EDIT MAY 2019: Sorry for reviving a dead thread but the alternative was making a new thread with the exact same title. Not sure what best practice is then.
I've completed the next iteration of my gas chromatograph and made a brief video about it! Hope you'll enjoy!Some of you will have seen my previous posts on different elements of this project but now that a working prototype has been finished, I thought I'd make a thread describing
the project in more details.
So here it is, my home-built gas chromatograph with thermal conductivity detector (GC-TCD).
It consists of the following major components:
- Carrier gas supply (helium)
- Carrier pressure regulator
- cold on-column injector
- column
- detector
- detector amplifier
I know there aren't many chemists here, and I know the project is a bit of a mashup of electronics, chemistry, mechanical engineering and so on, but bear with me.
For the non-chemists, here's a very TL;DR description of what this instrument does:
->a flow of gas is established through column; a long tube packed with a fine mineral or polymer powder with a large surface area, that can be either coated with a film of liqid or uncoated.
->A sample of a mixture of gasses is injected into the gas stream before the column, and as the molecules travel across the large surface in the column, they'll interact more or less strongly with it.
->this results in different components effectively moving through the column at different speeds and thus a separation has been performed.
->A variety of detectors is then used to sense the change in gas flow, indicating when each of the gas components comes through. detector readout as a function of time is recorded.
->These systems can analyze gasses, why the instruments are typically built in ovens, capable of reaching 400+*C
that's it, that's all. but it's one of the most robust tools in analytical chemistry, along with its liquid brother HPLc.
These machines usually costs 20,000+ USD, which gave the inspiration to this project: cheap, off the shelf and robust.
I wanted to design a high-capacity instrument for basic everyday lab use, following reactions and the like, that could be put together without (many) custom components.
Design considerations
Carrier gas:
In my mind, if I had to buy/rent a cylinder of high purity lab-grade gas, this project would already be so much over budget it wouldn't be worth it, so The carrier gas was chosen to be either welding argon or balloon helium.
Both of these can be obtained in low-pressure single use cylinders. Hydrogen is common also, and while it is handy that you can just have an electrolysis rig supplying your instruments, and not storing the gas, I still deemed it too
dangerous for me. I simply did not want to have to worry about it. Balloon helium was chosen over the grounds that it's cheap and helium is a very commonly used carrier gas, making comparisons with litterature easier.
Mechanical components:
Every part of the pressure part of the system is made from stainless steel tubing and compression fittings, both cheap and chinese from ebay. The proper fittings to use are the Swage-lok line of process fittings, but at 40 times
the cheapest price i found from china, i went with cheap, and hoped they wouldn't be leaking. The system only operates at max 60 PSI, so i wasn't too worried about fitting failure, more that the compression ferrules would be so rough they wouldn't seal tight.
Luckily, they did, a spray-down with soapy water is a good indicator, and giving the compression nuts 1/4 turn more usually solves any small leaks.
The inlet is made so that a rubber disk, known as a septum, can be placed under a compression nut on a T fitting and tightened down, to introduce samples via syringe. it's made longer than need be to give some volume where the gas
can sit until it enters the column. In the future this assembly will be outside the oven, heated separately.
The pressure regulator is a Brooks 8601 regulator scavenged from an old gas chromatograph, it's a panel mount reduction valve, they show up on ebay at reasonable prices.
Detector:
The detector design came from a paper in the Journal of Chemical Education, and simply consists of an 1n4148 in a short lenght of thin-walled 1/8 tubing, cathode spot welded to the wall, anode connected to a 150 ma current supply,
that heats the diode. it'll reach some equilibrium in the stream of helium, and when the gas momentarily changes, so will the heating of the diode, giving a change in voltage over the diode.
The diode voltage is fed into an instrumentation amplifier with a fairly large amplification set by a 10-turn pot, and compared to a "stable" voltage source (AA battery). The reference voltage can be changed with a potmeter to set the zero.
and the amplified signal is passed out to a BNC, where any datalogger can be used to record the data. I use an arduino with some Vbasic script i found that plots time and voltage in excel.
Column:
The column i use is also of 1/8" stainless tubing, around 50 cm packed with aluminum oxide (alumina, pottery store grade), which has been wetted with approximately 14% by weight liquid paraffin. this is mixed until the powder is reasonably dry.
the column (straightened) is fitted with a cotton plug in the bottom end, to which a small vacuum pump is attached, and a funnel is mounted on top, in which small amounts of the stationary phase is added.
The pump is turned on and the column tube is tapped with a screwdriver (ugh..) for a long.. long... time.. until no more alumina sinks in. at this point it is plugged with cotton (use glass wool if it needs to be heated!), the column is coiled up,
and ferrules and compression nuts are mounted.
test:
Here's the first analytical separation: a propane/butane mix from a blow-torch. 150 ul is drawn with a syringe and injected through the septum with a helium head pressure at 20 psi, giving around 18 ml/min flow through the column.
The sample is injected around 20s in. it is seen that there is a tiny wide peak, which is residual air, and then two large peaks with a minute inbetween. I'm fairly certain the first one is propane and the 2nd one is butane.
(propane is more polar than butane, thus more similar to air, thus less column retention, since the column packing is coated in oil).
I believe this is the first internet-available results of a homebuilt gas chromatograph!
Further work:
-better detector: I want a full wheatstone bridge thermal conductivity detector that compares the column output with the clean helium in the carrier line. this way any changes in flow or pressure will self-correct, it'll also benefit sensitivity a lot.
-heat: the column will be mounted in a toaster oven, power resistor heaters and thermostats on both injector and detector will allow for analysis of liquids and solids with a boiling point up to around 200 *C.
-temperature programming: being able to ramp temperature over a set time, make temperature plateaus and so on will MASSIVELY increase resolution.
-better columns: finding better coating liquids, making columns longer and more uniform for better performance.
Anyway I hope you found this interesting, I know I have! I'd also like to thank all of you who gave advice on the project in its different phases over the last year and a half.
--Chris
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