RU2090519C1 - Plant for producing liquid chlorination agent - Google Patents

Abstract

FIELD: production of chlorine-containing compounds. SUBSTANCE: plant has electrolyzer, electrolyte solution preparation and dosage unit, and communication unit. Electrolyzer has separated anode and cathode chambers. Plant also has water flow line and ejector installed in this line with its suction pipe connected to connecting pipe for discharging electrolysis products from anode chamber. There is also collector-separator with inlet connected to above-mentioned connecting pipe and outlet to suction pipe of ejector. Collector-separator also communicates with air-supply line. Electrolyte solution preparation and dosage unit includes solution reservoir, osmosis dispenser, and pipelines forming closed electrolyte solution circuit. Plant further has electrolyte solution desalting unit with its inlet connected to electrolyte solution preparation and dosage unit and outlet to electrolyzer inlet. EFFECT: improved design. 5 cl, 1 dwg

Description

 The invention relates to the field of water treatment, and in particular to installations for producing a liquid disinfecting chlorinating agent.

A known installation for producing a liquid chlorinating agent formed when gaseous chlorine is introduced into the water from a cylinder [1]
The feedstock for the process at this installation is liquefied chlorine, which is supplied to the installation in high pressure cylinders. To transfer liquefied chlorine to a gaseous state and to separate it from impurities, an intermediate cylinder is used.

 The installation contains a cylinder with liquefied chlorine, an intermediate cylinder and a storage tank with water, where chlorine gas is supplied from the intermediate cylinder through a gas metering unit. The resulting liquid chlorinating agent (chlorine water) from the storage tank is fed into the treated water.

 The operation of this installation is associated with the use of liquefied chlorine from cylinders, which can lead to environmental pollution by chlorine due to leakage. In addition, this installation is difficult and inconvenient in operation due to the need to transfer chlorine from liquefied to gaseous state, as well as due to the operation of periodic replacement of cylinders.

 A known installation for producing a liquid chlorinating agent [2] which is selected by the authors for the prototype.

 At this installation, a chlorinating agent is produced in the form of an aqueous solution of sodium hypochlorite. Sodium hypochlorite is obtained by electrolysis of sodium chloride (sodium chloride).

 An apparatus for producing a sodium hypochlorite solution includes a diaphragmless electrolyzer, a unit for preparing and dosing sodium chloride (electrolyte), a storage tank for a saturated sodium hypochlorite solution, as well as a communication system linking the units of the installation.

 A saturated solution of sodium chloride is prepared in the solution tank of the unit for preparing and dosing the electrolyte solution, it is pumped into the electrolyzer, where it is diluted with water to the desired concentration, and electrolysis is carried out, while chlorine and oxygen are released at the anode, and sodium hydroxide and hydrogen are extracted at the cathode. The design of a diaphragmless electrolyzer does not provide for separation of the electrolyzer volume into the cathode and anode chambers; therefore, chlorine and sodium hydroxide bind in the electrolyzer to sodium hypochlorite. Sodium hypochlorite in the form of a saturated solution enters the storage tank, from where it is fed into the treated water.

 During operation of this installation, the risk of environmental pollution by gaseous chlorine is significantly reduced, since it quickly passes into a bound state.

 However, due to the low yield of the chlorinating agent and the high energy consumption for carrying out the electrolysis process in non-diaphragm electrolysis, the described installation is not economical enough.

 In addition, the liquid chlorinating agent produced at the facility has a bactericidal effect that is not high enough.

 The objective of the invention is the creation of a plant for producing a liquid chlorinating agent with high disinfecting activity, which allows to increase the efficiency of the process while ensuring the safe operation of the plant.

 The essence of the claimed invention lies in the fact that the installation for receiving and dispensing an electrolyte solution, a communication system, as well as a flow line for water and an ejector, while an electrolyzer with separated anode and cathode chambers is used as an electrolyzer, an ejector is installed in a flow line for water, and its suction pipe is connected to a pipe for removing electrolysis products from the anode chamber.

 New in the proposed installation is that it contains a flow line for water and an ejector, an electrolyzer with separated anode and cathode chambers is used as an electrolyzer, an ejector is installed in a flow line for water, and its suction pipe is connected to a pipe for removing electrolysis products from the anode cameras.

 In addition, the installation contains a collector-separator, the input of which is connected to the pipe for removal of electrolysis products from the anode chamber, and the output is connected to the suction pipe of the ejector.

 In addition, the collector-separator is additionally connected to the air supply line.

 In addition, the unit for preparing and dispensing the electrolyte solution includes a solution tank, an osmotic dispenser, and pipelines forming a circulating circuit of the electrolyte solution.

 In addition, the installation contains a unit for cleaning the electrolyte solution from hardness salts, the input of which is connected to the output of the unit for preparing and dosing the electrolyte solution, and the output to the input of the electrolyzer.

 The use of an electrolyzer in the proposed installation makes it possible to electrolytically produce a gaseous chlorinating agent (chlorine) with high bactericidal properties in order to subsequently produce a liquid chlorinating agent (chlorine water).

 The use of an electrolyzer with separated anode and cathode chambers in an installation, the introduction of a flow line for water into the circuit and the installation of an ejector in this line connected to a pipe for removing electrolysis products from the anode chamber allow ejection of gaseous chlorine directly into the water supplied to the flow line . Thus, the high activity of chlorine formed during electrolysis is maintained and its leakage and environmental pollution are excluded.

 In addition, the use of an electrolytic cell with distributed anode and cathode chambers makes it possible to obtain a gaseous chlorinating agent in the anode chamber at relatively low energy consumption for electrolysis, which ensures the cost-effectiveness of the installation.

 The inclusion of a collector-separator in the installation diagram, the input of which is connected to the pipe for removing electrolysis products from the anode chamber, and the outlet with the suction pipe of the ejector, allows you to separate the gaseous and liquid phases of the analyte entering the collector-separator from the anode chamber, which increases the output of gaseous chlorinating agent and increases the efficiency of the installation.

 The connection of the collector-separator to the air supply line makes it possible to intensify the process of separating the gaseous chlorinating agent in the collector-separator.

 The inclusion of an osmotic doser and pipelines forming the circulation circuit of the electrolyte solution in the electrolyte solution preparation and batching unit allows dosing and circulation of the electrolyte solution to intensify the process of dissolution of the initial product due to the process of natural osmosis without additional energy costs, which also increases the efficiency of the installation.

 The presence in the installation of the unit for cleaning the electrolyte solution from hardness salts improves the electrolysis process, and also eliminates the ingress of hardness salts together with a chlorinating agent in the outlet line of the installation, and, therefore, in disinfected water.

 The drawing shows a schematic diagram of the proposed installation.

 The installation comprises a unit for preparing and dispensing an electrolyte solution, including a solution tank 1, an osmotic dispenser 2, and also lifting and lowering pipes 3 and 4, respectively, forming a circulation circuit of the electrolyte solution. The installation also includes a unit 5 for cleaning the electrolyte solution from hardness salts, the input of which is connected to the output of the osmotic dispenser 2 via line 6, and the output is connected to the electrolyzer 7 via line 8. As an cleaning unit 5, an ion-exchange filter is used, for example. As the electrolyzer 7, for example, a bipolar membrane filter-fresh electrolyzer with separated anode and cathode chambers 9 and 10, respectively, is used. The installation also contains a collector-separator 11, an ejector 12, a flow line 13 for water having an outlet section 14. A pipe 15 for removing electrolysis products from the anode chamber 9 is connected via a line 16 to a collector-separator 11, the output of which is connected via a line 17 to the suction a pipe (not shown) of the ejector 12. The ejector 12 is placed in the highway 13 for water. As the ejector 12 is used, for example, a plate ejector with a flat profile flow part formed in the internal volume of the ejector. This design of the ejector is technological in manufacture, which allows it to be made of anticorrosive materials, for example, fluoroplastics. The collector-separator 11 is connected to the highway 18 for air exhaust. The installation also includes a collector-separator 19, which is connected by a line 20 to the pipe 21 for removal of electrolysis products from the cathode chamber 10. The collector-separator 19 is connected by a line 22 to a tank 23 for draining liquid products coming from the cathode chamber 10.

 Installation works as follows.

 In the solution tank 1, sodium chloride (sodium chloride) is loaded as a starting product and the tank 1 is filled with tap water. At the same time, water is supplied to the line 13, while water, passing through the ejector 12, creates a vacuum in the suction pipe of the ejector 12.

 The solution of sodium chloride from the tank 1 enters through the drain pipe 4 into the osmotic dispenser 2. The osmotic dispenser 2 is divided by semipermeable membranes into a solution and a water chamber (not shown in the drawing). The sodium chloride solution enters the solution chamber of dispenser 2, and water is supplied to the water chamber of dispenser 2. In the osmotic dispenser 2, the process of natural osmosis proceeds due to the difference in osmotic pressures due to the difference in salt concentration in the media contacting through semipermeable membranes. In this case, the difference in osmotic pressures causes the circulation of the electrolyte solution along the circuit, including the solution tank 1, the drain pipe 4, the osmotic dispenser 2 and the lift pipe 3, as well as the supply of the salt solution to block 5 along the line 6.

 In block 5 of the electrolyte solution purification, the salt solution passing through it is purified from calcium and magnesium ions, due to which the electrolyte solution is softened.

 The solution of the electrolyte after ionic purification in block 5 enters through the line 8 into the electrolysis cell 7. In the electrolyzer 7, electrolysis of sodium chloride solution is carried out with the formation of gaseous chlorine at the anode, and hydrogen and hydroxyl ions at the cathode, which bind to ions to caustic soda.

 Chlorine gas formed in the anode chamber 9 is sucked from the nozzle 15 by the ejector 12, passing through highways 16 and 17, and also through the collector-separator 11. At the same time, chlorine gas and some analyte get into the collector-separator 11. In the collector-separator 11, the liquid and gaseous phases of the analyte are separated. the air coming from the highway 18 intensifies the process of phase separation in the collector-separator 11. In addition, due to air entering the collector-separator 11, an additional amount of chlorine dioxide is formed in it, which has high bactericidal properties, and thereby increases the activity of the gaseous chlorinating agent coming from the outlet of the collector-separator 11.

 The gaseous chlorinating agent is sucked in by the ejector 12 and enters the water passing through the flow line 13, while the water is saturated with the chlorinating agent. The resulting liquid chlorinating agent through the outlet section 14 of the line 13 enters the tank (not shown) with treated water.

 The catalysis formed in the cathode chamber 10 from the pipe 21 through the line 20 enters the collector-separator 19, while hydrogen gas is discharged into the atmosphere, and the alkali solution (caustic soda) enters the tank 23 through the line 22 into the alkali collector.

 Thus, the proposed installation allows you to get a liquid chlorinating agent with highly active bactericidal properties, moreover, the process of producing a liquid chlorinating agent is continuous and can be carried out in the immediate vicinity of the location of the tank with purified water.

 The installation provides efficiency and reliability, satisfies the requirements of ecology and ease of use.

 The by-product (caustic soda) obtained during the operation of the installation extends the functionality of the installation.

Claims (5)

 1. Installation for producing a liquid chlorinating agent, including an electrolyzer, a unit for preparing and dosing an electrolyte solution, a communication system, characterized in that an electrolyzer with separated anode and cathode chambers is used as an electrolyzer, the installation comprises a flow line for water and an ejector installed in a flow water lines, while the ejector is connected to a pipe for removing electrolysis products from the anode chamber.  2. Installation according to claim 1, characterized in that it comprises a collector-separator, the input of which is connected to a pipe for removing electrolysis products from the anode chamber, and the output is connected to an ejector.  3. Installation according to claim 2, characterized in that the collector-separator is additionally connected to the air supply line.  4. Installation according to paragraphs. 1 to 3, characterized in that the unit for the preparation and dosing of the electrolyte solution includes a solution tank, an osmotic dispenser and pipelines forming a circulation circuit of the electrolyte solution.  5. Installation according to paragraphs. 1 to 4, characterized in that it contains a unit for cleaning the electrolyte solution from hardness salts, the input of which is connected to the output of the unit for preparing and dosing the electrolyte solution, and the output to the input of the electrolyzer.