CS216100B1 - A method of separating the cation exchanger and anion exchanger from a mixture of these ion exchangers - Google Patents

Abstract

A method for the mutual separation of a corresponding cation exchange resin and anion exchange resin from their mixture, characterized in that the separation is carried out in a batch manner in a solution of an inorganic salt with a specific gravity less than the specific gravity of the cation exchange resin in the cationic cycle of this salt and greater than the specific gravity of the anion exchange resin in the anionic cycle of this salt, preferably in a saturated sodium chloride solution, in which both ion exchanges are separated according to their specific gravity.

Description

The present invention relates to the separation of a co-cation exchanger and an anion exchanger from a mixture of these ion exchangers, e.g.

For the preparation of high quality water with a specific resistance greater than 1 Mohm, conventional distilled or treated water may be used. reverse osmosis, further demineralisates on an ion exchange column containing a strongly acidic catheter in the H ⁺ -cycle and a strongly basic anion exchange in the OH-cycle, in the form of a so-called mixed bed in which the two ion exchangers are mixed together. The regeneration of the common types of these mixed ion exchangers is carried out after being washed away by a stream of water, since they are also consumed as a result; o. ati. Anion exchanger tends to be lighter. After regeneration, the two are mixed again. However, due to the specific gravity differences mentioned above, the intermixing is not perfect, in the case of the bottom flow operation, the layers are even separated and, therefore, so-called ion exchangers with the same or near sedimentation velocity in water are produced. The descent is achieved, for example, by the differences in the particle size of the two ion exchangers, more recently by the ion exchange resins _; g) such ion exchange resins having a not very different specific gravity; Although these bulk ion exchangers have excellent water-miscibility, they cannot be separated from each other in any known manner, in particular, they cannot be washed away by a stream of water. In some species, this does not work well in a manner applicable to other ion exchangers. For example, the mixed bulk ion exchange resin is poured over with 3% potassium hydroxide to regenerate the anion exchanger and convert the cation exchanger to the K @ ⁺ -cycle. The tin breaks the system sequence and ion exchangers can be washed away with water. For this reason, in some state-of-the-art devices for preparing high-quality water, cartridges and spent mixed ion exchange resin are simply discarded and replaced with fresh ones.

These drawbacks are eliminated by a method of separating the co-cation exchanger and the anion-exchanger from the composition according to the invention, which consists in that the separation is carried out in a batch process in an inorganic salt solution of specific gravity less than the specific gravity of cation exchanger. than the specific weight of the anion exchanger in the anionic cycle of the salt, preferably in a saturated sodium chloride solution, in which the two ion exchangers are separated by specific weights, whereupon both ion exchangers are mechanically separated and recovered in a conventional manner.

The advantages of the invention are particularly economical. The separation process is technically easy to carry out, does not require any special equipment, and allows one set of mixed ion exchangers to be regenerated and reused multiple times. In addition, when separating using a saturated sodium chloride solution, all polyvalent ions are simultaneously exchanged for one-year sodium and chlorine ions, which facilitates subsequent regeneration since less concentrated regeneration solutions may be used.

An example of liters of bulk and exhausted mixed ion exchangers is slowly poured over 5 liters of 5% sodium chloride. After aspirating the liquid, it is transferred to 10 liters of saturated sodium chloride solution at room temperature, where it is stirred slowly for about 10 minutes and then left to stand. The anion exchanger floats to the surface of the solution and the cation exchanger settles at the bottom of the vessel. Both ion exchangers are separated mechanically, after sucking off the liquid, most of the sodium chloride is washed off with water and then regenerated in a conventional manner. After regeneration and mixing with each other, they again provide high-quality demineralised water. >

Claims (1)

A method of separating a co-cation exchanger and an anion exchanger from a mixture of these ion exchangers, characterized in that the separation is carried out in a batch process in a solution of an inorganic salt of a specific gravity less than the specific gravity cycles of this salt, preferably in a saturated sodium chloride solution, in which the two ion exchangers are separated by epeoiphatic mass, whereupon both ion exchangers are mechanically separated and recovered in a conventional manner.