CH87382A - Process for the production of particularly durable colloidal solutions. - Google Patents

Description

  

  Process for the production of particularly durable colloidal solutions. It is known that mechanically sufficiently comminuted solid substances can be converted into colloidal solutions by loading with solutions of certain compounds. It is known, for example, that kaolin is largely converted into a hydrosol with small amounts of alkali solutions. On the other hand, it is also known that additional electrolytes or organic non-electrolytes can significantly increase the shelf life of brine that is already available. Such substances of the latter type, which are usually referred to as protective colloids, include: protein, gelatine, gum arabic, agar, isinglass, etc.



  It has now been found that aqueous solutions of cherry gum have the two effects just mentioned, namely to colloidalize mechanically finely comminuted solid substances and stabilize already existing brine, to a particularly excellent extent. The colloidal solutions obtained show a very outstanding durability not only with regard to the settling speed of their particles, but also with regard to their resistance to flocculating agents.



  Chemical substances that can be colloidalized according to the present process include, for example, the solid elements, for example sulfur, selenium, tellurium, carbon in various modifications, in particular as soot, graphite, blood charcoal, animal charcoal, silicon, titanium, nickel, Molybdenum or chromium. There are also chemical compounds; such as barium sulfate, lead sulfate, white lead, iron oxides, Chromosy de, metal sulfides and the like in question.



  The substances are expediently used in extremely finely ground or amorphous or small crystalline states.



  In some cases, the present process does not initially lead to fully colloidal systems. Rather, in addition to the desired ultra-microscopic particles, the brines produced also contain coarser particles that are already visible under the microscope or with the naked eye. This incomplete colloidalization occurs, for example, with substances which have not been mechanically comminuted to a sufficient extent prior to the treatment with cherry gum.



  In such cases it is sufficient to let this brine, which still contains larger particles, stand still for some time, with those larger particles settling on the ground. The excess liquid is then separated from the sediment, for example by decanting. If the settling time is long enough, the liquid obtained contains ultimately ultramicroscopic particles. The separation of the ultramicrons from the coarser particles can of course also be carried out by means of centrifugation or filtration.



  In this embodiment, the present method can also be used to largely or completely separate the components of a substance mixture from one another. Since different substances can be colloidalized with different degrees of ease, by choosing suitable amounts of cherry gum and by choosing suitable mixing times, one substance is already converted into the colloidal state, while, for example, a second component of the original substance mixture is not yet colloidal .

    The subsequent sedimentation process, or the subsequent centrifugation or filtration, then simultaneously with the separation of the colloidal particles from the non-colloidal ones also leads to a separation of the components of the original mixture.



  Example 1: Iron oxide, which is to be used as a coloring agent, is mixed with about 3% cherry green which has previously been brought into an aqueous solution, and both are intimately mixed with the required amount of water. If you stop stirring, the coarser particles still present in the rabbit will settle on the ground over the course of some time and can be separated from the suspension above. This residue can possibly be ground again and treated again with cherry gum solution.

   The colloid solution obtained can then be used, for example, as a paint.



  Example 2: The hydrosols of elemental platinum, which have been produced by electrical atomization, for example by the Bredig process, have a relatively short shelf life. If you mix such a sol, which. Contains 0.02% platinum, with so much cherry gum solution that the sol then contains 0.05-0.5% cherry gum, or if the corresponding amount of cherry gum dissolves in this sol, the result is brine with a significantly superior shelf life. Naturally, the electrical atomization can be carried out from the outset in a diluted cherry gum solution instead of in pure water.

 

Claims (1)

PATENT CLAIM: Process for the production of particularly long-lasting colloidal solutions, characterized by the fact that cherry gum is used as an aid. SUBClaims: 1. Method according to claim, characterized in that the substances to be colloidalized are intimately mixed with aqueous solutions of cherry gum. 2. The method according to claim, characterized in that the substances to be colloidalized are intimately mixed in mechanically widely comminuted states with aqueous solutions of cherry gum. 3. Process according to patent claim, characterized in that the substances to be olloidized are first obtained in a known manner as hydrosols and then cherry gum is added. 4th Process according to patent claim, characterized in that the colloidalizing substances are first obtained in a known manner as hydrosols and mill gum solutions are then added.