TDK EE320x250x20 User manual

Category
Networking
Type
User manual

TDK EE320x250x20 is a large ferrite core developed for high power reactors and transformers.

With its superior magnetic characteristics and ability to withstand high temperatures, this core is ideal for use in demanding applications such as:

  • Uninterruptible Power Supply Systems (UPS)
  • CATV power supplies
  • Photovoltaic power generation
  • Power supplies for communications stations
  • Electrical vehicles
  • Automated warehouses and conveyor machines
  • Current sensors
  • General purpose inverters
  • Reactor chokes
  • Air conditioners
  • Pumps
  • Printing presses
  • Packing machines
  • Machines for the food industry

TDK EE320x250x20 is a large ferrite core developed for high power reactors and transformers.

With its superior magnetic characteristics and ability to withstand high temperatures, this core is ideal for use in demanding applications such as:

  • Uninterruptible Power Supply Systems (UPS)
  • CATV power supplies
  • Photovoltaic power generation
  • Power supplies for communications stations
  • Electrical vehicles
  • Automated warehouses and conveyor machines
  • Current sensors
  • General purpose inverters
  • Reactor chokes
  • Air conditioners
  • Pumps
  • Printing presses
  • Packing machines
  • Machines for the food industry
(1/6)
002-01 / 20071116 / e16_1.fm
• All specifications are subject to change without notice.
Large Size Ferrite Cores for High Power
Summary
Nowadays, more and more high-frequency circuits are being used in industrial equipment as well as consumer equipment. With the use of
higher frequencies, silicon steel sheets have become unsuitable for magnetic material used in transformers. Ferrite, its substitute, delivers
reduced core loss at high frequencies and is the optimum material for high-power requirements.
To meet these various demands, we at TDK have employed our ferrite development technologies accumulated over the years and
advanced production technologies to offer large, high-quality cores for high-frequency, high-power power supplies.
In the following information, introduce ferrite cores that used PE22 and PC40 materials having superior magnetic characteristics.
APPLICATIONS
Transformer
High frequency inductive heater EE320x250x20
Uninterruptible Power Supply System(UPS)
CATV’s power supply
Photovoltaic power generation
Power supply of communications station
EC70,90,120
Electrical vehicle
PQ78,107
Automated warehouse, conveyor machine
Current sensor
Reactor choke
General purpose inverter • Air conditioner
• Fun
• Pump
• Printing press
• Packing machine
• Machines for food industry
• Drier
• Compressor of freezer
• Textile machine
• Woodworking machine
• Medical machine
UU79x129x31
Trains
UU79x129x31
(2/6)
002-01 / 20071116 / e16_1.fm
• All specifications are subject to change without notice.
FEATURES
Large size ferrite cores developed for reactors and transformers used in high power units.
Please contact us for machinability of non-standard special forms.
MATERIAL CHARACTERISTICS (Typical)
• 1(mT)=10(G),1(A/m)=0.012566(Oe)
CORE LOSS vs. TEMPERATURE CHARACTERISTICS
Material PE22 PC40
Initial permeability µi [23°C] 1800 2300
Curie temperature Tc °C >200 >200
Saturation magnetic flux density
H=1194A/m
Bs
[23°C]
[100°C]
mT
510
410
500
380
Remanent flux density Br [23°C] mT 140 125
Coercive force Hc [23°C] A/m 16 15
Core loss
25kHz, 200mT
100kHz, 200mT
Pcv [100°C] kW/m
3
80
520
70
420
Electrical resistivity ρΩ • m 3 6.5
Approximate density dapp kg/m
3
4.8× 10
3
4.8× 10
3
Thermal expansion coefficient α 1/K 12× 10
–6
12× 10
–6
Thermal conductivity κ W/mK 5 5
Specific heat C
p J/kg • K 600 600
Bending strength δb3 N/m
2
9× 10
7
9× 10
7
Young’s modulus E N/m
2
1.2× 10
11
1.2× 10
11
Magnetostriction λs–0.6× 10
–6
–0.6× 10
–6
150
200
100
50
0
120100806040200
Temperature
(
˚C
)
P
cv
(
kW/m
3
)
PC40
PE22
25kHz-200mT
800
600
400
0
120100806040200
Temperature
(
˚C
)
P
cv
(
kW/m
3
)
PC40
PE22
100kHz-200mT
(3/6)
002-01 / 20071116 / e16_1.fm
• All specifications are subject to change without notice.
CORE LOSS vs. FREQUENCY CHARACTERISTICS
MATERIAL:PE22
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
Material : PE22
Temp.23˚C
300mT
250mT
200mT
150mT
100mT
50mT
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
Material : PE22
Temp.40˚C
300mT
250mT
200mT
150mT
100mT
50mT
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
Material : PE22
Temp.60˚C
300mT
250mT
200mT
150mT
100mT
50mT
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
Material : PE22
Temp.80˚C
300mT
250mT
200mT
150mT
100mT
50mT
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
Material : PE22
Temp.100˚C
300mT
250mT
200mT
150mT
100mT
50mT
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
300mT
250mT
200mT
150mT
100mT
50mT
Material : PE22
Temp.120˚C
(4/6)
002-01 / 20071116 / e16_1.fm
• All specifications are subject to change without notice.
MATERIAL:PC40
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
Material : PC40
Temp.23˚C
300mT
250mT
200mT
150mT
100mT
50mT
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
Material : PC40
Temp.40˚C
300mT
250mT
200mT
150mT
100mT
50mT
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
Material : PC40
Temp.60˚C
300mT
200mT
150mT
100mT
50mT
250mT
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
Material : PC40
Temp.80˚C
300mT
250mT
200mT
150mT
100mT
50mT
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
300mT
250mT
200mT
150mT
100mT
50mT
Material : PC40
Temp.100˚C
10
4
10
5
10
3
10
2
10
1
10
1
10
2
10
3
10
4
Frequency (kHz)
P
cv
(kW/m
3
)
300mT
250mT
200mT
150mT
100mT
50mT
Material : PC40
Temp.120˚C
(5/6)
002-01 / 20071116 / e16_1.fm
• All specifications are subject to change without notice.
SATURATION MAGNETIC FLUX AMPLITUDE PERMEABILITY vs. MAGNETIC PERMEABILITY vs.
DENSITY vs. TEMPERATURE SATURATION MAGNETIC FLUX FREQUENCY CHARACTERISTICS
CHARACTERISTICS DENSITY CHARACTERISTICS
INITIAL MAGNETIC PERMEABILITY vs.
TEMPERATURE CHARACTERISTICS
DIMENSIONAL RESONANCE
Dimensional resonance is a phenomenon which increases loss
and decreases magnetic permeability by electromagnetic standing
waves when the magnetic field of the core frequency is applied.
The phenomenon appears when the maximum dimension of the
cross section of the core perpendicular to the magnetic field is the
integral multiple of about half of the electromagnetic wavelength
λ.
C: Electromagnetic wave speed in a vacuum(3.0× 10
8
m/s)
µ
r: Relative magnetic permeability
ε
r: Relative permissivity
f: Frequency of the applied magnetic field(electromagnetic wave)
As µe decreases by inserting into the gap, using the same core
enables high frequency wave usage as indicated by the formula
above.
As dimensional resonance quickly decreases magnetic permeabil-
ity, design the actual frequency to avoid dimensional resonance.
In the case of possible dimensional resonance, it can be protected
against by dividing the core in the magnetic circuit direction and
bonding them.
RESONANCE DIMENSION vs. FREQUENCY
CHARACTERISTICS
100
200
300
400
500
600
700
0
150100500
Temperature
(
˚C
)
B
s
(
mT
)
PE22
PC40
1000
2000
3000
0
10
4
10
3
10
2
10
1
Frequency
(
kHz
)
µ′, µ′′
Material: PE22
Temp.: 23
˚C
µ′
µ′′
3000
4000
5000
2000
3002001000
Flux density
(
mT
)
µ
a
120˚C
100˚C
80˚C
60˚C
40˚C
23˚C
Material: PE22
f=16kHz
2000
1000
6000
0
3002001000
Temperature
(
˚C
)
µ
i
PE22
PC40
4000
3000
5000
f=1kHz
H
m
=0.4A/m
3000
4000
5000
2000
3002001000
Flux density
(
mT
)
µ
a
120˚C
100˚C
80˚C
60˚C
40˚C
23˚C
Material: PC40
f=16kHz
1000
2000
3000
0
10
4
10
3
10
2
10
1
Frequency
(
kHz
)
µ′, µ′′
Material: PC40
Temp.: 23
˚C
µ′
µ′′
λ=
f ×
µ
r
ε
r
×
C
10
3
10
2
10
1
10
3
10
2
10
1
Frequency
(
kHz
)
Resonant dimension
(
mm
)
PE22
PC40
(6/6)
002-01 / 20071116 / e16_1.fm
• All specifications are subject to change without notice.
GENERAL PRECAUTIONS WHEN USING FERRITE CORE
When selecting the material/form of the ferrite core, while
considering the margins select from the range in the catalog
(product manual) display where factors such as inductance
value, maximum saturation flux density, core loss, temperature
characteristics, frequency characteristics and Curie temperature
are concerned.
Select material that does not corrode or react in order to avoid
insulation failure or a layer short, and also be careful to avoid
loose winding of the core or causing damage to the wire.
Be careful that the equipment and tools you use do not strike the
core in order to avoid core cracks.
Please consider using cases, bobbins or tape for insulation
purposes.
When using cases and bobbins, select those with a heat
expansion coefficient as close to that of the ferrite as possible.
When laying out the case, bobbin, coil and the ferrite core,
create clearance between each part in order to prevent any core
cracks and to assure insulation.
Please handle with care, since a ferrite core is susceptible to
shock.
The outward appearance is determined according to the
standard of our company.
Do not place close to strong magnets.
Be careful not to cause shock by the use of equipment and tools.
Be careful not to expose to rapid change in temperature, since it
is also susceptible to thermal shock.
Careless handling may hurt your skin, since the corners of the
polished surface of the ferrite are very sharp, and in some
cases, burrs may have formed on the surface.
Please be very careful when stacking and handling the
containers, since some ferrite cores are heavy, and can cause
injury, toppling or back pain.
Where inner packaging is concerned, please be careful not to
damage the core when taking it out from the container since the
packing materials used in order to prevent damage during
transportation may make it difficult to take out.
Do not reprocess the ferrite core as it can cause problems, such
as injury.
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TDK EE320x250x20 User manual

Category
Networking
Type
User manual

TDK EE320x250x20 is a large ferrite core developed for high power reactors and transformers.

With its superior magnetic characteristics and ability to withstand high temperatures, this core is ideal for use in demanding applications such as:

  • Uninterruptible Power Supply Systems (UPS)
  • CATV power supplies
  • Photovoltaic power generation
  • Power supplies for communications stations
  • Electrical vehicles
  • Automated warehouses and conveyor machines
  • Current sensors
  • General purpose inverters
  • Reactor chokes
  • Air conditioners
  • Pumps
  • Printing presses
  • Packing machines
  • Machines for the food industry

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