• High performance detector design
  • Thermostatic construction protects from ambient temperature fluctuations
  • Optimized emitter control and detection circuitry
• Choice of either argon and helium carrier gas
• Increase laboratory productivity with automation options
  • Available autocleaner minimizes the need for manual cleaning between analysis
  • 20-position shuttle loader for both crucibles and samples
• Boom-mounted touch-screen interface provides improved ergonomics and intuitive operation
• State-of-the-art infrared (IR) detection for oxygen determination and thermal conductivity (TC) detection of nitrogen

Applications

The 736 series is ideal for the following applications: inorganic materials, ferrous and nonferrous alloys, copper, aluminum, and refractory materials.

The ON736 Oxygen/Nitrogen system is designed for simultaneous measurement of oxygen and nitrogen content of steel and other inorganic materials. The instrument features custom software designed specifically for
touch operation.

A pre-weighed sample is placed in a graphite crucible which is heated in an impulse furnace to release analyte gases. Oxygen present in the sample reacts with the graphite crucible to form CO and CO₂. An inert gas carrier, typically helium, sweeps the liberated gases out of the furnace and through a Mass Flow Controller. The gas then flows through a heated reagent, where the CO is oxidized to form CO₂, and H₂ is oxidized to form H₂O. Oxygen is detected as CO₂ using a non-dispersive infrared (NDIR) cell. CO₂ and H₂O are then scrubbed out of the carrier gas stream. A Thermal Conductivity (TC) detector is used to detect the remaining nitrogen.

The detection system is comprised of both NDIR and TC detectors. NDIR cells are based on the principle that analyte gas molecules absorb infrared (IR) energy at unique wavelengths within the IR spectrum. Incident IR energy at these wavelengths is absorbed as the gases pass through the IR absorption cells. TC detection takes advantage of the difference in thermal conductivity between carrier and analyte gases. Resistive TC filaments are placed in a flowing stream of carrier gas and heated by a bridge circuit. As analyte gas is introduced into the carrier stream, the rate at which heat transfers from the filaments will change producing a measurable deflection in the bridge circuit.

The concentration of an unknown sample is determined relative to calibration standards. To reduce interferences from instrument drift, reference measurements of pure carrier gas are made prior to each analysis.