Simple Combination Lock


This simple combination
lock accommodates codes from 1-9 digits long, with the only restriction
being that the same digit cannot be used twice. The circuit shows
strapping for a 4-digit code, in this case “2057”. Any unused switches
are strapped to ground. When power is applied, the 330nF capacitor
connected to pin 1 of inverter IC1a is discharged, holding it at a logic
low level. The high output is inverted by a second gate (IC1b), with
the result being a logic low on pin 4. This pulls Q1’s emitter low via
D1, causing the transistor to conduct. The falling voltage on the
collector then pulls the input of IC1c low, which in turn resets counter
IC2.

On reset, output O0 (pin 3) of IC2 goes high, charging the 330nF
capacitor via D2 and the 33kΩ resistor. If switch S2 is now pressed,
Q2’s emitter will be pulled high and so Q2 conducts, applying a rising
positive voltage to one end of the 1MΩ resistor. This resistor and the
33nF capacitor act as a switch “debounce” circuit, delaying the pulse
through IC1e by about 33ms. After the delay, the output of IC1e goes
low. However, counter IC2 does not increment at this stage, since it
needs a positive-going edge at the clock input (pin 14). When the switch
is released, Q2 turns off, IC1e’s output goes high after the debounce
period and the counter advances to the next state (ie. O0 goes low and
O1 goes high).

Circuit diagram:

Simple Combination Lock Circuit

Simple Combination Lock Circuit Diagram

When output O0 (pin 3) goes low, the 330nF capacitor starts
discharging through the 33kΩ and 10MΩ resistors. This allows about 3s
for the operator to press the next button. If no button is pressed
within this period, IC1b’s output goes low, which pulls Q1’s emitter low
and resets the counter via IC1c. Hence the code entry must be
restarted. When the second digit of the code is entered (0 in this
example), Q2’s emitter is again pulled high. Q2 thus turns on and after
the debounce delay, IC1e’s output goes low. When the switch is released,
Q2 turns off, IC1e’s output goes high and the counter advances to state
2.

Note that while the switch is pressed, IC1d’s output is high,
recharging the 330nF capacitor and therefore resetting the 3s delay.
Thus, the operator is allowed another 3s to press the next digit. This
process is repeated for each digit in the sequence. If the wrong switch
is pressed at any point, IC2 is reset as described above. Conversely, if
the correct code is entered, IC1 advances to state 4 (for our 4-digit
example) on release of the fourth switch. Output O4 then goes high and
turns on Q3 and relay 1. Q3 can handle up to about 300mA of load
current. If more current is required, then either a Darlington or power
Mosfet can be substituted. D4 is required if the load is inductive (eg, a
relay, solenoid, etc).

Author: Len Cox – Copyright: Silicon Chip Electronics

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