Following up upon a reader request for a circuit to monitor the fuses in his car , I designed the following circuit that can be used to monitor in addition to fuses any positive or negative voltage lines or fuses whether in a car , aircraft , boat or instrument circuitry .
Shown below is the circuit that will enable you to monitor just about any signal line as you wish the LED's to indicate whether a line signal is on/off or negative/positive or square , AC , or pulsing . ( see application notes below )
Circuit Description
The circuit has been designed to be operated
using a voltage supply of 9 to 14 volts as required and explained
later . CMOS IC MC or CD4050 an HEX Non-Inverting Buffer is made of six
non-inverting gates and can supply more current than the standard CMOS .
Each can either drain or source depending on its logic state being
either high or low .
Using all gates of one IC will enable the monitoring of six lines . Any unused inputs gates must be connected to positive or negative ie., pin 1 or pin 8 .
Using all gates of one IC will enable the monitoring of six lines . Any unused inputs gates must be connected to positive or negative ie., pin 1 or pin 8 .
Red ON , line zero : The input of
the gate pin 3 is pulled down to ground through the connection of the
10K resistance to a logic LOW and the output will also be LOW as long
as there is no positive input high enough
for the gate to switch to a HIGH . When logic input is low , the
current flows from positive through the 1.2k resistor , the red LED and
the gate output , pin 2 , and is now said to be draining the current
to the IC ground .
Green ON , line positive : The input
pin 3 of the gate that we will name gate A is connected to the line
that we wish to monitor through the 1K ohms input resistor when this
line has a voltage with a positive polarity of at least 4.6 voltsat the
gate input pin 3 it will keep the gate input at a logic high , this
high positive voltage
cannot be allowed to be higher than the IC supply voltage rail ( see
application notes below ) . As long as a logic high is present at the
input the output will also be high and the current will flow from pin 2
to the green LED through the 1.2K resistor to ground .
Application Notes
Voltage supply
If the system is to be used only as an occasional test instrument a 9
volt battery may be sufficient as voltage supply . For a permanent
installation a maximum IC permissible voltage ( VCC ) of 14 volts is
allowed without any changes to the 1.2K current limiting resistors to
limit the LED's current to 10 mA .
When used as fuse monitor for a car for exemple the current will
fluctuate from a 12 volt battery voltage to 14.5 volts
charging voltage and the LED's current as well as brightness will
fluctuate . A 9 volt regulator should be used to protect the circuit as
the regulator requires two (2) volts extra for good regulation allowing
for a weak battery voltage .
Input Monitor voltage
Exemples of voltage range input application AC or DC .
Allowing for diffrent IC's used , a
minimum trigger voltage of 4.6 to 5 volts is required at the gate input ,
the 1K resistor will need at least 5.2 volts line input to trigger the
gate to a logic HIGH and any voltatge below that level will be a logic
LOW. With a supply of 9 volts ( VCC ) we can monitor a voltage range of
5.2 to 9.4 volts .
We can increase the voltage monitoring
range by increasing the 1K resitance value to lets say 9.5 K ohms and
still be in a positive trigger range to monitor a line voltage from 9.4
to 17 volts . Higher ranges can be used by calculating the voltage
divider
formed by the input and shunting resistance ( 10K ) to the the gate
input .
For multiple different line levels monitoring it would more pratical to
replace the 1K input resistors with a 10K miniature pot to calibrate the
trigger input level voltage required .
We can monitor a square, sine or pulse
signal and both LED's will flash indicate alternating HIGH and LOW logic
at a low
frequency up to about 30Hz , above this frequency the LED's will appear
to be both ON without any fluctuation . This could be useful to detect a
failed or overloaded rectified DC supply line .
Monitoring a Ground or Zero volt line is simply a matter of reversing
the LED's colour meaning or the LED's pysically in the circuit .
LED Current Resistance
The 1.2K LED current limitimg
resistance value has been chosen to limit the current to 10 Ma with a 14
volts supply with an acceptable lower level of brightness at 9 volts .
When changing the supply voltage the LED current resistance value can be found as Supply voltage minus 1.5v (LED voltage ) divided by the LED allowed current ( 10 mA ) . Thus for a supply voltage of 9 volts , R = 9 - 1.5 = 7.5 / .010 = 750 ohms.
When changing the supply voltage the LED current resistance value can be found as Supply voltage minus 1.5v (LED voltage ) divided by the LED allowed current ( 10 mA ) . Thus for a supply voltage of 9 volts , R = 9 - 1.5 = 7.5 / .010 = 750 ohms.
To monitor line voltage level lower than 5 volts a voltage amplifier can
be used made of simply one transistor or an op-amp inserted between the
line to be monitored and the gate
resistance input to raise the level to the gate minimum trigger level of
5 volts.
Have fun !
The suggested following layout has been designed for a six lines
monitoring capability . Any number of lines below that number can be
used and the unused gates input pins must be connected to ground or
positive , and associated components can be omitted.
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