RU2051115C1 - Complex water treatment installation - Google Patents

Abstract

FIELD: water treatment. SUBSTANCE: installation comprises a cylindrical casing with inlet and outlet branch pipes, a settler in the form of two successively-connected compartments, one containing a package of membrane elements and provided with a branch pipe having an adjusting element, an accumulating unit with branch pipes for discharge of sediment, electric coagulator with a system of cylindrical electrodes installed coaxially with the casing; the external and internal cylindrical electrodes are connected in series with each other and connected to the negative pole of the current source while the middle electrode and a replaceable rod electrode located co- axially in the space of the internal cylindrical electrode are connected to the positive pole of the current source. The rod electrode may be made from anode-soluble or anode-insoluble material, made up of sections with different anodic solubility, and of sections with different thickness. The membrane package is made of elements. EFFECT: improved design.

Description

 The invention relates to techniques for treating natural, industrial and domestic wastewater and can be used in chemical, oil and gas and other industries.

 A known installation for the purification of industrial effluents of the type "Jet", including the inlet and outlet pipes, inclined sump and flocculation chamber, as well as a sand filter / 1 /.

 However, such an installation is not effective enough, since the principle of cleaning it requires the introduction of significant quantities of coagulant reagents and additional clarification of the purified water on sand filters. In addition, the installation is cumbersome and is intended only for stationary production.

 Closest to the proposed is an electrocoagulation unit, including an inclined cylindrical body with inlet and outlet nozzles, a tubular thin-layer sedimentation tank, a drive with a sediment discharge pipe and an electrocoagulator with a system of cylindrical electrodes / 2 /.

 However, such an installation has insufficient productivity and the efficiency of removing coagulation-resistant fine particles formed during electrochemical processes in the near-electrode layers and the volume of water being treated.

 This is explained by the fact that with an increase in the flow rate of the liquid being cleaned, and, consequently, in the productivity of the installation, the residence time of finely dispersed particles in the apparatus turns out to be less than necessary for their complete coagulation and sedimentation in the settling unit of the installation. As a result, some of the uncoagulated contaminants do not have time to settle in the apparatus and are discharged together with the water being treated.

 In addition, without a significant readjustment of the electrode system, the known installation cannot be used for a wide category of treated effluents, which sharply differ in the composition and properties of the contaminants contained.

 The aim of the invention is to increase the productivity and degree of purification of a wide category of treated effluents while ensuring the compactness of the installation and the possibility of its transportation.

 The goal is achieved by the fact that in a complex installation for the purification of contaminated water containing a cylindrical body with inlet and outlet nozzles, a sump, a drive with a sediment discharge pipe and an electrocoagulator with a system of cylindrical electrodes mounted coaxially to the body, the electrocoagulator is equipped with an additional electrode made interchangeable in the form of a rod and placed coaxially inside the cavity of the inner cylindrical electrode, the outer and inner cylindrical electrodes are connected in series between and the negative pole, and the middle cylindrical electrode and the rod electrode to the positive pole of the current source, the sump is made in the form of two series-connected compartments, one of which contains a package of membrane elements and is equipped with an additional pipe with a regulatory body.

 The goal is also achieved by the fact that the rod electrode is made of anode-soluble or anode-insoluble material. The goal is also achieved by the fact that the rod electrode is made up of sections with different anodic solubility, the rod electrode is made up of sections with different thicknesses, the membrane bag is made up of ultrafiltration elements.

 Salient features of the invention are: the electrocoagulator is equipped with an additional electrode, made removable in the form of a rod and placed coaxially inside the cavity of the inner cylindrical electrode; the outer and inner cylindrical electrodes are connected in series with each other and connected to the negative pole, and the middle cylindrical electrode and the rod electrode to the positive pole of the current source; the sump is made in the form of two series-connected compartments, one of which contains a package of membrane elements and is equipped with an additional pipe with a regulatory body; the rod electrode is made of anode-soluble or anode-insoluble material; the rod electrode is made integral of sections with different anodic solubility; the rod electrode is made integral of sections with different thicknesses; the membrane package is made in the form of ultrafiltration elements.

 The drawing shows a diagram of the proposed installation.

 The installation includes an inclined cylindrical body 1 with an installed electrocoagulator 2 with an electrode system in the form of three coaxial cylinders: external 3, internal 4 and middle 5, cantilevered to the upper part of the electrocoagulator 2 using a flange connection 6. Electrodes 3 and 4 are cathodes and interconnected at the bottom. Electrode 5 by the anode. Electrocoagulator 2 is equipped with gaskets 7 located in the interelectrode gap with alternating left- and right-side grooves.

 The inner space 8 of the electrode 4 of the electrocoagulator 2 communicates with the interelectrode space using an annular gap 9 and is provided along the axis with a rod electrode 10 connected to the positive pole of the DC source.

 At the exit (hole) 11 of the inner electrode 4 is a reflective shield 12. Electrocoagulator 2 is equipped with a cover 13 with a pipe 14 for input of the rod electrode 10 and the removal of gaseous electrolysis products.

 For the introduction of contaminated water in the upper part of the external electrode 3 tangentially to the main axis of the electrocoagulator 2 is mounted inlet pipe 15.

 In the space between the electrocoagulator 2 and the wall of the cylindrical body 1 in its lower part there is a tubular thin-layer settling block 16 supported by a grill 17, and in the upper one a package of membrane elements 18.

 In the cylindrical housing 1 mounted outlet pipes 19 and 20, on which are installed locking and regulating devices 21 and 22.

 The cylindrical housing 1 has a conical bottom 23, which serves as a sedimentation tank and equipped with a discharge pipe 24 with a valve 25.

 The installation is supported in an inclined position using the support 26.

 Installation works as follows.

 The processed liquid is supplied under pressure through a tangentially located pipe 15 to the electrocoagulator 2, namely to the upper part of the electrode 3.

 Next, the water passes through the annular gap between the electrodes 3 and 5, and then the upward flow along the annular gap between the electrodes 4 and 5 enters the inner space 8 of the electrode 4.

 Thanks to the tangential fluid supply, an initial spiral-shaped flow stream is created, which is further supported throughout the electrode system by gaskets with helical gaskets 7 located in it, and the alternation of gaskets with right- and left-side grooves additionally creates flow turbulence. All this increases the efficiency of electrocoagulation of effluents, since the spiral-shaped flow increases the contact time of the fluid in the interelectrode space, and the turbulization of the flow favors the active contact of the fluid with the electrodes and reduces their passivation (polarization).

 When the fluid moves from the interelectrode space to the inner space of the electrode 4, the flow velocity sharply slows down, as a result of which the necessary conditions are created for the formation of suspensions formed in the electrocoagulator into aggregates and flakes.

 To a decisive extent, this process is facilitated by the presence in the axial space of the rod electrode 10, which leads to the appearance of an inhomogeneous electric field of increased intensity in the inner space 8 of the electrode 4. Finely dispersed particles, being polarized, are drawn into this region of force fields, mutually coagulating and forming aggregates and flakes from suspension of contaminants. At the same time, the effect of high-voltage electric current improves the bacteriological and organoleptic characteristics of water.

Next, the flow of purified water through the outlet 11 enters the sludge block 16, while changing its direction by 180 ^about . Such a sharp change in flow direction improves the effect of separating coagulant flakes from water.

 Further separation of the solid phase from the liquid and its clarification takes place on the tubular thin-layer elements of the settling unit 16. The precipitate deposited on the walls of the tubular elements by gravity slides into the lower part of the cylindrical body 1, where it collects in the bottom 23, is compacted and periodically removed through the pipe 24 from the installation, while to prevent the sediment from stirring up during its accumulation, a reflective shield 12 is installed at the outlet (hole) 11 from the electrocoagulator 2.

 For final and complete cleaning, consisting in the removal of colloidal fractions of contaminants with high aggregate stability, as well as impurities of high molecular weight compounds, the purified water from the sludge block 16 is sent to the membrane compartment (elements) 18, equipped with ultrafiltration tubular elements in which under the action of excessive pressure ( 0.1-0.4 MPa) there is a separation of the flow. Pure water that seeps through the walls of the tubular elements is removed from the apparatus through the outlet pipe 20. Residual contaminants that do not pass through the side walls of the tubular membranes are discharged from the apparatus through the outlet pipe 19, which is equipped with a shut-off and control device 21 that controls the amount of excess pressure on the ultrafiltration membranes. The locking device 22 of the outlet pipe 20 serves to periodically flush the membrane elements, as well as to turn them off (if necessary), while the device 21 is fully open and the device 22 is closed.

 The use of an additional rod electrode and a package of membrane elements in the installation not only increases its overall performance, but also significantly expands its functionality.

 The introduction of an oppositely charged rod electrode 10 into the axial space of the cylindrical electrode 4 leads to the appearance of an additional cylinder-rod type electrode system in the installation. In contrast to the plane-plane electrode system, the electric field strength (E, V / cm), which obeys the linear law EU / l (where U is the voltage at the electrodes, V; l is the distance between the electrodes, cm), is the electric field in the cylinder system - the rod obeys the logarithmic law EU / (r ln R / r) (where R is the radius of the cylinder, r is the radius of the rod).

 Such a dependence (table) is manifested in a significant increase in the electric field strength at the rod electrode.

 As can be seen from the table, at equal distances between the electrodes and at the same voltage across them, the electric field strength in the coaxial system increases with a decrease in the radius of the rod electrode by an order of magnitude or more compared to a plane-parallel system.

 As a result of the emergence of a powerful electric force field, the coagulation time of finely dispersed particles is sharply reduced and they drop out of the stream of purified liquid in the form of aggregates of particles and flakes. All this allows you to increase the flow rate of the treated effluents in the apparatus, and, consequently, its performance.

In addition, exposure to treated water of strong electric fields leads to a deep destructive decomposition of complex organic pollutants (dyes, surfactants: phenols, etc.) to the simplest low-toxic or non-toxic compounds (СО ₂ , Н ₂ О, N ₂ , etc.) .

 The impact of high voltage electric current is also universal in terms of improving a wide range of bacteriological and organoleptic indicators of water.

 Moreover, since the electric field strength in the coaxial system can be controlled both by the standard size of the rod electrode and the magnitude of the voltage of the electric current supplied to the electrodes, the required electric field at which complete coagulation of contaminants is achieved is achieved by reducing the size of the rod electrode while reducing and voltage (load) on the electrodes, and, consequently, the cost of wastewater treatment.

 The nature of electrochemical processes is such that most metal electrodes, which are the anode, are susceptible to dissolution in electrically conductive aqueous media. When creating high electric field strengths due to a sharp decrease in the radius of the anode, the same sharp decrease in its service life occurs.

 It is necessary to combine these two opposite trends.

 In these cases, the long-term operation of the electrode can be achieved either by manufacturing the anode from insoluble conductive materials (graphite, lead, magnetite, oxycobalt, etc.), or by feeding a charge opposite in sign, which is achieved by simply switching the poles of the DC source.

 However, in some cases it is necessary to combine these two opposite trends (the simultaneous presence of solubility and high electric field strength).

 For example, electrolysis of cyanide wastewater using lead, magnetite or other insoluble anodes leads to the destruction of contaminants to form cyapates, and then nitrogen gas and ammonia.

 On the other hand, when dissolving, for example, iron anodes due to the transition of ferrous iron ions into the solution, it is possible to neutralize the chromium compound in wastewater of galvanic production, fur factories, etc.

 That is, with a complex composition of wastewater, a combined effect on them is necessary, for example, a high electric force field and delivery of iron, copper or other metals to the solution to be treated.

 In these cases, the simultaneous use of opposite effects can be achieved by using combined electrodes, individual sections of which are made of alternating anodically soluble and insoluble materials, while the insoluble sections are made as low as possible (to create high tensions), and soluble as long as possible.

 Such a combination of electrode sections of the anode rod allows one to purposefully change the physicochemical conditions for optimal treatment of a wide category of treated effluents by their composition and properties.

 To date, there is no general explanation for all known electrochemical reactions, therefore, in each case, a special study of the mechanism of destruction and deposition of organic and inorganic contaminants is necessary, and depending on the electrolytic effect, select the electrolysis conditions, electrode materials, their configuration and design.

 In this sense, the constructive combination in the proposed installation of an electrocoagulator, a flocculation chamber with a replaceable combined rod electrode, a thin-layer sedimentation tank and a package of membrane elements makes it possible to ensure optimal physical and chemical conditions for high-performance and deep treatment of a wide category of wastewater as a result of their close functional interconnection while maintaining the compactness of the installation and the possibility of its transportation.

Claims (5)

 1. COMPREHENSIVE INSTALLATION FOR PURIFICATION OF CONTAMINATED WATER, comprising a cylindrical body with inlet and outlet nozzles, a sump, a reservoir with a sediment discharge pipe and an electrocoagulator with a system of cylindrical electrodes mounted coaxially to the body, characterized in that the electrocoagulator is equipped with an additional rod made in the form of a replaceable electrode and placed coaxially inside the cavity of the inner cylindrical electrode, the outer and inner cylindrical electrodes are connected in series between oh and connected to the negative pole, and the middle cylindrical electrode and the rod electrode to the positive pole of the current source, the sump is made in the form of two series-connected compartments, one of which contains a package of membrane elements and is equipped with an additional nozzle with a regulatory body.  2. Installation according to claim 1, characterized in that the rod electrode is made of anode-soluble or anode-insoluble material.  3. The installation according to claim 1, characterized in that the rod electrode is made integral of sections with different anodic solubility.  4. Installation according to claims 1 and 3, characterized in that the rod electrode is made integral of sections with different thicknesses.  5. Installation according to claim 1, characterized in that the membrane package is made in the form of ultrafiltration elements.

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