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Devil Potash
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 48 lb Devil Potash Potassium Hydroxide biodiesel koh  US $132.25
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2 lb Food Grade Potassium Hydroxide Red Hot Devil Potash Lye Sale Price: $7.25  |
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Red Hot Devil Potash 90+% Pure Potassium Hydroxide (koh) Food Grade: This koh meets the specifications of the Food Chemicals Codex and U. S. Pharmacopoeia.Made in America Packaged in a safe and convenient, wide mouth container with a foam lined child safety cap for prolonged freshness. Container is anti-static. Uses: Biodiesel catalystSoap-makingRat PoisonDrain cleanerHHO Systems catalystCleaning (Picks up oily stuff WELL!)Potassium Hydroxide (KOH), also known as Potash or Lye can be used for making Biodiesel, soap and many other products. This is the preferred catalyst for producing biodiesel for the large industry because it dissolves quickly into methanol and the by-product (glycerin) is a usable fertilizer. |
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24 lb Food Grade Potassium Hydroxide Red Hot Devil Potash Lye Sale Price: $72.50 |
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Red Hot Devil Potash 90+% Pure Potassium Hydroxide (koh) Food Grade: This koh meets the specifications of the Food Chemicals Codex and U. S. Pharmacopoeia.Made in America Packaged in a safe and convenient, wide mouth container with a foam lined child safety cap for prolonged freshness. Container is anti-static. Uses: Biodiesel catalystSoap-makingRat PoisonDrain cleanerHHO Systems catalystCleaning (Picks up oily stuff WELL!)Potassium Hydroxide (KOH), also known as Potash or Lye can be used for making Biodiesel, soap and many other products. This is the preferred catalyst for producing biodiesel for the large industry because it dissolves quickly into methanol and the by-product (glycerin) is a usable fertilizer. |
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48 lb Food Grade Potassium Hydroxide Red Hot Devil Potash Lye Sale Price: $139.00 |
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Red Hot Devil Potash 90+% Pure Potassium Hydroxide (koh) Food Grade: This koh meets the specifications of the Food Chemicals Codex and U. S. Pharmacopoeia.Made in America Packaged in a safe and convenient, wide mouth container with a foam lined child safety cap for prolonged freshness. Container is anti-static. Uses: Biodiesel catalystSoap-makingRat PoisonDrain cleanerHHO Systems catalystCleaning (Picks up oily stuff WELL!)Potassium Hydroxide (KOH), also known as Potash or Lye can be used for making Biodiesel, soap and many other products. This is the preferred catalyst for producing biodiesel for the large industry because it dissolves quickly into methanol and the by-product (glycerin) is a usable fertilizer. |
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12 lb Food Grade Potassium Hydroxide Red Hot Devil Potash Lye Sale Price: $39.25 |
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Red Hot Devil Potash 90+% Pure Potassium Hydroxide (koh) Food Grade: This koh meets the specifications of the Food Chemicals Codex and U. S. Pharmacopoeia.Made in America Packaged in a safe and convenient, wide mouth container with a foam lined child safety cap for prolonged freshness. Container is anti-static. Uses: Biodiesel catalystSoap-makingRat PoisonDrain cleanerHHO Systems catalystCleaning (Picks up oily stuff WELL!)Potassium Hydroxide (KOH), also known as Potash or Lye can be used for making Biodiesel, soap and many other products. This is the preferred catalyst for producing biodiesel for the large industry because it dissolves quickly into methanol and the by-product (glycerin) is a usable fertilizer. |
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Food Grade Potassium Hydroxide, 45 lb Red Hot Devil Potash Lye Sale Price: $125.00 |
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Red Hot Devil Potash 90+% Pure Potassium Hydroxide (koh) Food Grade: This koh meets the specifications of the Food Chemicals Codex and U. S. Pharmacopoeia.Made in America Packaged in a UN-approved heavy duty bucket with tear strip lid Uses: Biodiesel catalystSoap-makingRat PoisonDrain cleanerHHO Systems catalystCleaning (Picks up oily stuff WELL!)Potassium Hydroxide (KOH), also known as Potash or Lye can be used for making Biodiesel, soap and many other products. This is the preferred catalyst for producing biodiesel for the large industry because it dissolves quickly into methanol and the by-product (glycerin) is a usable fertilizer. Price includes $25 Hazmat fee charged by Fedex Ground to meet DOT regulations. |
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250 lb of Potassium Hydroxide Caustic Potash Flakes 90+% Sale Price: $525.00 |
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"90% Potassium Hydroxide Flake Packaged in 50 lb vacuum sealed bags. Ships by freight only. Email for quotes & to order. * 90%+ Pure Potash - Potassium hydroxide * dissolves faster into methanol than naoh * Flake form Potassium Hydroxide (KOH), also known as Potash or Lye can be used for making Biodiesel, soap and many other products. This is the preferred catalyst for producing biodiesel for the large industry because it dissolves quickly into methanol and the by-product (glycerin) is a usable fertilizer. " |
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1000 lb of Potassium Hydroxide Caustic Potash Flakes 90+% Sale Price: $1,675.00 |
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"90% Potassium Hydroxide Flake Packaged in 50 lb vacuum sealed bags. Ships by freight only. Email for quotes & to order. * 90%+ Pure Potash - Potassium hydroxide * dissolves faster into methanol than naoh * Flake form Potassium Hydroxide (KOH), also known as Potash or Lye can be used for making Biodiesel, soap and many other products. This is the preferred catalyst for producing biodiesel for the large industry because it dissolves quickly into methanol and the by-product (glycerin) is a usable fertilizer. " |
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500 lb of Potassium Hydroxide Caustic Potash Flakes 90+% Sale Price: $899.00 |
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"90% Potassium Hydroxide Flake Packaged in 50 lb vacuum sealed bags. Ships by freight only. Email for quotes & to order. * 90%+ Pure Potash - Potassium hydroxide * dissolves faster into methanol than naoh * Flake form Potassium Hydroxide (KOH), also known as Potash or Lye can be used for making Biodiesel, soap and many other products. This is the preferred catalyst for producing biodiesel for the large industry because it dissolves quickly into methanol and the by-product (glycerin) is a usable fertilizer. " |
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2000 lb of Potassium Hydroxide Caustic Potash Flakes 90+% Sale Price: $3,125.00 |
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"90% Potassium Hydroxide Flake Packaged in 50 lb vacuum sealed bags. Ships by freight only. Email for quotes & to order. * 90%+ Pure Potash - Potassium hydroxide * dissolves faster into methanol than naoh * Flake form Potassium Hydroxide (KOH), also known as Potash or Lye can be used for making Biodiesel, soap and many other products. This is the preferred catalyst for producing biodiesel for the large industry because it dissolves quickly into methanol and the by-product (glycerin) is a usable fertilizer. " |
Here are some more information for Devil Potash:
Bring your sleeping bag and throw it down for one of the quietest nights of sleep to be had. If you arrive late in Moab, you will want to consider reserving a place to stay. The campsites operated by local business people have flushing toilets, showers, drinking water spigots at your disposal. The commercial privately owned campgrounds in Moab provide 468 tent sites, 771 RV sites with hook ups and 118 camp cabins. Reservations with these campgrounds in Moab, especially during weekends or late arrivals, will decrease your anxiety for finding a place to throw it down.
Arches National Park has 53 campsites available all year round. The camping in Arches is now reserved on line upon recreation.gov website. Devil's Garden campground has flushing toilets in the restrooms and an occasional spigot for filling drinking water containers is scattered within the campground. There are no hookups for RVs. These reserved national park campsites fill up two months at a time, so plan ahead. Backpacking, on the other hand, is not often sought after in Arches. A free backcountry permit to backpack and camp is readily available. Inquire in person at the Visitor Center. It is open 7:30 a.m. to 6:30 p.m. April through October. Hours shorten to 8:00 a.m. to 4:30 p.m. November through March.
The Canyonlands National Park backcountry use requires a fee and permits. In Canyonlands, visitor may camp by river rafting or canoeing, 4WD or mountain bike trails, or backpacking. Reservations for backcountry permits can be made the second Monday of July for the following year, if you like to plan well in advance. Reservations cannot be made within two weeks of a date. In this situation apply in person at the applicable visitor center. The Maze District camping is only available by backcountry permit. The Island in the Sky and Needles visitor centers are open 9 a.m. to 4:30 p.m.; Maze's Hans Flat Ranger Station is open 8 a.m. to 4:30 p.m.
For front country camping use, the Island in the Sky district has 12 primitive campsites at Willows Flat. Bring your own water. A pit toilet is erected in the Willows Flat campground. The 26 sites in the Needles District of Canyonlands are divided between two loops. Squaw Flat campground has drinking water. Some of the sites are adequate for shorter RVs willing to park with no hook ups. Pit toilets are located in the campgrounds. Flushing toilets are housed at the Needles Visitor Center. The visitor center is not immediately close to the campgrounds. Both districts have fire rings in the sites. Collection of wood is forbidden in the parks. The Canyonlands National Park camping is a first-come-first-served process. No reservations are taken, except for the group sites. Plan to arrive around 3 PM for the best chances of acquiring one of these park campsites. If you arrive too late, understand that there are reasonable alternatives nearby. The Bureau of Land Management has 432 campsites located within 24 additional campgrounds dotting the surrounding canyons of Moab. Pay attention to informational signs for more campgrounds as you drive to the National Parks of Moab. Decide to nab one of these in route or plan to back track if the park campground is full.
The Bureau of Land Management (BLM) sites will have pit toilets and fire rings. There is no firewood collection allowed. Bundles of firewood are for sale at the grocery and convenient stores of Moab for around $4.99 a bundle. Bring plenty of water as there will be no water available at the BLM campgrounds. The shop, Gear Heads, and Moab's gas stations are amenable to filling water containers. Arches National Park's visitor center has a row of spigots available to fill water containers too.
The BLM has 87 additional designated camping spots. These require the user to have a toilet. Bring your own or rent a camp toilet from Canyon Voyages, Tag-A-Long Expeditions or Tex's Riverways of Moab. Sometimes, Moab's Walker Drug camping aisle has portable toilets for sale too. Dump stations are available at Dead Horse Point State Park, most of the commercial campgrounds and Quality RV at 850 South Hwy 191 in Moab.
Dead Horse Point State Park has 21 RV sites have hook ups, there are 21 tent sites, flushing toilets, drinking water spigots and fire rings. Again bring your own firewood. Reservations online are available for Dead Horse Point State Park of Utah. In May 2009, Dead Horse Point dedicated two new trails with spectacular views. These are beginner graded mountain bike single track, shared with pedestrians only. No motor use on the Intrepid Trails (named for the Intrepid Potash Mine which is seen from Dead Horse Park in the form of the evaporation ponds.)
Use the camping scoop on Moab to enjoy some gorgeous night skies, panoramic views, helpful hints on planning, reservations, and rules for the many campground possibilities in Canyonlands, Arches, parks and Moab.
http://www.moabutah.info
http://www.recreation.gov/camping/Devils_Garden_Campground_Ut/r/campgroundDetails.do?contractCode=NRSO&parkId=74066&topTabIndex=CampingSpot
Aluminum Discovery and Extraction – A Brief History
The term aluminum comes from the alum compound, (KAl(SO4)2?12H2O), which contains it. In 18th century it was realized that alum contained a peculiar base, different from all others, but only in the 19th century scientists were able to isolate it.
Berzelius and Davy tried to use electrolysis processes to isolate the metal contained in alumina. In particular Davy heated a mixture of alumina and potash and then submitted the mix to a electrical current, but with no success.
In 1825 was Oersted to try to isolate the metal believed to be contained into the alumina. He first prepared anhydrous aluminum chloride (AlCl3) by passing a current of chlorine over a mixture of charcoal and alumina heated to redness. Then, the aluminum chloride produced was mixed and heated with potassium amalgam producing potassium chloride and aluminum amalgam. Distillation of this amalgam without contact with the atmosphere left a lump of metal which color, said Oersted, resembles tin in color and sheen.
Wöhler repeated the Oersted experiment, but was unable to duplicate the results. Recent repetitions of the experiment, based on Oersted notes, have shown that using a very dilute potassium amalgam (1.5% K) it is possible to extract the aluminum.
Oersted encouraged Wöhler to continue in his attempts. So, Wöhler first produced the anhydrous aluminum chloride. Then, he put in a platinum crucible a mixture of AlCl3 and potassium (K), instead of using potassium amalgam as Oersted. The crucible was closed and some heat applied just to start the reaction. Soon, the crucible became very hot, being the reaction:
3K + AlCl3 -> Al + 3KCl
exothermic. The produced aluminum was contaminated with platinum, so he repeated the experiment with porcelain and other materials crucibles, always being able to produce aluminum in the form of a gray powder. The aluminum produced was contaminated by potassium, platinum or aluminum chloride, however he first described the most important properties of aluminum and then, in 1845, was able to produce a coherent mass of aluminum.
In 1855 French scientist Henri Sainte-Claire Deville, ignoring Wöhler 1845 experiment, duplicated it. Observing the aluminum chloride reduction, he understood the importance of the discovery and immediately started to study how to produce large quantities of this metal to be commercialized. Two ways were possible. The first one was the chemical production of the aluminum, using the chloride as salt and the potassium as the agent to reduce it, the second choice was an electrolytic method to reduce the chloride, with a carbon anode and a platinum cathode. Both methods were difficult to implement on a large scale. In the chemical method, the potassium was very expensive and dangerous to manipulate, while there were not available sources of electricity at low cost, the only one existing being primary batteries. Hence, H. St.Claire Devile choose the chemical method to produce aluminum, using as reduction agent the most common in nature sodium (Na) rather than potassium. The Deville’s work was greatly helped by the funds gave him by Napoleon III. Thanks to the work of other chemists of that time, Deville was able to produce for himself large quantities of sodium. At the same time in this period two other processes had to be converted into industrial processes, the first one being the production and refining of alumina and the second one the conversion of alumina into aluminum chloride. Anyway, in 1859 the available quantity of aluminum increased (2 tons/year produced in Salindres plant). Through the years going from 1855 to 1890 the aluminum price declined from the equivalent 1200 €/kg to 13 €/kg. During that years, different chemical and electrochemical methods were developed for the aluminum extraction. Chemical methods were more or less variations around the basic St. Claire Deville process. We can mention: Castner, Netto, Grabau, Webster, Frismuth, etc…The electrochemical processes could be splitted into two main categories: electrothermic and electrolytic. For the electrothermic processes we can mention Cowles, Héroult, Brin, Bessemer, Stefanite, Moissan, while for the electrolytic processes we have Héroult, Adolphe Minet, Hall, Hampes, Kleiner, Gooch, Waldo.
From all these processes, emerged the work of the American Charles Martin Hall and French Paul Louis Toussaint Héroult, whom independently and at the same time invented the process that is still used to reduce alumina to aluminum.
In 1880 at the Oberlin College near Cleveland, Ohio, two people met. One was Frank Fanning Jewett, professor of chemistry and mineralogy at the Oberlin College. Jewett had the possibility to study at the University of Göttingen in Germany between 1873 and 1875. During his stay in Germany he met Wöhler, who had isolated aluminum in 1827. The other was a young student from Oberlin, Charles Martin Hall, self-educated person in chemistry and so passionate to conduct experiments at his home. Hall, at the age of 16, already knew the problems involved in the aluminum production and, under the Jewett guidance and encouragement, worked on aluminum chemistry both at home and Oberlin College laboratory. Hall first tried chemical reduction methods to produce aluminum, but with no results. Then, together with Jewett, they decided to follow the electrolytic way to produce aluminum. In a first attempt, Hall tried to decompose aluminum fluoride (AlF3) dissolved in water, but the only results was the production of hydrogen at the anode and aluminum hydroxide at the cathode. The important thing in this work was the selection of the fluoride, never tried before. The next step was the use of fused salts as solvents. After different experiment, he choose the cryolite as the solvent, being him and Jewett aware of its use in the Deville works. He was able to melt cryolite and showed that it was a good solvent for alumina. The first electrolysis attempt was made using a clay crucible, but the result was the production of silicon from the crucible material. Then, recognizing this, the clay crucible was lined with graphite, it was added some aluminum fluoride to the cryolite in order to lower the melting point and the experiment was repeated. After several hours of electrolysis, he cooled the melt and broke it open, finding small silvery globules that Jewett confirmed to be aluminum. It was February, 23rd 1886.
After some troubles, in 1888 a group of investors, organized by Captain Alfred Hunt, provided Hall with enough fund to establish the Pittsburgh Reduction Company, the Alcoa predecessor.
One or two months later the Hall discovery, French Paul Louis Toussaint Héroult made the same discovery independently. He learned of the St.Claire Deville discoveries at the age of 15 reading the Deville’s famous treatise. He tried to produce aluminum electrolyzing various aluminum compound, with no success. Then, he tried to electrolyze cryolite. During the process, he find the iron cathode was melted. Because the temperatures were not so high to justify a melting of the iron, he realized that some alloy had been formed. Few days later, in an attempt to lower melt temperature he added some sodium aluminum chloride and noticed that the carbon anode was consumed. What happened was that the sodium aluminum chloride entered in contact with the moisture, being converted into hydrated alumina. So, basically Héroult discovered the same process to produce aluminum revealed by Hall just a couple of months before.
http://www.aluminumsmeltingprocess.com
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Red Devil athletes place at Carbon track meet
The Grand County High School track team held its own at a meet held at Carbon High School in Price on Saturday, April 17. For the girls, Cassie Lema took sixth place in the 3200-meter run, and Rachel Garrett took fourth in discus and seventh in the shot put.
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