SU906944A1 - Method for desalinating water - Google Patents

Description

one

The invention relates to the purification of water and can be combined in tetgloenergy, chemical, chemical and metallurgical industrial m.

There is a known method of water desalination, according to which H-cationic water freed from mechanical impurities is 8 straight-through filters, 8 decarbonisers are decarbonated and OH-anioned in straight-through filters. The desalinated water is then sent to the consumer.

The disadvantages of this method are low degree of purification and high consumption of reagents for filter regeneration.

The closest to the proposed technical essence and the achieved result is the method of water desalting, which means that the water being treated after coagulation and mechanical filtration is H-cationated in step-anti-current filters, decarbonated in decarbonisers and then OH-anion is ruled in step-countercurrent filters loaded along the water with a weakly basic and strongly basic anion exchange resin 23.

The disadvantages of this method are the low degree of water purification and the high cost of desalting. The low degree of purification of water according to a known method is due to the aging process of anion exchangers, in which the latter exhibit amphoteric properties, as a result of which sodium ions displaced from the anion exchanger are contained in the desalination process in the water supplied to the consumer form alkalinity. This phenomenon is also caused by insufficient washing of anion-exchange filters, ingress of cation exchangers in them and premature leakage of cation-exchange filters. In addition, in the final stages of H-cationization by a known method, the concentration of anti-hydrogen is very high, which requires high specific consumption of acid and washing water during regeneration and washing, respectively. The aim of the invention is to increase the degree of water purification and reduce the cost of the process. The goal is achieved by the fact that according to the method of water desalination, including H-cationization, decarbonization and OH-anionization, OH-anionized water additionally passes a cation-exchange filter in hydrogen in the regime of starvation regeneration. The process is made cheaper by reducing the specific acid consumption for regeneration of H-cation-exchange filters and by reducing the total amount of wash water. The use of the starvation mode of regeneration of the cation-exchange filter in the H-form, i.e. the use of acid in an amount not exceeding the theoretically necessary, also prevents the occurrence of acidity in demineralized water. The process technology (the process is described in the following. The treated water released from mechanical impurities is passed through stepwise countercurrent H-cationite filters, where the cations of the source water are hydrated to hydrogen ions. Next, the H-cationated water is decarbonated by passing through decarbonisers and decarbonisation through decarbonisation and decarbonisation through decarbonisation and decarbonisation through decarbonisation and decarbonisation by passing through decarbonisers and decarbonisation through passing through decarbonisers and decarbonisation through passing through decarbonisers and decarbonisation through passing through decarbonisers and decarbonisation through passing through decarbonisers and decarbonisation by passing through decarbonisers and decarbonisation by passing through decarbonisers and decarbonisation by passing through decarbonisers and decarbonisation through decarbonisers and decarbonisation by passing through decarbonisers and decarbonisation by passing through decarbonisers and decarbonisation by passing through decarbonisers and decarbonisation. water is OH-anioned by passing through step-countercurrent HE-anionite filters loaded with weakly basic and strongly basic anion exchangers. After the anion-exchange filters, O, 2-0, mg-eq alkalis are contained.PI-anion-enriched water is additionally passed through a hydrogen-cation-exchange filter loaded with a strongly acidic cation exchanger operating in a fast-regeneration mode. At the same time, sodium ions in demineralized water replace hydrogen ions in the cation filter, the latter are displaced into water, where they are neutralized by OH ions. 6 As a result, the depth of purification of demineralized water reaches 0.01-0.02 mg eq / l, the process reliability is increased by eliminating the danger of under-washing of ion exchangers, as well as is the process by reducing the specific consumption of acid for regeneration H cationite filters and for reducing the total amount of water in laundering. The use of the starvation mode of regeneration of the cation-exchange filter in the H-form, i.e. the use of acid for regeneration in an amount not exceeding the theoretically required amount also prevents the appearance of acidity in demineralized water. Example. The source water containing mg-EQ / gg of CA 2, Mg 1.5-, Na 1.5i, 5i CJ 1 and HCO 3 2.5- is passed successively through two H-cationite filters, connected in a stepwise counter-current scheme, calciner and two OH-anion exchangers}) iltra, also included stepwise countercurrent. The cation-exchange filters were loaded with sulfonic carbon, and the anion-exchange filters, AN-31 and AB-17, respectively. Desalted water after anion-exchange filters contains 0.3 mEq / l Nadi. OH-anionized water is passed through a hydrogen-cation-exchange filter operating in the regime of fast regeneration, loaded with cation exchanger KU-2-8. At the same time, demineralized water is obtained, containing 0.01-0.2 mg-eq / g sodium. The technological indicators of desalting according to the proposed and known methods are presented in the table.

Claims (2)

SUMMARY OF THE INVENTION i Method for desalting water, including H-cationization, decarbonization and OH-anionization, characterized in that, in order to increase the degree of desalination and reduce the cost of the process, OH-anionized water is additionally passed through a hydrogen-cationic filter operating in the hungry mode regeneration. . Sources of information taken into account during the examination 1. Water treatment. Processes and apparatuses. Ed. Martynova. Atomiz dates, 1977, p. 118. 2. Handbook of chemical energy. t. 1, ’1972, p. 44, (prototype). VNIIIPI Order 502/28 Circulation 980 Subscription branch PPP Patent, Uzhgorod, Project 4,