-
- Posts: 2
- Joined: Fri Jul 15, 2016 4:01 pm
Hello Everyone,
Our lab is currently shopping for a GC that would help us accurately analyze the products of Steam Methane Reforming. The products we need to look at are pretty simple, mostly just refinery gas products and hydrogen. Even though this is a fairly easy task for a gas chromatograph equipped with a TCD detector, the concerns arise when attempting to detect H2 and refinery gas products simultaneously due to their drastically different thermal conductivities.
One setup we used to use was dual TCD, one running Argon carrier to detect H2, and the other running Helium for everything else. The issue with this is a complicated method that led to 20 min run times due to a column isolation step (piping diagram below).
The other setup was one TCD running just Argon carrier, and dealing with the low responses from the refinery gases. This was not ideal, but might do the trick.
With the SMR reaction we also need to worry about moisture getting into the system, so a good condenser upstream would be required.
When looking for quotations, various companies have said the first setup is probably the best, but maybe use an FID for the refinery gases.
Agilent suggests the 490micro, which im apprehensive about due to its limitations, but seemingly offers the fastest run times and most accurate results. Reminds me kind of a laptop vs a desktop pc. The desktop pc offers much more customization, cheaper components, and you can maintain it much easier yourself. What are your experiences with these microGCs?
Any help or suggestions would be much appreciated.
N.
Our lab is currently shopping for a GC that would help us accurately analyze the products of Steam Methane Reforming. The products we need to look at are pretty simple, mostly just refinery gas products and hydrogen. Even though this is a fairly easy task for a gas chromatograph equipped with a TCD detector, the concerns arise when attempting to detect H2 and refinery gas products simultaneously due to their drastically different thermal conductivities.
One setup we used to use was dual TCD, one running Argon carrier to detect H2, and the other running Helium for everything else. The issue with this is a complicated method that led to 20 min run times due to a column isolation step (piping diagram below).
The other setup was one TCD running just Argon carrier, and dealing with the low responses from the refinery gases. This was not ideal, but might do the trick.
With the SMR reaction we also need to worry about moisture getting into the system, so a good condenser upstream would be required.
When looking for quotations, various companies have said the first setup is probably the best, but maybe use an FID for the refinery gases.
Agilent suggests the 490micro, which im apprehensive about due to its limitations, but seemingly offers the fastest run times and most accurate results. Reminds me kind of a laptop vs a desktop pc. The desktop pc offers much more customization, cheaper components, and you can maintain it much easier yourself. What are your experiences with these microGCs?
Any help or suggestions would be much appreciated.
N.
