Chemical trap, Oil coalescing filter, Fid adapter (optional) – Agilent Technologies G6600-90006 User Manual

Operation and Maintenance Manual

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• Collection and transfer of the combustion gases from the Burner to the

reaction cell.

• Transfer of ozone from the ozone generator to the reaction cell.

• Reduction of non-radiative collisional quenching of the emitting species in

the chemiluminescent reaction cell.

The higher vacuum produced by the oil-sealed rotary pump facilitates a
shorter residence time in the reaction chamber, and therefore reduces the
incidence of collisional relaxation of the excited SO

2

. This results in slightly

lower detection limits using the oil-sealed pump as compared to the oil-free
pump.

Chemical Trap

To protect the vacuum pump from exposure to ozone, a chemical trap is
located at the inlet of the vacuum pump. This trap contains a catalyst that
converts ozone to diatomic oxygen. This trap is a consumable part and should
be replaced every 90 days of continuous Detector usage.

Oil Coalescing Filter

The oil-sealed rotary vacuum pump is operated with the gas ballast partially
open to aid in the elimination of water produced in the Burner and transferred
to the pump. As a result of the open gas ballast and the high flow rates of
gases, oil vaporized in the pump can escape through the pump exhaust. To
minimize oil loss, an oil coalescing filter is placed on the pump exhaust to trap
vaporized oil and to return this oil to the vacuum pump oil reservoir. This is
not necessary for use with the oil-free pump. A replaceable element in the
filter is a consumable part and should be replaced every 90 days of continuous
use.

FID Adapter (Optional)

The Agilent 355 Sulfur Chemiluminescence Detector is designed to mount into
most GC detector ports and operate as a stand-alone sulfur detector. For some
applications it is desirable to monitor both sulfur and hydrocarbon
components using a single column without splitting. For this reason, Agilent
offers a few adapter kits to mount the Dual Plasma Burner onto a Flame
Ionization Detector for the simultaneous collection of FID and SCD
chromatograms. During dedicated SCD operation, 100% of the column effluent
passes through the Burner to the Detector. During simultaneous detection
approximately 10-20% of the FID exhaust gases are drawn into the Burner
through a restrictor, which reduces sulfur sensitivity to approximately 1/10 of
the signal observed in a dedicated SCD Burner.

NCD Reaction Cell

The model 255 NCD reacts nitric oxide from the Burner and ozone from the
Ozone Generator in the Chemiluminescence Reaction Cell. The reaction occurs