RU2324529C2 - Electro-baromembranous apparatus of flat chamber type - Google Patents

Abstract

FIELD: mechanic.

SUBSTANCE: apparatus includes channels for inlet and outlet for the mixture being separated, and for outlet of permeate, a device for direct current conveying; separating chambers, electrodes, and membranes installed in sequence. The electrodes are designed bipolar; each of them includes porous cathode and porous anode connected to the device for direct current conveying, graphite fabric, and dielectric partition between them. Each electrode is equipped with an anode membrane and a cathode membrane; the channel between the membranes has spacers installed, designed as an ion-conducting grid, between the nodes of which, ion-exchange material granules are placed. The graphite fabric serves as a unipolar electrode and a drain for the outlet of permeate.

EFFECT: increase in membrane area and decrease in energy consumption.

5 dwg

Description

The invention relates to the field of separation, concentration and purification of solutions by electro-microfiltration, electro-ultrafiltration, electroosmofiltration methods and can be used in chemical, textile, pulp and paper, microbiological, food and other industries.

An analog of this design is the baromembrane apparatus, given in the work of Yu. "Reverse osmosis and ultrafiltration." M .: Chemistry, 1978, p. 111, 197-200. It is a single-chamber apparatus consisting of a porous anode and cathode, an anode and cathode membranes. The disadvantages are the small separation area with high energy consumption for the separation process. These disadvantages are partially eliminated in the prototype.

The prototype of this design is a flat-chamber type apparatus, the design of which is given in the copyright certificate SU 1664353 A1, 02/03/1989. The known apparatus consists of channels for input and output of the solution to be separated and for removal of permeate, a device for supplying direct current, sequentially located separation chambers, electrodes, membranes, and in the intermembrane space there is an ion-exchange material that acts as a separator. The disadvantage is the small membrane placement area per unit volume of the apparatus, low separation efficiency and high energy consumption for the separation process.

The technical task is to increase the membrane area, increase the separation efficiency and reduce energy consumption in the electrobaric membrane apparatus by replacing the middle part of the bipolar electrodes in series with a dielectric partition and graphite fabric, which serves as a unipolar electrode and drainage for permeate removal, and ion-exchange spacers are located in the intermembrane channel, consisting of ion exchange mesh and granules.

Figure 1 shows the electrobaromembrane apparatus flat-chamber type, a longitudinal section; figure 2 - section aa in figure 1; figure 3 - diagram of the ion-conducting spacer with membranes; 4 is a porous bipolar electrode, a longitudinal section; 5 is a section bB in figure 4.

The electro-baromembrane apparatus consists of two flanges 1 with channels 2 and 3 for input and output of the solution to be separated and channels 4 and 5 for the removal of the near-cathode and anode permeate, holes 6 for hairpins, a device 7 for supplying direct electric current to the parallel connected chambers of the device, near-cathode and anode membranes 8 and 9, ion-conducting spacers 11, transfer holes 12, studs 13, gaskets 14, porous bipolar electrode 15, graphite fabric 10 and dielectric septum 16.

The ion-conducting spacer 11 consists of cation-exchange nets 17 and placed in a row in the interstice of granules of anion exchangers 18.

The porous bipolar electrode 15 consists of two porous electrodes - the anode 19 and the cathode 20, which can be made of porous stainless steel, titanium or nickel, graphite fabric 10, which is located in the middle of the bipolar electrode and serves as a conductive material, as well as drainage for removal permeate, channels for removal of the near-cathode 4 and anode 5 permeate, dielectric septum 16, transfer hole 12, used to transfer the shared solution from the chamber to the chamber, holes for the studs 6, devices for suspension and 7, a constant electric current.

The device operates as follows.

The initial solution at a pressure exceeding the osmotic pressure of the substances dissolved in it, is fed into the first separation chamber through channel 2, FIGS. 1, 2. At the same time, an external constant electric field with a given current density is supplied to the apparatus. Then the solution, through the ion-conducting spacer 11, figure 3, enters the membranes. In the separation chamber, anions penetrating through the anode membrane 8 located together with the anode on flange 1 are diverted with permeate through channels 4 in the form of acids, and cations penetrating through the cathode membrane 9 located on the cathode 20 of the porous bipolar electrode 15, FIG. 4 , 5, are discharged with permeate through channels 5 in the form of bases. Next, the solution to be separated passes from chamber to chamber through transfer openings 12, where a similar separation occurs, anions and cations with permeate are discharged through the anode and cathode membranes 8, 9 in the form of acids and bases. The initial solution, flowing through all the chambers, is purified from anions and cations. After separation, the initial solution is discharged through channel 3.

Graphite fabric is a conductive material between the electrodes and the drainage for the removal of permeate, figure 4, 5.

Filling the separation chamber with ion-conducting fillers allows combining periodic depolarization (destruction of diffusion layers) with an increase in the mass transfer surface, compared to inert turbolizers that shield part of the membrane’s working surface, and allows reducing the electrical resistance of the electromembrane system. Thus, the presence of ion-conducting spacers, Fig.2, 3 leads to an increase in the local flow rate of the solution in the narrowing of the channel and the formation of the zone of increased mass transfer. Also, the function of the spacers filling the intermembrane space during the electrobaromembrane process is to prevent adhesion of the membranes, which leads to the flow of current through the contact and the burning of the membranes due to the release of a large amount of Joule heat. In addition, spacers separating the membranes intensify mass transfer due to turbulence in the flow and, consequently, a decrease in concentration polarization.

Claims (1)

The flat-chamber electrobaromembrane apparatus including input and output channels of the solution to be separated and permeate withdrawal, a DC supply device, sequentially located separation chambers, electrodes, membranes separated by ion-exchange material, characterized in that the electrodes are made of bipolar, each of which includes connected to the device for direct current supply, the porous anode and cathode, graphite fabric and the dielectric partition between them, as well as channels for the removal of the anode and permeate and transfer openings for the solution to be separated from the chamber to the chamber, with each electrode having an anode and cathode membranes, and spacers made in the form of an ion-conducting network with granules of ion-exchange material placed in the intermembrane channel.

Images