Electronics > Projects, Designs, and Technical Stuff

Vacuum/Gas system for DIY plasma tube

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brm:
Hi guys,

I would like to construct a plasma tube but I'm unsure of how to set up the vacuum system and gas dispension system.
The idea is to use a plexiglass tube, approx. 100mm long and 40mm diameter, with plastic end-caps and o-rings
at the end, held together at both sides with screws and maybe hotglued to the plexiglass as well. At both plastic
ends, there would be holes for a set of nuts and a screw, and the screw-heads will be fastened to be approx. 20mm
apart within the tube and will serve as the electrodes.

Now my issue is with the vacuum/gas connections to the tube. Since I want to do some experiments at low gas pressures,
say 10-15 mbar of H2, I assumed I need to use a T-connector with a 3-way valve, with one end going to the tube, one to
the vacuum pump, and one to the H2 cylinder (with it's own separate valve as well). If I understand correctly, one needs to
evacuate the tube first, then shut off the valve to the vacuum pump, and then slowly add H2 until the desired pressure is reached.
The idea is that the tube can be periodically refilled or emptied if needed.

However, I am not sure how to connect the vacuum tubing to the plasma tube itself. I saw that there are center-vented screws
available, however they have the hole running up to the head of the screw which makes it unsuitable as a plasma electrode (I guess).
I was thinking to maybe drill a hole in one side of the plastic end-caps, and then fit and hot-glue some plastic tubing to the hole, but I'm
doubtful if this is a proper way to achieve a good connection at low vacuum. Also, I was thinking of using a differential manometer
from ebay
( https://www.ebay.com/itm/Manometer-Digital-Air-Pressure-Meter-Differential-Gas-Tester-Tool-LCD-Gauge-Test/352238313315?hash=item52030a1f63:m:mTVd680ZQycxEkT0_xyC-kQ ),
but I'm not sure whether you can measure the absolute vacuum level accurately with it since it is difficult to get a good 0-bar reference.

For sake of clarity I have attached a picture of a similar construction to what I was describing. If anyone with more experience has any advice
on how to go about it I'm all ears! thanks.

ChristofferB:
I'd be VERY cautious about all those soft squishy construction components and high vacuum.
In the picture below, the nuts the electrode screw rods are mounted on are not regular nuts, they're swage-lok compression fittings - tube fittings. Maybe that's the way to go. Thread some 1/4" fittings into the end caps of the tube (you can get compression fitting - NPT pipe thread adapters).

Separating your pressure lines from the HV electrodes also has the benefit of... not having to energize all your gas gear.

I'd go for two needle valves connected to a 4-way fitting: one port to each valve, one to the chamber, one to a pressure gauge. One needle valve can be connected to a vacuum pump and the other to any gas source.

I'd consider a used thermocouple gauge from ebay for pressure monitoring.

Also: if you put high voltage through hydrogen and there's air present, bad things could happen. Make sure you can purge/flush your assembly and there are no leaks!

Be careful.

--Chris

brm:
Hi Chris,

thanks for the info - you have clarified things a lot. I will look into the components you mentioned and see what I can get. I'm also most likely

going to work with helium, at least initially, until I get a "feel" for using the setup. For the end-caps of the tube I am planning to use "delrin", a

kind of hard non moisture-absorbing plastic.

cheers

qwaarjet:
While I agree with the needle valve for letting gas in pulling vacuum through one is going to be awful. A good quality ball valve or even globe valve would be preferable. Also with low diameter tubing getting down to a good base pressure is going to take a surprising amount of time. Keep you tubing as large diameter and as short as possible. Additionally I didn't see any mention of  pressure regulator on gas supply bottle, without one a moment of inattention could rapidly over pressurise such a small test article and frag it, in a professional environment I would suggest adding a burst disk as safety feature as well as heating of the gas in the test article could over pressure as well if not careful. Not trying to be kill joy just just seen a lot of overpressurization events in my life (mostly intentional ;D). 
PS on pumping H2 though vacuum pumps if it's oil  sealed pump the H2 will dissolve in the oil and when you vent the pump back to atmosphere it can come out in big burp of highly flammable gas, never had it be an issue but just an FYI.

LaserSteve:
 Most modern gas regulators will "Slam" or "dump wide open" into a vacuum chamber.  You need some form of resistance to flow between the regulator and the plasma chamber or your regulator will surge..  Most of us use very narrow gauge , very thick wall,  stainless steel capillary  tubing for this.  The length has to be determined experimentally in your case, but can be quite long.

Also the minute you apply high voltage to that setup your probably going to blow up that cheap digital gauge.  Plasma tends to form up and down the system piping on improvised systems like that..  One of my favorite plasma demos is a large  square of glass tubing about a foot per side with two electrodes close together, about four inches apart, on one side.  You would think the plasma will always take the short path, but  depending on the mean free path and ionization potential of the gas, it will often consistently take a longer path. Seriously, it will light the whole square in some cases, if you have enough current.  Thus Discharge isolation is important, as it will tend to follow the tubing to the pump or the regulator, even if they are floating from the HV source.

Plastic tubing is fine for beginners, provided it is thick walled enough to not collapse.  However it outgasses like crazy and can be easily decomposed by some plasmas.  Arcs will tend to blow holes in it. In the lab, we resort to  Pyrex  Glass for a lot of these things. (Not Pyrex(tm)  kitchen ware, which is has not been thermal shock resistant BOROSILICATE glass since the 1990s)  Use  Corning 7740 Pyrex, or Kimax or Simax. Borosilicate glass is your friend in this area, although professional systems are known to use ceramic isolators metalized and brazed to vacuum flanges.

As I have no idea how your setup is going together,  I cannot advise you on how to isolate the discharge.  I can tell you that while fine mesh metal screens really slow down the response of most gauging systems, they do a decent job of keeping direct plasma off the sensor interior.

Short pieces of isolated metal tubing have a bad habit of electron  multipaction and forming hollow cathodes that increase electron emission from the metal.  This is why if you look at a neon sign electrode, its a cylinder  inside...  Point being as your new at this, it is very easy to charge up your pump, valves,  etc and get shocked from the plasma conducting leakage or from corona discharge. Especially if you use cheap plastic tubing to handle the gas...  Even if you have a meter or two of tubing in circuit.

As mentioned previously, TC gauges are the way to go, but avoid 531 series tubes for plasma work.  Old systems with analog meter movements tend to hold up, and if you get one of the 1970s designs, easy to repair.   Your not ready for capacitance manometers yet, you have to learn how glow discharges act. 

TCs are for checking the pump and  finding leaks, and with that plastic type of rig, you WILL be chasing leaks.  Home made glass tubing  based Oil manometers using  decent grade low vapor pressure vacuum pump oils are good for beginners for your first couple of runs.   Well, until you get to the point that your pressure is so low that you need a cold trap to keep oil out of the experiment. Simple plasma experiments usually don't get that low.

That tube in the picture has a lousy electrode structure, that looks designed for short arcs of short duration.  Pyrex glass, even if it is a short tube inside the plastic, will be a good choice for containing the discharge from such poor electrodes.  What I see there will sputter off metal if ran for prolonged times in certain pressure regimes.  Even a short piece of tungsten welding rod will lighten your day compared to those cheap spheres... Air and Nitrogen discharges get hot and emit little light, but tend to oxidize things.

Ballast resistors may be needed to protect cheap sources of high voltage from "negative delta" plasma regimes acting as a dead short.  While some people would prefer to label that "negative resistance", the term is a misnomer as the plasma consumes current, and is not creating it.

Big tubing on the suck end. Fine tubing on the feed end, and use valves.  Rotary vane pumps are a must for this sort of thing.

"In Vaccuo, Veritas"

BE CAUTIOUS.. Don't get shocked by leakage or blinded by an implosion. Wear safety glasses and use thick plastic shields or metal mesh around improvised vacuum chambers.  I've seen shards of broken glass sticking out of walls on more then one occasion when people tried to improvise, but I've been at this over 20 years.

Helium is expensive, start with Argon. I'm not sure about Europe, but in the US the He and Ar tanks use the same fittings, CGA 580.

Swagelok fittings are your new  friends... Good parts come from Kurt J.  Lesker and Duniway Supply.  Hysol 1C White is a good substitute for Torr Seal and a hell of a lot cheaper. Well, in fact it is the basis of Torr Seal, and missing one not so critical ingredient.

Steve






 

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