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stricnine
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Increase people's daily cheese intake, so their intestines get clogged, and then :we can market glycerin as "Human Drano"!! (IN other words, as a
laxative) LOL!!
[Edited on 10-11-2006 by stricnine]
I am getting old. I used to push it aside with one hand... now I need both!
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Ozone
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Well, glycerol is used as a stool softener, not a laxative per-se. Of interest, however, is that molasses (I mean blackstrap, not the stuff they sell
for consumption, viz. "Steens"). This stuff has a very high ash content, including Mg/Ca citrates! A couple of spoonfulls (which I tried when I was
naive, thinking it smelled delicious)...was able to hit the "eye of a needle at fifteen paces" (harsh!). I've thought of mixing it with bleached
powdered cellulose and coating it with Nukol and marketing it is "all natural" "Molaxative".
I apologize for deviating from the thread, but my inner juvenile could not resist the anectdotal reference.
The composition of molasses, however, is of interest since the production of EtOH supports the production of greasle. Molasses is about the most
complicated composition of *shit* and sugar imaginable, but with 30% fermentable carbohydrate is a viable (*cheap*) feedstock. Experimentally, we have
been growing rapeseed ("canola") to compliment this process.
This is theoretically possible on the home-scale, at least, until the industry scoops up all of the molasses .
Best of luck to all on the homebrew,
O3
-Anyone who never made a mistake never tried anything new.
--Albert Einstein
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froot
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Well glycerine could be a fuel in itself. It has a boiling point of 290 deg.C, a flashpoint of 160 deg.C and a BTU of about 97000/gallon. (reference
for this: http://biodiesel.infopop.cc/eve/forums/a/tpc/f/739605551/m/1...) biodiesel having about 117000 btu/gallon.
I dont see why, with a bit of manipulation, biodiesel and glycerol cant be used as a fuel in turbine engines. With a good preheat in the combustion
chamber past their respective flashpoints, they both should ignite readily when exposed to oxygen. Just think, you could go see the world and all you
need is a truckload of laxative .
The safety aspects make it a rather attractive option compared to kerosene and it's eagerness to burn everything up.
We salute the improvement of the human genome by honoring those who remove themselves from it.
Of necessity, this honor is generally bestowed posthumously. - www.darwinawards.com
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Tacho
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Burning glycerine produces acrolein, ranked as one of the most hazardous compounds (worst 10%) to ecosystems and human health.
I could not open the link you posted, maybe it shows a way to circunvent this problem. Sorry if that is the case.
Ozone, since you brought that very interesting point up, why don't you start a thread about possible uses for glycerine. Indeed, it seems that there
will be lots of it available in the near future.
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froot
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No, that link is just my reference for the BTU of glycerol.
Well after a bit of googling, I read that acrolein autoignites at 233 deg.C or there abouts. The temperature of the gases after combustion in a
turbine engine are well above 1000 deg.C. I'm pretty sure any trace of acrolein will be decomposed by secondary combustion releasing more energy.
Ps, sorry for off topic, maybe the glycerine part split off into a new topic?
[Edited on 14-11-2006 by froot]
We salute the improvement of the human genome by honoring those who remove themselves from it.
Of necessity, this honor is generally bestowed posthumously. - www.darwinawards.com
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Ozone
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Hello all,
The *big* problem with glycerol in an internal combustion engine is the fact that the acrolein (besides toxicity and a bunch of condensation products,
viz. dioxolanes from glycerol and acrolein) will polymerize fouling the hell out of everything.
I thought a new thread would be a good idea as well! I'll try to get one up.
-Anyone who never made a mistake never tried anything new.
--Albert Einstein
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Ozone
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OK everyone,
I started a new thread regarding the valorization of glycerol!
See you there,
O3
-Anyone who never made a mistake never tried anything new.
--Albert Einstein
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DrP
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Hi,
I wasn't sure if I should start a new thread for this question or not, so, I'll put it here.
Does anyone know anything about the antifreeze used in diesel? I'm presuming it is more sophisticated than simple ethylene glycol! So - What
chemical is used as antifreeze in diesel fuel for engines?
Thanks!
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Ozone
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Depending on the weather, up to 10% EtOH can be added to (or left in!) the biodiesel; this helps to prevent gelation (without fuel warmers).
O3
-Anyone who never made a mistake never tried anything new.
--Albert Einstein
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tito-o-mac
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do hydrogen fuel cells work just as well as biodiesel?
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Centimeter
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I think a lot of people confuse hydrogen as a source of energy. In truth it is looked at as more of an energy bank for transferring energy to a car
where it can be mobile. If memory serves me correctly, hydrogen is the most efficient energy vector that we know of. The energy that produces the
hydrogen gas comes from a different source, currently fossil fuels. It poses an interesting solution in particular if nuclear power becomes more
widely used. As you can imagine, it's much easier to make a nuclear power plant generate hydrogen gas than it is to put nuclear reactors on every
single car! The same would be true with solar, wind, and geothermal energy.
I wanted to address vulture's comment that biodiesel would not solve CO2 emission problems. You forget that fossil fuels are accessing carbon from
carbon banks where as biodiesel, and in fact any grown fuel, accesses atmospheric carbon. The issue with fossil fuels is that we are effectively
increasing atmospheric concentrations of CO2. Biodiesel would not only create a sustainable carbon cycle but could potentially, through sheer
cellulose refuse, reduce atmospheric CO2 concentrations.
One issue that I've always wondered about with regards to cultivated fuels is the source of fertilizers. It is my understanding that we currently
derive the majority of our fertilizers from fossil fuels. That could put a serious damper on cultivated fuels if we suck the world dry of fossil
fuels, not to mention the whole issue with food. As chemists have been saying for decades, it’s a shame that we burn petroleum for such easy to find
things as energy.
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Intergalactic_Captain
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A couple of articles to add to the conversation - The first one is an overview of miscellaneous pyrolytic routes to fuel from triglycerides, with a
good bit on straight-up catalytic cracking. One of the things that caught my eye was the mention of "H ZSM-5" zeolite to produce highly aromatic
gasoline-grade fuels...Definitely gonna do more looking into this.
The second article is from the DOE regarding their goals for biofuel production - Haven't gotten a chance to read into it in any detail yet, but
it's quite long and looks like it might yeild some interesting info.
[Edited on 11-14-07 by Intergalactic_Captain]
Attachment: triglyceride pyrolysis.pdf (314kB) This file has been downloaded 4753 times
If you see me running, try to keep up.
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Ozone
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ZSM-5 and the Mobil process are quite cool, aren't they? Please check out also, a nice Fischer-Tropsch application, which I have attached here.
(see also Zeachem)
Cheers,
O3
[Edited on 14-11-2007 by Ozone]
Attachment: Lamprecht 2007.pdf (213kB) This file has been downloaded 2360 times
-Anyone who never made a mistake never tried anything new.
--Albert Einstein
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Intergalactic_Captain
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Cool - I did a little research into synthesis gas last year, but put it on the backburner due to the energy input required to produce it. Interesting
part on the composition of the JP-8 fuel - at ~55% heptane, it should be a good starting point for gasoline type fuels....Gotta track down their
references and see if there's anything useful.
The way I figure it, gasoline-type fuels, ie. shorter chained, more volatile hydrocarbons, are where the money's at in biofuel production. The
average american thinks of biofuel as something they put in their car, not necessarily in the grander terms of the national grid and industry. As
such, biodiesel doesn't fit the bill - there just aren't enough diesel cars. However, a renewable gasoline alternative that costs less than $3/gallon
would get more people's attention. Even if the difference was only in the cost to the consumer, the desire for cheap gas would generate a high demand
for the product. Whoever can set up for large-scale low-cost production first will end up all the richer, able to invest in other areas of research
and carve out a place in the renewable fuels industry.
Here's a link to a preparation of a ZSM-5 zeolite...Looks like it might be the right one by some odd coincidence...An excerpt:
Quote: |
lWeigh out about 0.510 g of sodium hydroxide pellets and finely grind with a mortar and pestle. Place this mixture in a 250 ml beaker, and add 2.01 g
of silicic acid and 1.01 g of tetrapropylammonium bromide. Mix with 5.0 ml distilled water, then add 1.0 ml of n-propylamine and mix the solution
again.
Place 1.0 ml of a prepared 1 molar solution of aluminum sulfate along with about 0.05 ml of the concentrated sulfuric acid in a separate 50 ml beaker.
Then add the first solution to this beaker as well. Add enough distilled water to raise the volume to about 25 ml, and mix the solution (26 ml total
volume) on a stir plate for ten minutes. Then transfer the solution to the Parr "Bomb" and seal it. Gently shake it, before placing in the oven. Heat
the sample to 160°C and hold there for 44 hours (note how long it takes to reach 160°C). Do not worry if you cannot remove every last trace of the
solid out of the beaker.
After 2 days heating, turn off the oven and remove the Parr reactor and let it cool to room temperature. Remove a small sample for x-ray analysis. If
the x-ray pattern matches the expected one, see figure 2, then filter the rest of the reactant in a Buchner funnel with fine filter paper (541 grade).
Wash it three times with copious amounts of water and then dry for 20 minutes on the filter paper.
You are now going to calcine the sample to remove the organic cation, so set-up the tube furnace assembly (Figure 2). Place the zeolite inside, on top
of the frit in the middle of the tube, and spread out to maximize the surface area. Fit a ground glass elbow at each end, one attached to a nitrogen
cylinder and the other immersed in a beaker of water, to regulate the flow of nitrogen gas. Slowly heat the tube to 500°C in increments of 50 to
100°C, when water vapor will be released, then in increments of 100 to 500°C. Heat for two hours after reaching temperature, where the
tetrapropylammonium bromide will decompose to tripropylamine, propylene, and water. Cool and weigh the materials (note the weight in g). Remove
another sample for x-ray analysis; how does it compare to the previous x-ray?.
Any sodium ions remaining in the zeolite will now be ion exchanged for protons to fully convert the zeolite to the acid form. The sodium product from
above is placed in a 100 ml beaker, and stirred with 12.60 ml of 1 M aqueous ammonium sulfate for 15 minutes. Collect the zeolite by Buchner
filtration (repeat for a total of 3 washings). Wash the product with small amounts of acetone. Then wash several times with distilled water to remove
all sulfate ions. Test the washings for this anion by adding drops of an aqueous solution of BaCl2; the formation of a BaSO4 precipitate indicates the
presence of the ion.
When the solution no longer produces a precipitate, wash the zeolite once more with acetone to dry it, and then dry in the oven at 120°C for 20
minutes. The acid hydrogen form of the compound is prepared by transferring the oven-dried compound to a tube furnace. Heat the ammonium zeolite for 3
hours to ensure the thermal decomposition of the NH4+ ions. Over the course of this process, the zeolite should turn from a white to brown/black to an
off-white color. Cool the material and store in a desiccator to preserve the acid hydrogen form. |
Seems like it could be done in an amateur lab...Perhaps not as powerful as the industrial version, but proof of concept might be enough to test its
viability as a small-scale method.
If you see me running, try to keep up.
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Intergalactic_Captain
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ZSM-5 followup
For anyone interested, I've found a great book on the industrial production and usage of zeolites in the petrolum industry.
"Zeolite Technology and Applications; Recent Advances," Chemical Technology Review #170, Copyright 1980 by Noyes Data Corporation, Edited by Jeanette
Scotte
Tons of goodies in here...I'll be scanning what I can on the ZSM-5's and posting them (hopefully) tonight. If anyone's interested in any other
zeolites, there are articles on:
Zeolites A, B, X
Zeolites L, VK-2, Phi
Zeolite Y
ZSM 4, 5, 11, 21, 23, 34, 35, 38
...Most include both production and experimental usage results. The majority of the syntheses are on the laboratory scale, with easily attainable
apparati, temperature ranges, and precursors.
It's really quite an amazing book - too bad it's the library's copy...I'd highly recommend it to anyone interested in zeolite-based fuel production.
EDIT - Attached is a zip file containing several sections on ZSM-5's and a chapter on ZSM's for hydrocarbon conversion and oxidation
[Edited on 11-29-07 by Intergalactic_Captain]
Attachment: zeolites.zip (734kB) This file has been downloaded 1213 times
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chemrox
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higher alcohols in trans reax
I'm going to stick my neck out and raise a question that might have been addressed already. I looked but did not find. Would we get a better fuel if
we used higher alcohols such as pentanols, octanols, etc. And if these ols could be made cheaply as from fermentation is this a worthwhile endeavor?
Again, if this has been discussed please send me a PM and I'll delete this post.
CRX
"When you let the dumbasses vote you end up with populism followed by autocracy and getting back is a bitch." Plato (sort of)
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not_important
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The fist problem is that those currently can't be produced as cheaply as EtOH and fatty acids for biodiesel. Maybe with enough gene tweaking, but
that's not been shown to be true.
Next would be a comparison of the entire system efficiencies of standard IC engines, diesel, the several varieties of hybrids, and pure battery
operated electric. The standard automotive engine isn't that efficient, partly because it has to operate over a wide range of loading and speeds. A
modern electric power plant can 60% or better, some combined cycle designs with advanced turbines or SOFC can hit 80% efficiency. Is it more efficient
to do your burning in a large powerplant, where it's fairly easy to capture CO2 and pollutants, ship that power over lines, charge batteries, and
drive electric motors from those batteries? Or is it better to spread the combustion out over thousands of independent small engines?
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chemoleo
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I think the idea is that the biodiesel is made organically, by energy harvested using the sun.
However I seem to have read, if we were to plant vast areas of land (country-sized) with Rapeseed and similar, we'd still not provide all the fuel
necessary to still humanity's energy hunger.
I really don't understand why these genetic engineering companies haven't reported successes yet in generating plants that have minimal carbohydrate
production, and maximal fatty acid yields. I mean, rape seed plants are *big*. Very little effective mass that can be used for oils in the end, mostly
it's just useless plant matter. Surely this can be improved? Anyone got some data on this?
[Edited on 11-12-2007 by chemoleo]
Never Stop to Begin, and Never Begin to Stop...
Tolerance is good. But not with the intolerant! (Wilhelm Busch)
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not_important
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You can only cut out so much carbohydrate from a plant before it has no stem or leaves. The mass doesn't got into the oil, but into the energy
collectors and supporting them. The seeds don't need much oil, but given the 1 to 3 percent typical conversion of sunlight into stored energy it takes
a lot of support area. On top of that is the carbon loss when going from carbohydrates (photosyntheses product) to oil - effectively 3 CHOH => 2
CH2 + H2O + CO2
This is one reason some are strongly in favour of oil producing algae, the oil content can be higher. However there is the additional infrastructure
needed; the algae must be grown in sealed systems as the oil producers would be overrun by wild strains that put energy into replicating rather than
making oil.
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chemrox
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I didn't realize the higher ols lagged so far behind EtOH. I thought pentanol production was a big thing for the brits dring WWII and that
fermentation was the process. I'm way behind reading on this; if you know some current literature I'd like to read up.
"When you let the dumbasses vote you end up with populism followed by autocracy and getting back is a bitch." Plato (sort of)
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not_important
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Weizmann developed the acetone-butanol fermentation prior to WW-I. Because of the shortages of food it wasn't much used in England during either WW,
but the US did put it into production. This is a bacterial fermentation, not yeast.
http://mmbr.asm.org/cgi/reprint/50/4/484.pdf
There are companies that claim to have breakthroughs in butanol production, http://www.butanol.com/ for example, but they talk about scaling up to 100 gallons a week pilot plant, and there are some other problems with
using it as fuel http://en.wikipedia.org/wiki/Butanol_fuel
There are fermentation routes to pentanols, but SFAIK they are not as productive as the butanol one. A problem with these is that the alcohols become
toxic to the bacteria at a lower concentration than ethanol with yeast, meaning you're working with a more dilute solution to pull the alcohol out of.
I know that pervaporation has been looked at as a means to continuously pull the alcohols out of the mash to prevent toxic levels from building up,
and gene tweaking to increase tolerance to the alcohols also has been studied.
I don't know of any fermentation where pentanols are the primary product, and in quantity to be harvested. They're the major alcohols in fusel oil,
but that's a byproduct of ethanol fermentation being present at a level of less than one percent of the ethanol.
I think that doing a Web search for "alcohol-name fermentation" or "alcohol-name fuel" is the best way to get more information; what
I have is a series of notes with too few references :-( .
And again, small combustion engines with varying speed and loads will be lower efficiency than those working at near constant speed, and less
efficient than large scale power plants. If you want to save money or the ecology or whatever, I suspect you need to get away from IC engines as the
prime motivators for vehicles.
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ShadowWarrior4444
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The issue of using 2,5-Dimethylfuran as a gasoline alternative should be considered more closely. Recent advances have allowed its production from
glucose and fructose using an acid catalyzed method.
Notable qualities:
Immiscible with water
All current internal combustion engines can use it without modification
40% higher energy density compared to ethanol
Will require +/- no modifications to the current petrol infrastructure
The only issue that seems to be blocking its use is that its toxicity has not been completely evaluated--there are some concerns that in its capacity
as a metabolite of hexane, it plays a role in the neurotoxicity of said compound.
Note: http://en.wikipedia.org/wiki/Dimethylfuran
A practical lab synth of DMF would also be appreciated; my cursory digging around has not yielded much in the way of a concrete procedure. (Though,
I'll likely continue in a bit more depth.)
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YT2095
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I`v also had a go at making some Biodiesel yesterday/last night, using the formula:
100g virgin rapeseed oil
23.8g EtOH
1.43g KOH
I left it on the magnetic stirrer overnight and then a few mins to settle, and this is the result:
all in all I`m quite pleased with it
\"In a world full of wonders mankind has managed to invent boredom\" - Death
Twinkies don\'t have a shelf life. They have a half-life! -Caine (a friend of mine)
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chemrox
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Quote: | Recent advances have allowed its production from glucose and fructose using an acid catalyzed method.
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Is there a technical ref for this?
"When you let the dumbasses vote you end up with populism followed by autocracy and getting back is a bitch." Plato (sort of)
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ShadowWarrior4444
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Quote: | Originally posted by chemrox
Quote: | Recent advances have allowed its production from glucose and fructose using an acid catalyzed method.
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Is there a technical ref for this? |
In my thread devoted to the topic of 2,5-Dimethylfuran, which I believe you have already read. *smirk*
(https://www.sciencemadness.org/talk/viewthread.php?tid=10488)
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