Ethanol From Ether De/Re-Hydration Process

So I was thinking, as ethanol has a boiling point relatively close to that of methanol and other denaturants used in the industry, and diethyl ether has such a vastly distant boiling point from dimethyl and methyl-ethyl ethers, one ought to be able to make reagent ethanol from the denatured variety by converting it ether, distilling it, and then converting it back to ethanol. The process would go something like this:

Sulfuric acid is added to denatured alcohol, and ethers are distilled out. Dimethyl ether condenses out -23°C, with the help of a brine cooled condenser hooked up to some peltiers or a phase change pump. Methyl-Ethyl ether then condenses out at 7.4°C similarly. Diethyl ether then condenses out at 34.6C. In practice this could be done with a continuous fractionating still, or with a cascade of three continuous reflux stills, or a cascade of three batch reflux stills. It could also be done in three steps with a single still but that would be more work. For a continuous still, the steam feed would consist of ethanol, while H2SO4 is fed in from the middle and runs out the bottom containing water. The water could be distilled out from that and the same H2SO4 cycled back in, if one wanted to get that elaborate. I have a hybrid two stage continuous/batch still which could at least separate the diethyl ether from the dimethyl/methyl-ethyl ether blend. I put together this still mainly for distilling solvents and nitric acid, but the feed sources aren't fully chemically compatible just yet.

The purified diethyl ether would then be fed into a continuous still from the side while a stochiometric amount of water in the steam feed hydrates it, as the column would be packed with solid catalyst. I am not sure exactly what solid catalysts might be appropriate (though I'm sure someone here does), but I know an alternative could be to include phosphoric or sulfuric acid in either of the incoming process streams to catalyze the reaction. The acid catalyst would then run out the bottom with any waste waters. This step could produce at least 190 proof ethanol which could then be easily dehydrated with zeolite or something to make anhydrous reagent ethanol. Anhydrous ethanol could possibly be produced directly here if the amount of water could be carefully controlled, and the conversion complete.

An alternative to the continuous rehydration is to feed diethyl ether and water vapors into a cooled flask or separatory funnel containing the catalyst, condensing out ethanol in a batch process. If sulfuric acid is used in this process, it could be neutralized with copper oxide in order to distill out the ethanol without dehydrating it again. Copper sulfate can then be recycled to SO3/oleum/H2SO4.

If desired, the dimethyl ether could be similarly rehydrated to obtain pure methanol. I'm not sure what the equilibrium or proportions of methyl-ethyl ether would look like or if the methyl and ethyl groups would be mobile in the solution at all. I'm sure someone here knows this though.

The absolute boiling point of methyl-ethyl ether is only 91% that of dimethyl ether, while the boiling point of dimethyl ether is only 81% that of diethyl ether. Compare this to the boiling point of methanol being 96% that of ethanol.



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-23C isn't that hard to achieve. A CaCl2 brine cooled condenser could work down to almost -50C as long as you've got a cooler than can reach that. Another, option, wasteful as it may be, would be a dewar condenser containing liquid propane or another refrigerant. I have a variety of fridge/freezer condensers and have been working on retrofitting some of them, including a -50C 6000BTU/hr cascade for condensing chlorine. If nothing else, the Me2O could be piped out and burned, and used to heat the still, or something.

You're right the process is cumbersome, but it should work for extracting from E85 fuel and such too as the other hydrocarbons won't react and have a much lower boiling point than the ethers. Really, it should work for about any source of ethanol, but is definately only practical if you really need some pure reagent ethanol and don't wish to pay for taxed alcohol, or have a 20ft still.

edit:

Well, yes, it CAN be done, but the conditions would (i imagine) be most awful. Since ethers are very unreactive it would have to be hot,possibly very hot, like >150*C. which means gas phase or very high pressures (or both maybe?) anyhow I know I wouldnt like to work with ether at 150*C, because I don't like dying in an explosion but I don't know what apparatus your have available. I will leave it to someone more knowledgeable to tell you whether it is actually impossible, or just very hard.

C-> M conversion and what is this shit?

Well I daresay it would be slightly easier than the catalytic hydration of ethylene. It should be fun, anyhow, I am curious how well it might work out.

A little off topic, but are you familiar with sucrose fermentation?

Also, cleaning up ethanol from E85 fuel seems like it would be MUCH simpler.

And... If you need Et2O as a solvent, a few percent of dissolved MeOEt isnt going to affect the results. Again, for most needs as a solvent *a few percent* of MeOH in EtOH is not going to have a detrimental affect. It has similar properties, except that polar substances are slightly more soluble (negligable effect in small concentration. As per adding ethanol to a water solution... I have done this with a CuSO4 solution and it knocks ALL the colour out, zero solubility even though there is 20%+ water there).

If you need reagent ethanol, then I would suggest buying reagent ethanol...If its a reagent you probably wont need to use much so the cost is acceptable. Or if you were so inclined to buy OTC products then I would recommend a Polish drinking product called "95" (95% ). Bad as tarrifs are this will still only cost 2-3 times as much as chemical supplier ethanol. Or in some cases, it would be cheaper. It all comes down to a balancing act of your time, your money and the quality of your product.

As smuv pointed out, you could hydrolise ethyl acetate. This may be cost effective for you if you have a cheap source of EtOAc. Basic hydrolysis is easy since it can only proceed one way and sequesters the acetate, certainly easier than playing with ethers.

[Edited on 28-10-2007 by Antwain]

Quote:

Or if you were so inclined to buy OTC products then I would recommend a Polish drinking product called "95" (95% ).

We have 95% ethanol here too, for relatively cheap compared to other booze. However, I am not remotely inclined to use OTC products for chemistry if I can make suitable ones myself for cheaper. There are much better things to do with drinking products anyway, such as drinking them. In regard to both this and the commercial ethyl acetate idea, I don't generally like to buy reagents reagents this way. They are expensive, and are getting harder and harder to obtain all the time. I do all my chemistry under the assumption that someday a regular citizen will NOT be able to buy ANY chemicals (beyond certain staple ones like NaCl, gypsum, fuel products, distilled water, automotive products, etc.) due to increased government regulations and other "phasing out" of chemical products. For example, I would not count on being able to buy HCl or H2SO4 from a commercial source years from now, and anyone who relies on these commercial products for home chemistry without being able to make their own will probably find themselves out of business one day. About the only non-consumer chemicals I ever buy are ones that contain uncommon elements like lithium, bromine, iodine, cesium, mercury, etc. I also have a good stock of chemicals that are still cheaper to buy than they are to make, such as nitrate and carbonate salts, sulfuric acid, acetone, urea, etc, but I have plans to synthesize from scratch too when they become unavailable/illegal. It would already be difficult to obtain a reagent like ethyl acetate for a reasonable price, as it is not something you can pick up in bulk at the grocery or hardware store.

The only way to get ethyl acetate, as far as I'm concerned, is as garage chemist described, by esterfying ethanol and acetic acid, with said acetic acid being distilled from vinegar or made by fermentation. Of course, if I did fermentation, I could just use it to make ethanol itself. The nice thing about the ester process though is that an amount of acetic acid can be used over and over again to purify something cheap like E85 by acidifying the resultant sodium acetate (from the alkali hydrolysis) with HCl. Admittedly the process is still rather round-about in comparison to distillation without chemical conversions. I see we have another thread on E85 separation, which I have been following as well.

I have some 4A zeolite, perhaps I could try that to further purify after plain distillations.

One of my biggest issues is time, since I feel overwhelmed by my other and more important chemistry projects, and very seldom get to actually work on them. I need to finish my fused alkali salt cell first thing when I get the chance, then I need to set up apparatus for the Contact Process with SO2 coming from the firing of gypsum with coke and silica and being liquefied out from CO2 by a compressor), the Ostwald Process, metal casting furnaces, chlorate cell and associated oxygen generator, amalgam cell for NaOH/KOH production and an associated UV pulsed HCl furnace. Distillations take a long time and use a lot of energy especially when there is a lot of water involved and I want to keep that to a minimum and be able to use my glassware for more important things. It feels like all work and no play because I spend so much time and effort making reagents that I hardly have time to use them for what I want, like making exotic rocket propellants and the like.

Methanol and water don't form an azeotrope at atmopheric pressure

[Edited on 28-10-2007 by leu]