DE2900073A1 - Prepn. of alkylation deriv. of starch - by dry reaction with sodium hydroxide mono:hydrate followed by alkylation - Google Patents

Abstract

Starch derivs. are prepd. by (a) allowing NaOH, H2O, with grain size 0.3-0.01 mm., to act on native starch with a natural or slightly reduced water content, in a dry and finely divided state, for 1-20 mins. at 5-80 degrees C., followed by (b) alkylation. Use of large amts. of water or organic solvent is avoided. The starch does not become pasty. Starch derivs. are obtd. directly in powder form. The prods. are used as thickeners and bonding agents for aq. systems, in pharmaceutical prepns., as textile aids, and as paper size.

Description

Process for the production of starch derivatives by

Alkylation of alkali starch It is known that the substitution or alkylation of starch in a suspension of the starch in water can be made, the pH is to be adjusted so that a possible slight gelatinization of the starch occurs and the greatest possible implementation of the alkylating agent takes place.

It is also possible for the alkylation or substitution the starch in organic solvents such as lower alcohols or ketones. A breakdown of the starch, for example, with a low level of acidity or an esterification or etherification has already taken place in a vacuum with the exclusion of oxygen in dry, fluid state carried out, whereby by practically complete withdrawal of the water the treated starch derivatives were obtained in a non-gelatinized state.

The known methods have the disadvantage that relatively large Amounts of solvents or water are used and if necessary there is a risk of losing strength. The effort larger amounts Processing starch in a vacuum and in the absence of water is disproportionate great, also with regard to the dangers of a dust explosion.

The object of the present invention was to provide such a method To find the production of starch derivatives that do not have the disadvantages outlined above enter. In particular, the disadvantages caused by using it should be avoided larger amounts of water or organic solvents or the application are given by vacuum. In other places, the task was in the present to work as little as possible or practically without cash, to prevent gelatinization of the starch and directly from the native starch to it powdered starch derivatives.

According to the invention, this object was achieved by relying on native Starch with a natural or slightly reduced water content in dry and finely divided state initially for 1 to 20 minutes at temperatures between 5 and 800 C sodium hydroxide monohydrate with a grain size between 0.3 and 0.01 mm act and then the alkylation reaction in a manner known per se under the special conditions undertakes.

Application is a prerequisite for the method according to the invention a powdered non-caking starch that is practically only the natural one Has content of water. Of course, it can also be pre-dried, especially when in the alkylation stage additionally introduced water will. The starch to be used can be obtained from potatoes, tapioca roots, Corn, wheat or rice grain. In principle, all types of starch are suitable for the invention Procedure suitable.

The second essential reaction component is sodium hydroxide monohydrate. This must have a grain size between 0.3 and 0.01 mm, preferably between 0.08 and 0.01 mm. In the case of sodium hydroxide monohydrate, also caustic soda hydrate or caustic soda monohydrate, it is a well-known compound that on cooling rollers from the liquid hydrate by crushing the initially coarse Prills or scales can be obtained. The sodium hydroxide monohydrate fraction with the specified grain size can also be produced by cooling the liquid Sodium hydroxide monohydrate under high shear conditions such as those found in kneaders can be generated. This arises depending on the kneading or shearing speed and cooling a more or less fine-grained product.

In itself, the water content is clear from the name of the compound given. An excess of water which does not exceed about 10 percent by weight Should, however, nothing harms if the grain structure is retained.

It is also possible to lower the water content a bit, like this that a mixture of sodium hydroxide and sodium hydroxide monohydrate is present. Included However, the sodium hydroxide content must not be too high, as this leads to dust formation and can cause irritation of the respiratory tract.

The production of the reaction product from sodium hydroxide and starch (i.e. the alkali strength) takes place in a dry, turbulent mixing process. This can be caused by common, strongly whirling aggregates will. High-speed mixers (turbulence mixers) are suitable as such. Included the grain structure of the starch is not changed. The amount of sodium hydroxide used on starch, i.e. in the present case on native starch, should be at least 0.2 % and not exceed 10% by weight. In general, one sets 0.5 to 5 percent by weight of sodium hydroxide.

As a further reaction partner for the substitution respectively The so-called alkylation of the alkali starch produced as an intermediate are suitable G salt (sodium salt of chloroacetic acid), acetic anhydride, epichlorohydrin, methyl chloride, Allyl chloride, glycidyltrimethylammonium chloride, - chlorohydroxypropyltrimethylammonium chloride or analogous substitution agents. Preferred alkylating agents are alkylene oxides, such as, in particular, ethylene oxide, propylene oxide and butylene oxide. In this implementation a particularly high level of alkalinization of the starch is not required. Also needs the Temperature should only be moderately increased (approx. 250 C), but should not exceed 90 C. Furthermore, it is expedient to exclude air during the alkylation and to work under nitrogen or other inert gases.

The starch derivatives that can be prepared according to the invention are to products known per se. They can be used as thickeners and adhesives for aqueous Systems are used. They are also used in pharmaceutical preparations or possible as a textile auxiliary. Depending on the substituent and degree of substitution are they directly soluble in water or can be brought into solution via gelatinization in water.

Example 1 In a so-called turbulence mixer, 20 kg became more commercially available Potato starch (18% water content) with 870 g of fine-crystalline sodium hydroxide hydrate a particle size between 0.02 and 0.04 mm mixed vigorously for four minutes.

After this time the alkalization of the starch was finished and that Reaction product was transferred to a slowly running stirred vessel and shut off of oxygen at 3110 C within 3 hours with 3.9 kg of propylene oxide. It was then held at about 30 to 320 ° C. for a further 12 hours.

The powdery product was added in 5% aqueous stirring Room temperature an apparent viscosity of 14,000 mPa.s (Brookfield viscometer).

Example 2 18.2 kg of commercial corn starch (9% water content) were obtained with 290 g caustic soda hydrate with a grain size between 0.02 and 0.05 in a turbulence mixer mixed for 3 minutes. Then 1.8 kg of water was added with further mixing sprayed on. The mixing time was a total of 10 minutes.

grooves. After transferring it to a slowly running stirred vessel, it was added Nitrogen mixed with 580 g of propylene oxide gas at 34 ° C within 30 minutes. The temperature was increased slowly after 4 hours until 700 ° C. was reached (6 hours). There was then a white, non-caking, powdery product before.

The hydroxypropyl starch obtained in this way was stirred in a 10% aqueous solution gelatinized at 90 ° C. for 5 minutes. The Brookfield viscosity was thereafter at 220 C 40,000 mPa.s.

The flow behavior of this aqueous solution also changed afterwards Storage for 4 weeks no.

Example 3 20 kg of commercial potato starch (water content 18 %) were in an intensive mixer with 870 g caustic soda hydrate with a grain size between Offset by 0.01 to 0.04 mm. After five minutes of mixing, 1.2 was added kg of powdered sodium monochloroacetate, which has a grain size of less than 0.2 mm had. The powdery, homogeneous mixture obtained was poured into a closed transferred with a slowly running stirrer equipped reactor and under nitrogen at 340 C within 3 hours with 1.0 kg of propylene oxide. Simultaneously 2 g of epichlorohydrin were fed in with the propylene oxide. After 3 hours it was the temperature increased slowly until it was 700 C after 6 hours.

It was a powdery reaction product obtained in 5% aqueous stirring after 1 day 25,000 mPa.s and in 2.5% solution 5,000 mPa.s after Brookfield (220 C) had.

Example 4 20 kg of commercial potato starch (water content 18 to were intensively in a turbulence mixer with 2.8 kg of powdered sodium monochlorac etat (grain size below 0.2 mm) and 1.4 kg of finely crystalline caustic soda monohydrate (Grain size between 0.01 and 0.03 mm) mixed.

In addition, 2.0 grams of epichlorohydrin was fed to the reacting mixture. After 15 minutes of mixing in the intensive mixer, a slow-running Stirrer equipped reactor transferred and the mixture 4 hours held at 70 to 750 C.

The powdery reaction product resulted in 5% aqueous stirring a viscosity of about 25,000 mPa.s according to BrookfeId (230 c).

Example 5 453 g of potato starch were added to a so-called Turbulenam mixer (Residual moisture 10%) with 73 g fine-grained caustic soda monohydrate (grain size between 0.01 and 0.03 mm) mixed intensively, then under nitrogen with 600 ml of liquefied Methyl chloride was added at 700 ° C. under pressure. After 3 hours there was excess Blown off methyl chloride and allowed to cool.

The methyl ether of starch, present as a white, neutral powder had 2,000 mPa.s. in a 10% solution. The solution was smooth and clear.

Example 6 In a turbulent mixer, 20 kg became more commercially available Potato starch with a residual moisture content of about 18% with 200 g of finely crystalline caustic soda monohydrate (Grain size between 0.02 and 0.05 mm) intensively mixed. Was in a stirred tank then 1.13 kg of a 50% strength aqueous chlorohydroxypropyltrimethylammonium chloride solution under nitrogen sprayed. The reaction mixture was heated to 50 to 600 C and 4 hours at leave this temperature.

The powdery product obtained was soluble in hot water and as cationic cterk product not suitable for paper fiber glue.

Example 7 in a turbulence mixer becomes 20 kg more commercially available Potato starch <10 7 residual moisture) with 580 g of finely crystallized caustic soda monohydrate (Grain size between Oß02 and 0.05 mm) offset. In an agitator tank was 835 g of ethylene chlorohydrin were sprayed in together with 805 g of water under nitrogen. The reaction mixture was then held at 25 ° C. for 24 hours.

The hydroxyethyl starch obtained could by boiling a 10 g aqueous suspension are gelatinized.

The solution obtained in this way had a viscosity of about 25 at 220.degree 000 mPa.s (Brookfield).

Claims (3)

Process for the production of starch derivatives by altylation of Alkali starch Patent claims: 1. Process for the preparation of derivatives of starch by reaction of alkali starch with alkylating agents, characterized in that you can rely on native starch with natural or slightly reduced water content in dry and finely divided state initially for 1 to 20 minutes at temperatures between 5 and 800 C sodium hydroxide monohydrate with a grain size between 0.3 and 0.01 mm can act and then in a known manner under the special Conditions the alkylation reaction takes place. 2. The method according to claim 1, characterized in that the Carries out an alkalization reaction in a high-speed mixer. 3. The method according to claim 1, characterized in that the Alkylation reaction with moderate agitation at elevated temperature with exclusion of atmospheric oxygen.