2.1 ORIGINAL VOLTAIC CELL
About the year 1799 Alessandro
Volta, an Italian scientist (after whom the unit ‘volt’ is
named), discovered
that, if two dissimilar metals were separated by a certain liquid which was in
contact with both, an ‘electromotive force’ (emf), or ‘voltage’, appeared across
the metals and, when they were connected together, an electric current
flowed. Volta used zinc and copper discs
separated by a piece of cloth moistened with a solution of common salt. Later the voltage was found to be 1.0V no
matter what the size of the metal discs.
Of course at that time no such unit as the ‘volt’ was known. This was the original ‘Voltaic Cell’ and was
used, with modifications, for 150 years as almost the sole source of electric
currents for the experimenters of the day.
Figure 2.1 PRIMARY CELLS
If several such cells are arranged
in a pile as in the lower part of Figure 2.1 (as Volta did), each cell is in
fact in series with its neighbour, and the voltages of each individual cell add
together to give a much higher voltage than could be achieved with only
one. Such a series collection is
referred to as a ‘battery of cells’ (by analogy with a battery of guns) - or
nowadays simply as a ‘battery’.
2.2 PRIMARY CELLS
Although Volta used zinc and copper
as his main elements, almost any two dissimilar
metals will produce a like
result. Only the voltages would be
different, depending on the metals actually used.
Such voltaic cells, whatever the
materials used, are termed ‘primary cells.’
They do not have to be charged, as in a modern battery, but derive their
electrical energy from chemical action between the metals and the surrounding
conducting liquid, called the ‘electrolyte’.
As power is extracted, one of the two metals gradually erodes away as
the chemical action proceeds, and the process is not reversible - that is to
say, the cell cannot be recharged. It
will continue to give power until the erosion is complete.
An example of the application of
primary cells was in the domestic bell systems of some old houses, which used a
battery of ‘Leclanche’ cells. Each
consisted of a glass jar filled with sal ammoniac and containing a zinc rod and
a carbon plate inside a porous pot.
After prolonged but intermittent use the zinc rod eventually eroded away
and had to be replaced.
Certain types of primary cell are
still used in laboratories as a voltage reference; they are called ‘standard
cells’, and their voltage is very accurate and constant. One such is the ‘Weston Standard Cell’. Its electrodes are mercury (positive) and
mercury-cadmium amalgam (negative) with an electrolyte of a solution of cadmium
sulphate. The emf of this cell is
1.0183V at 20oC, varying by only one part in 25 000 per oC
change. Such a cell is never used as a
source of current, it is purely a very accurate voltage reference.
A common use for the primary cell
today is the so-called ‘dry battery’.
This uses zinc and carbon for its two elements, the zinc forming the
outer case and the carbon taking the form of a rod down the centre. The electrolyte is a stiff moist paste packed
into the space between the zinc case and carbon rod. It is not strictly dry, but it cannot spill
and can be sealed in the case.
Except in such special applications
primary cells are little used in power plants today, being replaced by the ‘secondary
cell’, which is rechargeable.
2.3 SECONDARY CELLS
Like the primary cell, the
secondary cell, also sometimes called an ‘accumulator’ or ‘storage battery’,
consists of two metal plates immersed in a conducting liquid electrolyte. They fall into two types: ‘lead-acid’ and
‘alkaline’.
Lead-acid Cells
In the original lead-acid cell both
plates were of pure lead, immersed in dilute sulphuric acid. In this state the metals are not dissimilar,
and no emf (i.e. voltage) is developed between them. But after an external ‘charging’ current has
been passed through the cell from one plate to the other, a chemical action
takes place; one plate becomes covered with spongy lead and the other with lead
peroxide. In this state the cell behaves
like a primary one, the spongy lead plate being the negative and the lead
peroxide the positive. When these plates
are connected together externally, a current will flow, driven by the cell’s
emf or internal voltage.
This construction was soon found to
be rather unsatisfactory, as the plates’ coatings rapidly fell off. Now each plate consists of a grid of
lead-antimony alloy, into which the active materials are inserted in the form
of a hard paste.
As shown in Figure 2.2, positive
and negative groups of plates are interleaved.
The capacity of the cell is determined by the number and total surface
area of the plates, which are kept from touching each other by
‘separators’. These were originally of
wood, but nowadays porous plastic is often used. If, due to too heavy a rate of discharge,
some of the active material becomes dislodged from its grid, it will gradually
accumulate in the bottom of the cell until its level rises to touch the bottoms
of the plates. This will short-circuit
them and rapidly discharge the battery.
If the cell is sealed, its life is finished, but if the plates can be
removed, the cells can be flushed out, refilled and used again.
Figure 2.2 TYPICAL LEAD ACID CELL
The sulphuric acid electrolyte is diluted to a relative
density between 1.200 and 1.300, depending on the make and duty of the
battery. When fully charged, an
open-circuit voltage of about 2.1V appears across the cell’s terminals.
As power is taken out, derived from the chemical action,
the sulphuric acid begins to form lead sulphate at both plates and in doing so
loses density. The cell voltage also
falls steadily. Once the acid density
has fallen to 1.150 (the figure differs somewhat with different makes of cell), the cell is regarded as ‘discharged’, and further extraction of power
could damage it.
It must then be recharged (not possible with primary
cells). The current is reversed by
applying an external voltage to the cell higher than the cell’s own
voltage. The chemical action is thereby
reversed, the lead sulphate returning to the electrolyte and raising its
density again to its original level, at the same time restoring the cell
voltage.
Lead-acid cells must never be left for long periods
in a discharged state.
The ability to discharge and recharge is a property only
of the secondary cell. Its efficiency is
such that it takes about 1.4 times the power to recharge it as can be obtained
out of it on discharge. The lost power
appears as heat.
Another property of the secondary cell is that, if
discharged too quickly, not only is active material liable to be dislodged from
the plates but also the normal chemical processes are upset and limit the
output obtainable. For this reason the
rated discharge current is always specified as a certain maximum rate - for
example 50A at a 5-hour rate, or 70A at a 10-hour rate. If these rates are exceeded, the cells will
not give their full output for the stated times.
The capacity of a cell is expressed in ‘ampere-hours’
(Ah). For example, if a battery is rated
300Ah, it should sustain a discharge rate of 1A for 300 hours, or 5A for 60
hours, or 10A for 30 hours, so long as the discharge rate does not exceed the
stated rating. If it does, the rated
ampere-hour capacity will not be achieved.
The easiest way to test a lead-acid cell’s state of
charge is to measure the electrolyte density with a hydrometer. The full-charge density varies somewhat
between makes of battery, but it is always stated by the maker. A typical figure is 1.250.
Since a cell can only lose liquid by evaporation or by
‘gassing’, it is only water that is lost, not the acid. Therefore liquid should only be replaced by
topping up with pure (distilled) water, never by acid (unless the acid has actually
been spilt).
When a secondary cell is recharged, the power going into
it is at first absorbed by causing chemical changes. But once these changes are complete the
power, if continued, starts to electrolyse the water, forming hydrogen and
oxygen at the two plates; the cell is said to be ‘gassing’. Gas bubbling is a sign of a completed charge,
but if allowed to continue it will release a considerable quantity of hydrogen
and oxygen mixed in its most explosive proportions.
Ventilation of battery rooms is therefore very
important, and charging should on no account continue, at least at full rate,
unless ventilation is available. Most
platforms now have ventilation monitors which stop, or at least reduce,
charging on failure of air flow.
Alkaline Cells
A different class of secondary cell is known as
‘alkaline’. It was invented by Edison
and originally consisted of plates of nickel hydrate and iron oxide immersed in
an electrolyte of a solution of potassium hydroxide (with some lithium
hydroxide added) in distilled water.
These were the original nickel-iron (or ‘NiFe’) cells; they had a cell
voltage of about 1.2V.
The chief advantages of the alkaline call over the
lead-acid are:
·
longer
life
·
greater
reliability
·
less
maintenance
·
lighter
weight per Ah
·
greater
robustness against vibration and shock
·
good
high-rate discharge performance
·
ability to
accept high rates of charge
·
better
charge retention during long periods of rest
·
rapid
voltage recovery after heavy discharge
·
immunity
from harm if over-discharged.
Alkaline cells differ from
lead-acid not only in their voltage but also because their electrolyte does not
lose density as the cell discharges. The
electrolyte is necessary to sustain the chemical actions but is not itself
affected - it is in fact a ‘catalyst’.
The only way to know the state of charge is to measure the cell
voltage. When it has fallen to about
0.8V, the cell is considered to be discharged.
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Figure 2.3 TYPICAL ALKALINE (NICKEL-IRON) CELL
A typical alkaline cell is shown in Figure 2.3. During charging, the positive nickel hydrate
plates become heavily oxidised, whereas the negative iron oxide plates are
reduced to pure iron, and the cell voltage rises to about 1.2V. This amounts simply to the transfer of oxygen
from one plate (the positive) to the other and does not call for any chemical
changes in the electrolyte. It is for
this reason that in an alkaline cell the electrolyte density does not change
with the state of charge. On discharge
the chemical process is reversed, oxygen returning to the iron to re-form it
into iron oxide, and in so doing the cell voltage is reduced.
Like the lead-acid cells, alkaline cells are rated in
ampere-hours at a specified maximum discharge rate. However, they are very robust and can stand
heavy discharges without damage, though in that case they will not give their
full rated ampere-hour output.
More recently the iron in alkaline cells was replaced by
cadmium to give the nickel-cadmium (‘Nicad’) cell. Most platforms and shore installations use
this type exclusively rather than the lead-acid or nickel-iron. It has about 20% higher voltage per cell.
The foregoing description of the nickel-iron cell
applies in large part also to the nickel-cadmium, except that the cell’s
open-circuit voltage lies between 1.4 and 1.5V, and at 1.1V the cell is
regarded as discharged.
The nickel-cadmium cells are manufactured in either
plastic or steel containers. The latter
have greater strength against severe vibration and shock and also have
advantages when operating in extreme climates.
Plastic containers on the other hand are completely free from corrosion,
especially in salt-laden atmospheres, and, being translucent, allow the
electrolyte level to be checked at a glance and the electrolyte topped up if
necessary.
2.4 CHARGING OF SECONDARY CELLS
The apparatus for charging secondary cells and the
voltage variations during charge are described in the manual ‘Electrical
Distribution Equipment’.
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