RU182470U1 - INSTALLATION OF ALKALINE WASTE WATER DISPOSAL - Google Patents

Abstract

The utility model relates to the field of utilization of industrial alkaline wastewater (SHSV), namely to the disposal of highly mineralized alkaline wastewater generated during the operation of the water treatment plant (VPU) of thermal power plants and other industrial enterprises.

The technical result is to simplify the technological scheme of utilization of alkali-iron oxide with the production of concentrated alkali and partially desalinated softened solution through the use of a single electro-membrane apparatus, which excludes the introduction of chemicals in the form of demineralized water.

The technical result is achieved by the fact that the alkaline wastewater treatment plant contains an alkaline wastewater supply line arranged in a technological sequence, a working solution recirculation unit and a multi-chamber electromembrane apparatus for producing a concentrated alkaline solution and partially desalinated softened solution, while the working solution recirculation unit contains three tanks tied with pipes made of chemically resistant material, the first tank is installed with the possibility of filling industrial a washing solution, and the second and third tanks are installed with the possibility of filling with alkaline wastewater, the inputs of the multi-chamber electro-membrane apparatus are connected respectively to the outputs of the first, second and third tanks of the recirculation unit of working solutions, and the outputs of the multi-chamber electro-membrane are connected to the inputs of the first, second and third tanks block recirculation of working solutions, moreover, multi-chamber electro-membrane apparatus is made in the form of a three-channel multi-chamber electro-membrane o apparatus, eliminating the additional input of chemical reagents in the form of demineralized water, with alternating anion-exchange and cation-exchange membranes with two near-electrode washing chambers. 3 tablets, 2 ill.

Description

The utility model relates to the field of utilization of industrial alkaline wastewater (SHSV), namely to the disposal of highly mineralized alkaline wastewater generated during the operation of the water treatment plant (VPU) of thermal power plants and other industrial enterprises.

Wastewater of VPU is the most mineralized effluent of thermal power plants and industrial enterprises and contains alkali, salt residues and organic impurities.

For the disposal of alkali-iron oxide, methods of evaporation, neutralization, reagent treatment, electrochemical and others are used.

A known installation of electro-membrane production of softened saline and concentrated alkaline solution from alkaline highly mineralized industrial effluents (RF patent No. 2548985, IPC B01D 61/42, publ. 04/20/2015).

The disadvantages of the known installation are:

1. Low productivity - not more than 0.1 t / h in wastewater, due to the parallel-sequential scheme of operation of the first and second stages of electro-membrane treatment.

2. A complex technological scheme, due to the presence of two electro-membrane devices and a pre-treatment unit for industrial effluents.

The prototype is a plant for processing industrial wastewater and obtaining a concentrated solution and softened saline solution (RF patent No. 121500, IPC C02F 9/08, B01D 61/44, publ. 07.10.2012).

According to the description, the installation includes an accumulation and preliminary treatment unit for the treated wastewater, a unit for recirculating working solutions, a unit for multi-chamber electro-membrane devices, and the unit for multi-chamber electro-membrane devices consists of a unit for the first stage of the electro-membrane treatment for separating the alkaline solution from the initial solution, and for obtaining a softened saline solution, and a block of the second stage of the electro-membrane treatment to obtain of a concentrated alkaline solution, the recirculation block of working solutions contains four tanks tied with pipelines of chemically resistant material, the first tank being installed with the possibility of filling with a washing solution, the second tank is installed with the possibility of filling with demineralized water, the third tank is installed with the possibility of accumulating alkaline solution from the block of the first stage electro-membrane treatment, the fourth tank is installed with the possibility of filling with purified alkali-containing drain and connected to the storage unit and preliminary treatment of the treated wastewater, the inputs of the unit of the first stage of the electro-membrane treatment being connected respectively to the outputs of the first, second and fourth tanks of the recirculation unit of the working solutions, the outputs of the unit of the first stage of electro-membrane processing are connected respectively to the inputs of the first and third tanks of the recirculating unit of working solutions, and the inputs of the block of the second stage of the electro-membrane processing are connected respectively to the outputs of the first, third and fourth tanks of the recirculation block working solutions, the output of the block of the second stage of the electro-membrane treatment is connected to the inlet of the first tank of the recirculation block of working solutions.

The disadvantages of the prototype are:

1. Low productivity - not more than 0.1 t / h in wastewater, due to the parallel-sequential scheme of operation of the first and second stages of electro-membrane treatment.

2. A complex technological scheme, due to the presence of two electro-membrane devices and four tanks for working solutions,

3. The total electricity consumption of 13 kWh, due to the use of 2 multi-chamber electro-membrane devices.

4. The additional consumption of demineralized water for the withdrawal of softened saline from the block of the first stage of the electro-membrane treatment.

The objectives of the utility model is to develop the design of the installation for the disposal of alkaline wastewater and to obtain a concentrated alkaline solution and partially desalinated softened solution, which eliminated the disadvantages of the analogue and prototype.

The technical result is to simplify the technological scheme of utilization of alkali-iron oxide with the production of concentrated alkali and partially desalinated softened solution through the use of a single electro-membrane apparatus, which excludes the introduction of chemicals in the form of demineralized water.

The technical result is achieved by the fact that the alkaline wastewater treatment plant contains an alkaline wastewater supply line arranged in a technological sequence, a working solution recirculation unit and a multi-chamber electromembrane apparatus for producing a concentrated alkaline solution and partially desalinated softened solution, while the working solution recirculation unit contains three tanks tied with pipes made of chemically resistant material, the first tank is installed with the possibility of filling industrial a washing solution, and the second and third tanks are installed with the possibility of filling with alkaline wastewater, the inputs of the multi-chamber electro-membrane apparatus are connected respectively to the outputs of the first, second and third tanks of the recirculation unit of working solutions, and the outputs of the multi-chamber electro-membrane are connected to the inputs of the first, second and third tanks block recirculation of working solutions, moreover, multi-chamber electro-membrane apparatus is made in the form of a three-channel multi-chamber electro-membrane o apparatus, excluding the additional input of chemical reagents in the form of demineralized water, with alternating anion-exchange and cation-exchange membranes with two near-electrode washing chambers.

The invention is illustrated by drawings, where in FIG. 1 shows a technological block diagram of the proposed installation for the disposal of alkaline wastewater, and in FIG. 2 - three-channel multi-chamber electro-membrane apparatus with alternating anion-exchange and cation-exchange membranes.

In the drawings, the numbers indicate:

1 - the first tank of the block recirculation of working solutions (tank washing solution),

2 - the second tank of the recirculation block of working solutions (concentrate tank),

3 - the third tank of the recirculation unit of working solutions (diluent tank),

4 - multi-chamber electromembrane apparatus,

5 - anion exchange membrane

6 - cation exchange membrane

7, 8 - near-electrode chambers,

9, 10, 11, 12, 13 ... N - working chambers.

The alkaline wastewater treatment plant contains an alkaline wastewater supply line arranged in a technological sequence, a working solution recirculation unit, and a multi-chamber electromembrane apparatus 4 for producing a concentrated alkaline solution and obtaining a partially desalted softened solution.

The recirculation block of working solutions contains three tanks 1, 2, 3, tied with pipes of chemically resistant material.

The first tank 1 - tank wash solution is installed with the possibility of filling the wash solution.

The second tank 2 - the concentrate tank, and the third tank 3 - the diluent tank - are installed with the possibility of filling with alkaline wastewater.

The inputs of the multi-chamber electro-membrane apparatus 4 are connected, respectively, with the outputs of the first, second and third tanks of the recirculation unit of the working solutions.

The outputs of the multi-chamber electro-membrane apparatus 4 are connected, respectively, with the inputs of the first, second and third tanks of the recirculation unit of the working solutions.

Multi-chamber electro-membrane apparatus 4 is made in the form of a three-channel multi-chamber electro-membrane apparatus with alternating anion-exchange 5 and cation-exchange 6 membranes and two near-electrode washing chambers 7 and 8.

The multi-chamber electro-membrane apparatus 4 contains working chambers 9, 10, 11, 12, 13 ... N. Working chambers 9, 11, 13, N are dilution chambers, and working chambers 10, 12 are concentrate chambers.

In the multi-chamber electromembrane apparatus 4, two types of membranes are used: membranes selectively permeable to anions — anion-exchange membranes 5, and membranes selectively permeable to cations — cation-exchange membranes 6. The three-channel multi-chamber electro-membrane apparatus 4 shown in FIG. 2, has two groups of chambers isolated from each other — diluent chambers 9, 11, 13, N and concentrate chambers 10, 12. Structurally, the multi-chamber electromembrane apparatus 4 is a packet drawn by sequential alternation of ion-exchange membranes 5, 6 and intermembrane gaskets, enclosed between clamping plates with built-in electrodes (not shown in the drawing). Each intermembrane gasket with two adjacent membranes 5 and 6 form a working chamber (9, 10, 11, 12, 13 ... N), which is a sealed flow channel, into the cavity of which separator-turbulators are placed (not shown in the drawing), the purpose of which is to create the required turbulence of the solution flow and to prevent direct contact between the membranes. In the process, the washing solution, concentrate, diluent continuously flow through the corresponding chambers of the apparatus. The outflowing streams of each path are combined in prefabricated outlet channels. The extreme chambers 7 and 8 of the package, located directly at the electrodes, are near-electrode, with separate washing. The multi-chamber electromembrane apparatus 4 is made in the form of a three-channel assembly: a concentrate path, a diluent path and a wash solution path.

The essence of the alkaline waste disposal method implemented by the proposed installation is the directed transfer of dissociated ions (salts dissolved in water) under the influence of a constant electric field through selectively permeable ion-exchange membranes.

The process of disposal of alkaline wastewater is carried out in the following way.

Alkaline wastewater is fed into tanks 2, 3. Tank 1 is filled with a 1-2% alkaline wash solution. From tanks 1, 2, 3, alkaline water is fed to fine filters (not shown in the drawing). Pre-cleaned and clarified solutions in fine filters are sent to a three-channel multi-chamber electromembrane apparatus 4, which is divided into chambers of the dilute 9, 11, 13, N and concentrate 10, 12 limited by anion exchange 5 and cation exchange 6 membranes. In the extreme chambers 7 and 8, bipolar platinum-titanium electrodes are installed (not shown in the drawing). In the chambers of the concentrate 10, 12, concentration and purification of the alkaline solution occurs, in the chambers of the diluent 9, 11, 13, N - desalination of the effluents. Concentrated alkali pump (not shown in the drawing) is allocated for reuse. The diluate, a partially desalted softened solution, is diverted by a pump (not shown in the drawing) for technical needs. Through the near-electrode chambers 7 and 8 and the tank 1 by a pump (not shown), an alkaline wash solution is circulated.

Concrete example

The alkaline wastewater disposal plant was tested at the electro-membrane installation (EMU) of Kazan TPP. The installation includes a modernized, according to this utility model, multi-chamber electromembrane apparatus - EMA-120/2. The characteristics of the device are shown in table 1.

From the storage tanks (BN) of the chemical workshop of the Kazan CHP, SCHW is fed to the alkaline wastewater disposal plant. During the operation of the multi-chamber electromembrane apparatus, the initial alkali-metal alloys are divided into two products - concentrate and diluent. The chemical composition of the initial alkali metal oxide and processed products EMA-120/2 are shown in tables 2 and 3.

According to the results of chemical analysis, the concentrate of the electro-membrane apparatus is a concentrated alkaline solution with an alkali concentration of 3.12 masses. %, and the diluent is a softened partially desalted solution. The resulting concentrated alkaline solution is fed into the strong alkaline water tank of the chemical workshop for reuse in the regeneration of anion exchange filters of the first stage. A softened partially desalted solution is fed into a tank of chemically purified water, and then used, for example, to feed the heating system. Thus, when disposing of alkali-iron ore, there is no additional consumption of reagents at the alkaline wastewater disposal plant, and waste is not generated.

ShchSV utilization rate on the proposed installation is 0.5 t / h. In this case, the mass ratio of the obtained products (concentrated alkaline solution: softened partially desalted solution) is 1: 4. The specific energy consumption for the disposal of 1 ton of SCHW is 6 kWh.

The proposed installation provides a reagent-free and waste-free disposal of alkaline wastewater in a simple and effective way.

Thus, the use of the proposed utility model allows you to:

1. To increase the productivity of obtaining a concentrated alkaline solution from alkaline wastewater to 0.2 t / h,

2. To simplify the technological scheme for the utilization of alkali-iron oxide with the production of concentrated alkali and partially desalinated softened solution.

3. To reduce the total electricity consumption from 13 to 6 kWh.

4. To exclude the introduction of chemicals in the form of demineralized water.

Claims (1)

An alkaline wastewater treatment plant comprising an alkaline wastewater supply line arranged in a technological sequence, a working solution recirculation unit and a multi-chamber electromembrane apparatus for producing a concentrated alkaline solution and partially desalinated softened solution, while the working solution recirculation unit contains three tanks connected by chemically connected pipelines resistant material, the first tank is installed with the possibility of filling with a washing solution, and the second and third tanks are installed with the possibility of filling with alkaline wastewater, the inputs of the multi-chamber electro-membrane apparatus are connected respectively to the outputs of the first, second and third tanks of the working solution recirculation unit, and the outputs of the multi-chamber electro-membrane apparatus are connected respectively to the inputs of the first, second and third tanks of the working solution recirculation block, the multi-chamber electro-membrane the apparatus is made in the form of a three-channel multi-chamber electromembrane apparatus, eliminating the additional the introduction of chemical reagents in the form of demineralized water, with alternating anion-exchange and cation-exchange membranes with two near-electrode washing chambers.

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