Patent Application
20120145605
This invention relates to the flotation of ores. More particularly, the invention relates to collectors for the flotation of molybdenum-containing ores.
Flotation is a process for concentrating minerals from their ores. Flotation processes are well known in the art and are probably the most widely used method for recovering and concentrating minerals from ores. In a flotation process, the ore is typically crushed and wet ground to obtain a pulp. Additives such as flotation or collecting agents and frothing agents are added to the pulp to assist in subsequent flotation steps in separating valuable minerals from the undesired, or gangue, portion of the ore. The flotation or collecting agents can comprise liquids such as oil, other organic compounds, or aqueous solutions. Flotation is accomplished by aerating the pulp to produce froth at the surface. Minerals, which adhere to the bubbles or froth, are skimmed or otherwise removed and the mineral-bearing froth is collected and further processed to obtain the desired minerals.
The basic techniques behind froth flotation are to use chemicals to increase the hydrophobicity of the mineral to be beneficiated to form a concentrate. Meanwhile, chemicals are added, as necessary, to decrease the hydrophobicity of unwanted (“gangue”) minerals, so that these minerals report to the slurry and are discarded as tail. The main alternative technique in froth flotation is “reverse flotation.” This consists of floating the gangue minerals as a concentrate and keeping the mineral of interest on the slurry.
Chemicals that promote hydrophobicity of a mineral are called out that mineral's “promoter” or “collector.” Collectors based on fatty acids have long been used in collecting one or more of the oxide minerals such as fluorspar, iron ore, chromite, scheelite, CaCO2, MgCO2, apatite, or ilmenite.
Early work used alkali metal salts of fatty acids or soaps derived from natural oils by the process known as saponification. When an oil containing triglycerides is treated with a caustic solution under certain harsh processing conditions, the triglycerides disassociate into the alkali metal salts of the component fatty acids. The dissociation of the triglycerides into neutralized fatty acids is the saponification process. These neutralized fatty acids are soaps that act as non-selective flotation collectors. Compounds containing sulfur, such as xanthates, thionocarbamates, dithiophosphates, and mercaptans, will selectively collect one or more sulfide minerals such as chalcocite, chalcopyrite, galena, or sphalerite. However, sulfur based collectors are often toxic and/or have repugnant odors. Amine compounds are typically used to float KCl from NaCl and for silica flotation. Petroleum-based oily compounds such as diesel fuels, decant oils, and light cycle oils, are often used to float molybdenite. Those oils are also used as an “extruderoil” that reduces the dosage of other more expensive collectors in the amine flotation of KCl.
Previous work on sulfide minerals has indicated that molecules containing sulfur are useful compounds for the froth flotation of sulfide minerals. These collectors are usually grouped into two categories: water-soluble and oil (i.e., hydrophobic) collectors. Water-soluble collectors such as xanthates, sodium salts of dithiophosphates, and mercapto benzothiazole have good solubility in water (at least 50 gram per liter) and very little solubility in alkanes. Oily collectors, such as zinc salts of dithiophosphates, thionocarbamates, mercaptans, and ethyl octylsulfide, have negligible solubility in water and generally good solubility in alkane.
Currently used collectors for most sulfide minerals are sulfur-based chemicals such as xanthates, thionocarbamates, dithiophosphates, or mercaptans. These chemicals have problems with toxicity and/or malodor.
This invention is directed to a method of beneficiating a molybdenum-containing material by froth flotation in the presence of a collector as well as a collector for beneficiation of molybdenum sulfide minerals, precipitates, or metallic species. In both aspects, the collector includes at least one oil which is either an essential oil or a derivative thereof, or a natural or synthesized oil comprising triglycerides containing fatty acids of only 20 carbons or less, or an ester made from a fatty acid and an alcohol.
In the method aspect of the invention, the method includes the steps of (1) providing an aqueous slurry of the molybdenum-containing material, (2) adding a selective collector to the slurry, the collector comprising at least one oil selected from the group consisting of (a) a natural oil or synthesized oil comprising triglycerides containing fatty acids of only 20 carbons or less, or an ester made of fatty acid and an alcohol; and (b) an essential oil or a derivative thereof; (3) selectively floating the molybdenum-containing material; and, then (4) recovering the molybdenum-containing material.
In the method aspect of the invention, the molybdenum-containing material may be comprised of no other metallic element besides molybdenum, or it may contain other metallic elements. Copper minerals such as chalcocite, chalcopyrite, and bomite often occur together with molybdenum minerals in mined ores. The molybdenum-containing material may also contain minerals comprised of silver and gold, either in the crystal structure or in association as an independent mineral species, and combinations thereof. Molybdenum-containing materials which occur with a second mineral species of copper, gold or silver will generally require a flotation collector comprised of one or more of the subject oils plus one or more organic sulfur flotation promoter compounds.
In the collector aspect of the invention, a collector is provided for beneficiation of molybdenum-containing materials, which may include sulfide minerals or precipitates from ores, concentrates, residues, tailings, slags, or wastes. The collector includes at least one organic sulfur-containing flotation promoter; and at least one oil selected from the group consisting of (1) a natural or synthesized oil comprising at least one triglyceride, or at least one ester made from a fatty acid and an alcohol, or a derivative of said oils; and (2) an essential oil, or a derivative of said essential oil.
This invention has an advantage that the specified triglyceride, or essential oil, or derivatives thereof will selectively float molybdenum-containing materials by itself or in combination with other collectors. This and other advantages will be apparent from the detailed description of the invention and the appended claims.
While the present invention is susceptible of embodiment in various forms, there will hereinafter be described a presently preferred embodiment with the understanding that the present disclosure is to be considered an exemplification of the invention and is not intended to limit the invention to the specific embodiment illustrated.
It should be further understood that the title of this section of this specification, namely, “Detailed Description of the Invention,” relates to a requirement of the United States Patent Office, and does not imply, nor should be inferred to limit the subject matter disclosed herein.
The subject invention provides materials and methods useful in the recovery of minerals. These materials and methods are specifically applicable to froth flotation procedures; whereby, minerals are removed and recovered from complex mixtures of ores, residues, concentrates, slags, and wastes. The subject invention can be used in remediation processes to remove unwanted materials or may be used in mining processes to recover valuable minerals. Specifically exemplified herein is the use of certain triglycerides, esters of the fatty acids and long chain alcohols, and essential oils of both terpene and aromatic chemistries. Furthermore, derivatives of the said oils which are produced by oxyalkylation, esterification or ether formation are useful in the subject invention. Any of these oils may be used alone, in mixtures, or in combination with other collectors.
In the method aspect of the invention, the method includes the steps of (1) providing an aqueous slurry of the molybdenum-containing material, (2) adding a selective collector to the slurry, the collector comprising at least one oil selected from the group consisting of (a) a natural oil or synthesized oil comprising triglycerides containing fatty acids of only 20 carbons or less, or an ester made from a fatty acid and an alcohol; and (b) an essential oil; or a derivative of the said oils which are produced by oxyalkylation, esterification or ether formation (3) selectively floating the molybdenum-containing material; and, then (4) recovering the molybdenum-containing material.
In the collector aspect of the invention, a collector is provided for beneficiation of molybdenum-containing materials or precipitates from ores, concentrates, residues, tailings, slags, or wastes. The collector includes at least one organic sulfur-containing flotation promoter; and at least one oil selected from the group consisting of (1) a natural or synthesized oil comprising at least one triglyceride, or at least one ester made from a fatty acid and an alcohol; and (2) an essential oil, or a derivative of the said oils which are produced by oxyalkylation, esterification or ether formation.
Preferably the molybdenum-containing material is comprised of molybdenite, and other sulfide minerals containing molybdenum. The molybdenum-containing material may also be present with copper minerals selected from the group consisting of chalcocite, chalcopyrite, bomite, and other sulfide minerals containing silver, gold, either in the crystal structure or in association as an independent mineral species, and combinations thereof. The molybdenum-containing material may also be present with metallic species such as copper, gold, and silver. This material may be derived from ores, concentrates, precipitates, residues, tailings, slag, or wastes.
The oils used according to the subject invention can be readily obtained and used by a person trained in the teaching of this patent. The natural oils identified in this invention are obtained directly or indirectly from plants or animals.
In a specific embodiment, the process of the subject invention can comprise the following steps: a) pulverizing a mineral-containing material to appropriate fine-sized particles; b) mixing the pulverized particles with water to produce a slurry; c) agitating the mixture and adjusting its pH as necessary to produce a conditioned slurry; d) adding a sufficient amount of a naturally occurring oil or a mixture thereof to the slurry with conditioning to render the surfaces of the particles containing the desired minerals hydrophobic; e) agitating the resultant slurry under conditions and for a time sufficient to obtain a sufficiently homogenous mixture; f) adding a frothing agent to the homogenous mixture in an amount sufficient to cause frothing of the homogenous mixture upon injecting air or other gases; g) injecting air or other gas into the mixture to form bubbles in the resultant composition in an amount and under conditions sufficient to cause the hydrophobic particles to become attached to the bubbles and cause the resultant bubbles with attached particles to rise and form froth; and h) separating the froth fraction and recovering the desired mineral.
In a specific embodiment of the subject invention, the mixture produced in Part (b) will have between about 1% to 75% solids by weight. In Part (c) of the process, the pH may be adjusted to anywhere in the 5 to about 13 pH range, with particularly good results in the 7 to 10 pH range. With regard to Part (d), a natural oil, such as cottonseed, may be used as the only collector or it may be used with other collector compounds. In a preferred embodiment, the concentration of the natural oil used according to the subject invention can range from about 1 gram per ton of ore to about 1,000 grams per ton of ore. The temperature range of the use of these compounds goes from 5 to 75 degrees Centigrade with most normal operations in the 15 to 40 degree Centigrade range. Preferably, the flotation conditions should be kept mild enough to prevent significant disassociation of the triglycerides, or other components, contained in the natural oils into fatty acids, and to prevent the subsequent saponification into fatty acid soaps. The selectivity of the flotation when using oils according to this invention is evidenced by the selective recovery of the minerals, and substantiates this observation. A skilled artisan trained in the teachings of this patent can adjust the concentration and conditions to achieve optimization of the process for a particular mineral once a collector compound has been identified as useful for that mineral species.
The invention is specifically exemplified for the recovery of molybdenum containing materials alone or in combination with minerals of copper, gold or silver, or in combination with metallic copper, gold or silver. A skilled artisan, having the benefit of the instant disclosure, could readily adapt the process for the recovery and/or removal of a broad range of sulfide minerals, silver, gold or platinum group metals.
It was found, however, that there are unexpected benefits of using certain organic compounds containing no sulfur, no nitrogen and no phosphorous for selective froth flotation of certain sulfides. These molecules contain oxygen in a variety of functional groups such as triglycerides and esters. These groupings occur in many natural oils, such as cottonseed, corn, canola, palm, safflower, jojoba, and clove. Surprisingly, many of these oils are non-toxic and are used in foodstuffs throughout the world.
It was also unexpected that blends of these oils with each other and with standard collectors frequently exhibit synergistic or enhanced effects, in that a mixture of an organic sulfur collector compound with a non-sulfur containing collector may perform better than either of the components alone, and mixtures of multiple components may perform better than a two-component blend. This invention is uniquely suited to molybdenum-containing materials such as molybdenite. Other sulfide minerals such as chalcocite, chalcopyrite, bornite, galena, and sphalerite are also floated by the said non-sulfur containing collectors. However, sulfur species such as pyrite are not as readily floated by these non-sulfur-containing collectors.
Most natural plant and animal oils are triglycerides of mixtures of fatty acids. A triglyceride is simply the reaction product of a carboxylic acid and glycerol. Triglycerides are generally made from fatty acids with typically 10 to 24 carbon atoms and from 0 to 3 double bonds in their chains. Some triglycerides are made from hydroxyl fatty acids that have an alcohol group somewhere in the chain. An example of this is castor oil. Another oil, oiticicia, has three double bonds and a ketone functionality in its composition.
Saturated or highly saturated oils, such as coconut oil, contain triglycerides made from a zero to a low percentage of fatty acids having double bonds. Linseed oil contains a high percentage of linolenic acid oil, an 18 carbon fatty acid with three double bonds (expressed as C18:3). The composition of some common natural oils is shown in Table 1. The iodine value is a measure of the unsaturation of the oil. The saturated fat column is for the percentage of saturated fat when the extract chain length is unspecified. A given type of oil composition will vary with the variety of plant, the growing conditions and the treatment of the oil after pressing. For instance, there are both high and low erucic acid (C22:1) species of canola oil. Some canola oil is also hydrogenated (hydrogen reacted with the double bonds) before being sold.
It was unexpectedly found, however, that oils containing triglycerides that have fatty acids with 20 carbon atoms or less, perform much better than oils that contain triglycerides with fatty acids having 22 carbons or more, such as erucic acid. Moreover, since oils containing triglycerides of fatty acids with twenty carbon atoms or less do not contain free fatty acids, they do not behave as either fatty acids or soaps of fatty acids. The selective nature of these oils in flotation was surprising because fatty acids and fatty acid salts (i.e., soaps) are very non-selective.
Other sources of triglycerides are animal oils. Commercially available animal oils have a limited range of unsaturation values. A highly unsaturated lard oil will have triglycerides containing 46% C1×1 (oleic acid), 15% C1×2 (linoleic acid), 1% C1×2 (linolenic acid), and 62% saturated fatty acids.
There are some unique natural oils. Sperm whale oil contains esters made from long chain fatty acids and long chain fatty alcohols instead of esters of the fatty acid and glycerol as in triglycerides. Both the fatty acid and long chain alcohol usually contain at least one double bond. Sperm whale oil is, of course, no longer available due to whaling restrictions. However, its replacements, jojoba oil (vegetable) and orange toughy oil (fish), have the same basic chemistry as sperm whale oil. The only differences between them are in the carbon numbers (chain length) of the various components of the oils.
Chemical manufacturers can synthesize a long chain ester from a fatty acid and a long chain alcohol. One example of a “synthesized oil” or “synthetic oil” is 2-butyloctyl oleic acid ester. This compound contains one unsaturated site in the fatty acid molecule. The carbon numbers of the largest fractions of these oils are shown in Table 2.
Preferably, the natural oils used in this invention include triglycerides that contain predominantly fatty acids having a carbon number less than 20. Also, it is preferred that the triglycerides include an alcohol, an ether, an aldehyde, or a ketone functional group, or an aromatic group. A preferred group of natural oils includes cottonseed, corn, linseed, rice bran, safflower, soybean, avocado, jojoba, menhaden, lard, castor, cod liver, tung, oiticicia, apricot, sunflower pistachio, herring, low-erucic acid canola oil, and coconut oils. A more preferred group of natural oils includes cottonseed, corn, linseed, rice bran, safflower, soybean, avocado, jojoba, menhaden, lard, castor, cod liver, tung, and oiticicia. A still more preferred group of natural oils includes cottonseed, corn, linseed, rice bran, safflower, soybean, avocado, jojoba, menhaden, lard, and castor oils. An even more preferred group of natural oils includes cottonseed, corn, linseed, rice bran, safflower and soybean.
Another class of naturally occurring oils is called “essential oils” or “volatile oils.” These are fragrant oils derived from various plant species. They have been used for their fragrance and reputed medicinal properties. The chemistry of most of these compounds is based on either terpene chemistry or aromatic chemistry.
Terpenes are defined as compounds that can be assembled from two or more molecules of isoprene (C5H8) and the alcohol, aldehyde, and ketone derivatives of such compounds. A terpene compound can be defined as a monoterpene, sesquiterpene, or diterpene compound based on whether it contains 2, 3, or 4 isoprene units, respectively. Within each of these classifications the compounds can be further defined as being acyclic, monocyclic, bicyclic or tricyclic depending on whether the terpene contains, respectively, 0, 1, 2, or 3 ring structures (only diterpenes are tricyclic). Tricyclic diterpenes are generally solids.
Aromatic chemistry for essential oils refers to the chemistry of derivatives of benzene. The two most common aromatic components of essential oils are cinnamaldehyde and eugenol. These are obtained from cinnamon and clove oil.
Most essential oils have one single major terpene or aromatic component or are a mixture of closely related terpenes or aromatics. Table 3 shows the composition of some representative essential oils. Note that any particular oil's composition can vary with factors such as geography, variety, weather, etc.
Cymbopogon
winterianus
Eucalyptus
Eucalyptus
globus
Preferably, the essential oils used in the methods of this invention include either a terpene compound or an aromatic compound. More preferably, the essential oil includes a terpene derivative having a functional group selected from an alcohol, an ether, an aldehyde, and a ketone. Specific preferred essential oils include limonene, citronella, eugenol, eucalyptus globus, camphor, and clove oil. A more preferred group of essential oils includes limonene and citronella.
As work with the triglycerides, esters and alcohols have indicated, other oxygen-containing compounds such as aldehydes, ketones, and ethers of sufficient carbon number to be water-insoluble function as collectors for sulfide minerals. These compounds may or may not have carbon-carbon double bond(s).
The literature has shown that emulsified collectors can give better results than unemulsified collectors. Emulsification should also allow the combining of inexpensive water-soluble xanthates and sodium sulfide into the oils. Other water-soluble collectors that may be amenable to emulsification into oil include sodium dithiophosphates and mercapthobenzothiazole.
The invention also includes the use of the plant and animal oil collectors blended with known commercial collectors. Commercial collectors are also known as “flotation promoters” and are identified herein as “sulfur-containing flotation promoters.” These common commercial promoters are usually separated into two classes of chemicals based on their water solubility.
Water soluble sulfur containing collectors, or promoters, used in the froth flotation of sulfide minerals include such well-known collectors as xanthates and dithiophosphates. These are usually used as sodium or potassium salts of the respective organic acids. An example of a water-soluble collector would be sodium isopropyl xanthate. The other class of sulfur containing collectors would be water insoluble collectors. These collectors are generally referred to as oil collectors, because they are liquids that are insoluble in water. These collectors include thionocarbamates, mercaptans, organic sulfides, and the zinc salts of dithiophosphates. Even though these compounds are chemical reaction products, they are called oils.
Another grouping of collectors commonly used in froth flotation of substances such as coat, sulfur, and molybdenite are petroleum-based products that are truly oils. These oils generally consist of kerosene, vapor, diesel, fuel, turbine, light cycle, and carbon black oil. These petroleum oils are generally called “extender oils” are generally exhibit poor collecting ability and very poor selectivity when used by themselves. To distinguish these “petroleum-based collectors” from other described collectors, the term “oil collector” used in this text means a synthesized organic chemical compound containing sulfur such as the group of “sulfur-containing flotation promoters” described above.
This invention also includes the use of any of these aforementioned natural, synthetic or essential oils in combination. The essential oils are found to be very potent collectors. As such they are ideally suited for use in small amounts in combination with other oils or with other sulfide-containing flotation promoters. Good results have been obtained when using the essential oils in amounts of less than 10% weight blended with other collectors. Preferably, less than 2% by weight is used.
Also, any of the natural oils including the higher carbon fatty acid-containing triglycerides, and in particular, the preferred natural oils alone or in combination with other preferred oils, may be used blended with any number of sulfur-containing flotation promoters.
In such blends, the natural oils make up preferably between 20% and 80% by weight of the blend, and the flotation promoters make up preferably between the remaining 80% and 20% by weight of the blend. Optionally, a frother may be added to that blend, preferably in an amount between about 10% and 40% by weight of the composition. Frothers are commercially available compositions that are used to develop a froth or foam on top of a slurry that has been aerated. A particular suitable frother is one such as that sold by Nalco Company under the designation 9743. Methyl isobutyl carbonol (MIBC), also known as methyl amyl alcohol, is one of the most widely used frothers in the mining industry.
The collectors and blends of collectors in accordance with the methods of this invention can be used in standard froth flotation processes known by those skilled in the art and modified by the teachings of this patent as illustrated in the following examples.
The following examples illustrate procedures for practicing the invention. These examples should not be construed as limiting the invention, but are provided to further illustrate the teachings of the invention. All percentages are by weight and all collector mixture proportions are by volume unless otherwise noted.
This example illustrates the effectiveness of cottonseed oil as a collector for molybdenite and chalcopyrite. The ore had a head grade of 0.259% Cu and 0.0064% Mo. The ore charge of 1.0 kilogram was ground at 60% solids to 60% passing (P60) a 150 micron (100 mesh) screen. The ground ore slurry was adjusted to a pH of 10.5 with lime. The ore was ground with 10 gram/top (0.020 pound/ton) of secondary collector. A Denver laboratory flotation machine was used. The ore slurry charge was diluted with water to 29 percent solids, and 6 grams per ton of the main collector, sodium ethyl xanthate, and 25 gram/ton (0.05 pound/ton) of the OrePrep F-533 further were added. The flotation was carried out for a total of six minutes with a two-minute break for conditioning at the halfway point. During the conditioning break, 4 gram/ton dosage of the sodium ethyl xanthate was added.
The cottonseed oil was used by itself in place of the standard decant oil-light cycle oil-mercaptan (tertiary dodecyl mercaptan) secondary collector. Also, a 33% each mixture of cottonseed oil, zinc di (1,3 dimethylbutyl) dithiophosphate, and the tertiary dodecyl mercaptan was tested. For comparison, a 33% each mixture of decant oil, the zinc dithiophosphate and the mercaptan was tested. The dosage of the main and secondary collector was 10 grams collector per ton of ore (g/t) for all tests. As shown in Table 4, cottonseed oil by itself improved the recovery of both molybdenum and copper and the copper grade over that obtained with the standard collector. The cottonseed mixture had a similar copper recovery as the decant oil mixture while improving, copper grade.
Apricot, sunflower, pistachio, cottonseed, and jojoba oils were tested on chalcopyrite ore containing molybdenum sulfide. The head assays of the ore were 0.704% Cu and 0.0119% Mo. The ore charge of 2.0 kilograms was ground at 65% solids to 90% passing a 212 micron (65 mesh) screen. The ore charge was diluted with water to 27% solids and placed in a Denver laboratory floatation cell. The ore was conditioned for two minutes by agitation at 2000 rpm. The ore was floated for one minute by allowing air to be drawn in by the impeller. Subsequently, the ore was conditioned for two minutes, floated for two minutes, conditioned for two minutes, and finally floated for three minutes. The standard collector is a mixture of 33% of the allyl ester of isopropyl xanthate, 33% of 2-ethylhexanol and 33% of sodium diisobutyl di-thiophosphate collector.
The standard reagent addition is as follows. Enough lime is added to the ball mill to adjust to a pH of 10.4. At the same time, 7.7 gram/ton (0.0154 pound/ton) of the standard collector or oil being tested. 7.5 gram/ton (0.0150 pound/ton) of diesel fuel are added. During the first conditioning step, 20 g/t (0.040 lb/ton) of frother is added. During the second conditioning step, 8 g/t (0.016 pound/ton) of sodium isopropyl xanthate (SIPX), 2.5 g/t (0.005 lb/t) of frother, and 5 g/t (0.010 lb/ton) of the standard reagent or oil are added. During the third and final conditioning step, 4 g/t (0.008 lb/ton) of SIPX, (0.005 lb/t) of frother and 5 g/t (0.010 lb/ton) of the standard reagent or oil are added.
The results for the final combined concentrates are presented in Table 5, sorted by copper recovery. Every oil listed above the sunflower oil gave essentially the same copper and molybdenum recovery as the standard reagent.
There are two primary types of cotton grown in the United States. Pima long staple cotton and short staple cotton. The oils derived from both were tested on a copper-molybdenum ore with a head grade of 0.663% Cu and 0.134% Mo. The ore was floated as in Example 2. The results of the test shown in Table 6.
A number of triglyceride, specially, and essential oil collectors were tested on chalcopyrite ore containing molybdenite. The head assays of the ore were 0.579% Cu and 0.010% Mo. The ore charge of 1.0 kilograms was ground at 65% solids to 90% passing a 212 micron (65 mesh) screen.
The standard flotation procedure was as follows. Enough lime (0.9 grams) was added to the grind for the flotation slurry to have a pH of 10.4. The following reagents were added to the grind, 5.5 gram/ton of the standard thiophosphate copper collector, 7.7 gram/ton of diesel fuel molybdenum collector, and 10 gram/ton of Nalco 9743 frother. A Denver laboratory flotation cell was used. The ore charge was diluted with water to 27% solids. The ore was floated for two minutes. The slurry was then conditioned for one minute with 6.5 gram/ton of frother and 8 gram/ton of sodium isopropyl xanthate. The slurry was floated for two more minutes, then conditioned for one more minute with half of the dosage of the previous conditioning step, and floated for a final three minutes. All concentrates were collected into one pan for a single concentrate for the whole flotation.
The oils were tested by using them as the only collector. Only lime, 10 grams/ton of frother and 24 gram/ton of the oil being tested were added to the grind. No xanthate or other collector was added to the conditioning step, only the listed frother dosage.
The results for the triglyceride tests are presented in Table 7. As tested, no triglyceride was as good a collector for copper as the standard collector system. Due to the low molybdenum grade of the head ore, molybdenum recoveries often have a large standard deviation in repeated tests on the same ore. Generally, compounds that show a 5% better recovery than another compound in single tests will have an average higher molybdenum recovery on multiple tests.
1Has a ketone functionality.
2Has an alcohol functionality.
The results of the testing of specialty and essential oils are shown in Table 8. The bicyclic compounds equaled or surpassed the standard for copper and molybdenum recovery.
Eucalyptus
globus
A number of triglycerides, specialty, and essential oil collectors were tested on a molybdenum sulfide ore. The head assay of the ore was 0.0638% Mo. The ore charge of 1.0 kilogram was ground at 65% solids to 90% passing a 425 micron (35 mesh) screen.
The flotation procedure is as follows. The 100 gram/ton of oil was added to the grind. A Denver laboratory flotation cell was used. The ore charge was diluted with water to 27% solids. To the two minute conditioning step, 40 g/t frother was added. The ore was floated for 1 minute. The slurry was then conditioned for one minute, floated for two minutes, conditioned for one minute, and filially floated for six minutes. Each concentrate was collected separately and assayed separately. One test was conducted with frother alone to test the free flotability of the ore. The standard collector used at the mine was diesel fuel.
The results of the flotation of molybdenum sulfide for the triglycerides are shown in Table 9. The percentage of fatty acids in the triglycerides with the shown number of double bonds is listed. All of these oils did better than the free-flotability test.
1Has a ketone functionality.
The results of specialty and essential oils are shown in Table 10. All of these oils did better than the free-flotability test.
Eucalyptus
globus
1Oil synthesized from natural products and used as a sperm whale oil replacement.
In this example the synergistic effect of various oils and a sodium isopropyl xanthate is shown. A chalcocite ore with a head assay of 0.602% Cu and 0.016% Mo was used. The ore charge of 1.0 kilogram was ground at 65% solids to 90% passing a 212 micron (65 mesh) screen.
The standard flotation procedure is as follows. Enough lime (1.9 grams) was added to the grind for the flotation slurry to have a pH of 10.8. To this grind 30 g/ton (0.060 lb/ton) of either the standard collector. Cytec S-8399, believed to be a blend of dithiophosphate and thionocarbamate available from Cytec, Inc., Wayne, N.J., U.S.A., or the natural oil collector being tested was added. The grind charge was transferred to a Denver laboratory flotation cell. The ore charge was diluted with water to 27% solids. The ore was conditioned for two minutes with 20 gram/ton of Oreprep F-533, a blended alcohol frother. The ore was floated for three minutes. The slurry was then conditioned for three minutes with 10 gram/ton of frother and 1.5 gram/ton of sodium isopropyl xanthate (SIPX). The slurry was floated three more minutes. The concentrates were collected separately except for the avocado oil and Cytec S-8399.
The results shown in Table 11. These results show that limonene oil has the best synergy with SIPX despite not collecting much chalcocite by itself as shown in the recovery in the first concentrate. All the oils performed better as a secondary collector than the regular thiophosphate based Cytec S-8399.
In this example, the various combinations of oils and standard collectors are shown. A chalcocite ore with a head assay of 0.543% Cu and 0.014% Mo was used. The ore charge of 1.0 kilograms was ground at 65% solids to 90% passing a 212 micron (65 mesh) screen.
The standard flotation procedure was as follows. Enough lime (1.9 grams) was added to the grind for the flotation slurry to have a pH of 10.8. To this grind 30 g/ton (0.060 lb/ton) of either the standard collector. Cytec S-8399, or the natural oil collector being tested was added. The grind charge was transferred to a Denver laboratory flotation cell. The ore charge was diluted with water to 27% solids. The ore was conditioned for two minutes with 20 gram/ton or Oreprep F-533 frother. The ore was floated for three minutes. The slurry was then conditioned for two minutes with 1.5 gram/ton of sodium isopropyl xanthate (SIPX). The slurry was floated three more minutes.
The mixtures tested are shown in Table 12. The mercaptan used was tertiary dodecyl mercaptan. The zinc dithiophosphate used was zinc di-(1,3-dimethylbutyl)-dithiophosphate. The thionocarbamate used was n-ethyl, o-isopropyl thionocarbamate.
The results of the flotation tests are summarized in Table 16. The results show that cottonseed interacts well with the mercaptan, zinc dithiophosphate and thionocarbamate collectors.
All patents referred to herein, are hereby incorporated herein by reference, whether or not specifically done so within the text of this disclosure.
In the present disclosure, the words “a” or “an” are to be taken to include both the singular and the plural. Conversely, any reference to plural items shall, where appropriate, include the singular.
From the foregoing it will be observed that numerous modifications and variations can be effectuated without departing from the true spirit and scope of the novel concepts of the present invention. It is to be understood that no limitation with respect to the illustrated specific embodiments or examples is intended or should be inferred. The disclosure is intended to cover by the appended claims all such modifications and/or equivalents as fall within the scope of the claims.
