The temperature of the electrolyte.

The temperature of the electrolyte. The hotter the electrolyte, the higher the current carried through it.
This can be a snag. Suppose it is decided that the current through the cell is to be 10 amps and the
electrolyte concentration adjusted to give that current when the engine is started. As time passes, the 125
watts of excess power drawn from the battery, heats the electrolyte, which in turn causes an increase in
the current flowing through the cell, which causes even greater heating, which..... The result is positive
feedback which causes a runaway temperature effect.
This effect is aggravated by the water in the cell being used up as the vehicle drives along. This raises
the concentration of the electrolyte because the amount of KOH remains the same while the amount of
water reduces.
There are different ways of dealing with this problem. One is to reduce the concentration of KOH so that
the chosen current is only reached when the electrolyte has reached its maximum working temperature.
This is a simple solution with the slight disadvantage that the gas production rate when starting is lower
than it could be. However, the heating power is so high that it will not be long until the cell is operating at
its maximum temperature.
A different way to handle the problem is to use an electronic circuit to limit the current through the cell to
the chosen value by dropping the voltage applied to the cell. This has the disadvantage that the extra
power is being dissipated in the electronics which then has a heat problem. Also, this solution does not
improve the overall efficiency of the process.
The best way of all is to reduce the voltage applied to the cell by using more than one cell connected in a
daisy-chain across the battery. With two cells, each will get about seven volts across it and the gas
production will be doubled. If space in the engine compartment allows, a chain of six cells can be used
which means each receives about two volts and the waste powers is reduced to some 10.6 watts per cell,
while the gas production is six times higher. With the higher rate of gas production, it would probably be
possible to reduce the chosen current flowing through the cell. Also, with six cells, the amount of water is
six times greater and so there will be less concentrating of the electrolyte due to the water being used up.
This is a “Series-Cell” arrangement.
6. The number of bubbles sticking to the surface of the electrode plates. This is generally considered to be a
significant problem. Many methods have been used to deal with it. Some people use magnets, others
pump the electrolyte around to dislodge the bubbles, others use buzzers to vibrate the plates and some
pulse the voltage to the cell at just the right frequency to vibrate the cell. Once the plates have become
fully "conditioned" bubbles break away from them very easily and there is no need for any dislodging
mechanism.