TH45877B - Inorganic oxide production, hydrophobic particles - Google Patents

Abstract

The described DC60 (12/12/57) is an enhanced method for the production of non-particle inorganic oxides. Hydrophobic is useful in reinforcing mixtures of polymers, for example, rubber, using auxiliary agents. The hydrophobicity of an inorganic oxide aqueous suspension with pH 2.5 or less, and the pH of the suspension after impregnation, is not hydrophobic. It is described as an enhanced method for the production of non-particle inorganic oxides. Hydrophobic is useful in reinforcing mixtures of polymers, for example, rubber, using auxiliary agents. The hydrophobicity of an inorganic oxide aqueous suspension with pH 2.5 or less, and the pH of the suspension after impregnation, is not hydrophobic.

Claims (7)

1. In the production method of hydrophobic inorganic oxides by contact with suspended solids. The acidic alkaline of inorganic oxides is selectable from those containing precipitated silica, colloidal silica and a mixture of those inorganic oxides, with organic compounds - Nomotalic to form acidic aqueous suspension of inorganic oxides, hydrophobic particles, with a choice of surfactants and / or mixed solvents. Do not bathe, and remove the oxide. The aforementioned inorganic hydrophobic particles were recovered, the enhancement consisted of the use of reagents. Contains the aforementioned organometallic oxides in sufficient quantities to make hydrophobic inorganic oxides, in such a way that inorganic oxides contain a hydroxyl content of 2 to 15. OH / nm2, carbon content from 0.1 to 6 percent by weight, and methanol wetting condition from 15 to 45 percent, in the alkaline oxide of inorganic oxides with PH 2.5 or less, and processed with acidic aqueous suspension of inorganic oxides, hydrophobic particles with auxiliary agents. Neutralizes acids to produce hydrophobic inorganic oxides with a pH of 3 to 10, a relatively non-extractable carbon content, and a standard M1 white area of less than 0.4 percent 2. The method of claim No. 1, where organometallic materials are selected from those containing substances Assemble the 1st organometallic compounds, represented by the following formula: R1aMX4-a, the 2nd class organometallic compounds, represented by the formula: R22n-2SinOn-. 1 The third class of organometallic compounds, represented by the formula: (R33Si) kNR53-k. And the fourth organometallic compound, denoted by the formula: R42mSimOm, where: (a) M is independent of silicon, titanium or zirconium; (b) Each R1 is independent of each other, i.e. Hydrocarbon groups without ethylene unsaturated and containing from 1 to 18 carbon atoms; (c) X each is independent, halos, amino, alkoxin with carbon from 1 to 12 atoms, or atoms with carbon from 1 to 12 atoms; (d) a is 1,2 or 3; (e) each R2 is independent of the halos, hydroxyls, or idro-carbon groups that are not ethylene saturation and contain carbon from 1 to 18. Atoms, provided that at least 50 percent by moles of the R2 displacement group is the hydrocarbon group mentioned; (f) n is from 2 to 10,000; (g) each R3 is independent of the halo, idrox, or hydrocarbon group without ethylene unsaturated and carbon from 1 to 18 atoms, Provided that at least 50 percent by moles of the replacement group R3 is the previously mentioned hydrocarbon group; (h) R5s are independent hydrogen or hydrocarbon groups with no Polyethylene unsaturated and has carbon from 1 to 18 atoms; (i) k is 1 or 2; (j) R4 each is independent. Concatenated are hydrocarbons without ethylene unsaturated and containing carbon from 1 to 18 atoms; And (k) m is from 3 to 20 3. Method of claim 1 in which inorganic oxides are Sediment silica 4. Method of claim 2 where M is silicon and X is an alkoxin group with carbon from 1 to 4 atoms or halo 5. Method of claim 4 where X is chloro or methe. Oxy 6. Method of claim 3, where the hydrophobic silica has a hydroxyl content of 4 to 12 OH / nm2, has a carbon content of 0.3 to 3% by weight. The white area M1 is less than 0.25 percent. 7. Method of claim 6, in which the amount of organometallic compounds used to remember carbon from 3 to 40 μmol per square silica. M 8. Method of claim No. 7 in which organometallic compounds are hexamethyl dysiloxane 9. Method of claim No. 6, which selects organometallic compounds. C is obtained from those represented by the formula R1aMX4-a, where each R1 is a non-ethylene unsaturated hydrocarbon group. And there is carbon from 1 to 8 atoms, x is halo or alcoxin group with carbon from 1 to 12 atoms and a is 1,2 or 3 1 0. Method of claim No. 1 where The hydrophobic particle tree was recovered. It was obtained by mixing incompatible organic solvents with water with aqueous oxide suspension. Inorganic hydrophobic particles, the destroyer weight ratio to inorganic oxides is greater than 5: 1, thereby transferring the treated inorganic oxides to Like water from the Aquias cycle Of mixtures into the organic solvent cycle 1 1. Method of claim 10, which selects organic solvents incompatible with water from them, which Contains aliphatic Hydrocarbons, cycloalkanes, aeromatic hydrocarbons and ketone 1 2. Method of claim 11, which selects incompatible solvents from hexane, hep-tane, toluene, cyclohexane and methyl isobi. Vatil Ketone 1 3. Method of claim 1, in which organic co-solvent is incompatible with water 1. 4. Method of claim 13, which selects the incompatible cogenerate with water from Tetrahydrofuran and C1-C4 Lkanol 1. 5. Method of claim No. 1 in which a particle-type inorganic oxide aqueous suspension can be Get wet grinding before coming into contact with organometallic compounds 1 6. Method of claim No. 10, in which the particles of inorganic oxides The hydrophobic has been milled wet prior to mixing with an incompatible organic solvent with water. 7.Method of claim No. 10, in which the ether-containing solvent cycle with particle-type inorganic oxides The hydrophobic gets wet grind.