Originally posted by Klaus:
NiMh don´t like being discharged below 0.9V
Klaus
<font size="2" face="Verdana, Arial">Actually NiMH _cells_ are fine with discharge below 0.9V. In general, there is very little reason to discharge below 0.9V per cell, however, because so very little energy is available at this point.
The problems occure with NiMH _batteries_, meaning a series connected string of cells.
NiMH cells are damaged by being charged in reverse. When you have an NiMH _battery_, all of the cells will have slightly different capacity. In general, unless the cells are _perfectly_ matched, one will discharge first. Since the other cells sill have charge, they can keep the current flowing. But since the cells are connected in series, this means that the _discharge_ current is still flowing through the fully discharged cell. In other words, it is being discharged 'past' zero, or _reverse_ charged.
The whole '0.9V per cell' thing is just a darn good rule of thumb for preventing this reverse charge failure mode. However it is only a rule of thumb, and there are situations in which it doesn't work. One is with very long series chains of cells, eg a 20 cell battery. The nominal voltage is 24V. If one cell happens to discharge first, and start reverse charging, then the battery voltage will drop to about 21V (you lose the 1.2V normal voltage, and then you lose >1.2V in the reverse charging process); but the 21V is > 0.9V per cell, so your system might not notice the reverse charging.
Another situation is under extremely high rate discharge, where the fully charged voltage is below 0.9V per cell because of the internal resistance of the cell. Clearly in this situation you need to discharge to a lower voltae (0.5V per cell) in order to use the battery.
Still another situation is with short battery packs, eg 2 cells in series, where a reverse charge situation would drop the battery voltage to zero...here you can safely discharge to <0.9V per cell because reverse charging is so unlikely.
-Jon