RU145898U1 - PLANT FOR PRODUCING AQUEOUS SOLUTION OF CHLORINE DIOXIDE AND CHLORINE - Google Patents

Abstract

1. Installation for obtaining an aqueous solution of chlorine dioxide and chlorine, containing a reactor for producing a gas-liquid mixture of chlorine dioxide and chlorine, reagent supply lines, metering pumps for supplying reagents to the reactor, a safety valve, a water jet ejector, a control unit, characterized in that the installation for for obtaining an aqueous solution of chlorine dioxide and chlorine is additionally equipped with a check valve, and the check valve is installed after the water jet ejector on the supply line of the obtained aqueous solution of chlorine dioxide and chlorine to the treated water. Installation for obtaining an aqueous solution of chlorine dioxide and chlorine according to claim 1, characterized in that the control unit includes a system for monitoring the pressure of water entering the water jet ejector, a system for monitoring the vacuum in the reactor, a system for monitoring the temperature in the reactor and the environment surrounding the reactor, a system for monitoring the availability chlorine dioxide in the resulting aqueous solution of chlorine dioxide and chlorine. 3. Installation for obtaining an aqueous solution of chlorine dioxide and chlorine according to claim 1, characterized in that it is additionally equipped with a system for washing the reactor with water. Installation for producing an aqueous solution of chlorine dioxide and chlorine according to claim 1, characterized in that it is additionally equipped with a water pressure reducer. Installation for obtaining an aqueous solution of chlorine dioxide and chlorine according to claim 1, characterized in that it is additionally equipped with a flow meter, while the flow meter is installed on the water supply line in front of the water jet ejector.

Description

The utility model relates to chemical equipment for the production of a solution of chlorine-containing oxidizing agents, used as disinfecting agents in the disinfection and purification of drinking, waste, recycled water and other media, in particular, to plants for the production of an aqueous solution of chlorine dioxide and chlorine.

A known installation for the production of chlorine dioxide, including a reactor, containers for reagents, metering pumps for supplying reagents to the reactor, valves, ejector, control unit, while from the reactor the reaction medium (gas-liquid mixture of chlorine dioxide and chlorine) enters the ejector through a pipeline, which has a tap for pumping the reaction medium (a gas-liquid mixture of chlorine dioxide and chlorine) poured from the reactor. As a reactor in a plant for the production of chlorine dioxide, a hollow cylindrical apparatus is used with separate reagent inputs through the walls of the housing at the bottom, vertical rod-shaped heating elements connected through the bottom of the housing and placed in exhaust pipes, as well as one common opening at the top cover for piping output reaction medium (gas-liquid mixture of chlorine dioxide and chlorine) into the ejector (see patent for invention EP No. 0106503 "Production of chlorine dioxide", 3 IPC С01В 11/02, C01B 11/025, priority date 09/09/1982, publ. Rejoiced 04/25/1984).

A disadvantage of the known installation for the production of chlorine dioxide is the high energy consumption due to the need to heat the reaction medium and conduct a chemical reaction in the reactor in boiling mode. This also leads to the need to condense the formed steam with an additional amount of water passed through the ejector, and, consequently, to an additional flow of water.

In addition, the presence in the reactor of the aforementioned installation of vertical rod-shaped heating elements connected through the bottom of the housing and placed in exhaust pipes creates an unstable hydrodynamic mode of operation of the reactor due to the appearance of local overheating zones. This leads to the formation of large gas bubbles and the decomposition of chlorine dioxide ("pant"), and, therefore, reduces its reliability and safety of operation.

Also, as a result of the instability of the hydrodynamic regime, the operation of the above installation is possible only in a narrow range of strictly controlled parameters, which affects the stability of its operation and does not allow changing its performance during operation (all operating modes described in the description are periodic).

Closest to the claimed utility model is a plant for producing a solution of chlorine dioxide from sodium chlorate, containing a reactor for producing a solution of chlorine dioxide having a water jacket with vertical rod-shaped heating elements for heating water of a water jacket, reactant supply lines, metering pumps for supplying reactants to the reactor , safety valve, ejector, control unit (see CN patent application No. 101492152 "Chlorine dioxide solution generator with sodium chlorate as reaction raw material" , 8 IPC С01В 11/02, priority of March 13, 2009, published July 29, 2009).

A disadvantage of the known installation for the production of chlorine dioxide is the high energy consumption due to the use of vertical rod-shaped heating elements for heating water in a water jacket due to the need to heat the reaction medium and conduct a chemical reaction in the reactor in boiling mode. This also leads to the need to condense the generated steam with an additional amount of water passed through the ejector, and, consequently, to an additional flow of water.

The presence of a water jacket at the reactor also leads to additional water consumption of the above installation as a whole.

In addition, in the known device, the reactor, although equipped with a water jacket, in which vertical rod-shaped heating elements are placed (constructive heating of the reaction medium), however, for the operation of the known device, the chemical reaction in the reactor must still proceed in boiling mode, which leads to the formation of large gas bubbles and the decomposition of chlorine dioxide ("pant"), and therefore reduces its reliability and safety of operation.

At the same time, the presence of a safety valve of the installation, which is intended only to relieve excess pressure from the reactor in emergency situations, does not eliminate the possibility of transferring the pressure of the treated water through the ejector to the reactor when the installation stops (emergency or planned), which can lead to its damage / destruction, and, therefore, reduces the reliability and safety of operation of the installation.

Also, as a result of the instability of the hydrodynamic regime, the operation of the above installation is possible only in a narrow range of tightly controlled parameters (in particular, control of the water temperature of the water jacket), which does not allow changing its performance during operation.

The technical result of the claimed utility model is to increase the reliability and safety of operation of the installation to obtain an aqueous solution of chlorine dioxide and chlorine, as well as to reduce energy consumption and water consumption and the ability to vary productivity during operation of the installation.

The claimed technical result is achieved by the fact that in the inventive installation for producing an aqueous solution of chlorine dioxide and chlorine containing a reactor for receiving a gas-liquid mixture of chlorine dioxide and chlorine, reactant supply lines, metering pumps for supplying reactants to the reactor, a safety valve, a water-jet ejector, a unit According to a utility model, the installation for producing an aqueous solution of chlorine dioxide and chlorine is additionally equipped with a check valve, and the check valve is installed after the water-jet zhektora line feeding the resulting aqueous solution of chlorine dioxide and chlorine in the treated water.

In this case, the control unit of the installation for producing an aqueous solution of chlorine dioxide and chlorine dioxide includes a control system for the pressure of water entering the water jet ejector, a control system for rarefaction in the reactor, a system for monitoring the temperature in the reactor and the surrounding environment, and a system for monitoring the presence of chlorine dioxide in the resulting aqueous solution of dioxide chlorine and chlorine.

Moreover, the installation for producing an aqueous solution of chlorine dioxide and chlorine can be additionally equipped with a system for washing the reactor with water.

In addition, the apparatus for producing an aqueous solution of chlorine dioxide and chlorine may be further provided with a water pressure reducer.

Also, the installation for obtaining an aqueous solution of chlorine dioxide and chlorine may be additionally equipped with a flow meter, which is installed on the water supply line in front of the water-jet ejector.

Reliability and safety of operation of the installation for obtaining an aqueous solution of chlorine dioxide and chlorine is achieved due to the trouble-free operation of its reactor, which is not designed for high pressure. This technical problem is partially solved due to the presence of a safety valve designed to relieve excess pressure from the reactor resulting from the formation of an excess gas-liquid mixture of chlorine dioxide and chlorine in it. Additional supply of the installation for the production of an aqueous solution of chlorine dioxide and chlorine with a check valve installed after the water-jet ejector on the supply line of the obtained aqueous solution of chlorine dioxide and chlorine to the treated water prevents the transfer of the resulting aqueous solution of chlorine and chlorine dioxide through the water-jet ejector to the column reactor due to the difference in the heights of the installation itself and the direct point of entry of the resulting aqueous solution of chlorine dioxide and chlorine into the treatment yvaemuyu water, which is generally located above the level at which the plant itself. This allows, in case of stopping the operation of the installation, that is, when the water supply from the network to the waterjet ejector is stopped, to prevent damage / destruction of the reactor by preventing the flow direction of the resulting aqueous solution of chlorine dioxide and chlorine from changing, not only in case of emergency, but also during the planned shutdown of the installation .

In addition, the reliability and safety of operation of the inventive installation, reducing water consumption and energy consumption, as well as the ability to vary productivity during its operation, is achieved due to the stability of the hydrodynamic regime and the intensity of the chemical reaction in the reactor, which is facilitated by the mixing of the reactants without heating them (without use of heating elements, without the need to condense steam with additional water), to obtain a gas-liquid mixture of chlorine dioxide and x ENT, without the formation of large bubbles and without decomposition of chlorine dioxide ("pant") determined by the design of the reactor, for example, used in the inventive installation (see RF patent for the invention No. 2503614 "Apparatus for implementing the method for producing a solution of chlorine dioxide and chlorine in water", 8 IPC С01В 11/02, priority dated May 31, 2011, published December 10, 2013).

No technical solutions matching the totality of essential features of the utility model have been identified, which allows us to conclude that the utility model meets the patentability criterion of “novelty”.

The patentability condition “industrial applicability” is confirmed by examples of a specific embodiment of the apparatus for producing an aqueous solution of chlorine dioxide and chlorine.

Figure 1 presents the block diagram of the installation for obtaining an aqueous solution of chlorine dioxide and chlorine.

The apparatus for producing an aqueous solution of chlorine dioxide and chlorine contains a reactor 1 for producing a gas-liquid mixture of chlorine dioxide and chlorine, a supply line 2, 3 of reagents, metering pumps 4, 5 for supplying reagents to the reactor, a safety valve 6, a water-jet ejector 7, a control unit 8.

The apparatus for producing an aqueous solution of chlorine dioxide and chlorine is additionally equipped with a check valve 9. A check valve 9 is installed after the water-jet ejector 7 on the supply line of the obtained aqueous solution of chlorine dioxide and chlorine in the treated water.

The control unit 8 of the installation for producing an aqueous solution of chlorine dioxide and chlorine includes a system for controlling the pressure of water entering the water jet ejector, a system for controlling the vacuum in the reactor, a system for monitoring the temperature in the reactor and the surrounding environment, and a system for monitoring the presence of chlorine dioxide.

The apparatus for producing an aqueous solution of chlorine dioxide and chlorine may additionally be equipped with a system for washing the reactor with water (not shown in the drawing).

The apparatus for producing an aqueous solution of chlorine dioxide and chlorine may additionally be equipped with a water pressure reducer 10.

The apparatus for producing an aqueous solution of chlorine dioxide and chlorine may additionally be equipped with a flow meter 11, which is installed on the water supply line in front of the water-jet ejector.

Reactor 1 (RF patent for the invention No. 2503614) contains a housing with supply lines 2, 3 of reagents, an outlet for outputting a gas-liquid mixture of chlorine dioxide and chlorine located in the upper part of the housing and connected to a water-jet ejector 7. The reactor vessel 1 and the circulation device are made in the form of a truncated cone. Reagent supply lines 2, 3 are located in the end part of the reactor vessel 1, are inserted inside the circulation device, and are aligned with the axis of the vessel.

Installation for obtaining an aqueous solution of chlorine dioxide and chlorine works as follows.

Water from the network through a pressure reducer 10 and a flow meter 11 is fed into a water-jet ejector 7, while a vacuum is created in the reactor 1. Then, the metering pump 4 from the container 12 through the valve 13 into the reactor 1 serves sulfuric acid, then the metering pump 5 from the container 14 through the valve 15 into the reactor 1 serves a solution of chlorate and sodium chloride. In the reactor 1, a chemical reaction occurs with the formation of an aqueous solution of chlorine dioxide and chlorine and gaseous chlorine dioxide and chlorine to obtain a gas-liquid mixture of chlorine dioxide and chlorine. The gas-liquid mixture of chlorine dioxide and chlorine from the reactor 1 is removed by a water-jet ejector 7, in which this mixture is dissolved in water supplied to the water-jet ejector 7 from the network to obtain an aqueous solution of chlorine dioxide and chlorine, which is used to treat water as a combined disinfectant.

In an emergency situation associated with the formation of excess pressure in the reactor 1, the safety valve 6 relieves the excess pressure due to the release of excess gas-liquid mixture of chlorine dioxide and chlorine from the reactor 1, thereby eliminating the possibility of damage / destruction. When restoring the working pressure in the reactor 1, the safety valve 6 ensures the termination of pressure relief.

The non-return valve 9, installed after the water-jet ejector 7 on the supply line of the obtained aqueous solution of chlorine dioxide and chlorine into the treated water, automatically passes the resulting aqueous solution of chlorine dioxide and chlorine towards the inlet point (not shown) in the treated water. When the water supply from the network to the water-jet ejector 7 is stopped as a result of a planned or emergency shutdown of the installation for receiving an aqueous solution of chlorine dioxide and chlorine, a check valve 9 installed after the water-jet ejector 7 on the supply line of the obtained aqueous solution of chlorine dioxide and chlorine into the treated water, prevents the pressure of the treated water through the water jet ejector 7 to the reactor 1. The check valve 9 prevents the transfer of pressure through the water ejector 7 to the reactor 1 column pressure the resulting aqueous solution of chlorine dioxide and chlorine, arising due to the difference in the heights of the installation itself and the direct point of entry of the obtained aqueous solution of chlorine dioxide and chlorine into the treated water, as it does not allow a change in the direction of flow of the obtained aqueous solution of chlorine dioxide and chlorine, which eliminates probability of damage / destruction of the reactor 1.

The presence of chlorine dioxide in the resulting aqueous solution of chlorine dioxide is monitored by the sensor 16. To maintain the process in the reactor 1 in the specified mode, the control unit 8 is used, which receives information about the temperature in the reactor 1 and the environment surrounding the reactor 1 from the temperature sensors 17 and 18 through a meter-controller 19. Data on the pressure of the water supplied to the water-jet ejector 7 and the vacuum in the reactor 1 is supplied to the control unit 8 from the sensors 20 and 21 through the meter-regulator 22.

The control unit 8 controls the performance of the installation to obtain an aqueous solution of chlorine dioxide and chlorine, depending on the water flow rate, provides information on the main parameters of the operation mode of the installation (pressure of water entering the water-jet ejector 7, vacuum in reactor 1, temperature in reactor 1 and the surrounding reactor 1 medium, the presence of chlorine dioxide in the resulting aqueous solution of chlorine dioxide and chlorine) and controls the operation of the units of the installation as a whole (in particular, the operation of metering pumps 4, 5).

Example.

Installation for producing an aqueous solution of chlorine dioxide and chlorine with a productivity of 2 kg / h on chlorine dioxide at the parameters listed below. Sulfuric acid with a concentration of 94-96% and an aqueous solution of chlorate and sodium chloride containing 310-330 g / l sodium chlorate and 170-190 g / l sodium chloride are used as reagents. The feed rate of sulfuric acid into the reactor is 6.6 l / h. The feed rate of the solution of chlorate and sodium chloride in the reactor is 11.5 l / h. The water pressure at the inlet to the ejector is 0.4 MPa. The flow rate of water through the ejector is 2 m ³ / h. The content of the disinfectant is monitored by chlorine dioxide with a chlorine dioxide sensor. Under the above conditions, the concentration of chlorine dioxide in an aqueous solution of chlorine dioxide and chlorine, leaving the water-jet ejector, is 1 g / l.

The inventive utility model provides increased reliability and safety of operation of the installation to obtain an aqueous solution of chlorine dioxide and chlorine, as well as reduced energy consumption and water consumption, the ability to vary productivity during operation of the installation.

Claims (5)

1. Installation for producing an aqueous solution of chlorine dioxide and chlorine, containing a reactor for producing a gas-liquid mixture of chlorine dioxide and chlorine, reactant supply lines, metering pumps for supplying reactants to the reactor, a safety valve, a water-jet ejector, a control unit, characterized in that the installation for to obtain an aqueous solution of chlorine dioxide and chlorine is additionally equipped with a check valve, and the check valve is installed after the water-jet ejector on the supply line of the obtained aqueous solution of chlorine dioxide and Lora in treated water. 2. Installation for obtaining an aqueous solution of chlorine dioxide and chlorine according to claim 1, characterized in that the control unit includes a control system for the pressure of the water entering the water jet ejector, a control system for rarefaction in the reactor, a temperature control system in the reactor and the surrounding environment, system monitoring the presence of chlorine dioxide in the resulting aqueous solution of chlorine dioxide and chlorine. 3. Installation for producing an aqueous solution of chlorine dioxide and chlorine according to claim 1, characterized in that it is additionally equipped with a system for washing the reactor with water. 4. Installation for producing an aqueous solution of chlorine dioxide and chlorine according to claim 1, characterized in that it is additionally equipped with a water pressure reducer. 5. Installation for producing an aqueous solution of chlorine dioxide and chlorine according to claim 1, characterized in that it is additionally equipped with a flow meter, while the flow meter is installed on the water supply line in front of the water-jet ejector.