US1975798A - Process for recovering potassium salts from minerals - Google Patents
Process for recovering potassium salts from minerals Download PDFInfo
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- US1975798A US1975798A US623810A US62381032A US1975798A US 1975798 A US1975798 A US 1975798A US 623810 A US623810 A US 623810A US 62381032 A US62381032 A US 62381032A US 1975798 A US1975798 A US 1975798A
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- potassium
- compounds
- polyhalite
- magnesium
- calcium
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- C—CHEMISTRY; METALLURGY
- C01—INORGANIC CHEMISTRY
- C01D—COMPOUNDS OF ALKALI METALS, i.e. LITHIUM, SODIUM, POTASSIUM, RUBIDIUM, CAESIUM, OR FRANCIUM
- C01D5/00—Sulfates or sulfites of sodium, potassium or alkali metals in general
- C01D5/06—Preparation of sulfates by double decomposition
- C01D5/10—Preparation of sulfates by double decomposition with sulfates of magnesium, calcium, strontium, or barium
Definitions
- This invention relates to a method of treating complex potassium minerals or salts for the purpose of manufacturinga product of relatively high potassium content.
- the primary'object of the invention is the recovery of potassium salts in a valuable concentrated form from the mineral polyhalite (K2804.MgSO42CaSO42H2O) which is known to exist in extensive deposits in a region in the southwestern United States.
- the method of recovery disclosed may, however, also be applied to similar potassium minerals or salts, such as krugite, langbeinite, schiinite, leonite, syngenite, or to any mixture comprising potassium sulphate with magnesium sulphate and/or calcium sulphate.
- ter vapor and free sulphur present in the waste 6 gas Whilereduction may take place slowly at lower temperatures, it first becomes evident at a temperature or approximately 650 C. The rate of reduction increases with increase in temperature. This increase is particularly noticeable in the range from 800 to 900 C. The volatilization of potassium compounds is small in this temperature range, but increases rapidly with increase in temperature above approximately 1000 C. It is therefore desirable to' maintain a temperature between 800 and 1000 C. during reduction. A temperature of 900 C. has been found suitable since it results in a rapid rate of reduction with little loss of potassium compounds by volatilization. It is obvious, however, that the reduction might be carried out in practice at a somewhat higher or somewhat lower temperature.
- syngenite (K2SO4.C8.SO4.H2O), which contains only potassium sulphate and calcium sulphate with no magnesium sulphate might reasonably be assumed to respond in a manner similar to polyhalite. Mixtures of such minerals or salts, or of the constituent simple sulphates would not differ essentially in behavior. Satisfactory separation of potassium compounds by reduction and extraction of any such minerals or salts or mixtures would be reasonably expected by any person skilled in the art.
- the method of treatment comprises relatively simple operations which may be performed eiiiciently and economically on an industrial scale by one skilled in the art. Since each one of the necessary operations may be performed by various means, and
- the process of manufacturing potassium salts which comprises reducing a material containing potassium sulphate, magnesium sulphate and calcium sulphate by means of a suitable reducing agent ata moderately high degree of heat to yield a reduction product containing potassium sulphide together with calcium compounds and magnesiumcompounds substantially insoluble in water; extracting this reduction product with water to yield a liquor containing essentially potassium sulphide with practically no compounds of-calcium or of magnesium; and recovering solid potassium salts from this liquor by known means.
- the process of manufacturing potassium salts from polyhalite which comprises reducing polyhalite at a temperature in the range from 800 to 900 C. by means of a gaseous reducing agent containing carbon monoxide and hydrogen to yield a reduction product containing potassium sulphide together with calcium compounds and magnesium compounds substantially insoluble in water; extracting this reduction product with hot water to yield a liquor containing essentially potassium sulphide with practically no compounds of calcuim or of magnesium; and recovering solid potassium salts from this liquor by known means.
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- Organic Chemistry (AREA)
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- Inorganic Chemistry (AREA)
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Description
. reference vby Schumann Patented Oct. 9, 1934 UNITED STATES PROCESS FOR RECOVERING POTASSIUM SALTS FROM MINERALS Everett P. Partridge, Park View Estates, and Foster Fraas, New Brunswick, N. J assignors to the United States of America, as represented by the Secretary of Commerce No Drawing. ApplicationJuly 21, 1932, Serial No. 623,810
11 Claims. (CI. 23-27) (Granted under the act of March 3, 1883, as amended April 30,1928; 37 0 0. G. 757) This invention described herein may be manufactured and used by or for the Government for governmental purposes, Without the payment' to us of any royalty thereon.
This invention relates to a method of treating complex potassium minerals or salts for the purpose of manufacturinga product of relatively high potassium content.
The primary'object of the invention is the recovery of potassium salts in a valuable concentrated form from the mineral polyhalite (K2804.MgSO42CaSO42H2O) which is known to exist in extensive deposits in a region in the southwestern United States. The method of recovery disclosed may, however, also be applied to similar potassium minerals or salts, such as krugite, langbeinite, schiinite, leonite, syngenite, or to any mixture comprising potassium sulphate with magnesium sulphate and/or calcium sulphate.
The reduction-of simplesulphates, such for example as barium sulphate, by means of suitable reducing agents is old art, but no evidence concerning the behavior of double or triple salts containing potassium sulphate upon reduction is known with the exception of one laboratory v (Ann. 187, 286-321 (1877) p. 306) Schumann noted that the double sulphate of potassium and magnesium was reduced by hydrogen at a red heat and assumed from his qualitative experiments that K28 and MgO were theproducts obtained. No quantitative data were recorded by this investigator.
It is not possible to state definitely. from this experiment or from any other disclosure in the prior art that a satisfactory recovery of potassium compounds'would be obtained by a reduction method even in thecase of the double sulphateo f potassium and magnesium. In the case of polyhalite, which is a' triple sulphate of potassium, magnesium, and calcium, prediction of results could be no more than a hypothesis.
We have discovered that by maintaining a reducing agent in contact .with polyhalite at a moderately high degree of heat for a desirable period of time the polyhalite is so modified that on subsequent extraction with water practically allof the potassium compounds contained in the reduction product goes readily into solution, while practically no calcium or magnesium compounds are'dissolved; that an extract solution highly concentrated with respect to potash may thereby be obtained; and that evaporation of this extract solution yields desirable potash compounds.
For example, when polyhalite, ground to pass a screen with 10 meshes to the linear inch, is heated in contact with a stream of hydrogen, the polyhalite is decomposed, with hydrogen sulphide, wa-
ter vapor and free sulphur present in the waste 6 gas. Whilereduction may take place slowly at lower temperatures, it first becomes evident at a temperature or approximately 650 C. The rate of reduction increases with increase in temperature. This increase is particularly noticeable in the range from 800 to 900 C. The volatilization of potassium compounds is small in this temperature range, but increases rapidly with increase in temperature above approximately 1000 C. It is therefore desirable to' maintain a temperature between 800 and 1000 C. during reduction. A temperature of 900 C. has been found suitable since it results in a rapid rate of reduction with little loss of potassium compounds by volatilization. It is obvious, however, that the reduction might be carried out in practice at a somewhat higher or somewhat lower temperature.
' Experimentshave shown that when polyhalite is heated at'approximately 900 C. ina stream of dry carbon monoxide, practically no reduction takes place although the polyhalite is in the fluid state. If, however, a mixture of carbon monoxide and water vapor is used under otherwise similar conditions the polyhalite is readily reduced; Satisfactory reduction is likewise accomplished by the similar use of a mixture of carbon monoxide and hydrogen or a mixture of carbon monoxide, hydrogen and water vapor.
'We have also discovered that when natural gas in which methane is the chief constituent is passed over polyhalite heated at approximately 900 C. in the substantialabsence of water vapor, polyhalite is reduced, but carbon is deposited in considerable quantities. If, however, a mixture of this natural gas and water vapor is used under otherwise similar conditions the polyhalite is reduced without appreciable carbon deposition.
Experiment has further shown that when an intimate mixture of polyhalite and carbon is heated at approximately 900 C. the polyhalite is reduced, andthat this process of reduction may be facilitated by blowing water vapor through the heated mixture.
We have found that the potassium compounds present in the reduced material are easily and completely extracted by water. Water at ordinary atmospherictemperature may be used, but hot waterhas been found to be preferable. The potassium concentration of the extract liquor is limited by mechanical problems in the'separation of the extracted solid, rather than by the solubility of the potassium compounds present, which is very high. For example, we extracted l0 grams of reduced polyhalite with 50 grams of water at 100 C. for 30 minutes. The solid residue was separated by filtration, and the filtrate was then used to extract an additional 36 grams of reduced polyhalite. The filtrate from this second stage contained 28 per cent K, 16.9 per cent total sulphur, and no Ca, Mg, or S04. The solid residue from the first stage, after washing with 50 grams of water and drying at 110 0., contained only 0.22 per cent K, showing that the recovery of potassium compounds during extraction was very complete.
On evaporating the extract liquors rich in potassium small amounts of such compoundsas K2SO4 and K2803 are first deposited. When evaporated to dryness the major portion .of the potassium is obtained in the form of an essentially sulphidematerial, which upon being dried at 110 C. may contain 50 per cent K, and when fused to drive off water may contain 64 per cent K. For example, when 638 grams of reduced polyhalite were extracted with 630 grams of water at the boiling point for 10 minutes, and the solid residue was separated by filtration, a concentrated extract was obtained. After per cent of the extract had been evaporated, only 6 grams of solid material, consisting of K280i and K2803 had been deposited from solution. On evaporating the remaining solution to dryness and drying at 110 0., 124 grams of material were ob-. tained which contained 51.0 per cent K, 26.3, per cent total sulphur, 20.4 percent H20, and no compounds of calcium or magnesium.
Similar results were obtained by washing the solid residue from the above extractionwith 630 grams of cold water, and filtering oil? the final solid residue. After 80 per cent of the wash filtrate had been evaporatedonly 3 grams of solid material, consisting of K260; and K2803, had been deposited from solution. On further evaporation until per cent of the filtrate has been evaporated, an additional 2 grams of solid material had deposited. On evaporation of the remaining solution to dryness and drying at 110? C. 91 grams of material were obtained which contained 50.9 per cent K, 26.4 per cent total sulphur, 19.8 per cent H20, and no compounds or" calcium or magnesium.
Since polyhalite, a triple sulphate of potassium, magnesium and calcium, has been found to yield its potassium content readily upon extraction following reduction, it may reasonably be assumed that krugite which differs from polyhalite only in possessing a greater content of CaSO4, will yield similar desirable results. It may also be assumed that the less complex minerals or salts, langbeinite (KzSOnZMgSOr) schonite K2sol.Mgso4.sH2o and leonite (K2SO4.MSO4.4H20) which contain only potassium sulphate and magnesiurn sulphate with no calcium sulphate will yield their potassium content when treated in essentially the manner disclosed. Likewise, syngenite (K2SO4.C8.SO4.H2O), which contains only potassium sulphate and calcium sulphate with no magnesium sulphate might reasonably be assumed to respond in a manner similar to polyhalite. Mixtures of such minerals or salts, or of the constituent simple sulphates would not differ essentially in behavior. Satisfactory separation of potassium compounds by reduction and extraction of any such minerals or salts or mixtures would be reasonably expected by any person skilled in the art.
The method of treatment, examples of which are given above, comprises relatively simple operations which may be performed eiiiciently and economically on an industrial scale by one skilled in the art. Since each one of the necessary operations may be performed by various means, and
since control of these operations within narrow limits is not essential in obtaining desirable results, the scope of the invention should not be construed as being limited by the specific examples used above in an illustrative manner.
We have shown that by reducing polyhalite and subsequently extracting the reduction product with water it is possible to separate the potassium compounds from calcium and magnesium compounds in a simple and efiicient manner, yielding a product highly concentrated with respect to potassium.
Having described our invention, what we claim as new and wish to secure by Letters Patent is:
1. The process of manufacturing potassium salts which comprises reducing a material containing potassium sulphate, magnesium sulphate and calcium sulphate by means of a suitable reducing agent ata moderately high degree of heat to yield a reduction product containing potassium sulphide together with calcium compounds and magnesiumcompounds substantially insoluble in water; extracting this reduction product with water to yield a liquor containing essentially potassium sulphide with practically no compounds of-calcium or of magnesium; and recovering solid potassium salts from this liquor by known means.
2. The process of manufacturing potassium salts which comprises reducing a material containing potassium sulphate and magnesium sulphate by means of a suitable reducing agent at a moderately high degree of heat to yield a reduction product containing potassium sulphide together with magnesium compounds substan tially insoluble in water; extracting this reduction product with water to yield a liquoncontaining essentially potassium sulphide with practically no compounds of magnesium; andrecovering solid potassium salts from this liquor by known means. l
3. The process of manufacturing potassium salts which comprises reducing a material containing potassium sulphate and calcium sulphate by means of a suitable reducing agent at a; moderately high degree of heat to yield a reduction product containing potassium sulphide together with calcium fcompounds substantially insoluble in water; extracting this reduction product with water to yield a liquor containing essentially potassium sulphide with practically no compounds of calcium; and recovering solid potassium salts from this liquor by known means.
4. The process of manufacturing potassium salts which comprises reducing polyhalite by means of a suitable reducing agent at a moder ately high degree of heat to yield a reduction product containing potassium sulphide together with calcium compounds and magnesium compounds substantially insoluble in water; extract ing this reduction product with water to yield a liquor containing essentially potassium sulphide with practically no compounds of calcium or of magnesium; and recovering solid potassium salts from this liquor by known means.
5. The process of manufacturing potassium salts which comprises reducing polyhalite by means of a suitable reducing agent at a moderately high degree of heat to yield a reduction product containing potassium sulphide together with calcium compounds and magnesium compounds substantially insoluble in water; extracting this reduction product with hot water to yield a liquor containing essentially potassium sulphide with practically no compounds of calcium or of magnesium; and recovering solid potassium salts from this liquor by known means.
6. The process of manufacturing potassium salts from polyhalite which comprises reducing polyhalite at a temperature in the range from 809 to 900 C. by means of hydrogen to yield a reduction product containing potassium sulphide together with calcium compounds and magnesium compounds substantially insoluble in water; extracting this reduction product with hot water to yield a liquor containing essentially potassium sulphide with practically no compounds of calcium or of magnesium; and recovering solid potassium salts from this liquor by known means.
'7. The process of manufacturing potassium salts from polyhalite which comprises reducing polyhalite at a temperature in the range from 800 to 900 C. by means of a gaseous reducing agent containing carbon monoxide and hydrogen to yield a reduction product containing potassium sulphide together with calcium compounds and magnesium compounds substantially insoluble in water; extracting this reduction product with hot water to yield a liquor containing essentially potassium sulphide with practically no compounds of calcuim or of magnesium; and recovering solid potassium salts from this liquor by known means.
8. The process of manufacturing potassium salts from polyhalite which comprises reducing polyhalite at a temperature in the range from 800 to 900 C. by means of a gaseous reducing agent containing carbon monoxide and water to yield a reduction product containing potassium sulphide together with calcium compounds and magnesium compounds substantially insoluble in water; extracting this reduction product with hot water to yield a liquor containing essentially potassium sulphide with practically no compounds of calcium or of magnesium; and recovering solid potassium salts from this liquor by known means.
9. The process of manufacturing potassium salts from polyhalite which comprises reducing polyhalite at a temperature in the range from 800 to 900 C. by means of a gaseous reducing agent containing carbon monoxide, hydrogen, and water vapor to yield a reduction product containing potassium sulphide together with calcium compounds and magnesium compounds substantially insoluble in water; extracting this reduction product with hot water to yield a liquor containing essentially potassium sulphide with practically no compounds of calcium or of magnesium; and recovering solid potassium salts from this liquor by known means.
10. The process of manufacturing potassium salts from polyhalite which comprises reducing polyhalite at a temperature in the range from 800 to 900 C. by means of a gaseous reducing agent initially containing natural gas and water vapor to yield a reduction product containing potassium sulphide together with calcium compounds and magnesium compounds substantially insoluble in water; extracting this reduction product with hot water to yield a liquor containing essentially potassium sulphide with practically no compounds of calcium or of magnesium; and recovering solid potassium salts from this liquor by known means.
11. The process of manufacturing potassium salts from polyhalite which comprises reducing polyhalite at a temperature in the range from 800 to 900 C. by means of carbon and water vapor to yield a reduction product containing potassium sulphide together with calcium compounds and magnesium compounds substantially insoluble in water; extracting this reduction product with hot water to yield a liquor containing essentially potassium sulphide with practically no compounds of calcium or of magnesium;
and recovering solid potassium salts from this liquor by known means.
EVERETT P. PAR'IRIDGE. FOSTER FRAAS.
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US623810A US1975798A (en) | 1932-07-21 | 1932-07-21 | Process for recovering potassium salts from minerals |
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US623810A US1975798A (en) | 1932-07-21 | 1932-07-21 | Process for recovering potassium salts from minerals |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2837403A (en) * | 1955-05-24 | 1958-06-03 | Int Minerals & Chem Corp | Production of potassium carbonate |
US2903337A (en) * | 1955-07-05 | 1959-09-08 | Int Minerals & Chem Corp | Production of potassium bicarbonate |
US2903336A (en) * | 1955-07-05 | 1959-09-08 | Int Minerals & Chem Corp | Production of potassium carbonate |
-
1932
- 1932-07-21 US US623810A patent/US1975798A/en not_active Expired - Lifetime
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2837403A (en) * | 1955-05-24 | 1958-06-03 | Int Minerals & Chem Corp | Production of potassium carbonate |
US2903337A (en) * | 1955-07-05 | 1959-09-08 | Int Minerals & Chem Corp | Production of potassium bicarbonate |
US2903336A (en) * | 1955-07-05 | 1959-09-08 | Int Minerals & Chem Corp | Production of potassium carbonate |
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