CO Measurement in Coal Fired Plants

The ideal situation is to provide just enough excess air to produce complete combustion, but not any more than that. This will produce the highest efficiency, lowest emissions of pollutants, and maintain a high level of safety. The question is: How is the excess air setpoint determined?

Using CO to trim excess O₂

The amount of excess air in the flue gas is determined by measuring the concentration of oxygen (O₂). The ideal excess O₂ level (the lowest possible that allows complete combustion) depends on several factors: the fuel type, the burner type, humidity changes in the air, moisture content changes in the fuel, varying boiler loads, fouling of the burner system, and mechanical wear of combustion equipment. Since many of these factors are continuously changing, the ideal amount of excess oxygen continuously changes as well. Measuring carbon monoxide (CO) can help to determine the excess oxygen setpoint.

CO is the most sensitive indicator of incomplete combustion. As the amount of excess O₂ is reduced, the emergence of CO will occur before other combustibles appear (unburnt fuel). When the concentration of CO reaches the desired setpoint (typically around 400 ppm), the excess O₂ concentration is at the desired level and becomes the new excess O₂ setpoint. As the concentration of CO increases or decreases, the excess O₂ setpoint can be trimmed accordingly. CO trim control of excess O₂ concentration assures minimal energy loss, maximum efficiency, and reduced NOx emissions independent of boiler load, fuel type, humidity, moisture content of fuel and other variables that make excess O₂ control difficult. The key to obtaining these benefits is an accurate and reliable measurement of CO in low ppm levels.

Obstacles to Measuring CO in Coal Fired Boilers

Measuring CO accurately and reliably in coal fired applications has traditionally been extremely challenging. Some of the obstacles that must be overcome:

• Flue gas laden with fly ash particulate
• High temperature in the optimal measuring location
• Stratification of gas concentrations 
• Presence of SO₂ in the flue gas
• Speed of response in non-insitu installations

Catalytic Bead Sensor

Current measuring technologies that are employed to measure CO (or combustibles in general) are Catalytic Bead sensors, Thick/Thin Film thermistors, and IR spectroscopy.

The Catalytic Bead and Thick/Thin Film thermistors utilize the thermal properties of combustion to change the resistance of an active element compared to that of an inactive reference element. The active element is coated with metal that acts as a catalyst for combustion when exposed to air and a hydrocarbon. The other element is left in a natural state without a coating to act as a reference against background changes that would affect both elements (i.e. process temp, gas thermal conductivity etc). Combustion on the surface of the active bead increases the temperature of the bead in effect raising its resistance. The difference between the reference and active resistance values is proportional to the concentration of combustibles in the process gas. 

Infra-red Analyzers use an infrared source mounted directly on the flue gas duct or stack on the side opposite from the receiver. Infrared energy is radiated by the source, through the flue gas, to the receiver. The receiver employs gas filter correlation and narrow band pass optical filtration with a solid state detector to determine the absorption of radiation by CO in the flue gas. The magnitude of the absorption is proportional to the concentration of CO in the flue gas.

These measuring technologies are prone to the following problems:

Infrared Analyzer

• The catalytic sensors require sample extraction (not insitu) installations. These sample extraction systems are prone to plugging and fouling with fly ash in coal fired applications. They require frequent preventative maintenance and the filters they require cause slow response times.
• The catalytic sensors are discreet or point measurements. They do not provide a path or average measurement across the firebox. They are subject to stratification errors, may not detect isolated areas of CO breakthrough, and require multiple points of installation to provide adequate coverage.
• IR analyzers cannot make the measurement in particulate laden (fly ash) flue gas. This combined with temperature limitations prevents IR installation directly across the fire box. They must be installed further down the process, at lower temperatures after particulate removal (precipitators). This introduces more lag time in detecting CO breakthrough. Also CO that reacts after the fire box will not be detected (CO quenching). - IR analyzers are subject to interference from CO₂ and water. Catalytic sensors are subject to interference from NO₂ and water, and quickly deteriorate in the presence of SO₂. This mandates frequent calibrations, replacements, and suspect accuracy.

These problems prevent these traditional measurement technologies from providing an accurate and reliable CO measurement.

Solution to Measuring CO in Coal Fired Boilers

Flue Gas Stratification

Tunable Diode Laser Spectroscopy (TDLS) manufactured by Yokogawa Corporation of America has been proven in the field to be a solution for this difficult measurement. Tunable Diode Laser measurements are based on absorption spectroscopy. The TruePeak Analyzer (TDLS200) is a TDLS system and operates by measuring the amount of laser light that is absorbed (lost) as it travels through the gas being measured. In the simplest form a TDL analyzer consists of a laser that produces infrared light, optical lenses to focus the laser light through the gas to be measured and then on to a detector. The detector and electronics that control the laser then translate the detector signal into a signal representing the CO concentration.

The TruePeak Analyzer utilizes powerful lasers that are highly sensitive and selective for CO. This results in many benefits over traditional IR analyzers and catalytic sensors:

• The TruePeak Analyzer measures CO directly in the fire box. This means no lag time in detecting CO breakthrough and no false low reading due to CO quenching after the fire box.
• The TruePeak Analyzer measures CO insitu. There is no extractive sample system induced maintenance or lag time.
• The TruePeak Analyzer is a path (across the fire box) measurement. This provides an average reading that ensures isolated areas of CO breakthrough are detected. Multiple installations are not required.
• The powerful, selectable laser of the TruePeak Analyzer penetrates fly ash and is sensitive to low ppm levels of CO. 

Summary

Coal fired power plants can achieve the highest efficiency, lowest emission levels, and ensure safety by using CO concentration measurements to fine tune their excess O₂ setpoint. These benefits are achievable only if the CO measurement is accurate and reliable. Using TDLS, the TruePeak Analyzer from Yokogawa can provide that accurate, reliable CO measurement in coal fired power plants.