DE175794C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

Vr 175,794 CLASS Mp. GROUP

containing preparations.

Patented in the German Empire on November 4, 1903.

Becomes protalbinic or lysalbinate sodium in the amount equivalent to the sodium content Silver nitrate added,. this creates sparingly soluble protalbine or. lysalbic acid silver, which goes back into solution with potash or caustic soda. In this solution is the silver not in a so-called "organic bond", but as colloidal silver hydroxide or Contain silver oxide. In the treatise

ίο by C. P a a 1 (Ber. d. D. formerly Ges. XXXV [1902], p. 2206) the facts and reasons are given which lead to this view of the Force reaction process, after which the heavy metal salts of protalbic and lysalbic acid by fixed caustic alkalis in heavy metal hydroxide and protalbine or. lysalbic acid Alkali are broken down, but the former as a result of a specific effect of the both protein cleavage products are not deposited in an insoluble manner, but remain colloidally dissolved.

It has now been found that not only

Hydroxides and oxides of heavy metals with the help of protalbine- respectively. lysalbic acid Alkali can be obtained in colloidal form, but that one can do so by simple reactions from the colloidal hydroxides and from the heavy metal salts of the two protein cleavage. products also include heavy metal salts in colloidal solution as well as in solid, colloidal water-soluble Can gain form.

Let us take here as examples the representation of the previously unknown in colloidal form Silver carbonates and the tertiary silver phosphate as well as the colloidal chlorine, bromine and Iodized silver.

i. Representation of colloidal Si 1 b ercarbο ηat with protalbine and sodium lysalbinate.

If sodium protalbinic or lysalbinic acid is added to the equivalent amount of silver nitrate, so falls protalbin- respectively. lysalbinate from. The precipitates are filtered off (Washing out is not necessary) and the silver salts suspended in water are added with soda solution, solution occurs with the formation of a milky liquid that contains the shows the typical appearance of a colloidal solution (heating to 50 to 60 ° accelerates the Solution process). The liquid thus obtained is opaque in incident light like milk, completely clear in transmitted light and transparent in a thin layer of yellow color. If these solutions are freed from excess soda by dialysis against water in the dark and protected from light in a vacuum brought to dryness at a low temperature (first at 50 to 60 °, last at 30 to 40 °), this results in dark, shiny lamellae that are easily soluble in water. As a result of a slight reducing effect of the organic component cannot be avoided, that some colloidal silver is formed during dialysis and evaporation, hence the dark coloring of the preparations in the solid state. However, their aqueous solutions show the milky texture described above. The solid preparations, combined with acid, develop Carbon dioxide. Silver and carbon dioxide determinations provided values that

correspond exactly to the composition of the excess carbonate.

The shown in the manner indicated above

Provided products of colloidal silver carbonate with protalbin- respectively. lysalbic acid Sodium show the following properties in aqueous solution:

As mentioned, acids decompose them with the evolution of carbonic acid. on

ίο The addition of ammonia makes the solution clear and transparent, the milky appearance disappears, now there is a real solution formed from silver carbonate ammonia; further evidence of the colloid nature of the Preparations.

The solutions of colloidal silver carbonate are against aqueous solutions of neutral salts very resistant due to the protective effect of the organic component. Warmed up you z. B. with saline solution, no precipitation occurs, but it does form by interaction colloidal silver chlorine and sodium carbonate.

Solid preparations, from. silver protalbinate, contain about 15 percent Silver plus the equivalent amount of carbonic acid, that of lysalbinic silver approximately 25 percent silver in the form of colloidal silver carbonate.

In order to obtain preparations with an even higher content of colloidal silver carbonate, solutions of the same, as they are obtained by the method described above, silver nitrate is added again after dialysis, as long as a precipitate is formed. The precipitate is a mixture of colloidal silver carbonate with protalbinic acid respectively lysalbic acid silver. If this precipitate is dissolved after it has been filtered off, again in soda solution, so the protalbinbezw. the lysalbic acid silver again in silver carbonate and protalbin- respectively. sodium lysalbinate, and now all of the Previously existing and newly formed silver carbonate again in colloidal solution. After cleaning by dialysis and Evaporation in vacuo also gives these preparations in solid, water-soluble form. A The preparation prepared in this way by means of sodium protalbinate contains 30 percent Silver and the corresponding amount of carbonic acid, the same with lysalbinic acid Sodium 38 percent silver.

2. Representation of colloidal silver phosphate with protalbine- and sodium lysalbinate.

The aqueous solution of 1 part protalbine-

or sodium lysalbinate is mixed with 0.4 parts of sodium phosphate in concentrated aqueous solution and a solution of 1.4 parts of silver nitrate of the same type is then added. A yellow precipitate is formed, which is brought into a colloidal solution by the gradual addition of concentrated aqueous sodium phosphate. (You can also add a larger excess of Na ₂ HPO ₁ to the protalbic or lysalbic acid sodium solution in advance and only then enter the amount / igiVOg solution corresponding to the desired percentage of Ag _s P O _{4.) Gentle heating to 50 to 60 °} promotes the solution. The excess Na ₂ HPO2 and NaN0 _{s are} removed by dialysis against water and the dialyzed liquid is evaporated at a moderate temperature in a vacuum. In this way, the colloidal silver phosphate with sodium protalbinic or lysalbinic acid is obtained in the form of yellow-brown, translucent lamellae, which dissolve easily in water, particularly quickly when heated gently.

When using the proportions given above, preparations are obtained which contain 50 percent Ag _s PO _4. The solutions appear opaque milky in incident light, clear in transmitted light and transparent in a thin layer with a light yellow-brown color. The solutions are broken down by mineral acids. When ammonia is added, the colloidal load disappears immediately. Creativity of the solution, it becomes almost colorless and opaque, since a real solution of silver phosphate-ammonia has now been created. Solutions of colloidal Ag _s PO ₁ prove to be very resistant to electrolytes (neutral salts), even when exposed to heat.

3. Representation of colloidal silver halides with protalbine- and sodium lysalbinate.

The preparation of the colloidal silver halides succeeds in an excellent way if one first adds silver nitrate to the protalbic or lysalbic acid and dissolves the resulting silver precipitate with caustic soda to form colloidal silver oxide. If the halogen alkali is now added in excess in concentrated aqueous solution and heated very gently, the colloidally dissolved Ag ₂ O is immediately converted quantitatively with the halogen alkali, with the formation of colloidal solutions of halogen silver.

By dialysis against water, the colloidal solutions obtained in this way become halogenated silver cleaned, with excess halogen alkali and caustic alkali diffusing away. the dialyzed liquids are then gently evaporated in vacuo Brought dry.

Since you have it in your hand, by alternately adding silver nitrate and caustic soda to protalbin- respectively. sodium lysalbinate

to present very high-percentage solutions of colloidal silver oxide (see C. P a a 1, Ber. formerly Ges. XXXV, p. 2206), so can accordingly by reaction with haloalkali also win very high-percentage preparations of colloidal halogen silver.

a) Colloidal silver chlorine.

Preparations with 30 to 65 percent colloidal silver chloride are obtained in the manner indicated above, depending on the content of colloidal Ag ₂ O in the starting solution. The solutions of colloidal silver chlorine are light-sensitive. In the solid state, the preparations are light gray grains or lamellae that easily dissolve in water. In incident light, these solutions appear opaque and milky, in transmitted light they appear clear and yellow-brown in a thin layer.

The fully dialyzed solutions are not or only incompletely precipitated by acetic acid. Mineral acids precipitate analogously to the preparations of colloidal silver and gold (C. P a al,. Ber. Chem Ges. XXXV [1902],

S. 2224, 2236) high percentage mixtures of colloidal silver chlorine with free Protalbinbezw. Lysalbinic acid, which, like the corresponding gold and silver precipitations, is not in water, but in dilute, caustic solutions and dissolve carbonic acid alkalis. Especially when using lysalbic acid Alkali-represented colloidal silver chlorine solutions can be obtained by precipitation with hydrochloric acid Precipitates of colloidal silver chloride received, which were in the dry state Contains 70 to 80 percent silver chlorine. These precipitations are also more solid, drier Form soluble in alkali, in this state they form light gray-violet grains. Will this high-percentage precipitates dissolved again in a little dilute sodium hydroxide solution or soda, dialyzed and evaporated in vacuo, very high percentage, water-soluble, colloidal is obtained Silver chlorine preparations. The colloidal solution & i are against electrolytes (neutral salts) quite consistent ..

il are using colloidal silver chloride solutions If ammonia and cyanide are added, the colloidal character of the solution disappears immediately, it becomes clear and transparent, since there is now a real solution of chlorosilver with ammonia respectively Potassium cyan originated.

b) Colloidal silver bromide.

Is produced like the chlorosilver preparation and shows similar properties to this one. Colloidal silver bromide preparations with sodium protalbic and lysalbic acid are even more stable than the corresponding chlorine silver products. In solid condition the silver bromide preparations appear as almost white, somewhat grayish lamellae and Granules that easily dissolve in water. These solutions are in the striking light milky, clear in a thin layer in transmitted light and with a greenish-yellow color transparent.

Precipitation with hydrobromic acid produces high-percentage preparations of colloidal Obtained silver bromide with free protalbic and lysalbic acid, which do not dissolve in water, on the other hand, easily dissolve in alkali. Preparations of colloidal silver bromide with protalbic acid Sodium directly represented, contains 40 percent silver bromide, those with lysalbinic acid Sodium over 70 percent silver bromide.

c) Colloidal iodized silver.

Colloidal silver iodine preparations are the most resistant. You will be in shape yellow, water-soluble grains and leaflets. The solutions appear in the reflective Milky yellowish light, clear and deep yellow colored in transmitted light. The colloidal solutions are made by addition by ammonia, since this iodized silver hardly dissolves, not changed either; with potassium cyan on the other hand, a colorless, transparent real solution is created immediately. By precipitation with Hydrogen iodide is made from the products of colloidal silver iodine with sodium lysalbinate a precipitate is obtained which, when dried, forms yellow-brownish granules, easily dissolves in Alkali dissolves and contains 95 percent iodized silver.

In the reports of the German chem. Ges. Vol. XXXV, p. 2212, it is stated that by the interaction of certain neutral salts with solutions of colloidal silver oxide form the relevant colloidal solutions of the silver salts. With this brief statement there was no process yet, the colloidal silver salts in solid, permanent form to represent. To prove this, it should be pointed out that solutions of the colloidal Do not allow lead salts to isolate the colloidal salts in solid, durable form. But not only with the lead salts it depends on the properties and the nature of the colloidal ones Salt solutions, whether they can be produced in a durable form, but also with the Colloidal silver salt solutions other than those described in the present invention Way to be won. Lottermoser z. B. found that his colloidal silver solutions by the action of the free halogens colloidal solutions of Form halogen silver; from the solutions obtained in this way, however, the silver salts can be colloidal form cannot be obtained because they gelatinize easily and are not unchanged let it evaporate.

In the above treatise in the

Nothing has been said about the properties of the colloidal silver salt solutions; it it was therefore impossible to foresee whether these solutions would give rise to the salts without decomposition in solid, more durable shape would have shown. Also that information was not the one here in Claimed modification of the method can be found, after which one the Can enrich the content of the compounds in colloidal silver salt.

Furthermore, a method is known according to which certain by double conversion Mercury salts with the halogen salts of alkalis in the presence of protein products Mercury salts can be obtained in colloidal form (see American patents 740855 and 742429). This procedure, which is only a modification of the known Method of presenting colloidal substances is essentially different from that here .described differently, in which the heavy metal salts of certain protein breakdown products come into use. As is well known, protein breakdown products have the property of being substances in colloidal form to get to a very high degree. In the present case, in which they even are in a certain proportion to the metal salt used, is their effect a particularly pronounced one, in that it even succeeds in displaying preparations which up to Contains 90 percent silver salt in colloidal form. The preparations obtained are without additional. clearly soluble in water. The products of the known process contain only one very small percentage of metal salt, they are only slightly soluble in alkaline water and also contain somewhat insoluble products. The diversity of. both procedure is to the application essentially different protein substances.

Claims (2)

Patent Claims: 1. Process for the preparation of solid, water-soluble, silver salts in colloidal Form containing preparations, consisting in that the conversion of the silver salts of protalbic or lysalbic acid respectively of the colloidal silver oxide obtained by dissolving these salts in alkali with the solutions of neutral salts obtained solutions of the colloidal silver salts after previous dialysis evaporated in vacuo. 2. Embodiment of the method according to claim 1, consisting in that one after dialysis of the solutions containing the colloidal silver salts, these again mixed with silver nitrate and repeating the process, the content which enriches solutions in colloidal silver salts.