James A. Jahnke

Continuous Emission Monitoring


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      Analytical Techniques Used in CEM System Instrumentation

      Techniques used for laboratory analysis, as well as techniques applied specifically for emissions monitoring, have been incorporated into commercially marketed systems. New analyzers have been developed using established electro‐optical methods, but are beginning to incorporate new light sources and detectors, such as tunable diode lasers, quantum cascade lasers, and diode arrays and new techniques such as cavity ringdown spectroscopy. The incorporation of microprocessors into today's analyzers has added useful features such as data storage, troubleshooting diagnostics, and external communication.

Gases Flow/Velocity
Extractive In‐situ In‐situ
Absorption spectroscopy: Path: Path:
Differential absorption Differential absorption – IR/UV Acoustic velocimetry
Photoacoustic Second‐derivative spectroscopy Time‐of‐flight
Gas filter correlation Wavelength modulation
Fourier transform IR Gas filter correlation
Luminescence methods: Point: Point:
Fluorescence (SO2) Differential absorption – IR/UV Differential pressure
Chemiluminescence (NOx) Gas filter correlation Thermal sensing
Electroanalytical methods:
Polarography
Potentiometry
Calorimetry
Electrocatalysis (O2)
Paramagnetism (O2)
Methods for HAPS:
Differential absorption
Gas chromatography
Mass spectrometry
Fourier‐transform IR
Ion‐mobility spectrometry
Atomic emission (Metals)
Atomic absorption (Metals)
Atomic fluorescence (Metals)
Extractive In‐Situ
Point Point: Path
Beta radiation attenuation Light scattering Transmissometry
Light scattering Contact charge transfer Light scattering
Electrodynamic induction

      Succeeding chapters present details of both extractive and in‐situ systems – their advantages, disadvantages, and limits of application. The sampling interface is of particular importance in extractive system design and is treated separately in Chapter 3. Extractive system analyzers are discussed in Chapter 5. For in‐situ system design, the analyzer type is most important. In‐situ monitors for measuring gases are discussed in Chapter 6 and monitors designed for measuring flue gas flow, opacity and particulate matter in Chapters 79.

      Mercury monitoring, a field in itself, has advanced significantly, within 15 years of research and development. This topic is treated separately in Chapter 12, to outline how a new generation of mercury monitoring systems has evolved to enable continuous monitoring of stationary source mercury emissions down to less than 1 μg/m3. Monitoring for hazardous air pollutants (HAPs) has developed