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Film
CapacitorsEMI Capacitor Design and Performance
Jan-Ulf Johanson
Product Marketing Manager
Evox Rifa AB, Kalmar, Sweden
Originally published January 1996
EMI capacitor, design and performance
Capacitors are normally classified by the dielectric used, tantalum, electrolytic,
paper, ceramic and so on. However there is one particular capacitor identified by its
application area. It is the capacitor for electromagnetic interference suppression or EMI
capacitor. In the typical application the capacitor is a part of a simple L-C net work
between the equipment and the main's power supply.
The standards for approval of EMI-capacitors are EN132400 or IEC 384-14 2nd edition.
These standards set the minimum level for safety and performance. The design, material and
production process, for such a capacitor is a matter for the capacitor industry to solve.
The most important decision in the design process is the choice of dielectric material.
Common dielectrics on the market for EMI-capacitors are
- ceramic
- metallized plastic film (polypropylene and polyester)
- metallized and impregnated paper
The discussion in this paper will concentrate on capacitors with metallized film.
The thickness of films in an EMI capacitor varies between 4 and 40 m depending on class
and rated voltage. The material in the metallized electrodes on the film is either Zinc,
Aluminium or a combination of these materials. The thickness of the electrode varies
between 80 to 300 Å (1Å = 10-10m).
The films are wound to a capacitor element, namely a winding. To reduce the volume the winding is pressed flat. To obtain an electrical contact with the electrodes metal is sprayed on the end of windings.
Terminations are then welded to the sprayed contact and the finished windings are
placed in a box. If the dielectric is metallized paper the winding is impregnated, in
vacuum, with a special epoxy and becomes a solid capacitor element. All voids are filled
with epoxy. If the dielectric is metallized plastic film, the volume between the box and
the winding is filled with epoxy. The epoxy does not affect the hardness or the number of
cavities in the winding.
The capacitor is now finished and its function, the reduction of interference signals,
is the same for all technologies. The essential difference between technologies e. g.
choice of dielectric, metallization, process parameters, impregnation or casting is the
capacitor's safety performance when connected to the supply mains.
Safety performance relates to three incidents each of which could be catastrophic.
- fire as a consequence of dielectric break-down
- fire as a consequence of bad contact between wire, endspraying and electrodes
short-circuit of Y-capacitor and a risk of exposing someone to dangerous electrical
shock
EMI-capacitors are connected to the mains supply and must be designed for the
overvoltage, transients and high frequency signals that we all know exist on the mains
supply. These requirements can be transformed into measurable design criteria.
- high resistance to current surges
- high resistance to voltages surges
- high resistance against ionisation
To design and produce a capacitor that complies with these requirements is a challenge
for the capacitor industry.
High resistance to surge current
Peak current in a capacitor during a voltage surge is proportional to the rise-time of
the voltage.
Ipeak= CdV/dt
A typical capacitance value in application is C = 0.22 F and a typical rise time for a
transient is dV/dt = 2000 V/s. This gives a peak current in the capacitor of 440 A. Even
if the surge current lasts less than 1 s it is obvious that there will be large stresses
in contact areas and metallization. Performance depends on the thickness of metallization,
metal and methods for spraying and welding of wire. A measure of a capacitor's ability to
withstand current surge is the dV/dt value. Typical values for impregnated paper and
metallized plastic film you can find in the table below. It is normal that the capacitor
is tested with 10 000 pulses and du/dt value five times the specification.
dV/dt values in V/s
| Dielectric | Class | |||||
| X1 | X2 | Y | ||||
| spec | test | spec | test | spec | test | |
| Impregnated paper | 600 | 3000 | 600 | 3000 | 2000 | 10000 |
| Plastic film | 100 | 500 | 100 | 500 | 200 | 1000 |
You can see in the table that EMI-capacitors with impregnated paper as dielectric are
tested with du/dt values well above the typical rise-time for transients.
High resistance to voltage surges
Several different studies show that frequently there are transients with an amplitude
of several kilo-volts on the supply mains. In residential areas transients at 2.5 kV
should be expected and in industrial areas between 3 - 6 kV. The frequency for the highest
amplitudes is between 0.3 to 1 per year. Transients at the level of 2.5 kV can be expected
1 to 8 times per year.
A very important feature with metallized film capacitors is their ability to self-heal.
When the dielectric breaks down there is, in principle, a channel between the electrodes
that can be seen as a short circuit. The current or energy, increases very quickly, 10 ns,
from zero to a very high value, 100 - 200 mJ. The temperature in the channel increases to
a point where the dielectric material near the channel and the electrodes evaporate.
The effect of this process is that the dielectric break-down insulates itself i.e.
self-heals. The self-healing process depends on several factors such as electrode
thickness chemical composition of dielectric and process parameters during manufacturing.
It is verified in several investigations that impregnated metallized paper is the best
qualified dielectric to self-heal.
One way to improve the metallized plastic film capacitor's capability to self heal is
to divide the electrodes into segments, encl.1 type 1 and 2. The intention is that when
there is a dielectric break down in a segment the weak point will be insulated by breaking
the connections to the adjacent segments. The technology is interesting and Rifa´s
R&D department are investigating the performance of capacitors with segmented
metallization.
There are several questions:
Shape of segments and connections
Capacitance stability as a function of the number of self-healings
Surface resistivity as a function of the number of selfhealings, e.g. low insulation
across the winding
There are many questions but they can all be formulated into one single phrase "is
the design safe"?
To investigate the capacitance stability the winding structures in encl.1 was tested
with transients at 4-5 kV superimposed on the mains supply, result according to figure.
The test result clearly shows that after 50 transients the decrease in capacitance
value in metallized paper capacitors is less than in the other designs. Design of segments
and connection between them are important and can be seen by comparing the result for the
different types of segmented film. None of the capacitors start to burn during the test.
Clearly there has been a number of selfhealings in the plastic film capacitors during
the test. It is also verified that the "fuse" between the segments in film of
type 2 do not always function.
High resistance to ionisation
Ionisation is normally a destructive process and EMI capacitors should not operate in
that condition.
There are three areas in a capacitor where ionisation is likely to take place:
1) air pockets in dielectric
2) air pockets between films
3) air pockets at the end spraying
When the field-strength in a cavity reaches a critical value there will be an electric
break-down. The break-down voltage is called "Discharge inception voltage" and
is a function of the gas pressure in the cavity and the size of the cavity, "Paschens
law". In general the break-down voltage increases when the pressure in the cavity
increases. Dielectric material responds differently to this.
Polypropylene is sensitive to ionisation. It is a soft material and it is
difficult to build up a pressure to reduce the discharge inception voltage. The melting
point is relatively low and there is a clear risk that the material could begin to melt
and the capacitor becomes a short circuit.
Polyester is more resistant to ionisation. It is possible to build up the
pressure required to suppress the ionisation.
Impregnated paper contains, if properly impregnated, no cavities, - they are
completely filled with epoxy. The capacitor is therefore very resistant to ionisation.
Conclusion
The test we discussed above is to complement the tests required by the standards EN132400 and IEC 384-14 (1993). Rifa believes that high resistance to surges and ionisation are important for the safety of a component that is connected to the mains supply.
The new design with segmented metallization is interesting. Rifa has the opinion that
there should be further investigations regarding design rules before the technology can be
used on the market place. It is absolutely necessary that the weak point in a segment is
isolated by breaking the connections to the adjacent segments.
The capacitor on the market that fulfil all safety requirements in standards and
application is a modern impregnated metallized paper capacitor.
Encl. 1
Typical winding structures
Design with segmented metallization
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Last modified: november 24, 2003
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