DE648543C - Process for the separation of metals from the solutions of their salts - Google Patents

Description

Process for separating metals from solutions of their salts It is known to displace metals from their salt solutions with less noble metals and deposit. If metallic aluminum is used to deposit the metals, so it is necessary to @remove the oxide layer adhering to it, be it by suitable pretreatment of the aluminum to be added, save it by adding it of chemicals too. ' the solution itself, through which the oxide layer acts as a filler used aluminum is eliminated, so that @this. the more noble metals precipitate came.

It has now been found that with the help of this filling process it is possible to deposit the metals from the solutions in any desired To obtain grain size @ that one uses an aluminum powder for precipitation, its Grain size corresponds approximately to the grain size to be achieved of the metal to be precipitated. In @this way @es is e.g. B. possible iron and nickel deposits within an area of certain upper and lower limit values of the grain size by slow Entering aluminum of the corresponding grain size in. The salt solutions to win. The aluminum is activated in a known manner by pretreatment of the filler with activating agents - (e.g. Quiecksüberchloridlösung or diluted hydrochloric acid) or by adding an activating agent (e.g. ammonium or alkali chloride) to the salt solutions. , The aspired success, one by grain size classified precipitation of metals, n from their solutions by the addition of aluminum Corresponding grain size also occurs if, instead of activating the filling agent by adding chemicals the used aluminum with suitable metals, z. B. calcium alloyed, which are able to form a galvanic element with it.

Pulp: When performing the process, it is advisable to add the finely divided aluminum slowly and only in small amounts into the solution. The precipitation of the metal to be deposited, which corresponds to the grain size of the filler, caused by the activated aluminum, occurs all the faster, the more noble this metal is. In order to further accelerate the reaction in metals that are close to aluminum in the voltage series, it was recognized as beneficial to work at an elevated temperature. So it is beneficial with iron, nickel and Kadn-iium a temperature of e.g. B. about 9o ° to be adhered to, while with lead the best results between 4.o ° and 5o ° can be achieved. With the nobler ones, close to copper = - _the metals the concentration is deY @@ precipitating solution without influence. For the' nobler CIM, which is closer to aluminum talle is the yield of the fAin distributed M tall mostly within a certain concentration range, e.g. B. for nickel and iron between about 10 and about zoo g ferrous or nickel sulfate per liter is best.

Examples I. Preparation of Nickel Powder Zoo g are crystallized Nickel sulphate Ni S 0, I # 7 H., O dissolved to a liter of aqueous solution, which with 0.5 ccm of concentrated sulfuric acid is acidified. The solution is warmed to 20 ° C and after adding 10% of concentrated hydrochloric acid, 20 g of aluminum powder are added. The reaction sets in vigorously and comes to an end after half an hour Standstill. The liquid standing over the precipitated nickel powder was decanted and the precipitate first with a 10% sulfuric acid. and then with water washed, whereupon the precipitate is quickly air dried.

2. Production of iron powder 10 g of crystallized ferrous sulfate Fe SO, # 7 H O and 10 g of common salt are dissolved to form a solution which is slightly acidified with a few drops of sulfuric acid. The solution is heated to 90 ° C. and mixed with 10 g aluminum powder. Most of the metal powder initially floats on the surface, but then slowly goes under. The reaction takes place with evolution of hydrogen, whereby the liquid initially remains transparent. Then kick a cloudiness and at the same time the precipitation of iron powder. After 1 hour it will R -tion canceled, and the powder ., the eal, @ws ,, rd washed by decanting. if c last traces of aluminum removed "are supposed to be grounded, another treatment -ij @ lg with a 100% solo solution. That Powder obtained is quickly blown with air `tl-open to prevent oxidation. The sizes of the metal powder used and achieved are determined by a scale. which indicates the number of sieve holes per inch through which the powder will just pass. A powder. So No. 15 is coarser than powder No. 35.

When using aluminum with a grain size of 15 to 35 according to the above examples, metal powders are obtained that pass through a No. 15 sieve, but no longer through a No. 35 sieve. When using aluminum with a grain size of 35 to 60, powders were obtained which passed through sieve # 35, but no longer through sieve # 60. The grain size of the powder obtained is therefore always of the same order of magnitude as that of the aluminum powder used.

The aforementioned sieves for determining the grain size with 15, 35 or 60 sieve holes per inch have 35, 190 or 558 sieve holes per square centimeter on.

Claims (1)

PATEN TANSP RUCI-I Process for separating metals from the solutions of their salts with the aid of metallic aluminum with the addition of substances which dissolve an oxide layer adhering to the aluminum, characterized in that the aluminum is used in the corresponding grain size for the purpose of obtaining certain grain sizes of the metal to be precipitated will.