Download Model 42i-TL - User Manual
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Introduction Principle of Operation Thermo Fisher Scientific is pleased to supply this NO-NO2-NOx analyzer. We are committed to the manufacture of instruments exhibiting high standards of quality, performance, and workmanship. Service personnel are available for assistance with any questions or problems that may arise in the use of this analyzer. For more information on servicing, see Chapter 7, “Servicing”. Principle of Operation The Model 42i Trace Level operates on the principle that nitric oxide (NO) and ozone (O3) react to produce a characteristic luminescence with an intensity linearly proportional to the NO concentration. Infrared light emission results when electronically excited NO2 molecules decay to lower energy states. Specifically: NO + O 3 → NO 2 + O 2 + h ν Nitrogen dioxide (NO2) must first be transformed into NO before it can be measured using the chemiluminescent reaction. NO2 is converted to NO by a molybdenum NO2-to NO converter heated to about 325 °C. The ambient air sample is drawn into the Model 42i Trace Level through the sample bulkhead, as shown in Figure 1–1. The sample flows through a capillary, and then to the mode solenoid valve. The mode solenoid valve determines whether the sample flows through the NO2-to-NO converter (NOx mode) or bypasses the NO2-toNO converter (NO mode). The sample then flows through the converter output valve and a flow sensor to the prereactor solenoid valve. The prereactor solenoid valve directs the sample either to the reaction chamber, where it mixes with ozone to give an NO reading, or to the prereactor, where it reacts with ozone prior to the reaction chamber giving a dynamic zero reading for the analyzer. The prereactor is sized so that greater the 99% of a 200 ppb NO sample will react prior to entering the reaction chamber, yet is small enough to allow other potential interferents to pass through to the reaction chamber. Dry air enters the Model 42i Trace Level through the dry air bulkhead, passes through a flow switch, and then through a silent discharge ozonator. The ozonator generates the ozone needed for the chemiluminescent reaction. At the reaction chamber, the ozone reacts with the NO in the sample to produce excited NO2 molecules. A photomultiplier tube (PMT) housed in a thermoelectric cooler detects the luminescence generated during this reaction. 1-2 Model 42i Trace Level Instruction Manual Thermo Fisher Scientific