Simple NiCd Battery Charger

A simple NiCd charger
can be built using ‘junk box’ components and an inexpensive LM317 or
78xx voltage regulator. Using a current limiter composed of R3 and a
transistor, it can charge as many cells as desired until a ‘fully
charged’ voltage determined by the voltage regulator is reached, and it
indicates whether it is charging or has reached the fully charged state.
If the storage capacitor (C1) is omitted, pulsed charging takes place.
In this mode, a higher charging current can be used, with all of the
control characteristics remaining the same. The operation of the circuit
is quite simple. If the cells are not fully charged, a charging current
flows freely from the voltage regulator, although it is limited by
resistor R3 and transistor T1.

The limit is set by the formula Imax ≈ (0.6 V) ÷ R3 For Imax = 200 mA, this yields R3 = 3 Ω. The LED
is on if current limiting is active, which also means that the cells
are not yet fully charged. The potential on the reference lead of the
voltage regulator is raised by approximately 2.9 V due to the voltage
across the LED. This leads to a requirement
for a certain minimum number of cells. For an LM317, the voltage between
the reference lead and the output is 1.25 V, which means at least three
cells must be charged (3 × 1.45 V > 2.9 V + 1.25 V). For a 78xx with
a voltage drop of around 3 V (plus 2.9 V), the minimum number is four

Circuit diagram:

Simple NiCd Charger Circuit

Simple NiCd Charger Circuit Diagram

When the cells are almost fully charged, the current gradually drops, so the current limiter becomes inactive and the LED
goes out. In this state, the voltage on the reference lead of the
regulator depends only on voltage divider R1/R2. For a 7805 regulator,
the value of R2 is selected such that the current through it is 6 mA.
Together with the current through the regulator (around 4 mA), this
yields a current of around 10 mA through R1. If the voltage across R1 is
4 V (9 V – 5 V), this yields a value of 390 Ω. The end-of-charge
voltage can thus be set to approximately 8.9 V. As the current through
the regulator depends on the device manufacturer and the load, the value
of R1 must be adjusted as necessary. The value of the storage capacitor
must be matched to the selected charging current. As already mentioned,
it can also be omitted for pulse charging.

Author: Wolfgang Schmidt – Copyright: Elektor July-August 2004

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