Battery Tester For Deaf and Blind Persons


Many blind and
deaf-blind persons use portable electronic devices to assist their
everyday lives but it is difficult for them to test the batteries used
in this equipment. Talking voltmeters are available but there is no
equivalent usable by deaf-blind persons. This battery tester uses
vibration and a user-settable control to enable blind and deaf-blind
persons to test both ordinary and rechargeable AAA, AA, C, and D cells and 9V batteries. For ease of use and maintenance the device is powered by the battery under test.

The design is dominated by the fact that the pager motor will
operate down to only 0.7V. With a 0.3V drop from the switching
transistor, a weak cell, at 1.0V, will only just operate the motor. This
means that the 1.5V cell sensing circuitry cannot be isolated from the
9V test terminals using steering diodes – they would introduce too great
a voltage drop. The solution was to duplicate the level sensing
circuitry for each set of test terminals. On the 1.5V side of the
circuit, a resistance network consisting of two 10kO multi-turn trimpots
(VR2 & VR3) and user control VR1a produces an adjustable proportion
of the voltage of the cell under test.

VR1a selects a division ratio between the low and high limits set by
the trimpots. The resistance of VR1a is 10 times larger than the
resistance of these trimpots to minimise the interaction between their
settings. The voltage from the resistance network is applied to a
combined threshold detector and current amplifier formed by Q1 to Q4 and
associated components. When the threshold (about 0.6V) is exceeded the
pager motor is energised, causing the battery tester to vibrate. In use,
VR1 is first set to its fully counter-clockwise position, then a cell
is connected.

If the cell’s voltage exceeds the 1V low threshold set by the 1.5V LOW
trimpot (VR2), the battery tester will vibrate. Rotating VR1 clockwise
applies a progressively lower voltage to the threshold detector until a
point is reached when the threshold is no longer exceeded and the pager
motor switches off. The angle of rotation of VR1 then indicates the
voltage on the battery. VR1 is fitted with a pointer knob to make the
angle of rotation easy to feel. Having the pager motor switch off rather
than switch on ensures that the voltage of the battery is sampled while
it is supplying the load of the pager motor.

This gives a more accurate indication of the state of the battery
than its open-circuit voltage. To ensure that the user turns VR1
clockwise during the test, the circuit is designed so that once
vibration has ceased, it cannot be made to start again by rotating VR1
counter-clockwise. This also eliminates any possibility of user
confusion arising from any hysteresis in the circuit. This feature is
implemented by Q5, which forces the base of Q2 high if Q4 ceases to
conduct strongly. A 1µF capacitor between the base and emitter of Q5
forces it off when power is first applied, to give Q4 a chance to
conduct.

Battery Tester Circuit For Deaf and Blind Persons

Battery Tester Circuit Diagram For Deaf and Blind Persons

The parallel 1MO resistor discharges the 1µF capacitor when power is
removed, to reset the circuit. To prevent the pager motor being driven
through the base-emitter junction of Q5, the base of Q5 is connected to
the collector of Q4 via 10kO resistor. Another 10kO resistor is
connected in parallel with the pager motor to ensure that Q5 switches on
when Q4 switches off. The 9V test circuit is similar to the 1.5V
circuit. A 68O 1W resistor limits the current through the motor to
prevent it from being over-driven by the higher voltage.

In addition, there is a series diode to protect the 9V circuitry
against reverse polarity. A diode is not possible for the 1.5V side of
the circuit because it would introduce too great a voltage drop;
fortunately, it is also unnecessary since 1.5V is below the reverse
breakdown voltage of the transistors used. The 1µF capacitor across the
pager motor smoothes the load provided by the motor so that measurements
made by the circuit are consistent from one trial to another. The
1N4001 diode across the pager motor clips any back-EMF generated by the motor.

A D-cell holder and an AA-cell holder connected in parallel were
used for the 1.5V test terminals. The 9V test terminals are the studs
from a standard 9V snap screwed to the box. To calibrate the battery
tester, start with VR1 fully counter-clockwise. First adjust the 1.5V LOW
trimpot by turning it fully counter-clockwise, then apply 1.0V to the
1.5V test terminals and turn the trimpot slowly clockwise until
vibration just ceases. Now turn VR1 fully clockwise and adjust the 1.5V HIGH trimpot similarly with 1.6V applied to the 1.5V test terminals.

There is a small amount of interaction between the low and high settings, so repeat the adjustment of the 1.5V LOW
trimpot. Similarly, calibrate the 9V side of the circuit for a range of
6.0V to 9.6V. To test a battery, rotate VR1 fully counterclockwise
before connecting the battery to the appropriate set of test terminals
(1.5V or 9V). If the device does not vibrate, the battery is completely
dead. Otherwise, rotate VR1 slowly clockwise until the device just
ceases to vibrate. The position of VR1 then shows the condition of the
battery under test.

Author: Andrew Partridge – Copyright: Silicon Chip Electronics

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