UA81920C2 - Method and device of counterflow sorption of ions by ion-exchange sorbent - Google Patents

Abstract

The invention relates to the technology of ion-exchange purification of solutions. A method of counterflow sorption of ions by ion-exchange sorbent includes continuous process of sorption in two moving layers of sorbent. A process liquid is supplied from below into the upper moving layer of the sorbent, which is directed from top to bottom towards the motion of the process liquid, into the lower moving layer of the worked out sorbent the solution is supplied, which regenerates sorbent; the regenerated sorbent by means of an airlift is supplied for removal of mechanical impurities and remainders of regenerating solution, clean regenerated sorbent after washing is supplied to the upper moving layer of sorbent. A device for realization of the counterflow sorption of ions by ion-exchange sorbent and its regeneration – an ion-exchange reactor of continuous action, additionally contains a labyrinth channel; the upper operating layer of sorbent; a reducing device - a sluice; the lower layer of sorbent; the airlift; three systems of coaxial pipes and collectors. The use of invention makes it possible to simultaneously carry out two processes in one apparatus with increased efficiency: sorption of ions from the process liquid and regeneration of ion-exchange sorbents.

Description

Description of the invention

The invention relates to thermal power engineering, chemical industry, communal economy, mining 2 and food industries, namely to devices that serve to change and regulate the chemical characteristics of process fluids.

There are several methods and structures by means of which the process of continuous countercurrent sorption of ions by ion-exchange material is carried out. For example, a known counter-current ion exchange unit is used for the process of sorption of ions from a liquid (1Y1. The device is made in the form of a tubular structure. The operation of the device 70 is complex and characterized by a low degree of reliability. The method does not implement the processes of simultaneous sorption of ions from the technological liquid and regeneration of the sorbent.

The prototype of the proposed method and device is a method of continuous countercurrent sorption through two layers of sorbent |2), which implements the reverse direction of the solution flow and uses a device - an ionitic reactor of a "pipe-in-pipe" design, consisting of two coaxially inserted one-to-one pipes of different diameters 72 filled with ion exchange material. The initial solution is fed from above into the inner cylinder, passes through the layer of ionite and enters the lower part of the outer cylinder, and then passes through the second layer of ionites from the bottom up.

The disadvantage is that the method |2| does not implement processes of simultaneous sorption of ions from the process liquid and sorbent regeneration.

The purpose of the invention is to improve the method of countercurrent sorption of ions with an ion-exchange material and to develop a device for its implementation, which includes the simultaneous process of cleaning the technological liquid and regeneration of the sorbent in one device.

The method of countercurrent sorption of ions by an ion-exchange material from a technological liquid, which includes a continuous process of sorption in two moving layers of the sorbent, which realizes the reverse direction of the flow of the solution, additionally with 22 is equipped with the following stages: the technological liquid is fed from below into the upper moving layer of the sorbent, which Ge) moves from top to bottom towards the movement of process fluid; a solution regenerating the sorbent is supplied to the lower mobile layer of the spent sorbent; the regenerated sorbent is sent for washing from mechanical impurities and residues of the regenerating solution using an air lift; clean regenerated sorbent after washing is fed to the upper moving layer of the sorbent; at the same time, two processes are implemented simultaneously: sorption of ions from the process liquid and regeneration of the sorbent. Ha

The device for carrying out countercurrent sorption of ions by ion-exchange material and sorbent regeneration is a continuous-action ion-exchange reactor, which has two inserted coaxial one-to-one pipes of different Me, diameter, filled with ion-exchange material, which are additionally equipped with a labyrinth channel; upper working "- sorbent layer; narrowing device - a gateway that separates the upper and lower layers of the sorbent; bottom layer

From the sorbent, where its regeneration takes place; by airlift, by means of which the regenerated sorbent enters 99 from the lower layer to the upper working layer; a system of coaxial pipes and collectors that serve to supply the working process fluid, regenerating solution and air.

All the specified features are necessary and sufficient for achieving the technical result: simultaneous implementation of two processes in one device: sorption of ions from the process liquid and regeneration of ion-exchange sorbents. t s The continuous action ion exchange reactor shown in Fig. consists of a body 1, a washing unit 2, which is equipped with a labyrinth channel 3, an upper working layer of a sorbent 4, a narrowing device (gate) 5, a distribution collector of process liquid b, a distribution collector for regenerating solution 7, pipeline for airlift 8, drainage nozzles 9,10,11, inlet nozzles 12, 13, drainage cup 14, 49 grid of drainage cup 15, drain nozzle 16, annular gap 17, zone of sorbent regeneration 18, so valve descent 19, supporting legs 20, airlift 21. - The operation of the ion exchange reactor of continuous action is as follows. The process liquid, which needs to be cleaned, enters the distribution manifold 6 through the inlet pipe 13, then into the upper working layer of the sorbent (re) 4, where the sorption of certain ions from the process liquid takes place with the ion exchange material. The working layer t 20 of the sorbent 4 moves in the direction of the movement of the process fluid, because the regenerated sorbent falls from the labyrinth channel C from above onto the working layer 4. The spent sorbent through the annular opening of the 17-narrowing device (sluice) c 5 enters the sorbent regeneration zone 18. The purified liquid through drain pipe 16 comes as intended. The regenerating solution enters through the inlet pipe 12, which enters the sorbent regeneration zone 18 through the distribution manifold 7, where the sorbent is regenerated. The regenerated sorbent 52 with the help of the air lift 21 enters the drainage cup 14. The liquid with desorbed ions and mechanical impurities flows through the drainage nozzles 9, 10, 11. The mesh of the drainage cup 15 serves to separate mechanical impurities and the solution of desorbed ions. The dehydrated mass of the sorbent rolls over the edge of the drainage cup 14 and falls down into the labyrinth channel 3, because the liquid level in the washing unit is lower than the liquid level in the upper part of the reactor. This is achieved by appropriate adjustment of the cross-sections 60 of the drain nozzle 16 and the drainage nozzle 11. The purified liquid from the upper part of the reactor through the labyrinth channel C moves towards the movement of the sorbent, after it has spilled over the edge of the drainage cup 14; thus, the sorbent is cleaned from the remnants of the regenerating solution, desorbed ions and mechanical impurities. As a result, clean regenerated sorbent is fed into the upper part of the working layer of sorbent 4.

Thus, there is a process of simultaneous countercurrent sorption of ions and regeneration of the sorbent with the accompanying extraction of mechanical impurities that may be present in the initial process liquid.

An example of a specific application. The continuous reactor is loaded with KU-2-8 resin. Loading volume 2Odm 3; reactor diameter 0.145 m; height O0.9m; liquid to be cleaned - water; extracted ions - calcium, magnesium; general initial stiffness Ш o-3.5 mg-eq/dm in. Fluid consumption was Ohm m/h; 0.000028m U/s or 0.02dmU/s.

The total static capacity of the resin is 1.7 mg-eq/g; bulk density 720 kg/m3; mass 20dm? is equal to 20.0.72-14.4 kg. The total capacity of this amount of resin is 14.4.1.7-24.48 g-eq. At a hardness of 3.5 mg-eq/dm3, 24480/3.5-6994dm, or approximately 7m3, were cleaned. /0 For the regeneration of 14.4 kg of resin, 24.48 g-equivalent Mass is required, i.e. 24.48.58.44-1430.6 bg, or approximately 1.4 kg of mass.

When softening water with a hardness of 3.5 mg-eq/dm Z with a consumption of 0.028 dm/s, 0.028.3.5-0.098 mg-eq/s of hardness salts were removed. Thus, a dosage of at least 0.098 mg-eq/s of Mass is possible. One dm of the 1095th Mass solution! contains 100g of Massi or 100/5 8.44-1.7 mg-eq, i.e. 1.7.M-0.098. Whence 75 MEO,098/1.7-0.058dm Z/s. The consumption of the regenerating solution was 0.058 dm/s.

To improve the mass transfer, the consumption of the regenerating solution was increased by 1.5 times. Thus, the consumption of the 1096th Masi solution was 87 ml/s, and the total consumption of Masi is equal to 1.43.1.5-2 kg.

Consumption of the 1095th mass solution is equal to 21 kg or 25 dm?. The time of continuous regeneration of the sorbent was 24.48.1000/0.098-69 hours.

The technical and economic efficiency of the proposed method and device is characterized by the continuity of the filtration process, joint simultaneous regeneration, the constancy of the driving force of the adsorption process, the constancy of mass transfer processes, the absence of stops of the apparatus for regeneration, the minimization of the volumes of regenerated washing solutions. In connection with the implementation of the countercurrent movement of the sorbent and the liquid being purified, the diffusion peaks of the sorbed ions become less blurred, as a result of which the ions that are well sorbed (Ca?, Ma?) and ions, which are absorbed worse (Ma"K U. (o)

The sorbent layer is in constant motion, so the phenomenon of channel formation is completely eliminated. In the process of water purification, ions are removed, and the technological liquid is also purified from mechanical impurities.

Constant mixing of ionite particles in the circulation layer excludes the formation of stagnant zones of regenerating oxygen near each granule. Thus, the regeneration of the granules takes place over the entire surface, the granules uniformly increase their volume without changing the shape of the surface layer. Therefore, one more drawback of regeneration (in CM compared to a fixed sorbent layer) is excluded; decrease in the degree of crack formation, decrease in the percentage of granule splitting. Destroyed granules in the form of finely dispersed mechanical particles are constantly washed and removed from the reactor. When carrying out the stage of cationization using an acid reagent, the free carbonic acid formed is removed by the air lift from the cationate grains, thus in the schemes for obtaining especially pure desalted water, it is possible to eliminate the decarbonization stage from the technological scheme. The narrowing of the diffusion peaks of sorbed ions leads to the elimination of the passage through the cationic and ionite filters of traces of ions that are difficult to sorb, which allows not to use a complex-to-operate final filter of joint action, without worsening the quality of the water received. " 20 The proposed method and device increase the service life of the sorbent-ion exchange resin by 1.5-2 times. Z7Z

We take the cost of Itona resin KU-2-8 equal to 500 UAH. When using resin at the stage of water treatment from a large thermal power plant, the period of use of the sorbent is 2-3 years, the volume of resin is 50 tons. If the period of use is increased to 3-4.5 years, only from the increase of the period of use, we can save up to 25 tons of resin. i.e. 125,000 Ogr. in 1.5 years.

Literature: so 1. N.B. Ferapontov, V.I. Gorshkov, G.A. Medvedev, D.N. Muravyov, Yu.A. Kovalenko. Моннообменная installation for continuous counterflow of solution and sorbent.: in sb. "Monny exchange and chromatography." - 1984.-S. 152 - -155. "so 2. G.A. Chikyna, O.N. soft Ion exchange method of cleaning substances.: Voronezh. -Ed. Voronezhsk 5th year university.- 1984.- P. 104-105. ko c2

Claims (2)

The formula of the invention 1. The method of countercurrent sorption of ions by an ion exchange sorbent, which includes a continuous process of sorption in two moving layers of the sorbent and realizes the reverse direction of the flow of the solution, which differs in that liquid, a solution that regenerates the sorbent is fed into the lower moving layer of the spent sorbent; the regenerated sorbent is fed using an airlift to wash away mechanical impurities and the rest of the regenerating solution, the clean regenerated sorbent after washing is fed to the upper moving layer of the sorbent; at the same time, carrying out two processes: sorption of ions from the process liquid and regeneration of the sorbent. 2. A device for countercurrent sorption of ions by an ion exchange sorbent and its regeneration - a continuous action ion exchange reactor, which has tanks with a sorbent, which is distinguished by the fact that it additionally contains a labyrinth channel; the upper working layer of the sorbent; narrowing device - a gateway that separates the upper and lower layers of the sorbent, the lower layer of the sorbent, an air lift for the arrival of the regenerated sorbent from the lower layer to the upper layer; three systems of coaxial pipes and collectors: the first one is intended for the supply of the process liquid being cleaned to the corresponding upper distribution collector; the second is intended for supplying the regenerating solution to the corresponding lower distribution manifold; the third coaxial pipe is for air supply. s 7 o o s (22) «-- Zo so - with . and? so - (Se) ko c2 ko 60 b5