RU2257355C1 - Water purification installation in a swimming pool - Google Patents

Abstract

FIELD: swimming pools water treatment.

SUBSTANCE: the invention is pertaining to the field of water treatment, in particular, to purification and disinfection means of the recirculating water in the closed contours of swimming pools, which use the principle of operation based on a joint application of the ozone-sorption and vacuum-ejection equipment at utilization of chemical compounds of the metals possessing of oligodynamic properties. The water purification installation in a swimming pool contains located on a pipeline a circulation pump, a bypass trunk line, a sand filter, an ozonizer and an adjusting gate. Besides the installation is supplied with a unit of reception of solutions of disinfectants, the first ejection mixer, a unit of the sand filter disinfection, consisting of the second ejection mixer and the first function switch of the operation modes, a multi-nozzle ejection mixer; a sorption unit; a heat exchanger; a controller of ozone concentration in the recirculating water; a sensor of a reduction-oxidation potential; a transducer of the reduction-oxidation potential; a unit of primary water preparation, the second function switch of operation modes; a filter screen and the perforated pipeline. The technical result: increased sanitary-and-epidemiologic reliability of the waters purification processes and disinfection and also prevention of secondary bacterial pollution of a swimming pool.

EFFECT: the invention ensures increased sanitary-and-epidemiologic reliability of the waters purification processes and disinfection prevention of a swimming pool secondary bacterial pollution.

6 cl, 1 dwg

Description

The invention relates to the field of water treatment, and in particular to means (installations) for cleaning and disinfecting recycled water in closed circuits of swimming pools, the principle of which is based on the combined use of ozone-sorption and vacuum ejection techniques using chemical compounds of metals with oligodynamic properties.

Known devices for water purification recommended by V. Lukyanov and its co-authors for use in medical swimming pools:

1. “Recycling water treatment station” (Patent RU No. 2144514 C1, IPC C 02 F 1/78, 2000), equipped with a hair trap, filter, ozonizer, heat exchanger, two ejectors, a saturator, a pressure flotator, flush and booster pumps, shut-off valves with electromagnetic actuators, position sensors of shut-off valves with electromagnetic actuators, four pressure sensors and a control unit with appropriate connections, allowing automatic cleaning of the circulating water and regeneration of the filter load of the filter.

2. “Recycling water treatment station” (Patent RU No. 2180324 C2, IPC C 02 F 9/04, 2000), equipped with an ejector, a saturator, a pressure flotator, a flushing pump, a tank for storing flushing water, a crane with a float actuator, a residual dissolved ozone concentration meter in circulating water, pressure sensors, shut-off valves with electromagnetic actuators, shut-off valve position sensors with electromagnetic actuators, nozzle, shutter, shutter displacement actuator, control device comparing the device That sets and control devices with their connections.

The disadvantages of these stations are the complexity, and therefore the unreliability in the operation of automatic control systems, the absence of a prolonged disinfecting effect during automatic shutdowns, and the inability to inactivate viruses, protozoa, fungi and microalgae while automatically maintaining the concentration of ozone dissolved in water at 0.1 mg / l permitted by SanPiN 2.1.4.1074-01 and SanPiN 2.1.2.1188-03.

Known methods of disinfection and treatment of circulating water of swimming pools of water, recommended by Gutenev V.V. and his co-authors:

1. “Method for the disinfection of circulating water in swimming pools” (Patent RU No. 2182127 C1, IPC C 02 F 1/50, 2001), which provides for filtration with sequential treatment of circulating water with ozone, ultraviolet radiation and an organic silver compound.

2. “Method for the disinfection of recycled water in swimming pools” (Patent RU No. 2188166 C1, IPC C 02 F 9/12, 2001), which provides for the sequential treatment of recycled water with hydrogen peroxide, ultraviolet radiation and an organic silver compound.

3. “The method of processing circulating water of swimming pools” (Patent RU No. 2188168 C1, IPC C 02 F 9/12, 2001) provides for the sequential treatment of circulating water with ozone, ultraviolet radiation, silver and copper ions.

The main disadvantages of these methods are:

- the complexity of the implementation of the proposed multi-stage methods for treating recycled water due to the need to maintain clearly regulated time and quantity ratios of chemical ingredients and physical effects;

- inefficiency of using silver ions due to the formation of insoluble silver salts (according to SanPiN 2.1.4.1074-01, the maximum permissible salinity of tap water is 1000 mg / L, the maximum permissible concentration of silver ions in water is 0.05 mg / L, and from the inorganic silver salts are soluble only silver nitrates);

- the possibility of accumulation in toxic water of toxic substances (insoluble silver salts, products of oxidation and ozonolysis) formed as a result of sequential exposure of polluted circulating water to oxidizing agents and heavy metal ions.

It is known “Device for disinfecting water of swimming pools using chlorine and ozone” (Patent RU No. 2142430 C1, IPC C 02 F 1/50, A. Kournikov, 1999), containing an air dryer, an ozone generator and a chlorine tank with appropriate pipelines, a common ejector for introducing chlorine or ozone into the water, a common contact column and a water purification filter, as well as a simple system switch.

The main disadvantages of this device are:

- the formation in the circulating water of toxic organochlorine compounds that cause specific diseases in swimmers;

- the possibility of the release of gaseous chlorine into the atmosphere;

- the need for special safety measures during the transportation of chlorine and the operation of chlorination equipment.

The closest in technical essence and the achieved result is “Installation for water purification in swimming pools” (Patent RU No. 22217388 C1, IPC C 02 F 1/78, Zubkov V.I. and Litvinov V.V., 2002), containing a circulation pump located on the pipeline, a sand filter, a bypass line, an ozonizer and a control valve installed between the input and output of the bypass line.

The main advantage of this installation compared to the aforementioned analogues is the introduction of two disinfecting agents (UV radiation and ozone) into the circulating water of the swimming pool along two parallel highways: the main and the bypass.

In the practical implementation of this installation, the placement of a UV irradiator on the main line of the circulation pipeline allows the inventors only selectively (UV irradiators commercially available in the CIS and Russia are unable to inactivate viruses, Giardia cryptosporodi cysts, helminth eggs and microalgae) to disinfect the main reverse flow water without pressure loss in the main line.

The location of the ozonizer on the bypass line, which provides for the inclusion of an ejector or bubbler mixer in the bypass line to mix part of the bypass water with ozone, allows the oxidation and destruction of various organic and inorganic pollutants, as well as the inactivation of pathogenic microorganisms (viruses, protozoa, microalgae, helminths, etc. .) resistant to UV exposure.

However, such an ozonator incorporation scheme has the following disadvantages:

- the possibility of oxidation and destruction of organic pollutants only in the bypass line of the circulation pipeline;

- forced pressure loss (for example, for the ejector several times) in the bypass line during operation of the ejection mixer or bubbler sprayer, which increases the circulation cycle time and accordingly increases the cost of electricity.

Given the above, we can conclude that the main disadvantages of the installation, selected as a prototype, are:

- insufficient sanitary and epidemiological reliability of water treatment and disinfection;

- the possibility of secondary bacterial and viral contamination of water during operation of the unit because UV irradiation does not have a prolonged effect, and the bactericidal activity of ozone introduced into the circulating water is limited in time and depends on a number of parameters of the circulating water being treated (temperature, turbidity, color and pH of recycled water, as well as the chemical composition and amount of organic and inorganic pollutants);

- the possibility of biological fouling of the sand filter and the propagation of pathogenic microflora on it due to the time-limited prolonged action of ozone in recycled water;

- lack of regulation of ozone concentration in recycled water.

The technical problem to which the present invention is directed is to increase the sanitary and epidemiological reliability of the processes for cleaning and disinfecting water in the swimming pool, as well as preventing secondary bacterial contamination of the swimming pool.

The problem is solved in that the installation for water purification in the swimming pool, containing a circulation pump, a bypass line, a sand filter, an ozonizer and an adjustment valve located between the inlet and outlet of the bypass line located on the pipeline, is additionally equipped with a disinfectant solution receiving unit; first ejector mixer; a sand filter disinfection unit consisting of a second ejector mixer and a first mode switch; multi-nozzle ejector mixer; sorption block; heat exchanger; regulator of ozone concentration in recycled water; redox potential sensor; redox potential converter; primary water treatment unit; second mode switch; strainer and perforated pipe; moreover, the control valve input is connected to the output of the first ejector mixer, the suction input of which is connected to the first output of the disinfectant solutions receiving unit, and the pressure input is connected to the output of the sand filter; the second ejector mixer is connected by an output to the first input of the sand filter, the pressure input is connected to the output of the circulation pump, and the suction input is connected to the output of the first mode switch, the first input of which is connected to the second output of the disinfectant solution receiving unit, and the second input of the first mode switch is connected to the first exit of the ozonizer; a multi-nozzle ejector mixer with a suction inlet connected to the second ozonizer output, a pressure inlet connected to a sand filter output, and an output connected to an input of the sorption unit; the redox potential converter is connected by an input to the output of the redox potential sensor and by an output to the input of the regulator of ozone concentration in the circulating water, the latter being connected to the control input of the ozonizer by the output; the primary water treatment unit with the first input is connected to the water supply network, the second input is connected to the third output of the ozonizer, and the output is connected to the first input of the second mode switch, the second input of which is connected through the mesh filter to the outlet openings of the pool, and the output of the second mode switch is connected to the input circulation pump, the latter connected to the input of the sand filter by its output; a perforated pipe is placed along the bottom of the pool bowl and is connected by its inlet to the outlet of the control valve and the outlet of the heat exchanger; the inlet of the latter is connected to the outlet of the sorption unit.

It is preferable that the disinfectant solution preparation unit is provided with an ionization element with electrodes, at least one of which is made of a metal having oligodynamic properties, for example, from a series of silver, copper, manganese, zinc or nickel.

It is preferred that the disinfectant solution production unit is in the form of a series-connected liquid dispenser and a container for storing solutions of organic or inorganic silver and copper compounds.

Preferably, the primary water treatment unit is made in the form of series-connected blocks of coagulation, flocculation, microfiltration, demineralization and ozone absorption.

It is preferable that the multi-nozzle ejector mixer is made in the form of ejectors parallel to the space and is equipped with a hydraulic flow averager, and the pressure inputs of the ejectors are combined by a common collector and connected to the output of the sand filter, the suction inputs of the ejectors are combined by a common collector and connected to the second output of the ozone generator, and the output the ends of the pipes located in parallel are rigidly fixed to the common flange.

It is preferable that the hydraulic flow averager is made in the form of a tank, the upper part of which is equipped with a flange for connecting the outlet pipes of a multi-nozzle ejector mixer, and a layer of fine-grained loading, for example crushed zeolite, a supporting layer, for example coarse expanded clay, and a coaxially located outlet pipe are placed in the lower part.

Thus, the set of essential features of the invention indicated in the claims provides the intended technical result.

The present invention is illustrated in the drawing, which shows a functional diagram of an installation for water purification in a swimming pool.

Installation for water purification in the swimming pool contains a main pipe 2 connected to the pool bowl 1, a circulation pump 3, a bypass line 4, a sand filter 5, an ozonizer 6, an adjustment valve 7, a disinfectant solution receiving unit 8, a first ejector mixer 9, a sand disinfection unit filter 10, consisting of a second ejector mixer 11 and a first operating mode switch 12, a multi-nozzle ejector mixer 13 provided with a hydraulic output flow averager (not shown), with a unit 14, a heat exchanger 15, an ozone concentration regulator 16 equipped with a redox potential sensor 17 located in the flooded part of the basin 1 and a redox potential converter 18, a primary water treatment unit 19, a second operating mode switch 20, a mesh filter 21, perforated pipeline 22, as well as standard elements of swimming pools skimmer 23 and bottom 24 water outlet devices.

Functionally, a water treatment plant in a swimming pool can be represented in the form of two hydraulic systems: a main hydraulic circuit equipped with a skimmer 23 and a bottom 24 water outlet devices, a strainer 21, a second mode switch 20, a circulation pump 3, a sand filter 5, a multi-nozzle ejector mixer 13, sorption unit 14, heat exchanger 15, perforated pipe 22, and bypass line 4, consisting of a first ejector mixer 9 and a control valve 7. In addition, the installation is equipped with four autonomous devices that also provide a solution to the problem: an ozonizer 6, equipped with an ozone concentration regulator 16, a redox potential sensor 17 and a redox potential converter 18, a disinfectant solution receiving unit 8, a sand filter disinfection unit 10, consisting of a second ejector mixer 11 and a first mode switch 12, and a primary water treatment unit 19.

The operation of the installation for water purification in the swimming pool is as follows.

For the initial filling of the bowl of the pool 1, water is used prepared in the primary water treatment unit 19 by sequentially treating tap water in the coagulation, flocculation, microfiltration, demineralization and ozone absorption units. Structurally, the primary water treatment unit 19 is performed in the form of an assembly of fiberglass cylindrical containers, interconnected by appropriate fittings and sanitary fittings.

The filling of the pool bowl 1 with water prepared in the primary water treatment unit 19 is carried out by the circulation pump 3 through the second operating mode switch 20 set to the “Filling” mode. In this case, the transported water stream is divided into two streams: main and bypass. The main flow of prepared water passes sequentially through a pre-sanitized sand filter 5, a multi-nozzle ejector 13, a sorption unit 14, a heat exchanger 15, and through the openings of the perforated pipe 22 enters the pool bowl 1. A bypass flow of prepared water passes sequentially through the first ejector mixer 9, control valve 7 and bypass line 4 enters the perforated pipe 22, where it is mixed with the main stream.

After filling the pool bowl 1 with prepared water, the second operating mode switch 20 is set to the “Operation” mode and the process of circulating water circulation begins. Using the standard skimmer devices for the pool 23, the water from the pool 1 flows through the strainer 21 and the second mode switch 20 to the circulation pump 3, which transports the circulating water along the main and bypass lines described above.

Coarse purification of recycled water, including hair trapping, etc., is performed by a strainer 21 and a sand filter 5.

Disinfection of the main flow of circulating water is carried out by ozone, which is produced in the ozonizer 6 from oxygen in the air when exposed to a high voltage electric discharge. The mixture of the ozone-air mixture obtained in ozonizer 6 with circulating water and the oxidation of pollutants and microorganisms occur in the reactor and the hydraulic flow averager (not shown) of the multi-nozzle ejector mixer 13. In the sorption block 14 filled with activated carbon and zeolite, the sorption purification of recycled water from the products of ozonolysis and the processes of oxidation of pollutants and disinfection of microorganisms continue.

In the heat exchanger 15, the circulating water is heated to a temperature defined in SanPiN 2.1.2.1188-03, as well as the thermal decomposition of ozone that does not react with the circulating water.

Disinfection of the bypass flow of circulating water is carried out by a disinfecting solution of metal ions with oligodynamic properties produced in the block for obtaining disinfectant solutions 8 (two structural options: ionizer or ready-made disinfectant solution). The mixture of disinfectant solution with a bypass flow of circulating water, obtained in the first ejector mixer 9, enters through the control valve 7, the bypass line 4 and the perforated pipe 22 into the bowl of the pool 1. Depending on the design features of the pool and the technological scheme of water treatment, as well as the degree of contamination of the circulating water water, the ejector mixer 9 can be made in the generally accepted constructive embodiment or in the form of a multi-nozzle ejector mixer 13, considered in paragraphs 5-6 of the formula proposed of my invention.

The sand filter 5 is to be disinfected in three modes: ozone coming from the first output of the ozonizer 6 to the second input of the first mode switch 12; a disinfecting solution of metal ions coming from the second output of the disinfectant producing unit 8 to the first input of the first mode switch 12, and a mixture of ozone and a disinfecting solution of metal ions. The type of disinfection mode is determined by the selected position of the first mode switch 12.

The use of a perforated pipe 22 made of an ozone-resistant material, such as polypropylene or polyvinyl chloride, located on the bottom of the swimming pool, the placement of the heat exchanger 15 after the sorption block 14, and the use of an ozone concentration regulator 16 allow us to optimize the ozone treatment of the swimming pool recycled water, eliminating the need for an ozone destructor , as well as improve the environmental safety of ozone and the economical operation of the proposed installations for water purification in swimming pools.

The materiality of the differences and advantages of the proposed invention are determined by the following technical solutions:

1. Placement in the gap of the main pipeline of a multi-nozzle ejector mixer equipped with a hydraulic flow averager, structurally made in the form of ejectors parallel to the space, the pressure inputs of which are connected by a common collector and connected to the main line of the circulation circuit, the suction inputs are combined by a common collector and connected to the second output ozonator, and the output parallel to the nozzles are fixed using a flange connection on the top cover the body of the hydraulic flow averager, it is possible to efficiently mix the ozone-air mixture coming from the second output of the ozonizer with the treated circulating water without causing significant pressure losses in the main pipeline. To increase the interaction time of ozone with treated water, the hydraulic flow averager is constructed in the form of a tank, the upper part of which is equipped with a flange for connecting the outlet pipes of a multi-nozzle ejector mixer, and a layer of fine-grained loading, for example, crushed zeolite, a supporting layer, for example, coarse expanded clay, is placed in the lower part, and coaxially located outlet pipe.

2. Placing at the outlet of a multi-nozzle ejector mixer a series-connected sorption block filled with a mixture of activated granulated carbon and zeolite and a standard heat exchanger used to heat water in the pool, it allows to delay the products of ozonolysis and ozone itself, which will increase the estimated time of interaction of ozone with recycled water. In addition, the combined use of activated carbon and ozone causes a synergistic effect of accelerating the processes of ozonolysis. In addition, on a heat exchanger that maintains the temperature of the water in the swimming pool about 26 grams. Celsius (according to the requirements of SanPiN 2.1.2.1188-03), thermal decomposition of ozone will occur as on any standard ozone destructor.

3. Placing a redox potential sensor (Eh) in the pool bowl that generates an information signal about the dissolved ozone content in the pool water, coming through the redox potential converter and ozone concentration regulator to the ozonator control input, allows optimizing the process of disinfecting the circulating water in the pool. According to reference data, the disinfection of tap water and the inactivation of bacteria in it occur at Еh = 600 mV, which corresponds to the concentration of ozone in water C = 0.5 mG / L, and complete sterilization of water occurs at Еh = 800 mV, which corresponds to an increase in ozone concentration to values of 0.7-1.0 mg / l, depending on the physico-chemical composition of the circulating water.

4. The use of a perforated pipeline for introducing disinfectant reagents into the circulating water of the pool bowl made of ozone-resistant material, for example polypropylene or polyvinyl chloride, allows increasing the interaction time of ozone and disinfectants with circulating water due to the length of the pipeline and the process of bubbling disinfectant reagents through the water layer in the pool bowl, and also reduce the concentration of residual ozone in the circulating water of the basin by increasing the time of ozone treatment.

5. The use of a disinfectant solution production unit equipped with a first ejector mixer will prevent secondary bacterial contamination of the swimming pool circulating water by supplying an additional amount of disinfectants with prolonged action properties to the pool bowl through the bypass line.

Structurally, the block for obtaining disinfectant solutions is proposed to be performed in two versions:

- in the form of an ionizer, the electrodes of which are made of metals having oligodynamic properties, for example, from the series: silver, zinc, copper, manganese or nickel;

- in the form of a series-connected liquid dispenser and a container for storing solutions of organic or inorganic compounds of silver and copper.

The quantity and procedure for the introduction of disinfectants are determined by the regulations developed taking into account the design features of the pool and the physicochemical properties of the water filling it.

6. The use of a sand filter disinfection unit equipped with a second ejector mixer and a mode switch will prevent secondary bacterial and viral contamination of the sand filter itself, which uses a small part of the produced ozone and disinfectants with prolonged action properties. Structurally, the sand filter disinfection unit will be implemented as a mode switch, the first input connected to the second output of the disinfectant solutions receiving unit, the second input to the first output of the ozonizer, and the output to the input of the second ejector mixer, included in the gap of the auxiliary bypass line of small diameter, with an input and output connected to the main circulation line.

7. The use of the primary water treatment unit, the first input connected to the water supply network, the second input to the third output of the ozonizer, and the output connected to the first input of the second operating mode switch, allows for the initial filling of the pool from the water supply network to obtain conditioned and pre-decontaminated ozone water, and also reduce during the operation of the pool the amount of necessary disinfectants. Structurally, the block of primary water treatment is performed in the form of series-connected blocks of coagulation, flocculation, microfiltration, demineralization and ozone absorption.

8. The use of a strainer allows you to retain hair, large particles of contaminants, etc., which simplifies further filtering and disinfection of recycled water.

A comparative analysis of the claimed “Installations for water purification in a swimming pool” with a prototype and with other solutions in the art shows that the set of features set forth in the patent formula is unknown from the prior art, on the basis of which we can conclude that it meets the criteria of the invention “ novelty".

Moreover, the set of essential features set forth in the formula does not follow explicitly for a specialist from the existing level of technology, which allows us to conclude that the proposed solution meets the second criterion of the invention “inventive step”.

The compliance of the proposed solution with the criterion of the invention “industrial applicability” is obvious from the above description of the operation of the installation for water treatment in a swimming pool.

Claims (6)

1. Installation for water purification in a swimming pool, comprising a circulation pump, a bypass line, a sand filter, an ozonizer and an adjustment valve located between the inlet and outlet of the bypass line located on the pipeline, characterized in that, in order to increase the sanitary and epidemiological reliability of the cleaning processes , disinfecting water in the swimming pool, as well as preventing secondary bacterial contamination of the swimming pool, it is equipped with a disinfectant solution production unit ; first ejector mixer; a sand filter disinfection unit consisting of a second ejector mixer and a first mode switch; multi-nozzle ejector mixer; sorption block; heat exchanger; regulator of ozone concentration in recycled water; redox potential sensor; redox potential converter; primary water treatment unit; second mode switch; strainer and perforated pipe; moreover, the control valve input is connected to the output of the first ejector mixer, the suction input of which is connected to the first output of the disinfectant solutions receiving unit, and the pressure input is connected to the output of the sand filter; the second ejector mixer is connected by an output to the first input of the sand filter, the pressure input is connected to the output of the circulation pump, and the suction input is connected to the output of the first mode switch, the first input of which is connected to the second output of the disinfectant solution receiving unit, and the second input of the first mode switch is connected to the first exit of the ozonizer; a multi-nozzle ejector mixer with a suction inlet connected to the second ozonizer output, a pressure inlet connected to a sand filter output, and an output connected to an input of the sorption unit; the redox potential converter is connected by an input to the output of the redox potential sensor, and by the output to the input of the regulator of ozone concentration in the circulating water, the latter being connected to the control input of the ozonizer by its output; the primary water treatment unit, the first input is connected to the water supply network, the second input to the third output of the ozonizer, and the output is connected to the first input of the second mode switch, the second input of which is connected through the mesh filter to the outlet openings of the pool, and the output of the second mode switch is connected to the circulation input pump, the last connected to the input of the sand filter by its output; a perforated pipe is placed along the bottom of the pool bowl and is connected by its inlet to the outlet of the control valve and the outlet of the heat exchanger; the inlet of the latter is connected to the outlet of the sorption unit. 2. Installation according to claim 1, characterized in that the disinfectant solution production unit is provided with an ionization element with electrodes, at least one of which is made of metal having oligodynamic properties, for example, silver, copper, manganese zinc or nickel. 3. Installation according to claim 1, characterized in that the unit for obtaining disinfectant solutions is made in the form of a series-connected liquid dispenser and a container for storing solutions of organic or inorganic compounds of silver and copper. 4. Installation according to claim 1, characterized in that the primary water treatment unit is made in the form of series-connected blocks of coagulation, flocculation, microfiltration, demineralization and ozonorption. 5. Installation according to claim 1, characterized in that the multi-nozzle ejector mixer is made in the form of ejectors parallel to the space and is equipped with a hydraulic flow averager, the pressure inputs of the ejectors being combined by a common collector and connected to the output of the sand filter, the suction inputs of the ejectors being connected by a common collector and connected to the second output of the ozonizer, and the output parallel to the nozzle ends are rigidly fixed to the common flange. 6. Installation according to claim 5, characterized in that the hydraulic flow averager is made in the form of a tank, the upper part of which is equipped with a flange for connecting the outlet pipes of a multi-nozzle ejector mixer, and in the lower part there is a layer of fine-grained loading, for example, crushed zeolite, a supporting layer, for example coarse expanded clay, and a coaxially located outlet pipe.