichtete, kunststoffbeschichtete Teile können einer Mindestdurchschlagsspannung von 1000 Vrms widerstehen, die gleichmäßig über die "C" -Abmessung des Toroids angelegt wird.

Coating Options:

– Toroids with an outside diameter of 9.5 mm (0.375″) or smaller can be supplied Parylene C coated. The Parylene coating will increase the “A” and “C” dimensions and decrease the “B” dimension a maximum of 0.038 mm (0.0015″). The ninth digit of a Parylene coated toroid part number is a “1”. See reference tables for the material characteristics of Parylene C. Parylene C coating is RoHS compliant.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume
A_L : Inductance Factor

Funkentstörung

34 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Reso-nanz

Freq. MHz Breit-band

Freq. MHz Drossel

Initial Permeability@ B < 10 gauss

µ_i

820

3150

0.01-1

1-50

30-600

Flux Density @ Field Strength

Gauss
Oersted

B

H

2900

10

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02 cm²

Volumen

0.027 cm³

Residual Flux Density

Gauss

B_r

1300

Coercive Force

Oersted

H_c

0.45

Sättigungsflußdichte

10 Oe (Gauß)

2750

Vol.Widerstand Ω/cm

10⁵

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

250

1

Remanenzflußdichte

10 Oe (Gauß)

1200

Σl/A(cm^-1)

63.8

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

1.25

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>130

Resistivity

Ohm-cm

Ρ

1×10⁵

1×10⁸

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-34

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

158

±20%

NiZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

820

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

1.25

Typ.

Coercive Force

Hc

oersted

0.45

Typ.

Residual Flux Density

Gauss, Br

N/A

1200

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2900

Typ.

Gauss, H @

@ Field Strength (H), oersted

10

Typ.

Curie temperature

°C

Tc

> 130

Nom.

Resistivity

Ω cm. p

@ Field Strength

10⁵

Typ.

Loss Factor

1×10⁸Tan δ/ µ_i

Initial

250

Typ.

MHz

@ Frequency

1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.8

1.3

0.02

0.027

158

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

-0.10

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

-0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

Toroids are tested for A_L values at 10 kHz.

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

Spezifikationen für FT23-34 RF Toroids
Temperaturstabilität (ppm / ° C		= 12500
Farbcode		= glänzend schwarz
Anwendungsfrequenzbereich
Breitbandtransformatoren	5 - 400 MHz
Leistungstransformatoren	0,5 - 30 MHz
RFI-Unterdrückung	5 - 500 MHz
L = 158 ±20% uH = (A_L*Turns²) / 1000 <!--[if !supportLineBreakNewLine]--> <!--[endif]-->	Tatsächliche gemessene A_L unter Verwendung von 10 Windungen # 28 Draht

FT23-43

MATERIAL 43 (Permeabilität 850)

Ein Nickel-Zink Material mit großem Volumenwiderstand. Wird häufig für Spulen mittlerer Frequenz in Ringform und für Breitbandüber¬trager bis 50 MHz benutzt. Wird als Ferritperle besonders zur Dämpfung unerwünschter Oberwellen im Bereich von 50 bis 200 MHz eingesetzt.

Features

NiZn ferrite material with a range for inductive applications up to 25 MHz, that can be used for EMI applications to suppress noise frequencies above 200 MHz.

Burnished to break sharp edges, can contain Parylene C coat at smaller diameters from the length of 9.5mm (0.375") or a uniform coating of thermo-set plastic at larger dimensions (if part numbers ends with a C).

Beschichtungsoptionen:

- Toroide mit einem Außendurchmesser von 9,5 mm (0,375 ") oder kleiner können mit Parylen C beschichtet werden. Die Parylene-Beschichtung erhöht die Abmessungen "A" und "C" und verringert die Abmessung "B" um maximal 0,038 mm (0,0015 "). Die neunte Ziffer einer Parylene-beschichteten Toroid-Teilenummer ist eine "1". Siehe Referenztabellen für die Materialeigenschaften von Parylene C. Parylene C-Beschichtung sind RoHS-konform.
- Thermoplastisch beschichtete, kunststoffbeschichtete Teile können einer Mindestdurchschlagsspannung von 1000 Vrms widerstehen, die gleichmäßig über die "C" -Abmessung des Toroids angelegt wird.

Coating Options:

– Toroids with an outside diameter of 9.5 mm (0.375″) or smaller can be supplied Parylene C coated. The Parylene coating will increase the “A” and “C” dimensions and decrease the “B” dimension a maximum of 0.038 mm (0.0015″). The ninth digit of a Parylene coated toroid part number is a “1”. See reference tables for the material characteristics of Parylene C. Parylene C coating is RoHS compliant.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume
A_L : Inductance Factor

Funkentstörung

43 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Reso-nanz

Freq. MHz Breit-band

Freq. MHz Dro-ssel

Initial Permeability@ B < 10 gauss

µ_i

830

3000

0.01-1

1-50

30-600

Flux Density @ Field Strength

Gauss
Oersted

B

H

2900

10

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02 cm²

Volumen

0.027 cm³

Residual Flux Density

Gauss

B_r

1300

Coercive Force

Oersted

H_c

0.45

Sättigungsflußdichte

10 Oe (Gauß)

2750

Vol.Widerstand Ω/cm

10⁵

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

250

1

Remanenzflußdichte

10 Oe (Gauß)

1200

Σl/A(cm^-1)

63.8

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

1.25

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>130

Resistivity

Ohm-cm

Ρ

1×10⁵

1×10⁸

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-43

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

162

±20%

NiZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

830

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

1.25

Typ.

Coercive Force

Hc

oersted

0.45

Typ.

Residual Flux Density

Gauss, Br

N/A

1200

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2900

Typ.

Gauss, H @

@ Field Strength (H), oersted

10

Typ.

Curie temperature

°C

Tc

> 130

Nom.

Resistivity

Ω cm. p

@ Field Strength

10⁵

Typ.

Loss Factor

1×10⁸Tan δ/ µ_i

Initial

250

Typ.

MHz

@ Frequency

1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.8

1.3

0.02

0.027

162

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

-0.10

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

-0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

Toroids are tested for A_L values at 10 kHz.

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

43 Material This NiZn is our most popular ferrite for suppression of conducted EMI from 20 MHz to 250 MHz. This material is also used for inductive applications such as high frequency common-mode chokes. EMI suppression beads, beads on leads, SM beads, multi-aperture cores, round cable EMI suppression cores, round cable snap-its, flat cable EMI suppression cores, flat cable snap-its, miscellaneous suppression cores, bobbins, and toroids are all available in 43 material.

Spezifikationen für FT23-43 RF Toroids
Temperaturstabilität (ppm / ° C		= 12500
Farbcode		= glänzend schwarz
Anwendungsfrequenzbereich
Breitbandtransformatoren	5 - 400 MHz
Leistungstransformatoren	0,5 - 30 MHz
RFI-Unterdrückung	5 - 500 MHz
L = 158 ±20% uH = (A_L*Turns²) / 1000 <!--[if !supportLineBreakNewLine]--> <!--[endif]-->	Tatsächliche gemessene A_L unter Verwendung von 10 Windungen # 28 Draht

FT23-43

MATERIAL 43 (Permeabilität 850)

Ein Nickel-Zink Material mit großem Volumenwiderstand. Wird häufig für Spulen mittlerer Frequenz in Ringform und für Breitbandüber¬trager bis 50 MHz benutzt. Wird als Ferritperle besonders zur Dämpfung unerwünschter Oberwellen im Bereich von 50 bis 200 MHz eingesetzt.

Features

NiZn ferrite material with a range for inductive applications up to 25 MHz, that can be used for EMI applications to suppress noise frequencies above 200 MHz.

Burnished to break sharp edges, can contain Parylene C coat at smaller diameters from the length of 9.5mm (0.375") or a uniform coating of thermo-set plastic at larger dimensions (if part numbers ends with a C).

Beschichtungsoptionen:

- Toroide mit einem Außendurchmesser von 9,5 mm (0,375 ") oder kleiner können mit Parylen C beschichtet werden. Die Parylene-Beschichtung erhöht die Abmessungen "A" und "C" und verringert die Abmessung "B" um maximal 0,038 mm (0,0015 "). Die neunte Ziffer einer Parylene-beschichteten Toroid-Teilenummer ist eine "1". Siehe Referenztabellen für die Materialeigenschaften von Parylene C. Parylene C-Beschichtung sind RoHS-konform.
- Thermoplastisch beschichtete, kunststoffbeschichtete Teile können einer Mindestdurchschlagsspannung von 1000 Vrms widerstehen, die gleichmäßig über die "C" -Abmessung des Toroids angelegt wird.

Coating Options:

-Toroids with an outside diameter of 9.5 mm (0.375″) or smaller can be supplied Parylene C coated. The Parylene coating will increase the “A” and “C” dimensions and decrease the “B” dimension a maximum of 0.038 mm (0.0015″). The ninth digit of a Parylene coated toroid part number is a “1”. See reference tables for the material characteristics of Parylene C. Parylene C coating is RoHS compliant.

   Chart Legend
   Σl/A : Core Constant,    l_e : Effective Path Length,    A_e : Effective Cross-Sectional Area,    V_e : Effective Core Volume
   A_L : Inductance Factor

43 Material Characteristics

Property

Item

Symbol

Unit/

Symbol

Value

Max.

Permeabilität

Freq. MHz Reso-nanz

Freq. MHz Breit-band

Freq. MHz Dro-ssel

Initial Permeability@ B < 10 gauss

µ_i

850

3000

0.01-1

1-50

30-600

Flux Density @ Field Strength

Gauss
Oersted

B

H

2900

10

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02 cm²

Volumen

0.027 cm³

Residual Flux Density

Gauss

B_r

1300

Coercive Force

Oersted

H_c

0.45

Sättigungsflußdichte

10 Oe (Gauß)

2750

Vol.Widerstand Ω/cm

10⁵

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

250

1

Remanenzflußdichte

10 Oe (Gauß)

1200

Σl/A(cm^-1)

63.8

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

1.25

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>130

Resistivity

Ohm-cm

Ρ

1×10⁵

1×10⁸

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-43

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

162

±20%

NiZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

830

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

1.25

Typ.

Coercive Force

Hc

oersted

0.45

Typ.

Residual Flux Density

Gauss, Br

N/A

1200

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2900

Typ.

Gauss, H @

@ Field Strength (H), oersted

10

Typ.

Curie temperature

°C

Tc

> 130

Nom.

Resistivity

Ω cm. p

@ Field Strength

10⁵

Typ.

Loss Factor

1×10⁸Tan δ/ µ_i

Initial

250

Typ.

MHz

@ Frequency

1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.8

1.3

0.02

0.027

162

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

-0.10

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

-0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites.

Toroids are tested for A_L values at 10 kHz.

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

43 Material This NiZn is our most popular ferrite for suppression of conducted EMI from 20 MHz to 250 MHz. This material is also used for inductive applications such as high frequency common-mode chokes. EMI suppression beads, beads on leads, SM beads, multi-aperture cores, round cable EMI suppression cores, round cable snap-its, flat cable EMI suppression cores, flat cable snap-its, miscellaneous suppression cores, bobbins, and toroids are all available in 43 material.

Spezifikationen für FT23-43 RF Toroids
Temperaturstabilität (ppm / ° C		= 12500
Farbcode		= glänzend schwarz
Anwendungsfrequenzbereich
Breitbandtransformatoren	5 - 400 MHz
Leistungstransformatoren	0,5 - 30 MHz
RFI-Unterdrückung	5 - 500 MHz
L = 158 ±20% uH = (A_L*Turns²) / 1000 <!--[if !supportLineBreakNewLine]--> <!--[endif]-->	Tatsächliche gemessene A_L unter Verwendung von 10 Windungen # 28 Draht

FT23-43

MATERIAL 43 (Permeabilität 850)

Ein Nickel-Zink Material mit großem Volumenwiderstand. Wird häufig für Spulen mittlerer Frequenz in Ringform und für Breitbandüber¬trager bis 50 MHz benutzt. Wird als Ferritperle besonders zur Dämpfung unerwünschter Oberwellen im Bereich von 50 bis 200 MHz eingesetzt.

Features

NiZn ferrite material with a range for inductive applications up to 25 MHz, that can be used for EMI applications to suppress noise frequencies above 200 MHz.

Burnished to break sharp edges, can contain Parylene C coat at smaller diameters from the length of 9.5mm (0.375") or a uniform coating of thermo-set plastic at larger dimensions (if part numbers ends with a C).

Beschichtungsoptionen:

- Toroide mit einem Außendurchmesser von 9,5 mm (0,375 ") oder kleiner können mit Parylen C beschichtet werden. Die Parylene-Beschichtung erhöht die Abmessungen "A" und "C" und verringert die Abmessung "B" um maximal 0,038 mm (0,0015 "). Die neunte Ziffer einer Parylene-beschichteten Toroid-Teilenummer ist eine "1". Siehe Referenztabellen für die Materialeigenschaften von Parylene C. Parylene C-Beschichtung sind RoHS-konform.
- Thermoplastisch beschichtete, kunststoffbeschichtete Teile können einer Mindestdurchschlagsspannung von 1000 Vrms widerstehen, die gleichmäßig über die "C" -Abmessung des Toroids angelegt wird.

Coating Options:

– Toroids with an outside diameter of 9.5 mm (0.375″) or smaller can be supplied Parylene C coated. The Parylene coating will increase the “A” and “C” dimensions and decrease the “B” dimension a maximum of 0.038 mm (0.0015″). The ninth digit of a Parylene coated toroid part number is a “1”. See reference tables for the material characteristics of Parylene C. Parylene C coating is RoHS compliant.

   Chart Legend
   Σl/A : Core Constant,    l_e : Effective Path Length,    A_e : Effective Cross-Sectional Area,    V_e : Effective Core Volume
   A_L : Inductance Factor

43 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Reso-nanz

Freq. MHz Breit-band

Freq. MHz Dro-ssel

Initial Permeability@ B < 10 gauss

µ_i

850

3000

0.01-1

1-50

30-600

Flux Density @ Field Strength

Gauss
Oersted

B

H

2900

10

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02 cm²

Volumen

0.027 cm³

Residual Flux Density

Gauss

B_r

1300

Coercive Force

Oersted

H_c

0.45

Sättigungsflußdichte

10 Oe (Gauß)

2750

Vol.Widerstand Ω/cm

10⁵

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

250

1

Remanenzflußdichte

10 Oe (Gauß)

1200

Σl/A(cm^-1)

63.8

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

1.25

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>130

Resistivity

Ohm-cm

Ρ

1×10⁵

1×10⁸

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-43

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

162

±20%

NiZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

830

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

1.25

Typ.

Coercive Force

Hc

oersted

0.45

Typ.

Residual Flux Density

Gauss, Br

N/A

1200

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2900

Typ.

Gauss, H @

@ Field Strength (H), oersted

10

Typ.

Curie temperature

°C

Tc

> 130

Nom.

Resistivity

Ω cm. p

@ Field Strength

10⁵

Typ.

Loss Factor

1×10⁸Tan δ/ µ_i

Initial

250

Typ.

MHz

@ Frequency

1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.8

1.3

0.02

0.027

162

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

-0.10

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

-0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

Toroids are tested for A_L values at 10 kHz.

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

43 Material This NiZn is our most popular ferrite for suppression of conducted EMI from 20 MHz to 250 MHz. This material is also used for inductive applications such as high frequency common-mode chokes. EMI suppression beads, beads on leads, SM beads, multi-aperture cores, round cable EMI suppression cores, round cable snap-its, flat cable EMI suppression cores, flat cable snap-its, miscellaneous suppression cores, bobbins, and toroids are all available in 43 material.

Spezifikationen für FT23-43 RF Toroids
Temperaturstabilität (ppm / ° C		= 12500
Farbcode		= glänzend schwarz
Anwendungsfrequenzbereich
Breitbandtransformatoren	5 - 400 MHz
Leistungstransformatoren	0,5 - 30 MHz
RFI-Unterdrückung	5 - 500 MHz
L = 158 ±20% uH = (A_L*Turns²) / 1000 <!--[if !supportLineBreakNewLine]--> <!--[endif]-->	Tatsächliche gemessene A_L unter Verwendung von 10 Windungen # 28 Draht

FT23-61

MATERIAL 61 (Permeabilität 125

Ein Nickel-Zink-Material, das mittlere Temperaturstabilität, aber eine hohe Güte bietet (0,2 bis 15 MHz). In erster Linie Ersatz als Ringkern in Spulen hoher Güte. Auch lieferbar in Stabform oder als Breitband-Balunkern.

Ferrit-Ring für Breitbandtransformatoren
Frequenz hohe Güte bis 200 MHz

Features

NiZn ferrite material with a range for inductive applications up to 25 MHz, that

can be used for EMI applications to suppress noise frequencies above 200 MHz.

Burnished to break sharp edges, can contain Parylene C coat at smaller

diameters from the length of 9.5mm (0.375") or a uniform coating of thermo-set

plastic at larger dimensions (if part numbers ends with a C).

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume , A_L : Inductance Factor

61 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Reso-nanz

Freq. MHz Breit-band

Freq. MHz Dro-ssel

Initial Permeability@ B < 10 gauss

µ_i

125

430

0.2-10

10-200

200-1000

Flux Density @ Field Strength

Gauss
Oersted

B

H

2500

15

Mittlere Feld-

Linienlänge

7.3 cm

Oberfläche

0,37 cm²

Volumen

2,7 cm³

Residual Flux Density

Gauss

B_r

1000

Coercive Force

Oersted

H_c

1.1

Sättigungsflußdichte

10 Oe (Gauß)

2150

Vol.Widerstand Ω/cm

10⁸

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

30

1(Typ)

Remanenzflußdichte

10 Oe (Gauß)

1200

Σl/A(cm^-1)

63.8

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

0.1

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>300

Resistivity

Ohm-cm

Ρ

1×10⁸

1×10⁸

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-61

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

25

±25%

NiZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

125

±25%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.1

Typ.

Coercive Force

Hc

oersted

1.8

Typ.

Residual Flux Density

Gauss, Br

N/A

1200

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2350

Typ.

Gauss, H @

@ Field Strength (H), oersted

15

Typ.

Curie temperature

°C

Tc

> 130

Nom.

Resistivity

Ω cm. p

@ Field Strength

10⁸

Typ.

Loss Factor

1×10⁸Tan δ/ µ_i

Initial

30

Typ.

MHz

@ Frequency

1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor 

63.8

1.3

0.02

0.027

510

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

-0.10

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

-0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

Toroids are tested for A_L values at 10 kHz.

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

FT23-61

Toroids are tested for A_L values at 10 kHz.

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

MATERIAL 61 (Permeabilität 125

Ein Nickel-Zink-Material, das mittlere Temperaturstabilität, aber eine hohe Güte bietet (0,2 bis 15 MHz). In erster Linie Ersatz als Ringkern in Spulen hoher Güte. Auch lieferbar in Stabform oder als Breitband-Balunkern.

Ferrit-Ring für Breitbandtransformatoren
Frequenz hohe Güte bis 200 MHz

Features

NiZn ferrite material with a range for inductive applications up to 25 MHz, that

can be used for EMI applications to suppress noise frequencies above 200 MHz.

Burnished to break sharp edges, can contain Parylene C coat at smaller

diameters from the length of 9.5mm (0.375") or a uniform coating of thermo-set

plastic at larger dimensions (if part numbers ends with a C).

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume A_L : Inductance Factor

61 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Reso-nanz

Freq. MHz Breit-band

Freq. MHz Dro-ssel

Initial Permeability@ B < 10 gauss

µ_i

125

430

0.2-10

10-200

200-1000

Flux Density @ Field Strength

Gauss
Oersted

B

H

2500

15

Mittlere Feld-

Linienlänge

7.3 cm

Oberfläche

0,37 cm²

Volumen

2,7 cm³

Residual Flux Density

Gauss

B_r

1000

Coercive Force

Oersted

H_c

1.1

Sättigungsflußdichte

10 Oe (Gauß)

2150

Vol.Widerstand Ω/cm

10⁸

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

30

1(Typ)

Remanenzflußdichte

10 Oe (Gauß)

1200

Σl/A(cm^-1)

63.8

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

0.1

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>300

Resistivity

Ohm-cm

Ρ

1×10⁸

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-61

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

25

±25%

NiZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

125

±25%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.1

Typ.

Coercive Force

Hc

oersted

1.8

Typ.

Residual Flux Density

Gauss, Br

N/A

1200

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2350

Typ.

Gauss, H @

@ Field Strength (H), oersted

15

Typ.

Curie temperature

°C

Tc

> 130

Nom.

Resistivity

Ω cm. p

@ Field Strength

10⁸

Typ.

Loss Factor

1×10⁸Tan δ/ µ_i

Initial

30

Typ.

MHz

@ Frequency

1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor 

63.8

1.3

0.02

0.027

510

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

-0.10

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

-0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

Toroids are tested for A_L values at 10 kHz.

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

FT23-63

MATERIAL 63 (Permeabilität 40)

Ein Nickel-Zink-Material mit geringer Permeabilität und großem Volumenwiderstand. Material hoher Güte für den Frequenzbereich zwischen 15 und 25 MHz. Wird als Ringkern sehr häufig für Spulen hoher Güte verwandt. Lieferbar in Stab-, Perlen- oder Ringform.

Ferrit-Ring für Breitbandtransformatoren
Frequenz hohe Güte bis 300 MHz

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume A_L : Inductance Factor

63 Material Characteristics

Property

Item

Unit/Symbol

Value

(A_L-nH/ N²)

Max.

Permeabilität

Freq. MHz Resonanz

Freq. MHz Breitband

Freq. MHz Drossel

Initial Permeability@ B < 10 gauss

µ_i

40

125

15-25

50-500

500-2000

Flux Density @ Field Strength

Gauss
Oersted

B

H

2500

20

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02²

Volumen

0.027³

Residual Flux Density

Gauss

B_r

1000

Coercive Force

Oersted

H_c

2.5

Sättigungsflußdichte

10 Oe (Gauß)

1850

Vol.Widerstand Ω/cm

10⁸

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

200

50

Remanenzflußdichte

10 Oe (Gauß)

750

Σl/A(cm^-1)

63.80

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

0.05

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>475

Resistivity

Ohm-cm

Ρ

1×10⁷

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-63

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

6 Min

±25%

NiZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

40

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.05

Typ.

Coercive Force

Hc

oersted

3.5

Typ.

Residual Flux Density

Gauss, Br

N/A

800

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2300

Typ.

Gauss, H @

@ Field Strength (H), oersted

20

Typ.

Curie temperature

°C

Tc

> 475

Nom.

Resistivity

Ω cm. p

@ Field Strength

1×10⁷

Typ.

Loss Factor

10⁶Tan δ/ µ_i

Initial

200

Typ.

MHz

@ Frequency

50

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.80

1.3

0.02

0.027

6 min

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

±0.010

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

±0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

MATERIAL 63 (µ = 40)
For high 'Q' inductors in the 15 MHz to 25 MHz frequency range. Available in toroidal form only.

FT23-67

MATERIAL 67 (Permeabilität 40)

Ein Nickel-Zink-Material mit geringer Permeabilität und großem Volumenwiderstand. Material hoher Güte für den Frequenzbereich zwischen 15 und 25 MHz. Wird als Ringkern sehr häufig für Spulen hoher Güte verwandt. Lieferbar in Stab-, Perlen- oder Ringform.

Sehr gut geeignet für HF-Anwendungen hoher Güte. Wird verbreitet für Breitbandverstärker und Linearendstufen eingesetzt.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume A_L : Inductance Factor

67 Material Characteristics

Property

Item

Unit/Symbol

Value

(A_L-nH/ N²)

Max.

Permeabilität

Freq. MHz Resonanz

Freq. MHz Breitband

Freq. MHz Drossel

Initial Permeability@ B < 10 gauss

µ_i

40

125

15-25

50-500

500-2000

Flux Density @ Field Strength

Gauss
Oersted

B

H

2500

20

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02²

Volumen

0.027³

Residual Flux Density

Gauss

B_r

1000

Coercive Force

Oersted

H_c

2.5

Sättigungsflußdichte

10 Oe (Gauß)

1850

Vol.Widerstand Ω/cm

10⁸

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

200

50

Remanenzflußdichte

10 Oe (Gauß)

750

Σl/A(cm^-1)

63.80

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

0.05

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>475

Resistivity

Ohm-cm

Ρ

1×10⁷

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-67

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

6 Min

±25%

NiZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

40

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.05

Typ.

Coercive Force

Hc

oersted

3.5

Typ.

Residual Flux Density

Gauss, Br

N/A

800

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2300

Typ.

Gauss, H @

@ Field Strength (H), oersted

20

Typ.

Curie temperature

°C

Tc

> 475

Nom.

Resistivity

Ω cm. p

@ Field Strength

1×10⁷

Typ.

Loss Factor

10⁶Tan δ/ µ_i

Initial

200

Typ.

MHz

@ Frequency

50

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.80

1.3

0.02

0.027

6 min

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

±0.010

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

±0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

MATERlAL 67 ( µ= 40 ) Has greater saturation flux density and very good temperature stability. For high 'Q' inductors, ( 10 MHz to 80 Mhz ). Wideband transformers to 200 MHz. Toroids only

FT23-72

Material 72 (Permeabilität 2000)
Ein Mangan-Zink-Material mit großer Sättigungsflußdichte bei hohen Temperaturen. Niedrige Kernverluste im Bereich von 1 kHz bis 1 MHz. Ideal für Transformatoren und Breitbandübertrager bis 30 MHz sowie zur Nebenwellendämpfung zwischen 2 und 40 MHz. Lieferbar in Ring- oder Perlenform sowie als Topf- oder 'E'-Kerne.

Für Breitbandtransformatoren hohe Güte
Frequenz 0,5MHz bis 50MHz

Features

A MnZn ferrite for use in a wide range of high and low flux density inductive designs for frequencies up to 100 kHz.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume A_L : Inductance Factor

72 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Resonanz

Freq. MHz Breitband

Freq. MHz Drossel

Initial Permeability@ B < 10 gauss

µ_i

2000

6000

0.001-1

0.20-20

10-50

Flux Density @ Field Strength

Gauss
Oersted

B

H

5100

5

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02²

Volumen

0.027³

Residual Flux Density

Gauss

B_r

1800

Coercive Force

Oersted

H_c

0.25

Sättigungsflußdichte

10 Oe (Gauß)

4600

Vol.Widerstand Ω/cm

10²

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

15

0.1

Remanenzflußdichte

10 Oe (Gauß)

1150

Σl/A(cm^-1)

63.80

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

1.20

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>200

Resistivity

Ohm-cm

Ρ

100

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-72

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

420

±25%

MnZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

2030

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.7

Typ.

Coercive Force

Hc

oersted

0.30

Typ.

Residual Flux Density

Gauss, Br

N/A

1800

Typ.

Flux Density

Gauss, B

Initial (B), oersted

4900

Typ.

Gauss, H @

@ Field Strength (H), oersted

5

Typ.

Curie temperature

°C

Tc

> 200

Nom.

Resistivity

Ω cm. p

@ Field Strength

10²

Typ.

Loss Factor

10⁶Tan δ/ µ_i

Initial

15

Typ.

MHz

@ Frequency

0.1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.80

1.3

0.02

0.27

355

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

±0.010

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

±0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

MATERIAL 72 (µ = 2000)

Has high saturation flux density at high temperature. Low core loss in the 1 KHZ to 1 MHz range. For low level power conversion and wide band transformers. Extensively used for frequency attenuation from 0.5 MHZ to 50 M Hz. Available in toroids, pot cores, E-cores, beads, broadband balun cores and sleeves.

FT23-75

Material 75 (Permeabilität 5000)

Ein Mangan-Zink-Material, mit geringem Volumenwiderstand und niedrigen Kernverlusten zwischen 1 kHz und 1 MHz. Wird für Transformatoren niedriger Leistung, Breitbandübertrager und Puls-Transformatoren benutzt. Sehr geeignet auch zur Dämpfung unerwünschter HF im Bereich von 5 bis 20 MHz.

Lieferbar in Ring- oder Perlenform sowie als Topfkerne oder 'E'-Kerne

Low volume resistivity and low core loss from 1 KHz to 1 MHz. Used for pulse transformers and low level wide band transformers. Excellent frequency attenuation from 0.5 MHz to 20 MHz. Available tin toroidal form and ferrite beads as standard off the shelf in stock. Also available in pot cores, RM cores, E & µ cores as custom ordered parts with lead time for delivery.

Features

A MnZn ferrite for use in a wide range of high and low flux density inductive designs for frequencies up to 100 kHz.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume A_L : Inductance Factor

75 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Resonanz

Freq. MHz Breitband

Freq. MHz Drossel

Initial Permeability@ B < 10 gauss

µ_i

5000

8000

0.001-1

0.20-10

5-15

Flux Density @ Field Strength

Gauss
Oersted

B

H

4300

5

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02²

Volumen

0.027³

Residual Flux Density

Gauss

B_r

1400

Coercive Force

Oersted

H_c

0.16

Sättigungsflußdichte

10 Oe (Gauß)

1400

Vol.Widerstand Ω/cm

5x10²

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

15

0.1

Remanenzflußdichte

10 Oe (Gauß)

1250

Σl/A(cm^-1)

63.80

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

0.6

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>140

Resistivity

Ohm-cm

Ρ

300

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-75

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

975

±20%

MnZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

5000

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.6

Typ.

Coercive Force

Hc

oersted

0.16

Typ.

Residual Flux Density

Gauss, Br

N/A

1400

Typ.

Flux Density

Gauss, B

Initial (B), oersted

4300

Typ.

Gauss, H @

@ Field Strength (H), oersted

5

Typ.

Curie temperature

°C

Tc

> 140

Nom.

Resistivity

Ω cm. p

@ Field Strength

10²

Typ.

Loss Factor

10⁶Tan δ/ µ_i

Initial

15

Typ.

MHz

@ Frequency

0.1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.80

1.3

0.02

0.27

355

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

±0.010

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

±0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

MATERIAL 75 (µ = 5000)

Low volume resistivity and low core loss from 1 KHz to 1 MHz. Used for pulse transformers and low level wide band transformers. Excellent frequency attenuation from 0.5 MHz to 20 MHz. Available tin toroidal form and ferrite beads as standard off the shelf in stock. Also available in pot cores, RM cores, E & µ cores as custom ordered parts with lead time for delivery.

FT23-75

Material 75 (Permeabilität 5000)

Ein Mangan-Zink-Material, mit geringem Volumenwiderstand und niedrigen Kernverlusten zwischen 1 kHz und 1 MHz. Wird für Transformatoren niedriger Leistung, Breitbandübertrager und Puls-Transformatoren benutzt. Sehr geeignet auch zur Dämpfung unerwünschter HF im Bereich von 5 bis 20 MHz.

Lieferbar in Ring- oder Perlenform sowie als Topfkerne oder 'E'-Kerne

Low volume resistivity and low core loss from 1 KHz to 1 MHz. Used for pulse transformers and low level wide band transformers. Excellent frequency attenuation from 0.5 MHz to 20 MHz. Available tin toroidal form and ferrite beads as standard off the shelf in stock. Also available in pot cores, RM cores, E & µ cores as custom ordered parts with lead time for delivery.

Features

A MnZn ferrite for use in a wide range of high and low flux density inductive designs for frequencies up to 100 kHz.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume A_L : Inductance Factor

75 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Resonanz

Freq. MHz Breitband

Freq. MHz Drossel

Initial Permeability@ B < 10 gauss

µ_i

5000

8000

0.001-1

0.20-10

5-15

Flux Density @ Field Strength

Gauss
Oersted

B

H

4300

5

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02²

Volumen

0.027³

Residual Flux Density

Gauss

B_r

1400

Coercive Force

Oersted

H_c

0.16

Sättigungsflußdichte

10 Oe (Gauß)

1400

Vol.Widerstand Ω/cm

5x10²

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

15

0.1

Remanenzflußdichte

10 Oe (Gauß)

1250

Σl/A(cm^-1)

63.80

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

0.6

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>140

Resistivity

Ohm-cm

Ρ

300

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-75

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

975

±20%

MnZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

5000

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.6

Typ.

Coercive Force

Hc

oersted

0.16

Typ.

Residual Flux Density

Gauss, Br

N/A

1400

Typ.

Flux Density

Gauss, B

Initial (B), oersted

4300

Typ.

Gauss, H @

@ Field Strength (H), oersted

5

Typ.

Curie temperature

°C

Tc

> 140

Nom.

Resistivity

Ω cm. p

@ Field Strength

10²

Typ.

Loss Factor

10⁶Tan δ/ µ_i

Initial

15

Typ.

MHz

@ Frequency

0.1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.80

1.3

0.02

0.27

355

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

±0.010

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

±0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

MATERIAL 75 (µ = 5000)

Low volume resistivity and low core loss from 1 KHz to 1 MHz. Used for pulse transformers and low level wide band transformers. Excellent frequency attenuation from 0.5 MHz to 20 MHz. Available tin toroidal form and ferrite beads as standard off the shelf in stock. Also available in pot cores, RM cores, E & µ cores as custom ordered parts with lead time for delivery.

FT23-77

Material 77 (Permeabilität 2000)
Ein Mangan-Zink-Material mit großer Sättigungsflußdichte bei hohen Temperaturen. Niedrige Kernverluste im Bereich von 1 kHz bis 1 MHz. Ideal für Transformatoren und Breitbandübertrager bis 30 MHz sowie zur Nebenwellendämpfung zwischen 2 und 40 MHz. Lieferbar in Ring- oder Perlenform sowie als Topf- oder 'E'-Kerne.

Für Breitbandtransformatoren hohe Güte
Frequenz 0,5 MHz bis 50MHz

Features

A MnZn ferrite for use in a wide range of high and low flux density inductive designs for frequencies up to 100 kHz.

77 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Resonanz

Freq. MHz Breitband

Freq. MHz Drossel

Initial Permeability@ B < 10 gauss

µ_i

2000

6000

0.001-1

0.20-20

10-50

Flux Density @ Field Strength

Gauss
Oersted

B

H

5100

5

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02²

Volumen

0.027³

Residual Flux Density

Gauss

B_r

1800

Coercive Force

Oersted

H_c

0.25

Sättigungsflußdichte

10 Oe (Gauß)

4600

Vol.Widerstand Ω/cm

10²

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

15

0.1

Remanenzflußdichte

10 Oe (Gauß)

1150

Σl/A(cm^-1)

63.80

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

1.20

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>200

Resistivity

Ohm-cm

Ρ

100

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-77

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

420

±25%

MnZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

2030

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.7

Typ.

Coercive Force

Hc

oersted

0.30

Typ.

Residual Flux Density

Gauss, Br

N/A

1800

Typ.

Flux Density

Gauss, B

Initial (B), oersted

4900

Typ.

Gauss, H @

@ Field Strength (H), oersted

5

Typ.

Curie temperature

°C

Tc

> 200

Nom.

Resistivity

Ω cm. p

@ Field Strength

10²

Typ.

Loss Factor

10⁶Tan δ/ µ_i

Initial

15

Typ.

MHz

@ Frequency

0.1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.80

1.3

0.02

0.27

355

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

±0.010

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

±0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites

MATERIAL 77 (µ = 2000)

Has high saturation flux density at high temperature. Low core loss in the 1 KHZ to 1 MHz range. For low level power conversion and wide band transformers. Extensively used for frequency attenuation from 0.5 MHZ to 50 M Hz. Available in toroids, pot cores, E-cores, beads, broadband balun cores and sleeves.

FT23-F93

Material F 93 (Permeabilität 3000)

Mit hoher Sättigungsflussdichte bei hohen Temperaturen. Ideal für Leistungstransformatoren im Frequenzbereich von 0.5-50 MHz. Lieferbar nur als Ringkern in verschiedenen Größen

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume A_L : Inductance Factor

Bestellnr.

Frequenzbereich Resonanz

Frequenzbereich Breitband

Frequenzbereich

Drossel

Permeabilität

AL Inductance nH/T²

FT23-F93

0,001-1 MHz

0.5-30 MHz

1-20 MHz

3000

585

Electrical Specifications

Shape

OD / Length mm

ID /Length mm

HT / Height mm

Ve Volume mm³

Le Path Length mm

Ae Cross Section mm²

WaAc

Toroid - Uncoated

5.84

3.05

1.52

26.7

13

2

0.001

(mm)

Uncoated Nominal

Min:

Max:

O.D. (A)

5.84

5.55

6.13

I.D. (B)

3.05

2.76

3.34

Ht. (C)

1.52

1.33

1.71

Eff. Parameters

A_e

l_e

V_e

2.0

13

26.7

Inductance

A_LValue

Test conditions

585 ±20%

10 kHz, 0,5mT /For N=5, use 0.2 mA) 25°C

COATING

Uncoted

Note

Spec. Modifications

Previous

Revised

2006.01.12

Losses: General F93 Material

Losses: Datail as indicated

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites.

FT23 - J

Material J (Permeabilität 5000)

Ein Mangan-Zink-Material, mit geringem Volumenwiderstand und niedrigen Kernverlusten zwischen 1 kHz und 1 MHz. Wird für Transformatoren niedriger Leistung, Breitbandübertrager und Puls-Transformatoren benutzt. Sehr geeignet auch zur Dämpfung unerwünschter HF im Bereich von 5 bis 20 MHz.

Lieferbar in Ring- oder Perlenform sowie als Topfkerne oder 'E'-Kerne

Low volume resistivity and low core loss from 1 KHz to 1 MHz. Used for pulse transformers and low level wide band transformers. Excellent frequency attenuation from 0.5 MHz to 20 MHz. Available tin toroidal form and ferrite beads as standard off the shelf in stock. Also available in pot cores, RM cores, E & µ cores as custom ordered parts with lead time for delivery.

Features

A MnZn ferrite for use in a wide range of high and low flux density inductive designs for frequencies up to 100 kHz.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume
A_L : Inductance Factor

J Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Resonanz

Freq. MHz Breitband

Freq. MHz Drossel

Initial Permeability@ B < 10 gauss

µ_i

5000

8000

0.001-1

0.20-10

5-15

Flux Density @ Field Strength

Gauss
Oersted

B

H

4300

5

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02²

Volumen

0.027³

Residual Flux Density

Gauss

B_r

1400

Coercive Force

Oersted

H_c

0.16

Sättigungsflußdichte

10 Oe (Gauß)

1400

Vol.Widerstand Ω/cm

5x10²

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

15

0.1

Remanenzflußdichte

10 Oe (Gauß)

1250

Σl/A(cm^-1)

63.80

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

0.6

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>140

Resistivity

Ohm-cm

Ρ

300

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-J

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

975

±20%

MnZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

5000

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.6

Typ.

Coercive Force

Hc

oersted

0.16

Typ.

Residual Flux Density

Gauss, Br

N/A

1400

Typ.

Flux Density

Gauss, B

Initial (B), oersted

4300

Typ.

Gauss, H @

@ Field Strength (H), oersted

5

Typ.

Curie temperature

°C

Tc

> 140

Nom.

Resistivity

Ω cm. p

@ Field Strength

10²

Typ.

Loss Factor

10⁶Tan δ/ µ_i

Initial

15

Typ.

MHz

@ Frequency

0.1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.80

1.3

0.02

0.27

355

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

±0.010

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

±0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites.

FT23-W76/98

Lieferzeit: 6-8 Wochen

Material W76/98 Permeabilität 10.000

W material is a high permeability material used for frequency attenuation from 100 KHz to 1 MHz in EMI/RFI filters

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume A_L : Inductance Factor

Bestellnr.

Frequenzbereich Resonanz

Frequenzbereich Breitband

Frequenzbereich

Drossel

Permeabilität

AL Inductance nH/T²

FT23-W76/98

1 kHz-250 kHz

1 kHz-1 MHz

100 kHz –

1 MHz

10.000

1960 ± 30%

Electrical Specifications

Shape

OD / Length mm

ID /Length mm

HT / Height mm

Ve Volume mm³

Le Path Length mm

Ae Cross Section mm²

WaAc

Toroid - Uncoated

5.84

3.05

1.52

26.7

13

2

0.001

(mm)

Uncoated Nominal

Min:

Max:

O.D. (A)

5.84

5.55

6.13

I.D. (B)

3.05

2.76

3.34

Ht. (C)

1.52

1.33

1.71

Eff. Parameters

A_e

l_e

V_e

2.0

13

26.7

Inductance

A_LValue

Test conditions

1960±30%

10 kHz, 0,5mT /For N=5, use 0.06 mA) 25°C

COATING

Parylene rated for 130°C continuous operation

Voltage breakdown rating 1,000 V Min Wire-to-Wire

Note

Spec. Modifications

Previous

Revised

2005.12.16

Losses: General W Material

Losses: Datail as indicated

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites.

FT37-16

MATERIAL 16 (Permeabilität 120)

Eine Ringkonfiguration bietet die ultimative Nutzung der Eigenschaften des intrinsischen Ferritmaterials. Ringkerne werden in einer Vielzahl von Anwendungen eingesetzt, z. B. als Eingangsfilter, Fehlerstromschutzschalter, Gleichtaktfilter und in Impuls- und Breitbandtransformatoren.

Ein Nickel-Zink-Material, das mittlere Temperaturstabilität, aber eine hohe Güte bietet (0,2 bis 15 MHz). In erster Linie Ersatz als Ringkern in Spulen hoher Güte. Auch lieferbar in Stabform oder als Breitband-Balunkern.

Ferrit-Ring für Breitbandtransformatoren
Frequenz hohe Güte bis 200 MHz

Features

NiZn ferrite material with a range for inductive applications up to 25 MHz, that

can be used for EMI applications to suppress noise frequencies above 200 MHz.

Burnished to break sharp edges, can contain Parylene C coat at smaller

diameters from the length of 9.5mm (0.375") or a uniform coating of thermo-set

plastic at larger dimensions (if part numbers ends with a C).

Toroide werden auf AL-Werte bei 10 kHz getestet.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume
A_L : Inductance Factor

16 Material Characteristics

Property

Item

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Reso-nanz

Freq. MHz

Breit-band

Freq.

MHz

Drossel

Initial Permeability@ B < 10 gauss

µ_i

120

450

0.2-10

10-200

200-1000

Flux Density @ Field Strength

Gauss
Oersted

B

H

2500

15

Mittlere Feld-

Linienlänge

2.07 cm

Oberfläche

0.15 cm³

Volumen

0.072 cm²

Residual Flux Density

Gauss

B_r

1000

Coercive Force

Oersted

H_c

1.8

Sättigungsflußdichte

10 Oe (Gauß)

2500

Vol.Widerstand Ω/cm

10⁸

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

30

1(Typ)

Remanenzflußdichte

10 Oe (Gauß)

1000

Σl/A(cm^-1)

28.6

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

0.10

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>300

Resistivity

Ohm-cm

Ρ

1×10⁸

1×10⁸

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT37-16

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

55

±25%

NiZn

Le

cm

N/A

2.07

±10%

Ae

cm²

N/A

0.072

±10%

Ve

cm³

N/A

0.15

±10%

Initial Permeability

µ0

@ B < 10 gauss

120

±25%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.10

Typ.

Coercive Force

Hc

oersted

1.1

Typ.

Residual Flux Density

Gauss, Br

N/A

1000

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2500

Typ.

Gauss, H @

@ Field Strength (H), oersted

15

Typ.

Curie temperature

°C

Tc

> 300

Nom.

Resistivity

Ω cm. p

@ Field Strength

10⁸

Typ.

Loss Factor

1×10⁸Tan δ/ µ_i

Initial

30

Typ.

MHz

@ Frequency

1

Typ.

Chart Legend

Σl/A(cm^-1):

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

28.6

2.07

0.072

0.15

55

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.375

±0.008

9.5

±0.20

0.83 g

0.83 gramm

A (Inner Diameter)/mm

0.187

±0.006

4.75

±0.15

---

H (Height)/mm

0.125

±0.010

3.3

-0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites.

Toroids are tested for A_L values at 10 kHz.

16 Material

A high frequency NiZn ferrite developed for a range of inductive applications up to 25 MHz. This material is also used in EMI applications for suppression of noise frequencies above 200 MHz. EMI suppression beads, beads on leads, SM beads, wound beads, multi-aperture cores, round cable snap-its, rods, antenna/RFID rods, and toroids are all available in 61 material. Strong magnetic fields or excessive mechanical stresses may result in irreversible changes in permeability and losses.

16 Material Ferrite ToroidsFerrite Toroids 61 Material and is designed for inductive applications up to 25 MHz and also suppresses noise frequencies from 200 MHz to 1000 MHz Inner Diameter 0.186 Outer Diameter 0.376 Height 0.126 Al Value 55

Spezifikationen für FT37-16 RF Toroids
Temperaturstabilität (ppm / ° C		= 1000
Farbcode		= mattes Schwarz
Anwendungsfrequenzbereich
Breitbandtransformatoren	20-500 MHz
Leistungstransformatoren	0,2 - 10 MHz
RFI-Unterdrückung	über 20 MHz
*L = 55 ±20% uH = (A_LTurns²) / 1000**	Tatsächliche gemessene A_L unter Verwendung von 10 Windungen # 28 Draht

FT37-27

MATERIAL 27 (Permeabilität 2000)

Ein Mangan-Zink-Material mit großer Sättigungsflußdichte bei hohen Temperaturen. Niedrige Kernverluste im Bereich von 1 kHz bis 1 MHz. Ideal für Transformatoren und Breitbandübertrager bis 30 MHz sowie zur Nebenwellendämpfung zwischen 2 und 40 MHz.

Eine Ringkonfiguration bietet die ultimative Nutzung der Eigenschaften des intrinsischen Ferritmaterials. Ringkerne werden in einer Vielzahl von Anwendungen eingesetzt, z. B. als Eingangsfilter, Fehlerstromschutzschalter, Gleichtaktfilter und in Impuls- und Breitbandtransformatoren.

Alle Ringkerne sind brüniert, um scharfe Kanten zu brechen.

Beschichtungsoptionen:
- Toroide mit einem Außendurchmesser von 9,5 mm (0,375 ") oder kleiner können mit Parylen C beschichtet werden. Die Parylene-Beschichtung erhöht die Abmessungen "A" und "C" und verringert die Abmessung "B" um maximal 0,038 mm (0,0015 "). Die neunte Ziffer einer Parylene-beschichteten Toroid-Teilenummer ist eine "1". Siehe Referenztabellen für die Materialeigenschaften von Parylene C. Parylene C-Beschichtung sind RoHS-konform.
- Toroide mit einem Außendurchmesser von 9,5 mm (0,375 ") oder größer können mit einer gleichmäßigen Beschichtung aus thermofixierter Kunststoffbeschichtung geliefert werden. Diese Beschichtung erhöht die Abmessungen "A" und "C" und verringert die Abmessung "B" um maximal 0,5 mm (0,020 "). Die neunte Ziffer der mit Thermoplasten überzogenen Toroid-Teilenummer ist eine "2". Thermoplast-Kunststoffbeschichtung ist RoHS-konform.
- Thermoplastisch beschichtete Kunststoffteile können einer minimalen Durchbruchspannung von 1000 Vrms widerstehen, die gleichmäßig über die "C" -Abmessung des Toroids angelegt wird.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume
A_L : Inductance Factor

27 Material Characteristics

Property

Item

Unit/

Symbol

Value

Max.

Permeabilität

Freq. MHz Reso-nanz

Freq. MHz

Breit-band

Freq.

MHz

Drossel

Initial Permeability@ B < 10 gauss

µ_i

2000

3500

0.001-

2

0.5-

30

10-

50

Flux Density @ Field Strength

Gauss
Oersted

B

H

5100

5

Mittlere Feld-

Linienlänge

2.07 cm

Oberfläche

0.072 cm³

Volumen

0.15 cm²

Residual Flux Density

Gauss

B_r

1800

Coercive Force

Oersted

H_c

0.25

Sättigungsflußdichte

10 Oe (Gauß)

5100

Vol.Widerstand Ω/cm

10²

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

15

0.1

Remanenzflußdichte

10 Oe (Gauß)

1800

Σl/A(cm^-1)

28.6

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

1.2

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>200

Resistivity

Ohm-cm

Ρ

10²

1×10⁸

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT37-27

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

945

±25%

Mn-Zn

Le

cm

N/A

2.07

±10%

Ae

cm²

N/A

0.0072

±10%

Ve

cm³

N/A

0.15

±10%

Initial Permeability

µ0

@ B < 10 gauss

2000

±25%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

0.7

Typ.

Coercive Force

Hc

oersted

0.30

Typ.

Residual Flux Density

Gauss, Br

N/A

1800

Typ.

Flux Density

Gauss, B

Initial (B), oersted

5100

Typ.

Gauss, H @

@ Field Strength (H), oersted

5

Typ.

Curie temperature

°C

Tc

> 200

Nom.

Resistivity

Ω cm. p

@ Field Strength

10²

Typ.

Loss Factor

1×10⁸Tan δ/ µ_i

Initial

15

Typ.

MHz

@ Frequency

0.1

Typ.

Chart Legend

Σl/A(cm^-1):

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

28.6

2.07

0.0072

0.15

880

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.325

±0.008

9.50

±0.20

0.83 g

0.83 gramm

A (Inner Diameter)/mm

0.187

±0.006

4.75

±0.15

---

H (Height)/mm

0.125

±0.010

3.30

-0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites.

Induktivität in mH

Turns Count

Core Number

A_L-Wert

10

20

30

40

50

60

70

80

90

100

FT 37-27

884

.088

.354

.796

1.410

2.21

3.18

4.33

5.66

7.16

8.84

Ferrit-Ring für Breitbandtransformatoren.

FT37- 43P

A 10.20 Max 0.401 Max B 4.10 Min 0.162 Min C 3.80 Max 0.149 Max

Frequency Range: Low-Medium Permeability, 43 (ui=800) material Description: 43 TOROID PLASTIC COATED Application: Inductive Components Where Used: Closed Magnetic Circuit Part Type: Toroids Mechanical Specifications Weight: .830 (g) Part Type Information A ring configuration provides the ultimate utilization of the intrinsic ferrite material properties. Toroidal cores are used in a wide variety of applications such as power input filters, ground-fault interrupters, common-mode filters and in pulse and broadband transformers. -Toroids are listed by initial permeability classes and increasing dimension of the inside diameter. -All toroidal cores are supplied burnished to break sharp edges. -Toroids are tested for AL values at 10 kHz. -Toroids with an outside diameter of 9.5mm (.375'') or smaller can be supplied Parylene C coated. The Parylene coating will increase the 'A' and 'C' dimensions and decrease the 'B' dimension a maximum of 0.038mm (.0015''). The ninth digit of a Parylene coated toroid part number is a '1'. See the material characteristics of Parylene C in our online catalog. -Toroids with an outside diameter of 9.5mm (.375'') or larger can be supplied with a uniform coating of thermo-set plastic coating. This coating will increase the 'A' and 'C' dimensions and decrease the 'B' dimension a maximum of 0.5mm (.020''). The 9th digit of the thermo-set plastic coated toroid part number is a '2'. Thermo-set plastic coating is RoHS compliant. -Thermo-set plastic coated parts can withstand a minimum breakdown voltage of 1000 Vrms, uniformly applied across the 'C' dimension of the toroid. -The ''C'' dimension may be modified to suit specific applications. -For any toroidal core requirement not listed in the catalog, please contact our customer service department for availability and pricing. -Explaination of Part Numbers: Digits 1&2 = product class, 3&4 = material grade, 9th digit 1 = Parylene coating, 2 = thermo-set plastic coating.

FT37- 43

MATERIAL 43 (Permeabilität 850)

Ein Nickel-Zink Material mit großem Volumenwiderstand. Wird häufig für Spulen mittlerer Frequenz in Ringform und für Breitbandüber¬trager bis 50 MHz benutzt. Wird als Ferritperle besonders zur Dämpfung unerwünschter Oberwellen im Bereich von 50 bis 200 MHz eingesetzt.

Features

NiZn ferrite material with a range for inductive applications up to 25 MHz, that can be used for EMI applications to suppress noise frequencies above 200 MHz.

Burnished to break sharp edges, can contain Parylene C coat at smaller diameters from the length of 9.5mm (0.375") or a uniform coating of thermo-set plastic at larger dimensions (if part numbers ends with a C).

Beschichtungsoptionen:

- Toroide mit einem Außendurchmesser von 9,5 mm (0,375 ") oder kleiner können mit Parylen C beschichtet werden. Die Parylene-Beschichtung erhöht die Abmessungen "A" und "C" und verringert die Abmessung "B" um maximal 0,038 mm (0,0015 "). Die neunte Ziffer einer Parylene-beschichteten Toroid-Teilenummer ist eine "1". Siehe Referenztabellen für die Materialeigenschaften von Parylene C. Parylene C-Beschichtung sind RoHS-konform.
- Thermoplastisch beschichtete, kunststoffbeschichtete Teile können einer Mindestdurchschlagsspannung von 1000 Vrms widerstehen, die gleichmäßig über die "C" -Abmessung des Toroids angelegt wird.

Coating Options:

– Toroids with an outside diameter of 9.5 mm (0.375″) or smaller can be supplied Parylene C coated. The Parylene coating will increase the “A” and “C” dimensions and decrease the “B” dimension a maximum of 0.038 mm (0.0015″). The ninth digit of a Parylene coated toroid part number is a “1”. See reference tables for the material characteristics of Parylene C. Parylene C coating is RoHS compliant.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume
A_L : Inductance Factor

43 Material Characteristics

Property

Item

Symbol

Unit/Symbol

Value

Max.

Permeabilität

Freq. MHz Resonanz

Freq. MHz Breitband

Freq. MHz Drossel

Initial Permeability@ B < 10 gauss

µ_i

850

3000

0,01-1

1-50

30-600

Flux Density @ Field Strength

Gauss
Oersted

B

H

2900

10

Mittlere Feld-

Linienlänge

7,3 cm

Oberfläche

0,37 cm²

Volumen

2,7 cm³

Residual Flux Density

Gauss

B_r

1300

Coercive Force

Oersted

H_c

0.45

Sättigungsflußdichte

10 Oe (Gauß)

2700

Vol.Widerstand Ω/cm

10⁵

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

250

1.0

Remanenzflußdichte

10 Oe (Gauß)

1300

Σl/A(cm^-1)

21.3

Temperature Coefficient of Initial Permeability

(20 -70°C)

%/°C

1.25

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>130

Resistivity

Ohm-cm

Ρ

10⁵

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT37-43

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

470

±20%

NiZn

L_e

cm

N/A

5.2

±10%

A_e

cm2

N/A

0.243

±10%

V_ef

cm3

N/A

1.26

±10%

Initial Permeability

µ0

@ B < 10 gauss

830

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

1.25

Typ.

Coercive Force

Hc

oersted

0.45

Typ.

Residual Flux Density

Gauss, Br

N/A

1300

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2900

Typ.

Gauss, H @

@ Field Strength (H), oersted

10

Typ.

Curie temperature

°C

Tc

> 130

Nom.

Resistivity

Ω cm. p

@ Field Strength

10⁵

Typ.

Loss Factor

10⁶Tan δ/ µ_i

Initial

250

Typ.

MHz

@ Frequency

1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

21.3

5.2

0.243

1.26

470

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.375

±0.008

9.5

±0.20

0.83 g

0.83 gramm

A (Inner Diameter)/mm

0.187

±0.006

4.75

±0.15

---

H (Height)/mm

0.125

±0.010

3.3

-0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop)

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites.

Toroids are tested for A_L values at 10 kHz.

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

This NiZn is our most popular ferrite for suppression of conducted EMI from 20 MHz to 250 MHz. This material is also used for inductive applications such as high frequency common-mode chokes. EMI suppression beads, beads on leads, SM beads, multi-aperture cores, round cable EMI suppression cores, round cable snap-its, flat cable EMI suppression cores, flat cable snap-its, miscellaneous suppression cores, bobbins, and toroids are all available in 43 material.

43 Material is used for EMI/RFI suppression in the 20 MHz to 250 MHz range.

FT37-43

Zurzeit keine Aktion

MATERIAL 43 (Permeabilität 830)

Ein Nickel-Zink Material mit großem Volumenwiderstand. Wird häufig für Spulen mittlerer Frequenz in Ringform und für Breitbandüber¬trager bis 50 MHz benutzt. Wird als Ferritperle besonders zur Dämpfung unerwünschter Oberwellen im Bereich von 50 bis 200 MHz eingesetzt.

Features

NiZn ferrite material with a range for inductive applications up to 25 MHz, that can be used for EMI applications to suppress noise frequencies above 200 MHz.

Burnished to break sharp edges, can contain Parylene C coat at smaller diameters from the length of 9.5mm (0.375") or a uniform coating of thermo-set plastic at larger dimensions (if part numbers ends with a C).

Beschichtungsoptionen:

- Toroide mit einem Außendurchmesser von 9,5 mm (0,375 ") oder kleiner können mit Parylen C beschichtet werden. Die Parylene-Beschichtung erhöht die Abmessungen "A" und "C" und verringert die Abmessung "B" um maximal 0,038 mm (0,0015 "). Die neunte Ziffer einer Parylene-beschichteten Toroid-Teilenummer ist eine "1". Siehe Referenztabellen für die Materialeigenschaften von Parylene C. Parylene C-Beschichtung sind RoHS-konform.
- Thermoplastisch beschichtete, kunststoffbeschichtete Teile können einer Mindestdurchschlagsspannung von 1000 Vrms widerstehen, die gleichmäßig über die "C" -Abmessung des Toroids angelegt wird.

Coating Options:

– Toroids with an outside diameter of 9.5 mm (0.375″) or smaller can be supplied Parylene C coated. The Parylene coating will increase the “A” and “C” dimensions and decrease the “B” dimension a maximum of 0.038 mm (0.0015″). The ninth digit of a Parylene coated toroid part number is a “1”. See reference tables for the material characteristics of Parylene C. Parylene C coating is RoHS compliant.

Chart Legend
Σl/A : Core Constant, l_e : Effective Path Length, A_e : Effective Cross-Sectional Area, V_e : Effective Core Volume
A_L : Inductance Factor

43 Material Characteristics

Property

Item

Symbol

Unit/

Symbol

Value

Max.

Permeabilität

Freq. MHz Reso-nanz

Freq. MHz Breit-band

Freq. MHz Dro-ssel

Initial Permeability@ B < 10 gauss

µ_i

850

3000

0.01-1

1-50

30-600

Flux Density @ Field Strength

Gauss
Oersted

B

H

2900

10

Mittlere Feld-

Linienlänge

1.3 cm

Oberfläche

0.02 cm²

Volumen

0.027 cm³

Residual Flux Density

Gauss

B_r

1300

Coercive Force

Oersted

H_c

0.45

Sättigungsflußdichte

10 Oe (Gauß)

2750

Vol.Widerstand Ω/cm

10⁵

Loss Factor @ Frequency

10 ^-6MHz

Tan δ/ µ_i

250

1

Remanenzflußdichte

10 Oe (Gauß)

1200

Σl/A(cm^-1)

63.8

Temperature Coefficient of Initial Permeability (20 -70°C)

%/°C

1.25

Density gm/cm³

≈4.7 g/cm³

Curie Temperature

°C

T_c

>130

Resistivity

Ohm-cm

Ρ

1×10⁵

1×10⁸

1×10⁵

Electrical Specifications

Bestellnr.

Kern-Material

Item

Unit/Symbol

Condition

Value

A_L-Toleranz

FT23-43

Ferrit Toroid

A_L

nH/N2

@ 10 KHz

162

±20%

NiZn

Le

cm

N/A

1.3

±10%

Ae

cm2

N/A

0.02

±10%

Ve

cm3

N/A

0.027

±10%

Initial Permeability

µ0

@ B < 10 gauss

830

±20%

Temp. Coeff. Of initial

Permeability

% °C

20-70°C

1.25

Typ.

Coercive Force

Hc

oersted

0.45

Typ.

Residual Flux Density

Gauss, Br

N/A

1200

Typ.

Flux Density

Gauss, B

Initial (B), oersted

2900

Typ.

Gauss, H @

@ Field Strength (H), oersted

10

Typ.

Curie temperature

°C

Tc

> 130

Nom.

Resistivity

Ω cm. p

@ Field Strength

10⁵

Typ.

Loss Factor

1×10⁸Tan δ/ µ_i

Initial

250

Typ.

MHz

@ Frequency

1

Typ.

Chart Legend

Σl/A :

l_e :

A_e :

V_e :

A_L :

Core Constant

Effective Path Length

Effective Cross-Sectional

Effective Core Volume

Inductance Factor

63.8

1.3

0.02

0.027

162

Dimensional Tolerances

Case

In

Toleranz

mm

Toleranz

Weight

Gewicht

B (Outer Diameter)/mm

0.230

-0.10

5.95

±0.25

0.14 g

0.14 gramm

A (Inner Diameter)/mm

0.120

±0.004

3.05

±0.10

---

H (Height)/mm

0.060

-0.010

1.65

±0.25

---

--

Ferrite Material Constants

Specific Heat

0.25 cal/g/°C

Thermal Conductivity

3.5 - 4.5 mW/cm-°C

Coefficient of Linear Expansion

8 - 10x10^-6/°C

Tensile Strength

4.9 kgf/mm²

Compressive Strength

42 kgf/mm²

Young's Modulus

15x10³ kgf/mm²

Hardness (Knoop

650

Specific Gravity

≈4.7 g/cm³

Die oben genannten Eigenschaften sind typisch für Amidon MnZn- und NiZn-Ferrite.

The above quoted properties are typical for Amidon MnZn and NiZn ferrites.

Toroids are tested for A_L values at 10 kHz.

Characteristic curves are measured on standard Toroids (18/10/6 mm) at 25°C and 10 kHz unless otherwise indicated. Impedance characteristics are measured on standard shield beads (3.5/1.3/6.0 mm) unless otherwise indicated.

This NiZn is our most popular ferrite for suppression of conducted EMI from 20 MHz to 250 MHz. This material is also used for inductive applications such as high frequency common-mode chokes. EMI suppression beads, beads on leads, SM beads, multi-aperture cores, round cable EMI suppression cores, round cable snap-its, flat cable EMI suppression cores, flat cable snap-its, miscellaneous suppression cores, bobbins, and toroids are all available in 43 material.

43 Material is used for EMI/RFI suppression in the 20 MHz to 250 MHz range.

FT37-43 - 2401-FB

Dämpfungsperlen:FT-43-2401-FB

sind für alle Frequenzbereiche erhältlich. Anwendung: Für HF-Schaltungen, HF-Transistoren, Thyristoren und Triac-Schaltungen. Die Dämpfungsperlen werden über den Leiter geschoben, gewickelt. Der Dämpfungsanstieg wächst linear mit der Anzahl der Perlen. Siehe Einleitungstext.

Außen: 9,7 mm ["OD"]
Loch: 5,0 mm ["ID"]
Länge: 4,8 mm ["HT"]
Bauform: 1 ["Type"]

Permeabilität µ 850

A_LWert: 520 [nH/Wdg.²]
Impedanzfaktor: 1,02

Frequenzbereich für Drosselanwendung:200-2000 MHz

Wird als Ferritperle besonders zur Dämpfung unerwünschter Oberwellen im Bereich von 30 bis 200 MHz (RF Noise) eingesetzt.
Ferrit-Ring für Breitbandtransformatoren.

AMIDON-DEUTSCHLAND

PREISE-FT-TYP - Webshop

AMIDON-Kerne

Erläuterung

A_L (nH/Square Turn or nH/ N²) is the A_L value.
L is inductance in nH (nanohenries)
N is the number of turns of a wire
Required turns (N) = square root of (desired 'L' /'A_L'), √'L' /'A_L', or 1000 turns='mH' /'A_L', (square rooted)

Color may vary by material and coating characteristics
Parts are RoHS compliant

Berechnung der Ringkerne

FERRITRINGKERNE - FERRIT - TOROID - CORES

FT23-16

FT23-27

FT23-34

FT23-43

FT23-43

FT23-43

FT23-61

FT23-61

FT23-63

FT23-67

FT23-72

FT23-75

FT23-75

FT23-77

FT23-F93

FT23 - J

FT23-W76/98

FT37-16

FT37-27

FT37- 43P

FT37- 43

FT37-43

FT37-43 - 2401-FB

AMIDON-DEUTSCHLAND

PREISE-FT-TYP - Webshop

AMIDON-Kerne

Erläuterung

AL (nH/Square Turn or nH/ N²) is the AL value.L is inductance in nH (nanohenries)N is the number of turns of a wireRequired turns (N) = square root of (desired 'L' /'AL'), √'L' /'AL', or 1000 turns='mH' /'AL', (square rooted)

Color may vary by material and coating characteristicsParts are RoHS compliant

Berechnung der Ringkerne

FERRITRINGKERNE - FERRIT - TOROID - CORES

FT23-16

FT23-27

FT23-34

FT23-43

FT23-43

FT23-43

FT23-61

FT23-61

FT23-63

FT23-67

FT23-72

FT23-75

FT23-75

FT23-77

FT23-F93

FT23 - J

FT23-W76/98

FT37-16

FT37-27

FT37- 43P

FT37- 43

FT37-43

FT37-43 - 2401-FB

A_L (nH/Square Turn or nH/ N²) is the A_L value.
L is inductance in nH (nanohenries)
N is the number of turns of a wire
Required turns (N) = square root of (desired 'L' /'A_L'), √'L' /'A_L', or 1000 turns='mH' /'A_L', (square rooted)

Color may vary by material and coating characteristics
Parts are RoHS compliant