Gas Purity Monitoring in Air Separation Units

Schematic drawing of the ASU process

Gas Purity Monitoring of O₂, N₂ and Ar

An air separation unit (ASU) produces high-purity gases such as oxygen (O₂), nitrogen (N₂), and argon (Ar) via cryogenic distillation. These gases are used across industries including the steel, chemical, energy, electronics, and healthcare industries, where even trace impurities can impact processes.

HORIBA supports industrial and medical gas production with analyzers for continuous trace-level impurity monitoring down to ppb levels, as well as purity monitors covering the full 0–100% range. The portfolio also includes radiation thermometers for gas cylinder temperature monitoring.

Measure Trace-Level N₂O and CO₂ Impurities

HORIBA's Trace Gas Monitor GA-370 uses non-dispersive infrared (NDIR) photometry to measure trace levels of nitrous oxide (N₂O) and carbon dioxide (CO₂) behind the repurification unit. Trace levels of CO₂ are also measured in the N₂ and O₂ product stream with a typical monitoring level of 1 ppm.

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GA-370 Trace Gas Monitor

Measure Trace-Level TRS and SO₂ Impurities

HORIBA's Sulfur Dioxide Monitor APSA-380 uses UV fluorescence to measure trace levels of total reduced sulfur (TRS) and sulfur dioxide (SO₂) behind the repurification unit and in the N₂ and O₂ product stream.

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APSA-380 Sulfur Dioxide Monitor

Measure Trace-Level THC Impurities

HORIBA's Hydrocarbon Monitor APHA-380 uses flame ionization detectors (FID) to measure trace levels of total hydrocarbons (THC) at the air inlet and behind the repurification unit.

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APHA-380 Hydrocarbon Monitor

Related Brochures

GA-370 Trace Gas Monitor

The GA-370 Trace Gas Monitor enables continuous, high-sensitivity monitoring of CO, CO₂, CH₄, and N₂O in high-purity gases, supporting reliable quality control in air separation and semiconductor plants.

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AP-380 Series Air Quality Monitor

Within the AP-380 Series, the APSA-380 is used for sulfur dioxide measurement and the APHA-380 for hydrocarbon measurement.

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Related Applications

Related Webinar

Attend our webinar "Continuous Gas Analysis for High-Quality Industrial and Medical Gases" on May 20, 2026 and learn how gas purity and overall gas quality can be measured using different analytical technologies.
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Monitoring of Impurities in Hydrogen Gas for Fuel Cell Vehicles

Continuous measurement of impurities in hydrogen gas for Fuel Cell Vehicles (FCEV/FCV) with a highly sensitive analyzer.

Hydrogen Energy

Our wide range of proprietary measurement and analysis technologies can bring better energy usage for production by implementing hydrogen, ammonia and other forms of energy. Reducing costs and energy waste.

Useful Knowledge

Gases and their sources

N₂, O₂, Ar: Air separator

CO₂: Industrial sources or combustion

CO: Methane reformer (HyCO)

H₂: H₂O electrolysis and methane reformer

NH3: Haber-Bosch process

N₂O: Heating of NH₄NO₃

NO: Oxidation of NH₃

He: Natural gas sources

C₂H₄: Steam cracker

Optical Technologies for Gas Analysis

Non-dispersive infrared photometry (NDIR)
Used to measure impurities and purity levels in CO, CO₂, N₂O, CH₄, etc.

UV fluorescence (after oxidation)
Used to measure impurities in SO₂, H₂S and other sulfur-containing compounds (TRS, TS).

Other Technologies for Gas Analysis

Paramagnetic detector (PMD)
Used to measure impurities & purity in O₂.

Chemiluminescence detector (CLD)
Used to measure impurities in NO, NO₂, NO_x.

Flame ionization detector (FID)
Used to measure impurities in CH₄, C₂H₆, etc.

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Gas Purity Monitoring in Air Separation Units

Gas Purity Monitoring of O₂, N₂ and Ar

Measure Trace-Level N₂O and CO₂ Impurities