Tech notes on the Monoxor II Carbon Monoxide sensor
There are several things to keep in mind with regards to this type of sensor.
All CO sensors have a life span (Generally 2 - 5 years). Ten+ years of experience with this sensor has generally been 5 years of useful service life can be reasonably expected, depending on factors such as:
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Hours of use. |
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Age of sensor |
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Amount of exposure to carbon monoxide |
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Care and maintenance |
This type electrochemical sensor has a chemical reaction when exposed to CO. As the chemical is exposed to CO, an electrical current is generated which is picked up by the circuitry and translated into a parts per million (ppm) reading.
As such, the more CO it is exposed to, the shorter its life.
To extend the life of the sensor, try to minimize exposure to particularly high levels of CO. For example, if you see the reading quickly climbing towards the over range point (2000 ppm), remove the probe - or better yet, disconnect the probe from the top of the instrument and allow it to purge.
Typical heating equipment is designed to minimize CO production in the flue gas samples (i.e.. AGA - 400 ppm air free). When you start getting a couple of hundred ppm's above the allowable level, that's all you need to know - there's a problem.
However, do test every piece of equipment you are involved with. Frequent use and exposure to 'normal' flue gas CO levels will not shorten it's live significantly.
When this sensor is near the end of its service life, you will notice the reading wandering up and down (in clean air) and it will be hard to keep it adjusted to zero.
A rough field test to see if the sensor is working at all is to light a match and stick it into the probe allowing the suction of the pump to extinguish it. The reading should bump up to 600 to 800 ppm's.
Do allow the instrument to post purge after normal use or when the sensor has been exposed to high CO levels.
Once testing is complete, disconnect the hose assembly and let the instrument run for 5 - 10 minutes. This will purge out any residual CO and flue gas moisture.
The acids in flue gas condensate can also damage instrument parts and the sensor. Remember, these sensors are designed to be exposed to flue gas condensate, but not soaked in it.
Also remember to keep the yarn in the moisture trap dry and clean. When the yarn gets damp, put dry material in and let the original dry out, to be used again.
Along the same line, try not to expose the instrument to freezing temperatures. Moisture in the sensor can freeze, expand and crack the sensor case or when the instrument in brought into a warm, moist environment, condensation may occur on the circuit board.
Another thing to keep in mind is that this is a non-hydrogen compensated sensor.
Sometimes, particularly on larger commercial burners, hydrogen can be produced by a flame and exhausted along with the flue gases. This sensor reads hydrogen as carbon monoxide.
Hydrogen in the ambient air (i.e., charging automobile batteries) will also be read as carbon monoxide.
Hydrogen Compensated sensors are used in high end combustion analyzers such as the PCA and ECA 450. They actually have two sensors, one to measure CO and one to measure hydrogen, then make a calculation to deduct the hydrogen from the reading.
Under 'normal' circumstances you might see a 5 to 10 ppm reading difference in the flue gases on a residential unit - generally none.
Commercial equipment could be much higher. We've seen the difference as much as 60 to 70 ppm's between compensated and non compensated sensors, then again, frequently there is no difference.
If you have any questions feel free to contact us