Industrial,ppm,measurements,we technology Industrial ppm CO measurements

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It is a well known and heavily publicized fact that carbon monoxide is a dangerous gas even at low exposurelevels. While measurement solutions for residential applications are fairly simple, industrial and commercialapplications require a much more sophisticated instrument. Problems with the accuracy of many measurementdevices arise due to zero instability and cross sensitivity to other gasses on the sensors especially in industrialsituations where temperature changes and the presence of other process gasses are an ongoing part of everydaylife.Upper exposure limits for CO in the work place are normally set to provide alarms or warnings at 25-50ppm,sensor inaccuracies often cause alarms to be triggered when in fact no actual carbon monoxide danger exists. When higher levels of CO are present, proper safety procedure calls for the halt of production and theevacuation of all personnel from the area until the levels can be verified, reduced and the sourceidentified. These precautions taken against this potentially deadly gas show responsibility on the part of theemployer and can save the lives of many who work to make the company profitable. The resulting down time canhowever have many detrimental effects including, employee stress, safety concerns from outside agencies, andreduced production, it is therefore vitally important that we ensure that CO alarms are set off only by actualincreased levels of carbon monoxide. In an effort to reach this goal there are a number of considerations to belooked at, the following information is provided for that purpose.The most common types of detectors used for Carbon Monoxide measurements are,1) NDIR or infra-red which although is very specific to the gas being measured requires a warm-up time, is fairlylarge, can consume larger amounts of power making it unsuitable for small or portable instruments, and is moreexpensive. For ranges of CO measurement in industrial uses other than Low ppm this technology is by far thenumber one choice. 2) Solid State, while this technology is small and cost effective it is not selective enough for CO onlymeasurements and usually has higher temperature drift making the zero unstable.3) and Electrochemical which is the primary choice for the majority of Carbon Monoxide analyzers on the markettoday due to it’s many benefits which include, size, weight, power, cost, and proven performance.The remainder of this article will deal only with the electrochemical sensor.There are a number of electrochemical sensor manufacturers worldwide and each of these has a number ofsensors designed for carbon monoxide measurements in different applications, choosing the right one is the key tosuccess. The output from most of these sensors is very low, (pico amps per parts per million) so even subtlechanges or correction procedures must be dealt with using extreme care in order to preserve the integrity of thesignal.Sensors designed for higher concentrations of CO have a lower output per ppm which can cause it to have ahigher temperature coefficient, this leads to zero instability making it unsuitable for our task.Carbon and chemical filters are often attached to the face of the sensor or added in the sample stream to diminishthe effects of cross interference to many of the commonly encountered such as H2S, SO2, NO x, etc..This filter, it’s efficiency and life span can be an important consideration when measuring CO in the 0-50ppmrange.In a number of applications background levels of Hydrogen given off by nearby processes have been found tocause major problems with accurate low level carbon monoxide measurements and alarms. While it is possiblefor hydrogen levels to cause safety concerns that should be reported, the limit is magnitudes higher than whatcauses the CO alarms to trigger on most instruments. A hydrogen level of as little as 60ppm can trip the COalarms of many analyzers. The lower explosive limit (lel)for hydrogen is 4%, ten percent of that l.e.l. would be4000ppm, so we see that the 60ppm is insignificant to personnel safety but remains problematic to the carbonmonoxide measurement. This cross interference can not be easily overcome with chemical filters and thereforerequired a different approach. It has been found that by measuring the hydrogen separately and using that signalin conjunction with the mixed CO/H2 signal the majority of the interference can be nulled out, again manufacturesdeal with this differently with varying results. The use of two separate sensors can create a compensation lagtime and there may be temperature coefficient differences between the sensors, either of which will cause errorsin the readings and provide false alarms. Similar temperature problems can be found with units that use a singlesensor but do the electronic nulling and temperature compensation remote of the sensor itself. There are sensors now available that have separate electrodes for the H2 and CO/H2 signals with the nulling andtemperature compensation circuit attached directly to the rear of the sensor itself. The output of this surfacemount board is in the millivolt range making it less susceptible to interference and change from wiring,connectors and temperature effects. Each sensor and attached PCB come completely pre-calibrated for H2 crossinterference and relative CO output. Only a single calibration gas is required over the life of the sensor (2 years)with no need for re calibration of the hydrogen signal nulling found in any of the units put into service. Inaddition, the internal chemical filter provides excellent reduction of cross interference due to other commongasses found. This customer replaceable sensor has proven itself over time to provide consistently accurateresults in demanding applications against competitors instruments. Dover Gas Technologies Inc. www.dovergas.com incorporates such a sensor, we believe it best suits the needsaddressed above and use it in many of our portable, transmitter, and monitor products for low level ppm COmeasurement.