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Patent US2367496 - Method of improving the decolorizing properties of a synthetic hydrated ... - Google Patents
www.google.comhttp://www.google.com/patents/US2367496?utm_source=gb-gplus-sharePatent US2367496 - Method of improving the decolorizing properties of a synthetic hydrated magnesium silicate decolorizing materials
Publication number US2367496 A
Filing date May 12, 1941
Priority date May 12, 1941
Publication number US 2367496 A, US 2367496A, US-A-2367496, US2367496 A, US2367496A
Inventors Alexander Greentree
Original Assignee Lyle Caldwell
Method of improving the decolorizing properties of a synthetic hydrated magnesium silicate decolorizing materials
US 2367496 A
Patented Jan. 1%, 1945 METHQD F IMPROVING THE DECOLORIZ- ENG PROPERTIES 01? A SYNTHETIC HY- DRATED MAGNESIUM SILICATE DECOI ORIZING 'MATERIAL Alexander Greentree, South Charleston, W. Va,
assignors, by mesne assignments, to Lyle Caldwell, Los Angeles, Calif.
No Drawing. Application May 12, 194i,
. Serial No. 393,118
16 (Claims.
This invention relates to a process for the production of a decolorizing material, and pertains particularly to the production of an improved decolorizing material or adsorbent from a synthetic hydrated magnesium silicate of the type characterized by those produced according to the teachings of U. S. Patents Nos. 2,076,5 l5, 2,163,525, 2,163,526, and 2,163,527 granted to Lyle Caldwell.
One of the particular objects of this invention is t provide a process for the preparation of a decolorizing or adsorbent material of enhanced decolorizing power from a synthetic hydrated magnesium silicate material which itself has important adsorbent characteristics.
A further object of the invention is to provide an improved decolorizing material of the character described, containing an iron compound in a preferred proportion. I
i am aware of the fact that prior investigators in the art have proposed the treatment of an oil with a mixture of a soluble iron compound and a decolorizing material of the character of fullers earth, whereby the iron compound functions as an electrolyte to facilitate the agglomeration of contaminant coloring matter in the oil; I am further appreciative of the fact that it has been suggested that a clay material may be caused to have improved properties with respect to the removal of sulphur and sulphur compounds from petroleum oils, by the incorporation therein of soluble compounds of metals having an alfinity for sulphur, followed, if desired, by a roasting treatment to convert such metals to the oxide form.
The essential concept of my invention is that of incorporating a soluble iron compound with a particular type of adsorbent material, i. e., a finely divided synthetic hydrated magnesium silicate, preferably using a ferrous compound under conditions such as will convert the principal proportion of the iron of the ferrous compound from ferrous to ferric condition, for the specific purpose of improving the decolorizing property of the material. I have found that similar treatment of base materials other than a synthetic hydrated magnesium silicate is not productive of equivalent results, and, further, that incorporation of the iron compound in ferrous condition with concurrent or subsequent at least partial oxidation is materially more effective in enhancing the decolorizing characteristics of the synthetic magneslum silicate base material than is the incorporation of an iron compound in ferric condition.
A specific example of the practice of my invention is as follows:
To a slurry of 24 parts (dry basis) of a finely divided synthetic hydrated magnesium silicate and 136 parts of water, I add 1.2 parts of FeCh dissolved in 9 parts of water. The resulting slurry is thoroughly mixed and dried in contact with atmospheric or other oxygen, to a preferred moisture content, which may be varied between zero and 20% in the same manner and for the same reasons as are encountered in the production of any inorganic adsorbent material as is well known in the art.
In the above example, 5% of the ferrous salt (equivalent to 2.2% Fe) on the basis of the dry base material (synthetic hydrated magnesium silicate) was employed. I have found that the amount of FeClz added may be varied between 0.6 part (2 /2%) and 3 parts (m with the optimum at about 1.2 parts. The equivalent Fe range is from 1.1% to 5.5%, with an optimum at about 2.2%. I have found that FeSO4 (added as FeSO4.7HcO for example) is a full equivalent of FeClz, and tests indicate that sparingly soluble ferrous compounds may also be used, for example, ferrous oxalate. The above-recited Fe range of 1.1% to 5.5% is based on the amount of iron present in the contacting iron salt solution in proportion to the dry weight of the synthetic hydrated magnesium silicate employed. In the finished iron-treated, dried product, this corresponds generally to an iron proportion of from about 1% to about 5%, on a moisture-free basis. A more preferred range, in which the objects of the present invention are attained to the greatest degree, is a final iron content of from about 2% to about 2.5%, on a moisture-free basis. The concentration of the ferrous compound in solution seems not to be critical, and the slurry concen- 'The physical or chemical reasons for these obtration may be varied within economic limits as to facility of intermixing on the one hand and the necessity for drying on the other hand, without detrimentto the properties of the finished product.
During the contact of the base material (the synthetic hydrated magnesium silicate) with the iron salt in aqueous solution, the iron salt becomes intimately associated with the particlesof synthetic base material. Whether the iron compound reacts chemically therewith, or is merely adsorbed thereon, is not at this time known, but tests on the contacted base material, prior to drying, indicate that this intimate association is substantially non-reversible. Extraction with water,
served facts are not at present apparent to me. as for example, gives a negative iron test. Since the iron salt is applied to contact with the base material when in water solution, however, this intimate association may be the result of any one or any combination of the following possibilities:
(1) Chemical reaction has taken place between the silicate material and the iron salt, in the production of an insoluble iron reaction product;
(2) The iron salt has undergone chemical transformation, as by hydrolysis, which transformation might be facilitated by the tremendous surface area of the silicate material; and/or (3) The iron salt is so strongly adsorbed on the silicate material that it cannot be desorbed in water to an extent which will permit detection. To ascribe the observed results as resultant primarily from any particular one of these possibilities is quite diflicult. It has been determined, however, that when a ferrous salt is employed in the treatment of the synthetic silicate material, the final product when dried in the air contains only ferric iron; when oxygen-containing air is excluded from the drying operation, however, approximately three-fourths of the iron is found to be in ferric condition, indicating that an appreciable oxidation is obtained during the contact step. This would point to possibility (2) above. The decolorizing. characteristics of the three-quarters oxidized and fully oxidized products were equivalent.
Considerable improvements in the decolorizin properties of a synthetic hydrated magnesiuin silicate decolorizing material may be obtained by treating the base material with a water-soluble ferric salt in water solution, as with ferric chloride or the like. The improvement resulting from treatment with FeCla in th manner set forth above in the case of FeClz, is approximately 50% of that obtained with FeClz or FeSO4. A further improvement may be effected by treating the base material with a FeCla solution, for example, followed by contact with an alkali-metal hydroxide solution to convert the Fe of the FeCl: to Fe(OH)3, followed by drying. This results in an improvement in the decolorizing properties approximately 50% greater than that obtained with the straight FeCls plus drying procedure.
Typical data on the effect of varying quantities of ferrous salt on the bleaching efficiency of the product, for the bleaching of two different cottonseed oils, are as follows:
Lovibond colors Y-R Cottonseed oil Cottonseed oil Per cent Fe used in makin adsorbent product (dry basis) iggg g g gg' g ggfg Yellow Red Yellow Red Contact-- min. at 230 F.
Lovlbond colors Usinglnatural Using resent Per cent adsorbent used y adsor nt Yellow Red Yellow Red From the above, those skilled in the art will recognize that the color reduction obtained by using as much as 6% of the natural decolorizing clay. is not sufficiently great to meet commercial demands for a properly decolorized oil, while the color improvement with but 3% of the material prepared according to this invention is well within the range of commercial requirements. In general, in treating an oil such that a satisfactory color can be obtained with a natural clay if a suflicient amount is employed, I have found that one must use from 1.5 to 3 times, depending upon the oil bein treated, as much natural clay to secure the same color reduction as is obtainable with a nominal amount of the adsorbent of this invention.
The above examples of the practice of this invention are to be taken as illustrative rather than limitative, the scop of this invention beinl expressed in the subioined claims. The method of decolorizing vegetable oils, by contact thereof with the improved decolorizing composition described herein, is described and claimed in a patent a plication filed by me on November 24, 1944, Ser. No. 564,977,
1. The method of increasing 'the decolorizing properties of a synthetic hydrated magnesium silicate decolorizing material, which comprises subjecting such a material in finely divided condition to-contact with a water-soluble iron salt in aqueous solution, to cause such iron salt to become intimately associated with the particles of said material, and drying the contacted material, the proportion of said iron salt to said material being such that the final product contains from about 1% to about 5% of iron on a dry weight basis.
2. The method set forth in claim 1, in which the proportion of said iron salt to said silicate is such that the final product contains about 2% to2 ofiron.
3. The method of increasing the decolorizing properties of a synthetic hydrated magnesium silicate decolorizing material, which comprises subjecting such a material in finely divided condition to contact with a water-soluble ferrous salt in aqueous solution, to cause such ferrous salt to become intimately associated with the particles of,said silicate material, and drying the contacted material, such ferrous salt being employed in a proportion such that the final product contains from about 1% to about 5% of iron accuse silicate decolorizing material, which comprises subjecting such a silicate material in finely divided condition to contact with a water-soluble ferrous salt in aqueous solution, to cause such ferrous salt to become intimately associated with the particles of said silicate material, and drying the contacted material under conditions causing oxidation of the principal proportion of such ferrous iron to ferric condition, such ferrous salt being employed in a proportion such that the final product contains from about 1% to about of iron on a dry weight basis.
6. The method set forth in claim 5, in which the proportion of ferrous salt employed is such that the final product contains about 2% to 2V:
7. The method of increasing the decolorizlng properties of a synthetic hydrated magnesium silicate decolorizing material, which comprises subjecting such a silicate material in finely divided condition to contact with a water soluble ferric salt in aqueous solution, to cause such ferric salt to become intimately associated with the particles of said silicate material, and drying the contacted material, the proportion of said ferric salt to said silicate being such that the final product contains from about 1% to about 5% of iron on a dry weight basis.
a. The method set forth in claim 7, in which the proportion of ferric salt employed is such that the final product contains about 2% to 2/z% of iron. I
9. Themethod of increasing the decolorizing properties of a synthetic hydrated magnesium silicate decolorizing material, which comprises subjecting such a silicate material in finely divided condition to contact with a water-soluble ferric salt in aqueous solution, subsequently subjecting the so-contacted material to contact with an alkali-metal hydroxide to cause precipitation of ferric hydroxide within said silicate material, and drying the contacted material, the proportion of said ferric salt to said silicate being such that the final product contains from about 1% to about 5% of iron on a dry weight basis.
' 10. The method set forth in claim 9, in which the proportion of ferric salt employed is such that the final product contains about 2% to 256% of iron.
11. The method of increasing the decolorizing properties of a synthetic hydrated magnesium silicate decolorizing material, which comprises subjecting such a material in finely divided condition to contact with a sulphate of iron in aqueous solution, to cause said sulphate of iron to become intimately associated with the particles of said material, and drying the contacted material, the proportion of said sulphate'of iron to said material being such that the final product contains from about 1% to about 5% of iron on a dry weight basis.
12. The method of increasing the decolorising properties are synthetic hydrated magnesium silicate decolorizing material, which comprises subjecting such a material in finely divided conous solution, to cause such ferous sulphate to become intimately associated with the particles of said material, and drying the contacted material, such ferrous sulphate being employed in a proportion such that the final product contains from about 1% to about 5% of iron on a dry weight basis.
14. The method of increasing the decolorizing properties of a synthetic hydrated magnesium silicate decolorizing material, which comprises subjecting such a material in finely divided condition to contact with ferrous sulphate in aqueous solution, to cause such ferrous sulplate to become intimately associated with the particles of said material, and drying the contacted material under conditions to cause oxidation of the principal proportion of the iron to ferric condition, such ferrous sulphate being employed in a proportion such that the final product contains from about 1% to about 5% of iron on a dry weight basis.
15. The method of increasing the decolorizing properties of a synthetic hydrated magnesium silicate decolorizing material, which comprises 0 subjecting such a material in finely divided condition to contact with ferrous chloride in aqueous solution, to cause such ferrous chloride to become intimately associated with the particles of said material, and drying the contacted material, such ferrous chloride being employed in a proportion such that the final product contains from about.1% to about 5% of iron on a dry weight basis.
16. The method of increasing the decolorizing properties of a synthetic hydrated magnesium silicate decolorizing material, which comprises subjecting such material in finely divided condition to contact with ferrous chloride in aqueous solution, to cause such ferrous chloride to become intimately associated with the particles of said material, and drying the contacted material under conditions to cause oxidation of the principal proportion of the iron to ferric condition, such ferrous chloride being employed in a 00 proportion such that the final product contains from about 1% to about 5% of .iron on a dry weight basis.
ALEXANDER GREEN'I'REE.
dition to contact with ferrous sulphate in aque-
US2445345 * Feb 20, 1943 Jul 20, 1948 Union Oil Co Process for the catalytic reforming of hydrocarbon mixtures
US2450549 * Nov 24, 1944 Oct 5, 1948 Lyle Caldwell Decolorizing vegetable oils with ferric salts and silicates
U.S. Classification 502/406, 208/296
Cooperative Classification B01J20/10
European Classification B01J20/10