TH58259B - Organic-inorganic composite - Google Patents

Abstract

DC60 (11/12/57) An inorganic-organic composite comprising inorganic cycles, such as gypsum crystals, and organic cycles that form film-forming organic cycles. This was chosen from the substituted starch. Which has a degree of polymerization; The degree of displacement and viscosity in the way that the starch was Instead, it does not dissolve in water during mixing, but will dissolve at higher treatment temperatures. During formation, stabilization or drying of this composite therefore, thus preventing large displacement Too much of the starch was replaced and this made this composite a true boost of strength. Inorganic-organic compounding compounds that include inorganic cycles, such as gypsum crystals, and organic cycles that form film. The organic cycle that resulted in this film was chosen from a type of starch. Replaced, which has a degree of polymerization; Degree of displacement and viscosity in the manner in which the dough This displaced type will not dissolve in water during mixing, but will only dissolve at the desired treatment temperature. Increases during formation, stabilization or drying of this dressing compound, thus, preventing The excessive displacement of the starch is replaced and this gives the compound a true strength enhancement.

Claims (9)

1. organic-inorganic compounding compounds, including: substituted starch with at least one substitution class; Inorganic cycle; And water, where the inorganic cycle, the displaced starch and the water are mixed together to form a mixture, at least part of this inorganic cycle is combined with water by water, And the degree of displacement and moo Instead of at least one group selected in such a way that the displaced starch will not dissolve during mixing. At mixing temperature, but will dissolve at least partially as the temperature rises during the treatment The method of mixing and forming a film that is widely distributed throughout this organic-inorganic compound, which this organic-inorganic compound is highly strengthened with real 2. An organic-inorganic compound according to claim 1, which replaces at least one group. This group is chosen from a substitute group that contains an ether type substitute and ester type substitution. 3. An organic-inorganic compound according to claim 2, which replaces at least one group This group is chosen from a substitute group that contains an ester type substitute group. 4. An organic-inorganic compound according to claim 2, which replaces at least one group. This group is chosen from a substitute group that contains an ether type displacement group. 5. Organic-inorganic compounding according to claim 1, in which at least one substitute group This category was chosen from the substitutes containing alkyl substitutes, ethyl succinate substitutes, ionic cat-type substitutes, anionic substitutes, and their mixtures. Among these 6. The organic-inorganic compound according to claim 1, of which the substituted starch is Hydroxyethylened, hydroxypropylated, or acetylated 7. Organic-inorganic compounding according to claim 1, which at least one substitute group This group was chosen in such a way that the substituted starch is film-forming and hydrophobic in the way that the substituted starch is Instead, this is a film on the inorganic cycle that is combined with water. 8. The organic-inorganic compound according to claim 1, from which this substituted starch was Is a polymer film, oozing through 9. Organic-inorganic compounding compound according to claim 1, which at least one substitute group The group and degree of displacement are selected in such a way that the percentage by weight of solids at a viscosity of 1000 cps is at least 4%. 0. Organic-inorganic compounding according to claim 9, which replaces at least One group and degree of displacement are selected in such a way that the percentage by weight of the solids at a viscosity of 1000 cps and temperature of 150 degrees Fahrenheit ranges from 9 percent to 43 percent. 1. Organic-inorganic compound according to claim 9, which replaces at least One of these groups is the hydroxypropyl group. And the degree of this override is chosen in a percentage manner The weight of solids at a viscosity of 1000 cps and temperatures of 150 degrees Fahrenheit ranged from 14 percent to 20 percent. 2. Organic-inorganic compounding according to claim 11, which replaces at least One of these groups is the hydroxyethyl group. And the degree of this override is chosen in a percentage manner by The weight of solids at a viscosity of 1000 cps and temperatures of 150 degrees Fahrenheit ranged from 17 percent to 30 percent. 3. Organic-inorganic compound according to claim 12, whose degree of displacement The hydroxyethyl group was selected in such a way that the percentage by weight of the solids at a viscosity of 1000 cps and temperatures of 150 degrees Fahrenheit ranged from 17 percent to 21 percent. 4. Organic-inorganic compound according to claim 12, whose degree of displacement is less than 0.3 1. 5.Organic-inorganic compound according to claim 12, whose displacement level is less than 6 percent by weight 1. 6. Organic-inorganic compound according to claim 12, whose degree of displacement Are chosen in the range from 1 to 3 percent by weight 1 7. Organic-inorganic compound according to claim 1, whose starch was replaced At least some components include amylopectin 1. 8. The organic-inorganic compound according to claim 17, whose starch has been replaced Is predominantly amylopectin 1 9. Organic-inorganic compound according to claim 1, whose starch has been replaced Almost all of them will dissolve and form film 2 polymers. 0. The organic-inorganic compound according to claim 1, where the substituted starch is Corn Starch, Acid-Thin, Hydrophobic Modified 2 1. The organic-inorganic compound according to claim 1, in which the starch has been replaced Is an acid-thin starch, and at least one of these is a hydroxypropyl group 2. 2. Organic-inorganic compound according to claim 21, whose degree of displacement Are chosen in the range from 1.5 to 2.5% by weight of hydroxypropyl 2 3. The organic-inorganic compound according to claim 1, the substituted starch It is corn starch, acetylated wax type, acid-thin 2. 4. Organic-inorganic compound according to claim 1, which starch content This was not more than 2% by weight of the displaced starch and the inorganic cycle 2. 5. Organic-inorganic compound according to claim 1, which is supplemented. With fibers distributed over most of the organic-inorganic composites 2 6.Organic-inorganic compound according to claim 25, where this fiber is glass fiber 2. 7. Organic-inorganic compound according to claim 1, which is supplemented. With the selected cellulose ether additive in such a way that the Synergistic bend 2 8. Organic-inorganic compound according to claim 1, which cellulose ether Selected from the cellulose ether group consisting of hydroxypropyl methylcellulose, methyl cellulose, hydroxyethyl methyl cellulose, hydroxyethyl cellulose, hydroxyethyl cellulose, hydroxyethyl cellulose, hydroxyethyl cellulose, hydroxyethyl cellulose, and hydroxyethyl cellulose. Dogxypropyl cellulose, ionic cellulose catalyst, carboxymethylcellulose and a mix of them 2 9. Organic-inorganic compound according to claim 1, which cellulose ether is Hydroxypropyl methylcellulose 3 0. Method of preparation of workpiece organic-inorganic composites by means of processes that have a range Of the mixing temperature, this method includes; Selection of substituted starch with degree of substitution, degree of polymerization and group Replace at least one group, such that the substituted starch is insoluble in water in the mixing temperature range; Mixing of displaced starch, inorganic cycle and water in a continuous process at temperature Within the range of mixing temperatures; The occurrence of a composite workpiece; Making at least part of the inorganic cycle as water; Raising the temperature above the mixing temperature range, where the displaced starch dissolves in water At least some; And the stabilization and drying of the workpiece in such a way that the displaced starch formed It is a continuous polymer film inside the workpiece.