DE522675C - Process for the mechanical dispersion of compounds insoluble in the dispersant in question in the presence of peptizers - Google Patents

Description

Process for the mechanical dispersion of in the dispersant in question insoluble compounds in the presence of peptizers It is known that in the Colloidization of substances through partial crushing. for example with help the colloid mill. Additives, the so-called peptizers, play a major role. In many cases, a collision succeeds without the addition of such peptizers at all not, in all cases the colloidization is achieved by the addition of these agents much easier and faster. According to P. P. v. As is well known, Wle imarn presents itself peptization as a severely slowed down dissolution process of the dispersion precipitates According to this researcher, the following three conditions apply to this simple peptization: I. The solid crystalline substance must consist of crystals of such small dimensions exist in which the physical and chemical properties already have functions the size of the crystalline grain.

2. The peptizing substance (peptizer) must have the ability with a sufficiently high concentration in the solution, a stable, soluble, chemical one Connection with the substance which is peptized to result. If it is sufficiently smaller Concentration of the peptizer, however, does not have to result in the above-mentioned compound.

3. The medium in which the peptization process takes place is allowed in the absence of the peptizer in it, the substance to be peptized is practically cooked not solve.

Lottermoser regards this as opposed to this notion of Weimarn the peptization phenomena from the standpoint of ionic reactions and gives the following Conditions for the peptization process to take place effectively: I. Bring one an ion (or a related ion) in a higher concentration for an amorphous substance, When this substance is able to dissolve itself, it is converted into the Hydrosol transforms.

2. Condition for the success of this reaction is that the substance is in a state that it is due to the addition of the ion in the peptization is capable of molecular complex reduction or swelling, d. H. it must have a very specific physical constitution.

In contrast, we point out that peptization phenomena can also take place in solvents that have practically no electrolytic ability Have dissociations and, on the other hand, an oozing process in the ordinary sense of the previous tes in the peptization does not take place at all.

So much for the previous theory, according to which every body is peptized can be converted into a colloidal solution if you use the inert solvent and has found the suitable peptizer for it. The one for every substance into consideration coming peptizers have so far only been purely empirical found by repeated tests with various additives which seem to be the most favorable have been selected. A general instruction on which Substances to be used as peptizers have not yet been given.

Mention should also be made of the work of A. M ü 11 e r, the 1908 (Kolloidzeitschrift 2, G [i 908j) has concluded from his investigations that the effect of the entry is based on the fact that a trace of salt of the metals in question is formed. N1 over 11 He succeeded in peptizing many metals by adding a small amount of salt of the element concerned. So he peptized z. B. Thorium and Zircon by means of small Amounts of salts. v. Hahn (Fr.Vinzenz. V. H a h n: »About the production and stability colloidal solutions of organic substances «, special edition of the chemical collection and chemical-technical lectures, vol. 26, Stuttgart, 1922, page I3) believes own investigations do not speak of a specific effect of these salts can. v. H a h n particularly points out (loc. Cit. Page 14) that only the Investigations A. Müller s (Association of the German Chemical Society 39, 2857 - 1906-) the theory of AN e i m a r n s confirms that the peptizer only the property determines the solubility of the substances to be dispersed, but not should have a chemical relationship to it.

The new invention now shows that this theory is not generally valid is, and that it is contrary to the previous views of Müller. Weimarns and Hahn but it is possible to use peptizers because of their chemical relationship with the to find the substance to be peptized.

A systematic investigation has now succeeded in establishing a law find out by which the suitability of a peptizer for the transport of the Colloidization of a certain substance clearly appears. The new Knowledge leads to a technical rule that makes it possible for any substance to select the suitable peptizer according to plan and with its help the one for colloidization certain compounds in a more perfect and simple way in the colloids State than this has been achieved so far, and also substances that have so far could not be converted into the colloidal state at all, into the highly colloid To gain shape.

The invention was based on an experiment in which the colloidization of lead arsenate using another lead salt, namely, of lead antimony, which was a surprisingly complete and easy success as a peptizer is. A second attempt followed, in which lead arsenate was present from tin arsenate, i.e. a peptizer with an identical anion, to the colloid State was transferred. This experiment also showed a remarkably favorable one Result. Now the further question arose as to whether this was due to these preliminary tests law made probable in the correspondence between anion and Cation of the peptizer with the anion or cation of the substance to be dispersed is exhausted, and furthermore, whether there is any similarity or relationship would be useful between the other ions of the compounds. With the extraordinary numerous attempts that have been made to clear up this question have emerged then it became clear that there are secure relationships in this respect too, which in the periodicities shown by the curve of the equivalent volumes for Expression. As a result, this latter law is in the Came to the fore. since it has been shown that the choice of suitable peptizers in the first place can be derived dominant rule.

To illustrate these relationships, let us use the relationship as an example the compound to be dispersed: lead arsenate to the peptizers lead antimonate and tin arsenate on the basis of those shown in the drawing and from 0. S c h m i d t constructed curve of equivalent volumes can be examined. Are you looking for the for the anions characteristic elements As and Sb of the non-identical ions of the two compounds lead arsenate and lead antimoniate on this curve, see above shows that the equivalent volumes differ only a little by the equivalent volume of antimony is slightly larger than that of arsenic. the both elements are also on different branches of the curves, which but are rectified in that they represent both descending branches of the curve. The same applies to the non-identical ions of the two compounds lead arsenate and tin arsenate.

The equivalent volumes of the two elements lead and tin are almost same, both items are on different. but aligned, namely descending branches of the curve of the equivalent volumiua.

With further experimental research this question could be established be that this lawfulness in the relationship between the ions the compound to be dispersed and the peptizer have a very general validity comes, and compared to the examples treated above still in the sense to be extended is that also such pentisers, which one the anion or cation of the Substance to be dispersed in the equivalent volume relatively close anion or contain a cation. present themselves as suitable, which on a ulld the same The curve of the equivalent volumes have their place.

The relationships between two elements. which has a similar equivalent volume and on the upper branch of the curve of the equivalent volumes or on different, but unidirectional branches of this curve (in both cases ascending or in in both cases, descending branches) have their place, is referred to in the following as »Usage «In the sense of the periodicities expressed by the curve of equivalent volumes called "close to each other". The same name is used for these relationships applied between the ones. Are complex ions such as B. AsO4 or Sb4, that element is to be regarded as decisive for these relationships. which gives the lon its characteristic stamp, e.g. B. in the remains of the Oxygen acid the element associated with oxygen, e.g. B. in AsO4 the element As, in SbO4 the element Sb.

This term »closeness and kinship in the sense of through the curve of the atomic volumes given periodicities ”can thus be sharply separated on the relationship of the elements in the ordinary sense of how they express themselves finds z. B. in the group of alkali metals, halogens and the like.

From what has been explained so far, the technical rule has emerged, for the mechanical dispersion of insoluble in the dispersant in question Compounds so choose peptizer compounds, either their anion or cation the anion or cation of the compound to be dispersed in the sense of the curve of the equivalent volumes is related to the expressed periodicities. By scheduled Experimental research then found that this rule was another one further determination is required in order to reliably select the cheapest in all cases Enable peptizers. It has shown. that the nature of the other lons in the peptizer of the counterion is not without importance that rather also this counterion to the anion or cation of the substance to be dispersed in should have a certain relationship. This relationship can be that the Counterion in the peptizer with the anion or cation of the compound to be dispersed is identical, which applies to the examples given above.

This relationship can also be due to the fact that the counterion is in the peptizer the anion or cation of the compound to be dispersed in the sense of the curve of the equivalent volumes is close to the expressed periodicities, or finally, that it is related to it according to its position in the periodic system of the elements is.

The relationships between elements determined by the periodicities the curve of equivalent volumes expressed come in general also in the curve of the atomic volumes (E. A. Hoffmann. Textbook of organic chemistry ", Vieweg & Sohn, Braunschweig, 2nd ed.

Page 387). This curve can therefore also be used for orientation can be used. In the few points in which there is a difference in the periodicities, such as B. in the position of lead and molybdenum, the according to the atomic volume curve on differently directed branches (As on an ascending, Molybdenum on a descending branch), according to the curve of the equivalent volumes but both on a downward path, the latter curve is decisive. Indeed it succeeds z. B. lead arsenate using molybdenum arsenate as a peptizer to be converted into the colloidal state.

According to the present invention, e.g. B. for colloidization used by lead arsenate: lead stunate, lead antimoniate, tin arsenate or antimony arsenate. In order to convert mercury arsenate into the colloidal state, one uses as Peptizer, for example, potassium stannate or antimony arsenate. Also come as Peptizers for zirconium arsenate, titanium arsenate or antimony arsenate in question. To the For the purposes of the invention, lead tannate is used for colloidization of black lead or lead alumina. Calcium arsenate can be colloidized with titanium arsenate, for example.

It is appropriate to use a compound as a peptizer, which has the same sense of electrical charge as the compound to be dispersed.

It is known that practically every colloid and also every suspension has a certain sense of charge. Iron hydroxide can e.g. B. positive or negative be charged. It is therefore expedient in the sense of the law described above with an aluminum, chromium, manganese, cobalt, nickel, molybdenum, ruthenium, Rhodium, tungsten, osmium. {ridium peptizer that is positive or is negative, depending on one a positive or negative iron hydroxide sol wants to peptize. To stay with the examples given, one becomes in the example 9. To peptize the silver bromide, choose a tin bromur that is negative, this was done in such a way that the bromine was in excess in the formation of the tin bromine was.

Particularly favorable results are achieved if you use several of the simultaneously applied peptizers selected according to the invention. It has furthermore shown that the effectiveness of the peptizers is increased significantly if they are used in the colloidal state for dispersion.

The colloidization is achieved through the application of these peptizers conveyed in a way that allows the use of the colloid mill on one Limit minimum. In many cases, vigorous mixing in one is sufficient Ordinary agitator to move the substances in the presence of the suitable according to the invention To convert peptizers into the colloidal state. Of course it depends energy to be expended and the speed of colloidization by nature of the compounds to be dispersed. Connections which elements with high Containing equivalent volumes are more difficult to convert into the colloidal state than those which contain elements with a lower equivalent volume.

One is therefore taking compounds which are for a specific purpose have the same suitability for the conversion into the colloidal state those Select which contain the elements with the smallest equivalent volume.

D o u t o u p e p i e l e I. IOOO g become lead arsenate with 200 g of a 10/0 colloidal antimony arsenate solution in small portions rubbed in.

At first a firm, rubber-like, stringy mass forms. Now you add so much water slowly that an intimate mechanical mixing of Liquid and mechanical substance becomes possible. This trituration can be in any suitable milling device. Of course, the dispersion can can also be made in the presence of protective colloids, but these are not absolutely necessary. The product obtained in this way is a cloudy colloid Solution of lead arsenic.

2. 100 g of lead arsenic are mixed with 20 g of an antimony arsenic gel and as much water as is necessary. an intimate mechanical and vigorous trituration to be able to achieve ground. The resulting product is the same as that described under I.

3. 100 g of solid lead arsenate are mixed with 100 g of a woody aqueous solution Solution of arsenic molybdic acid triturated, then ground with as much water as is necessary for thorough work-through. Here, too, excellent peptization occurs a.

4. 100 g of lead arsenic are added to 400 g of a 100% suspension of lead stannate gel and as much water as is necessary for thorough processing, rubbed in until the desired peptization is achieved.

5. 1000 g of black lead are mixed with 400 g of a 10% semi-colloid Suspension of lead stannate gel "rubbed in" and then with the addition of water in installments Grind intimately in a suitable apparatus until a stable colloid Suspension has arisen.

6. 100 g of mercury arsenate are mixed with 200 g of a 10% antimony arsenate solution mixed and then ground further with the required amount of water. After short After a while, a colloidal suspension that no longer settles is created.

7. 1000g calcium arsenate, which is known to be particularly difficult to is colloidized, becomes with 200 g of a 10% titanium tartar arsenate solution colloid suspension by pasting in installments with the peptizer, adding Water reshaped to the required extent and thorough grinding.

8. Zirconium arsenate is exactly like calcium arsenate according to Example 7 treated; the peptization of the zirconium arsenate is much easier than that of calcium arsenate.

9. 100 g of freshly precipitated, washed silver bromide with a dry content of 10% are peptized with 2 cm3 of a 10% tin bromide solution.

Claims (3)

PATENT CLAIMS: I. Process for the mechanical dispersion of compounds insoluble in the dispersant in question in the presence of Peptizers, characterized in that a compound is chosen as the peptizer whose anion or cation is either the anion or the cation of the to be dispersed Connection in the sense of the periodicities expressed by the curve of equivalent volumes is close, where as a counterion in the peptizer with the anion or with the cation the compound to be dispersed identical or in the sense of the curve periodicities related to the equivalent volumes or related ion according to the periodic table is used. 2. The method according to claim 1, characterized by the simultaneous Use of two or more peptizers. 3. The method according to claim I and 2, characterized in that one a peptizer is used, which has the same sense of electrical charge like the compound to be dispersed.