EPCOS BCP54-10 45 v, 1 a npn medium power transistor Datasheet

General Technical Information
1
Inductive components for electronic equipment
Especially in this age of fully-electronic and highly-integrated equipment, inductive components are
indispensable. They are used to store energy intermittently in switch-mode power supplies and
DC/DC converters, as parts of high-frequency circuits, as filter elements and last but not least as
interference suppression components to ensure EMC.
Of course, the demands placed on inductors depend on how and where they are to be used. In HF
circuits, coils with high quality factors and resonance frequencies are needed. In EMC applications,
high inductances are required in order to achieve good interference suppression characteristics, low
Q factors being more desirable here due to the need to avoid resonances.
EPCOS provides suitable inductive components for all applications. This data book contains a wide
selection of standard components, from SMT types (starting with SIMID 0402) right up to the 4-line
high-current inductors for power electronics applications.
Attention is drawn to the excellent HF characteristics and the extremely high reliability of the components, achieved thanks to large-scale production automation and many years of experience in
the manufacture of this kind of components.
An overview of typical applications for inductors and chokes
Application
Inductance
Current rating Resonance
frequency
low
very high
HF circuits,
low
resonant circuits
EMC
high
∗
Filter circuits
high
high
Switch-mode
∗
∗
power supplies,
DC/DC converters
∗ depends on the specific application
1.1
high
high
medium
Q factor
DC resistance
very high
low
low
low
high
very low
very low
low
HF circuits
SMT styles (SIMID product range) and leaded RF chokes are especially suitable for RF and other
high-frequency circuits. Typical applications are resonant circuits and frequency-selective filters of
the type being increasingly used in telecommunications engineering and automotive electronics. In
some cases, special demands on the inductive components arise, for example, when used in transmitter output circuits of mobile telephones (high Q factors and resonance frequencies) and in airbag control circuits (high pulse currents).
1.2
Filter circuits
When inductive components are used for filters in power supplies for electronics, high inductances, the
lowest possible DC resistance and a low Q factor are required. The impedance should have a wideband frequency characteristic. In addition to the current rating, the maximum permissible pulse current
(switching transient currents) and adequately high core material saturation are of importance.
Chokes belonging to all type series presented here can be used for this range of applications, from
the SIMID types right up to chokes with powder cores and one or two lines.
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General Technical Information
1.3
Switch-mode power supplies, DC/DC converters
Inductive components are used for magnetic energy storage in all kinds of switch-mode power supplies and DC/DC converters. For example, the SIMID 1812 product range is used in low-power stepup converters in automobile electronics and in battery-powered equipment. They can be subjected
for short periods to currents which are the quadruple of their current rating without any saturation
effects occurring.
1.4
EMC applications
For broadband interference suppression, current-compensated chokes with ring cores or D cores
and powder core chokes are especially suitable.
Apart from use as filters in mains and other power supply lines, such chokes are important for data
lines as used in telecommunications engineering, e. g. in NTBAs (Network Termination Basic Access Units, ISDN), in line cards in telephone exchanges (ISDN and analog) and in the fast-expanding CAN bus application field (CAN = Controller Area Network) in automotive electronics.
Almost all the component families are approved in accordance with the main international standards. All chokes for low-frequency mains networks are dimensioned and tested in compliance with
the applicable EN and IEC standards.
Inductive components with particularly good RF characteristics are achieved by the use of ungapped
cores. The manufacturing methods developed by EPCOS lead to good reproducibility of the attenuation characteristics and enable the production of high-quality components at a favorable price.
The company’s many years of experience guarantee that customers quickly and economically obtain just the right solutions to their EMC problems. Our own EMC laboratory in Regensburg or one
of our European EMC partner laboratories is at your disposal at all times to help with professional
advice and in carrying out measurements (also refer to the chapter on “Services”).
1.4.1
Propagation of interference
Interference voltages and currents can be grouped into common-mode interference, differentialmode interference and unsymmetrical interference:
1a
1b
1c
Us
Uas
Uus1
Uus2
U = V = voltage
SSB1465-P
asymmetrical
asymmetrische
propagation
Ausbreitung
symmetrical
symmetrische
propagation
Ausbreitung
unsymmetrical
unsymmetrische
propagation
Ausbreitung
Fig. 1
Propagation modes
SSB1465-P
■ Common-mode interference (asymmetrical interference):
– occurs between all lines in a cable and reference potential (fig. 1a),
– occurs mainly at high frequencies (from approximately 1 MHz upwards).
■ Differential-mode interference (symmetrical interference):
– occurs between two lines (L-L, L-N) (fig. 1b),
– occurs mainly at low frequencies (up to several hundred kHz).
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General Technical Information
■ Unsymmetrical interference:
– This term is used to describe interference on a single line, relative to the reference potential
(fig. 1c)
1.4.2
Characteristics of interferences
In order to be able to choose the correct EMC measures, we need to know the characteristics of the
interferences, how they are propagated and the mechanisms by which they are coupled into the circuit. In principle, the interferences can also be classified according to their range (fig. 2). At low frequencies, it can be assumed that the interference only spreads along conductive structures, at high
frequencies only by means of electromagnetic radiation. In the MHz frequency range, the term coupling is generally used to describe the mechanism.
Analogously, conducted interference on lines at frequencies of up to several hundred kHz are mainly symmetrical (differential mode), at higher frequencies, they are asymmetrical (common mode).
This is because the coupling factor and the effects of parasitic capacitance and inductance between
the conductors increase with frequency.
X capacitors and single chokes are suitable as suppression measures for the differential mode components. Where asymmetrical, i.e. common-mode interference has to be eliminated, current-compensated chokes and Y capacitors are mainly used, the prerequisite for this being, however, a welldesigned, EMC-compliant grounding and wiring system.
The categorization of types of interference and suppression measures and their relation to the frequency ranges is reflected in the frequency limits for interference voltage and interference field
strength measurements.
SSB1558-D
Differential mode
Common mode
Field
Interference
characteristic
Line
Coupling
Field
Interference
propagation
X cap
Pc ch.
Y cap
Cc ch.
Ground
Interference voltage
10
_2
10
_1
10 0
Remedies
Shielding
Field strength
10 1
10 2
Max. ratings
MHz 10 3
f
Fig. 2
Frequency range overview
Pc ch. = Iron powder core chokes, but also all single chokes/ X cap = X capacitors
Cc ch. = Current-compensated chokes / Y cap = Y capacitors
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General Technical Information
2
Electromagnetic compatibility (EMC)
2.1
Introduction
For as long as electronic transmission equipment such as radio, television, and telephone has been
in existence, it has had a history of susceptibility to interference from other electronic devices. Legal
regulations on interference suppression (electromagnetic and radio frequency interference, EMI
and RFI) have been in existence since 1928. These regulations protect transmission paths and reception equipment by limiting the emitted interference.
In view of the increasing number of electrical and electronic appliances in use, not only the principles of interference suppression must be observed, but also, in the sense of electromagnetic compatibility (EMC), it must be ensured that all equipment is able to operate simultaneously without
problems. EMC is defined as the ability of electrical equipment to function satisfactorily in its electromagnetic environment without affecting other equipment in this environment to an impermissible
extent.
The European Communities’ EMC Directive (89/336/EEC) came into force on the 1. 1. 1996. It has
been transformed into corresponding legislation in the individual EU (European Union) member
states. With this, it has become mandatory to design electronic equipment to comply with the protection objectives of this Directive; i.e. to meet the requirements for electromagnetic emission and
electromagnetic immunity as laid down in the corresponding EN standards (European Standards).
The concept of EMC includes both electromagnetic emission (EME) and electromagnetic immunity/
susceptibility (EMS), see fig. 3.
EMC = Electromagnetic
compatibility
EMC
Emission
Susceptibility
EME
EMS
CE
RE
Interference
source
Fig. 3
Conducted
Radiated
Propagation
CS
EME = Electromagnetic
emission
EMS = Electromagnetic
immunity/susceptibility
CE
= Conducted emission
CS
= Susceptibility to
conducted emission
RE
= Radiated emission
RS
= Susceptibility to
radiated emission
RS
Disturbed
equipment
EMC terms
An interference source may generate conducted or radiated electromagnetic energy, i.e. conducted
emission (CE) or radiated emission (RE). This also applies to the propagation paths and to the electromagnetic susceptibility of disturbed equipment.
In order to work out economical solutions, it is necessary consider both phenomena, i.e. propagation and susceptibility, to an equal extent, and not just one aspect, e.g. conducted emission.
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General Technical Information
EMC components are used to reduce conducted electromagnetic interference to the limits in an
EMC plan or to reduce this interference below the limit values specified in the EMC regulations.
These components may be installed either in the source of potential interference or in the disturbed
equipment (fig. 4).
RE
Power supply
RE
CE
CE
Source
CE
CE
RE
Disturbed
equipment
CE
RE
SA
Signal line
CE
Control line
CE
Filter
Fig. 4
Interference currents
Interference voltages
RE
Electric field
Magnetic field
Electromagnetic field
Susceptibility model and filtering
EPCOS offers EMI suppression components with a well-balanced range of rated voltages and currents for power supply lines as well as for signal and control lines.
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General Technical Information
2.2
Interference sources and disturbed equipment
Interference source
An interference source is an electrical device or electrical equipment which emits electromagnetic
interference. We can differentiate between two main groups of interference sources corresponding
to the type of frequency spectrum emitted (fig. 5).
Interference source (emission)
Discrete frequency spectrum
(Sine-wave, low energy)
Continuous frequency spectrum
(Impulses, high energy)
µP systems
RF generators
Medical equipment
Data processing systems
Microwave equipment
Ultrasonic equipment
RF welding apparatus
Radio and TV receivers
Switch-mode power supplies
Frequency converters
UPS systems
Electronic ballast circuits
Fig. 5
Switchgear (contactors, relays)
Household appliances
Gas discharge lamps
Power supplies and battery chargers
Ignition systems
Welding apparatus
Motors with brushes
Oscillating drives
Atmospheric discharges
Sources of interference
Interference sources with discrete frequency spectra (e.g. high frequency generators and microprocessor systems) emit interference energy which is concentrated on narrow frequency bands.
Switchgear and electric motors in household appliances, however, distribute their interference energy over broad frequency bands and are considered to belong to the group of interference sources
having a continuous frequency spectrum.
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General Technical Information
Disturbed equipment
Electrical devices, equipment and/or systems subject to interference and which can be adversely
affected by it are termed disturbed equipment.
In the same way as interference sources, disturbed equipment can also be categorized corresponding to frequency characteristics. A distinction can be made between narrowband and broadband
susceptibility (fig. 6).
Narrowband systems include radio and TV sets, for example, whereas data processing systems are
generally specified as broadband systems.
Disturbed equipment (affected by EMI)
Narrowband susceptibility
Broadband susceptibility
Radio and TV receivers
Radio reception equipment
Modems
Data transmission systems
Telemetric radio transmission devices
Frequency-coded signalling equipment
Fig. 6
2.3
Digital and analog systems
Data processing systems
Process control computers
Control systems
Video transmission systems
Interface lines
Disturbed equipment
Propagation of electromagnetic interference and EMC measurement techniques
As previously mentioned, an interference source causes both conducted and radiated electromagnetic interference.
Propagation along lines can be detected by measuring the interference current and the interference
voltage (fig. 7).
The effect of magnetic and electric interference fields on their immediate vicinity is assessed by
measuring the radiated magnetic and electric field components. This method of propagation is also
frequently termed electric or magnetic coupling (near field).
In higher frequency ranges, characterized by the fact that device dimensions are in the order of
magnitude of the wavelength under consideration, the interference energy is mainly radiated directly (far field).
Conducted and radiated propagation must also be taken into consideration when measuring the
susceptibility of disturbed equipment.
Interference sources e.g. sine-wave generators as well as pulse generators with a wide variety of
pulse shapes are used for such tests.
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Netzzuführung
Stromwandler
Power
supply
Current
Voltage
probe
Tastkopf
probe
NetzLine impedance
stabilization
Nachbildung
network
Broadband
dipole antenna
Breitbandantenne
I int
Ι
S
Messempfänger
Selective
voltmeter
VUintS
PSint
Messempfänger
Selective
voltmeter
Spektrumanalysator
Spectrum
analyzer
Speicheroszillograph
Storage
oscilloscope
Transientenrekorder
Transient
recorder
Hint = Magnetic
interference fields
Eint = Electrical
interference fields
Pint = Electromagnetic
interference fields
(radiated emission)
Iint = Interference current
Vint = Interference voltage
Source
Quelle
EEint
S
H
HSint
Loop antenna
Rahmenantenne
Stabantenne
Rod
antenna
NearNahfeldkopplung
field coupling
Messempfänger
Selective
voltmeter
Messempfänger
Selective
voltmeter
SSB0016-2
SSB0016-2
Fig. 7
2.4
Propagation of electromagnetic interference and EMC measurement techniques
EMC regulations und legislation
A wide range of legislation and of harmonized standards have come into force and been published
in the field of EMC in the past few years. In the European Union, the EMC Directive 89/336/EEC of
the Council of the European Communites has come into effect on the 1st of January 1996. As of
this date, all electronic equipment must comply with the protection objectives of the EMC Directive.
The conformity with the respective standards must be guaranteed by the manufacturer or importer
in the form of a declaration of conformity. A CE mark of conformity must be applied to all equipment.
As a matter of principle, all electrical or electronic equipment, installations and systems must meet
the protection requirements of the EMC Directive and/or national EMC legislation. A declaration of
conformity by the manufacturer or importer and a CE mark are required for most equipment. Exceptions to this rule and special rulings are described in detail in the EMC laws.
New, harmonized European standards have been drawn up in relation to the EEC’s EMC Directive
and the national EMC laws. These specify measurement procedures and limit values or test severities, both for interference emission and for the interference susceptibility (or rather, immunity to interference) of electronic devices, equipment and systems.
The subdivision of the European standards into various categories (cf. following table) makes it
easier to find the rules that apply to the respective equipment.
The generic standards always apply to all equipment for which there is no specific product family
standard or dedicated product standard.
The basic standards contain information on interference phenomena and general measuring
methods.
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The following standards and regulations form the framework of the conformity tests:
EMC standards
Germany
Europe
International
Generic standards
define the EMC environment in which a device is to operate according to its intended use
Emission
residential
industrial
DIN EN 50081-1
DIN EN 50081-2
EN 50081-1
EN 50081-2
—
Susceptibility
residential
industrial
DIN EN 50082-1
DIN EN 50082-2
EN 50082-1
EN 50082-2
—
Basic standards
describe physical phenomena and measurement procedures
Basics
DIN VDE 0843
Measuring equipment
DIN VDE 0876
Measuring
methods
DIN VDE 0877
emission
susceptibility
EN 61000
IEC 61000
CISPR 16-1
EN 61000-4-1
CISPR 16-2
IEC 61000-4-1
Harmonics
DIN VDE 0838
EN 60555-2
IEC 61000-3-2
Interference factors
e.g.
ESD
EM fields
Burst
Surge
Injection
DIN VDE 0843-2
DIN VDE 0843-3
DIN VDE 0843-4
DIN VDE 0843-5
DIN VDE 0843-6
EN 61000-4-2
EN 61000-4-3
EN 61000-4-4
EN 61000-4-5
EN 61000-4-6
IEC 61000-4-2
IEC 61000-4-3
IEC 61000-4-4
IEC 61000-4-5
IEC 61000-4-6
EN 55011
1)
CISPR 11
1)
Product standards
define limit values for emission and susceptibility
ISM equipment emission
susceptibility
DIN VDE 0875 T11
1)
Household
appliances
emission
susceptibility
DIN VDE 0875 T14-1 EN 55014-1
DIN VDE 0875 T14-2 EN 55014-2
CISPR 14-1
CISPR 14-2
Lighting
emission
susceptibility
DIN VDE 0875 T15-1 EN 55015-1
DIN VDE 0875 T15-2 EN 55015-2
CISPR 15
IEC 3439
Radio and
TV equipment
emission
susceptibility
DIN VDE 0872 T13
DIN VDE 0872 T20
EN 55013
EN 55020
CISPR 13
CISPR 20
High-voltage
systems
emission
DIN VDE 0873
EN 55018
CISPR 18
ITE equipment emission
susceptibility
DIN VDE 0878
DIN VDE 0878
EN 55022
EN 55022
CISPR 22
CISPR 22
Vehicles
DIN VDE 0879
DIN VDE 0839
EN 72245
CISPR 25
ISO 11451/ S2
emission
susceptibility
1) Is governed by the safety and quality standards of the product families.
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The following table shows the most important standards in the field of immunity to interference.
Standard
Test characteristics
Phenomena
EN 61000-4-4
IEC 61000-4-4
5/50 ns (single impulse)
15 kHz burst
Burst
Cause: switching processes
EN 61000-4-5
IEC 61000-4-5
1,2 / 50 ms (open-circuit voltage) Surge (high-energy transients)
8 / 20 ms (short-circuit current)
Cause: lightning strikes mains
lines, switching processes
EN 61000-4-6 (ENV 50141)
IEC 801-6
1 V, 3 V, 10 V
150 kHz … 80 MHz
High-frequency coupling
Narrow-band interference
3 V/m, 10 V/m
80 … 1000 MHz
High-frequency
interference fields
Conducted interference
Radiated interference
EN 61000-4-3 (ENV 50140)
IEC 801-3
Electrostatic discharge (ESD)
EN 61000-4-2
IEC 61000-4-2
Up to 8 kV
5 / 50 ns
Electrostatic discharge
Voltage dips, short interruptions and variations
EN 61000-4-11
IEC 61000-4-11
0,7 VR
0,4 VR
1 … 50 ms optional
VR = 0
10 ms
Electrostatic discharge
The IEC 1000 or EN 61000 series of standards are planned as central EMC standards into which
all EMC regulations (e.g. IEC 801, IEC 555) are to be integrated in the next few years.
2.5
Propagation of conducted interference
In order to be able to choose suitable interference suppression components, the way in which conducted interference is propagated needs to be known (fig. 8).
Interference
source
Disturbed
equipment
Common-mode
interference current
Differential-mode
interference current
Cp: Parasitic capacitance
R: Resistance
Fig. 8
Common-mode and differential-mode interference
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An interference source which is at a floating potential primarily emits differential-mode, i.e. symmetrical interference which is propagated along the connected lines. On power lines, the interference
current will flow towards the disturbed equipment on one wire and away from it on the other wire,
just as the mains current does.
Symmetrical or differential-mode interference occurs mainly at low frequencies (up to several
hundred kHz).
However, parasitic capacitances in interference sources and disturbed equipment or intended
ground connections, also lead to an interference current in the ground circuit. This interference current flows towards the disturbed equipment through both the connecting lines and returns to the interference source through the ground lines.The currents on the connecting lines are in common
mode and the interference is thus designated as common-mode or asymmetrical interference.
Since the parasitic capacitances will tend towards representing a short-circuit with increasing frequencies and the coupling to the connecting cables and the equipment itself will increase correspondingly, common-mode interference becomes dominant at multiple-MHz frequencies.
In European usage, the concept of an “unsymmetrical interference” is used, in addition to the two
components described above, to describe interference. This term is used to describe the interference voltage between a line and reference ground potential.
2.6
Filter circuits and line impedance
Interference suppression filters are virtually always designed as reflecting lowpass filters, i.e. they
reach their highest insertion loss when they are - on the one hand - mismatched to the impedance
of the interference source or disturbed equipment and - on the other hand - mismatched to the impedance of the line. Possible filter circuits for various line, interference source and disturbed equipment impedance conditions are shown in fig. 9.
Line
impedance
Impedance of
source of interference / disturbed equipment
low
high
high
high
high
unknown
high
unknown
low
low
low
unknown
low
unknown
Fig. 9
Filter circuits and impedance relationships
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It is, therefore, necessary to find out the internal impedances so that optimum filter circuit designs
as well as economical solutions can be implemented.
The internal impedances of the power networks under consideration are usually known from calculations and extensive measurements, whereas the impedances of interference sources or disturbed
equipment are, in most cases, not or only inadequately known.
For this reason, it is impossible to design the most suitable filter solution without measuring the
equipment characteristics. In this context, we offer all our customers the competent assistance of
our skilled staff, both on-site and in our EMC laboratory in Regensburg (also see chapter on “Services offered”, page 32).
3
Selection criteria for EMC components
To comply with currently valid regulations, a frequency range of 150 kHz to 1000 MHz has to be
taken into consideration, in most cases, in order to ensure electromagnetic compatibility; in addition,
however, factors such as low-frequency line interference should be considered.
EMC components must thus have favorable RF characteristics and are ususally required to be effective over a broad frequency range.
For individual components (inductors) the RF characteristics are specified by stating the impedance
as a function of frequency.
4
Arrangement of EMC components
When designing filter circuits using individual components, observe the following basic rules:
■ The components should be arranged along the lines (see example in fig. 10) to avoid capacitive
and inductive coupling between components and between filter inputs and outputs.
■ As insertion loss of a filter circuit in the MHz range is mainly determined by the capacitors con-
nected to ground, the connecting leads of these capacitors should be as inductance-free as possible, i.e. short.
■ Filter circuits which are to be installed in devices with limited space must be shielded.
Chokeint
Fig. 10
Correct arrangement of filter components, e.g. on a PC board
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When using off-the-shelf filters, observe the following rules:
■ Ensure a proper electrically conductive connection between the filter case and/or filter ground
and the metallic case of the interference source or disturbed equipment, and
■ provide sufficient RF decoupling between the lines at the filter input (line causing the interfer-
ence) and the filter output (filtered line), if necessary by using shielding partitions.
5
Approvals
All products by EPCOS AG are basically designed to conform to the German VDE regulations
and/or EN standards. The respective regulations or standards are given for each component type.
Many of our components have also been approval-tested in accordance with national and international regulations. The approval marks and quality assurance marks are listed in the data sheets.
Examples of approval marks:
UL
USA
VDE
Germany
Example of a quality assurance mark:
CECC quality assurance mark
In future, chokes will be tested in accordance with the new European standard EN 138 100. A uniform European mark of conformity has not yet been defined. For the time being the national marks
of conformity are used (e.g. VDE) and the corresponding European standards is stated beside the
mark.
6
Safety regulations
When selecting EMC components – in particular in case of power line applications – the safety regulations applicable to the relevant equipment must be observed.
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7
Electrical characteristics
7.1
Rated voltage VR
The rated voltage VR is the maximum ac or dc voltage which can be continuously applied to the
component at temperatures between the lower category temperature Tmin and the upper category
temperature Tmax.
7.2
Test voltage VT
The test voltage VT is the ac or dc voltage which may be applied to the component for the specified
test duration in the course of final inspection (100% end of line testing). This test may be repeated
once as an incoming goods inspection test.
7.3
Rated current IR
The rated current lR is ac or dc current at which the component may be continuously operated under
the nominal operating conditions.
For components with 1, 2 or 3 lines, the rated current is specified for simultaneous flow of a current
of this value through all lines.
During ac operation, higher thermal loads may be caused due to waveforms which deviate from a
pure sine wave. Where necessary, such cases must be taken into consideration.
7.4
Overcurrent
The rated current may be exceeded briefly. Details on permissible currents and load duration can
be obtained upon request.
7.5
Pulse handling capability
Saturation effects (e.g in the ferrite cores used) may occur when high-energy pulses are applied to
the components and these may lead to impaired interference suppression. The maximum permissible voltage-time integral area is used to characterize the pulse handling capability of chokes. For
standard components a range from 1 to 10 mVs can be assumed. More specific data can be obtained upon request.
7.6
Current derating Iop/IR
At ambient temperatures above the operating temperature stated in the data sheet, the operating
current must be reduced according to the derating curve.
7.7
Rated inductance LR
The rated inductance LR is the inductance which has been used to designate the choke, as
measured at the frequency fL.
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7.8
Stray inductance LS
The stray inductance LS (also termed leakage inductance) is the inductance measured through
both coils when a current-compensated choke is short-circuited at one end. This affects symmetrical interference.
Fig. 11
7.9
Stray inductance
Inductance decrease ∆L/L0
The inductance decrease ∆L/L0 is the drop in inductance at a given current relative to the initial
inductance L0 measured at zero current. The data sheets specify this as a percentage. This decrease is caused by the magnetization of the core material, which is a function of the field strength,
as induced by the operating current. Generally the decrease is less than 10 % .
7.10
DC resistance Rtyp, Rmin, Rmax
The dc resistance is the resistance of a line as measured using direct current at a temperature of
20 °C, whereby the measuring current must be kept well below the rated current.
Rtyp
Rmin
Rmax
typical value
minimum value
maximum value
7.11
Winding capacitance, parasitic capacitance CP
Parasitic capacitances (CP), which impair the RF characteristics of the components, are related to
the component geometry. These capacitances may affect the two lines mutually (symmetrically) as
well as the line-to-ground circuit (asymmetrically). The design of all EMC components supplied by
EPCOS minimizes the parasitic effects. Due to this, these components have excellent interference
suppression characteristics right up to high frequencies.
7.12
Quality factor Q
The quality factor Q is the quotient of the imaginary component of the impedance divided by the real
component.
7.13
Measuring frequencies fQ, fL
fQ is the frequency for which the quality factor Q of a choke is specified.
fL is the frequency at which the inductance of a choke is determined.
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7.14
Insertion loss
The insertion loss is a criterium for the effectivity of interference suppression components, as
measured by using a standardized measurement circuit (fig. 12).
Reference measurement
U = V = Voltage
Insertion loss measurement
Fig. 12
Definition of insertion loss
The input terminals of the equipment under test are connected to an RF generator with impedance
Z (usually 50 Ω) . At the output end of the component, the voltage is measured using a selective
voltmeter having the same impedance Z. The insertion loss is then calculated from the quotient of
the no-load generator voltage V0 and half the output voltage V2.
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8
Mechanical properties
8.1
Potting (economy potting, complete potting)
We distinguish between economy potting and complete potting.
Economy potting is used to fix the the core and windings in the case and the windings on the core.
This is an economical technique which enables a single resin casting procedure to be used. Because of this, most chokes supplied by EPCOS are produced using this method.
Complete potting is only required when the thermal conductitvity of economy potting is not adequate
or if the customer has special demands. Complete potting requires several process steps to ensure
complete embedding of the core and the windings.
Economy potting
8.2
Complete potting
Types of winding
EPCOS uses different types of winding to suit the respective technical requirements:
– single-layer winding
– multilayer winding
– random winding
The different types of winding lead to different inductance characteristics, especially at high frequencies.
Single-layer winding:
1
2
3
4
5 6
7
8
9 10 11 12 13 14 15 16 17 18 19
1
2
3
4
5 6
7
8
9 10 11 12 13 14 15 16 17 18 19
The winding pitch is equal to or greater than the wire diameter. The coil is wound in one direction
only. The only capacitances (parasitic capacitances) are those between one turn to the next. In
comparison to all other types of winding, this type of winding leads to the lowest possible capacitances and thus the highest resonance frequencies.
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Multilayer winding:
19 18 17 16 15 14 13 12 11
1 2 3 4 5 6 7 8 9 10
1 2 3 4 5 6 7 8 9 10
19 18 17 16 15 14 13 12 11
The winding pitch is equal to the wire diameter. The coil is wound with several layers. This leads to
parasitic capacitances between the layers in addition to the turn-to-turn capacitances. In comparison to all other types of winding, this type leads to the highest capacitances and thus the lowest
resonance frequencies.
Random winding:
4
7 9
12
16 18
1 2 3 5 6 8 10 11 13 14 15 17 19
1 2 3 5 6 8 10 11 13 14 15 17 19
4
7 9
12
16 18
14
The winding pitch is smaller than the wire diameter. The coil is wound in one direction only. This
method of winding a coil does not permit the final position of a turn to be predetermined exactly. The
cross section of this type of winding clearly shows a disorderly, “random” arrangement of the turns.
This leads to the parasitic capacitances being only minimally greater than those achieved by singlelayer winding, and the resonance frequencies are equal to those achieved by single-layer winding.
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8.3
RF characteristics of various types of winding
Figure 13 shows the relation between the impedance and the frequency for two chokes of equal inductance. One of the chokes has a two-layer winding and the other is randomly wound. The choke
with random windings has a considerably higher first resonance frequency. The spurious resonances are very much higher than 10 MHz. The impedance at frequencies above the first resonance frequency is approximately five times higher. This leads to better interference suppression at high
frequencies.
2-layer wdg.
Random wdg.
Fig. 13
Impedance |Z| versus frequency f
comparison between two-layer winding and random winding
The RF characteristics of all chokes supplied by EPCOS are within the specifications and reproducible, as the winding processes which we have developed for single-layer, multilayer and random
winding ensure that the characteristics of the inductors produced display very little variation.
The reproducibility of electrical characteristics of chokes is mainly determined by the production
technique used. At EPCOS, coils are wound mainly by automatic machines (either fully or semi-automated). This permits even complicated winding patterns to be produced in large production runs
with very little variation in product characteristics. In fig. 14, the impedance curves of several
chokes, some wound manually and some by machine, are shown for comparison. With the random
winding used in this comparison, the advantages of machine winding are clearly noticeable.
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Manually wound
Machine wound
Fig. 14
Impedance |Z | versus frequency f
Reproducibility and scatter achieved by manual and by machine winding techniques.
9
Climatic characteristics
9.1
Upper and lower category temperature Tmax and Tmin
The upper category temperature Tmax und the lower category temperature Tmin are defined as the
highest and the lowest permissible ambient temperatures, respectively, at which the component
can be operated continuously.
9.2
Rated temperature TR
The rated temperature TR is defined as the highest ambient temperature at which the component
may be operated under nominal conditions.
9.3
Reference temperature for measurements
Unless otherwise specified in the data sheets, the reference temperature for all electrical measurements is 20 °C in accordance with IEC 60068-1.
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9.4
IEC climatic category
lEC 60068 -1, Appendix A, defines a method of specifying the climatic category by three groups of
numbers delimited by slash characters.
Example:
55/085/56
– 55 °C
+ 85 °C
56 days
1st group of numbers:
Absolute value of the lower category temperature Tmin as test temperature for
test Aa (cold) in accordance with IEC 60068-2-1
2nd group of numbers:
Upper category temperature Tmax as test temperature for
test Ba (dry heat) in accordance with IEC 60068 -2-2
test duration: 16 h
3rd group of numbers:
Number of days denoting the test duration for
test Ca (damp heat, steady-state) in accordance with IEC 60068-2-3
at (93 + 2/– 3) % rel. humidity and an ambient temperature of 40 °C
10
Sizes
The sizes of surface-mount components
are encoded using a four-digit coding system.
The code differs depending on the standard which it is based on.
The American EIA standards require the length and width to be stated in hundredths of an inch, in
European standards and in the IEC draft standards, these dimensions are encoded in tenths of a
millimeter. The following table sumarizes the sizes:
Length × width
(mm)
1,0 × 0,5
1,6 × 0,8
2,0 × 1,2
2,5 × 2,0
3,2 × 2,5
4,5 × 3,2
5,6 × 5,0
EIA
IEC/EN
0402
0603
0805
1008
1210
1812
2220
1005
1608
2012
2520
3225
4532
5650
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11
Dangerous substances in components
Dangerous substances (as defined by the German regulation “Gefahrstoffverordnung”) are only
used in our production and to an extent where the state of the art leaves us no alternative. Wherever
possible, we replace them by materials with safe characteristics. Where this is not possible, special
staff entrusted with environmental protection and supervision of noxious materials monitor strict adherence to relevant laws and regulations in each of our factories.
As part of these efforts to manufacture our products without using dangerous substances as far as
possible, we can guarantee for all components presented in this data book that they do not contain
the following materials and compounds:
–
–
–
–
–
–
–
–
acryl nitrile
aliphatic chlorinated organic componds
arsenic compounds
asbestos
lead carbonate and lead sulphide
halogenated dioxines and furanes
cadmium
chlorinated fluorocarbons (CFC),
nor are they used in component manufacture.
Others,
–
–
–
–
–
–
–
–
–
formaldehyde
pentachlorophenol (PCB)
polychlorinated biphenyles (PCB)
polychlorinated terphenyles (PCT)
mercury compounds
creosote
ugilec and DBBT (PCB substitutes)
organic tin compounds
vinyl chloride
may be used in manufacture but the components do not contain these.
The packaging of our components is generally suitable for ESD areas and free of pollutants. Full
details are available from our sales offices.
12
Disposal
In the light of the facts stated above on the topic of dangerous substances, all components presented in this book can be disposed of without problems. Most of our components will be accepted by
the respective electronic scrap recycling companies for material recycling and/or thermal decompositon. Of course the corresponding local regulations must be observed.
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