In 1745 a new physics
and mathematics professor at the University of Leyden (spelled Leiden in
modern Dutch), Pieter van Musschenbroek (1692 - 1791) and his assistants
Allmand and Cunaeus from the Netherlands invented the 'capacitor'
(electro-static charge or capacitance actually) but did not know it at first.
His condenser was called the 'Leyden Jar' (pronounced: LY'duhn) and named so by
Abbe Nollet. This Leyden jar consisted of a narrow-necked glass jar coated over
part of its inner and outer surfaces with a conductive metallic substance; a
conducting rod or wire passes through as insulating stopper (cork) in the neck
of the jar and contacts the inner foil layer, which is separated from the outer
layer by the glass wall. The Leyden jar was one of the first devices used to
store an electric charge. If the inner layers of foil and outer layers of foil
are then connected by a conductor, their opposite charges will cause a spark
that discharges the jar. Actually, van Musschenbroek's very first
'condenser' was nothing more than a beer glass!
By modern standards, the Leyden jar is cumbersome and inefficient.
It is rarely used except in exciting laboratory demonstrations of capacitance,
and exiting they are! Benjamin Franklin was acquainted with the Leyden Jar
experiments also so he decided to test his ideas that 'charge' could also be
caused by thunder and lightning. Franklin tested his theories, in Philadelphia
in June 1752, via his now famous 'Electrical Fluid Theory' to prove that
lightning was an electrical phenomenon. What he did was fly a kite which had a
metal tip. The kite was tied with wet conducting thin hemp cord and at the end
he attached a metal key to which a non-conducting silk string was attached which
he held in his hand; when he held his knuckles near the key he could draw sparks
from it. Although his experiment was completed successfully and the results as
he had calculated before, the next couple people after him who tried the
hazardous experiment were killed by lightning strikes. I guess Franklin was
extremely lucky with his hazardous experiments. I myself believe in some sort of
"time-line" in which inventions are invented 'no matter what'.
Look at the
picture at the right; the worlds first illustration of the working of a Leyden
Jar, by Abbe Jean-Antoine Nollet!
What exactly is a 'Capacitor'? A capacitor is a
device that stores an electrical charge or energy on it's plates. These
plates (see Fig. 1), a positive and a negative plate, are placed very close
together with an insulator in between to prevent the plates from touching each
other. A capacitor can carry a voltage equal to the battery or input voltage.
Usually a capacitor has more than two plates depending on the capacitance or
dielectric type.
Is it difficult or complicated to 'charge' a capacitor? Not at all.
Put proper voltage on the legs of the capacitor and wait till current stops
flowing. It goes very fast. Do NOT exceed the capacitor's working breakdown
voltage or, in case of an electrolytic capacitor, it will explode. The
break down voltage is the voltage that when exceeded will cause the dielectric
(insulator) inside the capacitor to break down and conduct. If that happens the
results can be catastrophic. And in case of a polarized capacitor, watch the
orientation of the positive and negative poles. A healthy, good quality
capacitor (disconnected) can hold a charge for a long time. From seconds to
several hours and some for several days depending on its size. A capacitor, in
combination with other components, can be used as a filter that blocks DC or AC,
being it current, frequency, etc.
Electrolytic - Made of electrolyte, basically conductive salt in
solvent. Aluminum electrodes are used by using a thin oxidation membrane. Most
common type, polarized capacitor. Applications: Ripple filters, timing circuits.
Cheap, readily available, good for storage of charge (energy). Not very
accurate, marginal electrical properties, leakage, drifting, not suitable for
use in hf circuits, available in very small or very large values in uF. They
WILL explode if the rated working voltage is exceeded or polarity is reversed,
so be careful. When you use this type capacitor in one of your projects, the
rule-of-thumb is to choose one which is twice the supply voltage. Example, if
your supply power is 12 volt you would choose a 24volt (25V) type. This type has
come a long way and characteristics have constantly improved over the years. It
is and always will be an all-time favorite; unless something better comes along
to replace it. But I don't think so for this decade; polarized capacitors are
heavily used in almost every kind of equipment and consumer
electronics.
Tantalum - Made of Tantalum Pentoxide. They are electrolytic capacitors
but used with a material called tantalum for the electrodes. Superior to
electrolytic capacitors, excellent temperature and frequency characteristics.
When tantalum powder is baked in order to solidify it, a crack forms inside. An
electric charge can be stored on this crack. Like electrolytics, tantalums are
polarized so watch the '+' and '-' indicators. Mostly used in analog signal
systems because of the lack of current-spike-noise. Small size fits anywhere,
reliable, most common values readily available. Expensive, easily damaged by
spikes, large values exists but may be hard to obtain. Largest in my own
collection is 220uF/35V, beige color.
Super Capacitors - The Electric Double Layer
capacitor is a real miracle piece of work. Capacitance is 0.47 Farad (470,000
uF). Despite the large capacitance value, its physical dimensions are relatively
small. It has a diameter of 21 mm (almost an inch) and a height of 11 mm (1/2
inch). Like other electrolytics the super capacitor is also polarized so
exercise caution in regards to the break-down voltage. Care must be taken when
using this capacitor. It has such large capacitance that, without precautions,
it would destroy part of a powersupply such as the bridge rectifier, volt
regulators, or whatever because of the huge inrush current at charge. For a
brief moment, this capacitor acts like a short circuit when the capacitor is
charged. Protection circuitry is a must for this type.
Polyester Film - This capacitor uses a thin polyester film
as a dielectric. Not as high a tolerance as polypropylene, but cheap,
temperature stable, readily available, widely used. Tolerance is approx 5% to
10%. Can be quite large depending on capacity or rated voltage and so may not be
suitable for all applications.
Polypropylene - Mainly used when a higher tolerance is
needed then polyester caps can offer. This polypropylene film is the
dielectric.
Polystyrene - Is used as a dielectric. Constructed like a
coil inside so not suitable for high frequency applications. Well used in filter
circuits or timing applications using a couple hundred KHz or less. Electrodes
may be reddish of color because of copper leaf used or silver when aluminum foil
is used for electrodes.
Metalized Polyester Film - Dielectric made of Polyester or
DuPont trade name "Mylar". Good quality, low drift, temperature stable. Because
the electrodes are thin they can be made very very small. Good all-round
capacitor.
Epoxy - Manufactured using an epoxy dipped polymers as a
protective coating. Widely available, stable, cheap. Can be quite large
depending on capacity or rated voltage and so may not be suitable for all
applications.
Ceramic - Constructed with materials such as titanium acid
barium for dielectric. Internally these capacitors are not constructed as a
coil, so they are well suited for use in high frequency applications. Typically
used to by-pass high frequency signals to ground. They are shaped like a disk,
available in very small capacitance values and very small sizes. Together with
the electrolytics the most widely available and used capacitor around. Comes in
very small size and value, very cheap, reliable. Subject to drifting depending
on ambient temperature. NPO types are the temperature stable types. They are
identified by a black stripe on top.
Multilayer Ceramic - Dielectric is made up of many layers.
Small in size, very good temperature stability, excellent frequency stable
characteristics. Used in applications to filter or bypass the high frequency to
ground. They don't have a polarity. *Multilayer caps suffer from high-Q internal
(parallel) resonances - generally in the VHF range. The CK05 style 0.1uF/50V
caps for example resonate around 30MHz. The effect of this resonance is
effectively no apparent capacitance near the resonant frequency.
Silver-Mica - Mica is used as a dielectric. Used in
resonance circuits, frequency filters, and military RF applications.
Adjustable Capacitors - Also called trimmer capacitors or
variable capacitors. It uses ceramic or plastic as a dielectric.
Tuning or 'air-core' capacitors.
Capacitors connected in parallel, which is the most desirable, have
their capacitance added together, which is just the opposite of parallel
resistors. It is an excellent way of increasing the total storage capacity of an
electric charge:
| microFarads (µF) | nanoFarads (nF) | picoFarads (pF) | ||
| 0.000001µF | = | 0.001nF | = | 1pF |
| 0.00001µF | = | 0.01nF | = | 10pF |
| 0.0001µF | = | 0.1nF | = | 100pF |
| 0.001µF | = | 1nF | = | 1000pF |
| 0.01µF | = | 10nF | = | 10,000pF |
| 0.1µF | = | 100nF | = | 100,000pF |
| 1µF | = | 1000nF | = | 1,000,000pF |
| 10µF | = | 10,000nF | = | 10,000,000pF |
| 100µF | = | 100,000nF | = | 100,000,000pF |
Table 1. Capacitance Conversion
Capacitors in
Schematics: Metric Prefix Symbol Power of 10 (multiplier)
giga [Note 2] G x 10^9
mega M x 10^6
kilo K x 10^3
(none) x 10^0 (same as 1 or unity)
milli m x 10^-3
micro f x 10^-6
nano n x 10^-9
pico p x 10^-12
This list does extend farther in either direction, but those larger and
smaller multipliers are not as commonly used in electronics. But using this
list, you'll find that the common capacitor multipliers in the United States
will be f (micro) and p (pico). A capacitor with a value of 3.3fF is the same as
a capacitor with a value of 3.3 x 10^-6 farads or 0.0000033 farads. "f", by the
way, is the lower-case Greek letter "mu", properly written as our Roman lower
case "u" with a leading descender much as a "y" has a trailing
descender.68 mF 68 MF 68 mfd 68 MFDIt was always understood that "mF", "MF", "mfd" or "MFD" ALWAYS meant microfarad. Microfarad or micromicrofarad were the only units used for capacitors back then, so no one would ever even consider that "mfd" might mean "millifarad" or that "MFD" might mean "megafarad"! Even today, you'll still see "MFD" on capacitors, especially on motor start or motor run capacitors.
B = ±0.1pF
C = ±0.25pF
D = ±0.5pF
E = ±0.25%
F = ±1.0%
G = ±2%
H = ±2.5%
J = ±5% *
K = ±10% *
L = ±15%
M = ±20% *
N = ±30%
P = -0, +100%
S = -20, +50%
W = -0, +200%
X = -20, +40%
Z = -20, +80% *
You'll find that the "Z" tolerance of -20, +80% to be common for aluminum
electrolytic caps and for disc ceramic caps that are used for what is known as
"bulk capacitance" in applications such as power supply bypassing or filtering.
These kinds of capacitors are used where it's OK for the value to be a lot
larger than nominal, but they don't want it to go very far below that
value. 1E 25V
1H 50V
2A 100VSince this seems to be
European in nature, these voltage markings are new territory for me. I would
appreciate more information on this so that I can flesh out this article and
make it more accurate. My e-mail address appears in the "Wrapup" section
following in case you would like to contact me with some of this information. I
try to be accurate, so please make sure that you include source material rather
than depending upon hand-me-down folklore!
