RU2716121C1 - Tubular electrobaromembrane unit - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to tubular-type membrane apparatus and can be used for membrane processes. Electrobaromembrane device includes cylindrical housing with mating and end flanges, tube grids, clamping grids, unipolar electrodes-anodes located between tube and pressure grids, unipolar electrodes-cathodes located between clamping grates and end flanges, a anodic permeate collector, a cathode permeate collector formed between a pressure grid and a monopolar cathode electrode, a cathode permeate channel, through holes for tubes with anode and cathode membranes located on the outside, electric current supply device terminals connected to anode electrode and cathode electrode, initial solution inlet unions, retentate outlet and anodic permeate outlet, two cathode permeate output nozzles located in apparatus section from horizontal axis at angles 3π/2 from its both end faces, right probes located inside tubes with cathode-ray membranes and connected to two end sides with cathode, and left probes arranged inside tubes with anode membranes and connected to two end sides with anode, wherein the diameter of the tubes with cathode membranes is three times larger than the diameter of the tubes with anodic membranes.

EFFECT: invention increases area of separation of solutions, reduces hydraulic resistance in channels for discharge of cathode permeate, high quality and efficiency of separation of solutions.

1 cl, 6 dwg

Description

The invention relates to designs of membrane apparatuses of a tubular type and can be used to carry out processes of membrane technology: electro-ultrafiltration, electrofiltration, electrofiltration and electro-osmofiltration.

An analog of this design is a membrane apparatus, the design of which is given in the work of Dubyagi V.P., Perepechkina L.P., Katalevsky E.E. Polymer membranes. M .: Chemistry, 1981. - S. 166-167. The apparatus is made of a housing, separating elements consisting of a tube and a membrane, fittings for the input of the solution to be separated and for the output of the retentate, fittings for the output of the permeate.

The disadvantages of the apparatus are the impossibility of separating the anions and cations of dissolved substances from industrial solutions and effluents, the low rate of removal of permeate, the formation of stagnant zones on the way permeate is removed. These disadvantages are partially eliminated in the prototype.

The prototype of this design is the tubular-type electrobaromembrane apparatus, the design of which is given in patent No.RU 2685091 C1, 04.16.2019, IPC B01D 61/46. The prototype consists of a cylindrical body with counter and end flanges, monopolar electrodes, anodes and cathodes, anode and cathode permeate collectors, a cathode permeate channel, through holes for tubes with external anode and cathode membranes respectively, sealing tube sheets through gaskets and gaskets with clamping grids and a cylindrical body with mating flanges, respectively, carried out by tightening the end flanges and mating flanges on qi the cylindrical housing with bolts, washers and nuts, which are located on the end flanges in their section at angles from the horizontal axis 0, π / 3, 2π / 3, π, 4π / 3 and 5π / 3, respectively, and are located from the edge of the end flanges on a distance of 15 mm, terminals of the device for supplying electric current, fittings for inputting the initial solution and withdrawing retentate, fittings for outputting the anode and cathode permeate, gaskets, probes of the right and left cylindrical, clamping grids.

The disadvantages of the prototype are: low membrane area for separation of solutions, high hydraulic resistance in the channels for removal of cathode permeate, low quality and efficiency of separation of solutions.

The technical problem is to increase the area of separation of solutions, reduce hydraulic resistance in the channels for removal of cathode permeate, increase the quality and efficiency of separation of solutions, by changing the design of the apparatus, consisting of a cylindrical body with mating and end flanges, monopolar electrodes-anodes and cathodes, anode collectors and cathode permeate, channel of cathode permeate, through holes for tubes with external anode and cathode membranes, respectively Of course, sealing tube sheets through gaskets and gaskets with clamping bars and a cylindrical body with mating flanges, respectively, was carried out by tightening the end flanges and mating flanges on the cylindrical body using bolts, washers and nuts, which are located on the end flanges in their section at angles from the horizontal axis 0, π / 3, 2π / 3, π, 4π / 3 and 5π / 3, respectively, located from the edge of the end flanges at a distance of 15 mm, terminals of the device for supplying electric current, input fittings of the bottom solution and withdrawal of the retentate, nozzles of the output of the anode and cathode permeate, gaskets, probes of the right and left cylindrical, clamping grids, characterized in that a monopolar electrode-anode 5 is located between the tube grids and clamping grids, and a monopolar electrode is located between the clamping grids and end flanges the electrode-cathode 6, while the metal probes - right 21, are located inside the tubes 29 with cathode membranes 27 and are connected from the two end sides to the cathode 6, and the metal probes - left 22, located s inside the tubes 25 with the anode membranes 26 and are connected on two end sides with the anode 5, the tubes 29 with the cathode membranes 27 are made three times larger in diameter, the terminals of the device for supplying electric current 9 are connected respectively to the unipolar electrode-anode 5 and the monopolar electrode cathode 6, a cathode permeate collector 7 is formed between the clamping lattice 4 and the monopolar cathode electrode 6, and the apparatus has two outlets of the cathode permeate 13, 28 located in the section of the apparatus from the horizon cial axis angles 3π / 2 on both front sides elektrobaromembrannogo apparatus.

In FIG. 1 shows a part of the view and section of the tubular-type electrobaromembrane apparatus; FIG. 2 - view from the left; FIG. 3 is a top view; FIG. 4 - section AA in FIG. 1; FIG. 5 is a view B enlarged in FIG. 1; FIG. 6 is a view B enlarged in FIG. 4.

The tubular-type electro-baromembrane apparatus consists of a cylindrical body with reciprocal 1 and end 2 flanges, monopolar electrodes-anodes 5 and cathodes 6, collectors of anode 8 and cathode 7 permeate, channels of anode 23 permeate, through holes for tubes 25 and 29 with anode 24 located outside and near-cathode 27 membranes, respectively, the sealing of the tube sheets 3 through the gaskets 15 and gaskets 14 with clamping bars 4 and a cylindrical body with mating flanges 1, respectively, is carried out by tightening the end flanges 2 and the counter flanges 1 on the cylindrical body using bolts 16, washers 17 and nuts 18, which are located on the end flanges 2 in their section at angles from the horizontal axis 0, π / 3, 2π / 3, π, 4π / 3 and 5π / 3, respectively, and are located from the edge of the end flanges 2 at a distance of 15 mm, the terminals of the device for supplying electric current 9, the inlets of the input of the initial solution 10 and the outlet of the retentate 11, the outlets of the outlet of the anode permeate 12 and two unions of the cathode permeate 13, 28, between the tube sheets 3 and the pressure grids 4 there is a monopolar electrode-anode 5, and between the clamping gratings 4 and the end flanges 2 there is a monopolar electrode-cathode 6, while the metal probes are right 21, are located inside the tubes 29 with cathode membranes 27 and are connected from the two end sides to the cathode 6, and metal probes - left 22, are located inside the tubes 25 with anode membranes 26 and are connected from the two end sides to the anode 5, and the tubes 29 with cathode membranes 27 are made up to three times the diameters, the terminals of the device for supplying electric current 9 are connected respectively, with a monopolar electrode-anode 5 and a monopolar electrode-cathode 6, a cathode permeate assembly 7 is formed between the clamping lattice 4 and the monopolar electrode-cathode 6, ring gaskets 19, 20, gasket 24.

Cylindrical body with mating flanges 1, end flanges 2, tube sheet 3, pressure plate 4, input solution inlet and outlet of retentate 10, 11, outlet cathode permeate 13, 28, outlet anode permeate 12, made of dielectric material - caprolon or fiberglass.

The tubes 25, 29 can be made of porous fluoroplastic.

Monopolar electrode-anode 5, connected to metal probes left 22 from two end sides and can be made of material grades X18H15-PM, X18H15-MP.

The monopolar electrode-cathode 6 is connected to metal probes on the right 21 from two end sides and can be made of material grades X18H15-PM, X18H15-MP, as well as the terminals of the device for supplying electric current 9.

Membranes of the following types MGA-95, MGA-70P, MGA-80P, MGA-90P, MGA-95P-N, MGA-95PT, MGA-100P, UAM-150P, UAM- can be used as anode and cathode membranes 26, 27 300P, UAM-500P, UAM-1000P, OPMN-P, OFMNP, OPM-K, ESPA, ESNA, Tammel membranes.

Sealing gaskets 15 and gaskets 14 can be made of paronite.

Ring gaskets 19, 20 and gasket 24 can be made of paronite, rubber.

Electrobaromembrane apparatus of the tubular type operates as follows. The initial solution under pressure exceeding the osmotic pressure of the substances dissolved in it, FIG. 1, 2, through the inlet of the initial solution 10, the inner space of the cylindrical body with mating flanges 1 is fed, where it gradually fills the entire volume. At the same time, an external constant electric field is applied to the apparatus causing a certain current density in the solution by connecting the terminals of the device for supplying electric current 9, FIG. 1, 2, 3, through monopolar electrodes-anode and cathode 5, 6, are connected to metal probes with right 21 and left 22, respectively, from two end sides. The solution flows in the intermembrane space, FIG. 1, between a cylindrical body with mating flanges 1, tube sheets 3 and anode and cathode membranes 26, 27 located on the tubes 25 and 29, respectively, moving, mixed. In the intermembrane space, FIG. 1, 4, 5, 6, a substance dissolved in a liquid dissociates into ions, under the influence of an electric current, anions and cations penetrate through anode and cathode membranes 26, 27, respectively, depending on the connection of the plus or minus electrodes, then through the tubes 25, 29 and into the gaps between the inner parts of the tube 25, 29 and the metal probes right 21 and left 22, and then by gravity with anode and cathode permeates and gases formed on the metal probes right 21 and left 22 as a result of electrochemical reactions after upaet in pre-anode and cathode collectors permeate 7, 8, Fig. 1. Next, the anode permeate is discharged through the channels of the anode permeate 23 located in the section of the apparatus from the horizontal axis at angles 3π / 2 coinciding with the holes in the outlet fittings of the anode permeate 12 screwed onto the pressure grids 4 in the form of acids and dissolved gases, and the cathode permeate is discharged from the cathode permeate collector 7, through the cathode permeate outlet fittings 13, 28, located in the apparatus section from the horizontal axis at angles 3π / 2 from both ends of the electrobaric membrane apparatus into e bases and dissolved gases, depending on the connection diagram of the plus or minus electrodes.

Thus, from a solution sequentially flowing over the entire intermembrane space of the tubular-type electro-baromembrane apparatus, FIG. 1 formed between a cylindrical body with mating flanges 1, tube sheets 3, anode and cathode membranes 26, 27, depending on the connection scheme of the plus or minus electrodes, dissolved substances are removed in the form of anions and cations. The end ends of the tubes 25, 29 of FIG. 1, with anode and cathode membranes 26, 27, respectively, fixed in the tube sheets 3 and clamping grids 4 using ring gaskets 19 and 20 inserted into the seating surface on the inner side of the tube sheets 3 and clamping grids 4, which cover the ends of the tubes 25, 29 from the outside, together with the anode and cathode membranes 26, 27 and prevent the flow of the shared solution into the collectors of the cathode and anode permeate 7, 8, respectively.

The increase in the area of membranes for the separation of solutions, FIG. 1, 4, 5, 6, it is ensured that the tubes 29 with external cathode membranes 27 are made three times larger in diameter, and the tubes 25 with anode membranes 26 are located in the solution separation chamber (intermembrane channel).

The decrease in hydraulic resistance in the channels for removal of the cathode permeate, FIG. 1, 5, it is ensured that the tubes 29 with external cathode membranes 27 are made three times larger in diameter and the cathode permeate is discharged through two cuffs of the cathode permeate 13, 28, which allows the cathode permeate to circulate more freely.

Increasing the quality and separation efficiency of solutions, FIG. 1, 4, 5, 6, due to the fact that in the separation chamber of the solutions there are more tubes 29, 25 with cathode 27 and anode 26 membranes located outside.

On the developed design of a tubular type electro-baromembrane apparatus without applying an electric field, it is possible to carry out baromembrane processes, for example microfiltration, ultrafiltration, nanofiltration and reverse osmosis in the separation of solutions of chemical, engineering and food industries.

Claims (1)

Tubular type electro-baromembrane apparatus, consisting of a cylindrical body with counter and end flanges, monopolar electrodes-anodes and cathodes, anode and cathode permeate collectors, cathode permeate channel, through holes for tubes with outside anode and cathode membranes, respectively, through the sealing of the tube sheets gaskets and gaskets with clamping grids and a cylindrical body with mating flanges, respectively, carried out by tightening end flanges and counter flanges on a cylindrical body with bolts, washers and nuts, which are located on the end flanges in their section at angles from the horizontal axis 0, π / 3, 2π / 3, π, 4π / 3 and 5π / 3, respectively, and located from the edge of the end flanges at a distance of 15 mm, terminals of the device for supplying electric current, fittings for inputting the initial solution and withdrawing retentate, fittings for outputting the anode and cathode permeate, gaskets, probes of the right and left cylindrical, clamping grids, characterized in that between the tube grids a monopolar electrode-anode (5) is located with clamping gratings and, and a monopolar electrode-cathode (6) is located between the clamping gratings and end flanges, while the metal probes, right (21), are located inside tubes (29) with cathode membranes (27 ) and are connected from the two ends to the cathode (6), and the metal probes, left (22), are located inside the tubes (25) with the anode membranes (26) and are connected from the two ends to the anode (5), and the tubes (29 ) with cathode membranes made up to three times the diameter, the terminals of the device for supplying an electric current (9) are connected respectively to a monopolar electrode-anode (5) and a monopolar electrode-cathode (6), a cathode permeate collector (7) is formed between the pressure grid (4) and the monopolar cathode electrode (6), and in the apparatus there are two outlets for the exit of the cathode permeate (13, 28) located in the section of the apparatus from the horizontal axis at angles of 3π / 2 on both ends of the electrobaric membrane apparatus.

Images