CN115072858A - A sodium hypochlorite intelligence disinfecting equipment for water treatment - Google Patents
A sodium hypochlorite intelligence disinfecting equipment for water treatment Download PDFInfo
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- CN115072858A CN115072858A CN202210832182.3A CN202210832182A CN115072858A CN 115072858 A CN115072858 A CN 115072858A CN 202210832182 A CN202210832182 A CN 202210832182A CN 115072858 A CN115072858 A CN 115072858A
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- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/72—Treatment of water, waste water, or sewage by oxidation
- C02F1/76—Treatment of water, waste water, or sewage by oxidation with halogens or compounds of halogens
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- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2103/00—Nature of the water, waste water, sewage or sludge to be treated
- C02F2103/003—Wastewater from hospitals, laboratories and the like, heavily contaminated by pathogenic microorganisms
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- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2303/00—Specific treatment goals
- C02F2303/04—Disinfection
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- Treatment Of Water By Oxidation Or Reduction (AREA)
Abstract
The invention relates to the technical field of water treatment, in particular to intelligent sodium hypochlorite disinfection equipment for water treatment, which comprises a machine body, wherein a pump body, a disinfection tube, a sodium hypochlorite generator, a sodium hypochlorite digestion mechanism and a carbon dioxide gas mechanism are sequentially arranged in the machine body, the pump body is used for pumping water into the disinfection tube, and the sodium hypochlorite generator is used for adding a sodium hypochlorite solution into the disinfection tube; according to the invention, water is disinfected through the sodium hypochlorite generator, carbon dioxide is introduced into the water disinfected by sodium hypochlorite, and the time of solution contact illumination is controlled in a segmented manner through the digestion pipe and the aeration pipe, so that the residual sodium hypochlorite in the water firstly generates hypochlorous acid, then generates a small amount of hydrochloric acid, and then sequentially generates oxygen and carbon dioxide, the residual sodium hypochlorite in the water is rapidly digested, the water disinfected by sodium hypochlorite can be rapidly used, and the digestion cost is reduced by recycling the carbon dioxide.
Description
Technical Field
The invention relates to the technical field of water treatment, in particular to sodium hypochlorite intelligent disinfection equipment for water treatment.
Background
The daily disinfection work is paid more and more attention by many people, and the adoption of sodium hypochlorite disinfection is an economic, practical and effective disinfection mode. In the operation of a water treatment system, sodium hypochlorite is obtained by electrolyzing sodium chloride through an electrode plate, so that the aim of disinfecting a water body is fulfilled, for example, a sodium hypochlorite generator is disclosed in the patent number 202020097872.5, and a small sodium hypochlorite generator for sewage treatment is disclosed in the patent number 201910015458.7, so that sewage is disinfected by a self-made sodium hypochlorite solution.
At present, medical wastewater is mainly sewage discharged from diagnosis and treatment rooms, laboratory rooms, sickrooms, laundries, operating rooms and the like of hospitals, clear water is obtained after the medical wastewater passes through a pretreatment filtering system, a flocculation system and a solid-liquid separation system, and then the clear water is disinfected by sodium hypochlorite to kill virus, bacteria and the like in the clear water.
Generally, in order to save water, water disinfected by sodium hypochlorite needs to be recycled; because sodium hypochlorite still remains in the aquatic after the sodium hypochlorite disinfection, it can not use immediately, and the water after the sodium hypochlorite disinfection is deposited into the water tank to the common way for sodium hypochlorite in the water slowly clears up, and it is slow to clear up, can't use the water after the disinfection immediately, and then causes to need a large amount of water tanks to deposit water, increases and deposits the water cost.
Therefore, the technical scheme discloses a sodium hypochlorite intelligence disinfecting equipment for water treatment, solves to clear up the water after the sodium hypochlorite disinfection fast to reach the water after using the sodium hypochlorite disinfection fast.
Disclosure of Invention
Solves the technical problem
Aiming at the defects in the prior art, the invention provides the intelligent sodium hypochlorite disinfection equipment for water treatment, which can effectively solve the problems in the prior art.
Technical scheme
In order to realize the purpose, the invention is realized by the following technical scheme:
an intelligent sodium hypochlorite disinfection device for water treatment comprises a machine body, wherein a pump body, a disinfection tube, a sodium hypochlorite generator, a sodium hypochlorite digestion mechanism and a carbon dioxide gas mechanism are sequentially arranged in the machine body, the pump body is used for pumping water into the disinfection tube, the sodium hypochlorite generator is used for adding a sodium hypochlorite solution into the disinfection tube, the sodium hypochlorite digestion mechanism is used for digesting sodium hypochlorite in water from the disinfection tube, and the carbon dioxide gas mechanism is used for providing carbon dioxide gas for the sodium hypochlorite digestion mechanism and recovering the digested carbon dioxide gas; wherein, clear up sodium hypochlorite mechanism including vertically setting up the hybrid tube in the organism, clear up pipe, aeration pipe and fluorescent tube, the hybrid tube is through communicating pipe and clear up the pipe intercommunication, and the hybrid tube pipe diameter is less than respectively and clears up pipe diameter and aeration pipe diameter, the intercommunication has the oxygen pipe of arranging on communicating pipe, clear up pipe and aeration pipe and be transparent material body, clear up pipe and aeration pipe intercommunication through buckling, buckle the pipe include with clear up the vertical pipe of pipe intercommunication and with the slope pipe of aeration pipe intercommunication, the slope pipe passes through muffler and carbon dioxide gas mechanism intercommunication in top portion.
Furthermore, the disinfection pipe, the digestion pipe and the aeration pipe are all arranged in a spiral structure.
Furthermore, the outer wall of the digestion pipe is equidistantly provided with shading films.
Further, the communication pipe is communicated with the oxygen exhaust pipe through a first one-way exhaust valve.
Furthermore, one end of the aeration pipe, which is far away from the bent pipe, is communicated with a U-shaped pipe.
Furthermore, the sodium hypochlorite digestion mechanism further comprises a water inlet pipe and a water wheel chamber, the water inlet pipe is communicated with the water wheel chamber in a tangent mode, the mixing pipe is coaxially and vertically arranged on the water wheel chamber, and the water wheel chamber is communicated with the mixing pipe through a branch pipe.
Furthermore, the water wheel chamber is connected with a water wheel through a rotating shaft in a rotating manner, the rotating shaft penetrates into the mixing pipe, and a plurality of groups of stirring paddles are arranged on the rotating shaft.
Furthermore, the carbon dioxide gas mechanism comprises a first gas storage tank, a second gas storage tank, a carbon dioxide gas tank and a carbon dioxide compressor, wherein a first electromagnetic three-way valve, a second electromagnetic three-way valve and an electromagnetic four-way valve are respectively communicated with the end of the first gas storage tank, the end of the second gas storage tank and the end of the carbon dioxide gas tank, the first electromagnetic three-way valve and the second electromagnetic three-way valve are respectively communicated with the electromagnetic four-way valve through a first gas pipe, a second gas pipe and an electromagnetic four-way valve, the electromagnetic four-way valve is communicated with the water inlet pipe through a third gas pipe, the gas outlet end of the carbon dioxide compressor is respectively communicated with the first electromagnetic three-way valve and the second electromagnetic three-way valve through a three-way pipe, and the gas return pipe is communicated with the gas inlet end of the carbon dioxide compressor.
Furthermore, an electric gas flow regulating valve and a second one-way exhaust valve are sequentially communicated between the third gas pipe and the water inlet pipe.
Advantageous effects
Compared with the known public technology, the technical scheme provided by the invention has the following beneficial effects:
according to the invention, water is disinfected through the sodium hypochlorite generator, carbon dioxide is introduced into the water disinfected by sodium hypochlorite, and the time of solution contact illumination is controlled in a segmented manner through the digestion pipe and the aeration pipe, so that the residual sodium hypochlorite in the water firstly generates hypochlorous acid, then generates a small amount of hydrochloric acid, and then sequentially generates oxygen and carbon dioxide, the residual sodium hypochlorite in the water is rapidly digested, the water disinfected by sodium hypochlorite can be rapidly used, and the digestion cost is reduced by recycling the carbon dioxide.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the invention, and that for a person skilled in the art, other drawings can be derived from them without inventive effort.
FIG. 1 is a schematic flow diagram of the present invention;
FIG. 2 is a reaction equation of the sodium hypochlorite digestion mechanism of the present invention for digesting sodium hypochlorite;
FIG. 3 is a schematic perspective first view structure of the present invention;
FIG. 4 is a schematic perspective structural view of the present invention;
FIG. 5 is a schematic view of a first perspective of the sodium hypochlorite digestion mechanism of the present invention;
FIG. 6 is a schematic diagram of a second perspective view of the sodium hypochlorite digestion mechanism of the invention;
FIG. 7 is an exploded view of the sodium hypochlorite digestion mechanism of the present invention;
FIG. 8 is a schematic cross-sectional view of the mixing tube and the water inlet tube of the present invention;
the reference numerals in the drawings denote: 1. a body; 2. a pump body; 3. sterilizing the tube; 4. a sodium hypochlorite generator; 5. a carbon dioxide gas mechanism; 501. a first gas storage tank; 502. a second gas tank; 503. a carbon dioxide tank; 504. a carbon dioxide compressor; 505. a first electromagnetic three-way valve; 506. a second electromagnetic three-way valve; 507. an electromagnetic four-way valve; 508. a first air pipe; 509. a second air pipe; 510. a third air pipe; 511. a three-way pipe; 6. a mixing tube; 7. a digestion tube; 8. an aeration pipe; 9. a lamp tube; 10. a communicating pipe; 1001. a thin tube; 1002. a thick pipe; 11. an oxygen discharge pipe; 12. bending the tube; 1201. a longitudinal tube; 1202. an inclined tube; 13. an air return pipe; 14. a light shielding film; 15. a first one-way exhaust valve; 16. a U-shaped pipe; 17. a water inlet pipe; 18. a turbine chamber; 19. a branch pipe; 20. a rotating shaft; 21. a water wheel; 22. a stirring paddle; 23. a flow electric regulating valve; 24. a second one-way exhaust valve; 25. a water inlet nozzle; 26. a water outlet nozzle; 27. and (4) exposing the area.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention. It is to be understood that the embodiments described are only a few embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
The present invention will be further described with reference to the following examples.
Examples
The intelligent sodium hypochlorite disinfection equipment for water treatment of the embodiment refers to the following steps: including organism 1, set gradually the pump body 2 in the organism 1, the disinfection pipe 3, hypochlorite generator 4, clear up hypochlorite mechanism and carbon dioxide gas mechanism 5, the pump body 2 is used for pumping into the disinfection pipe 3 with the water, hypochlorite generator 4 is used for adding sodium hypochlorite solution in to the disinfection pipe 3, clear up hypochlorite mechanism and be used for clearing up the sodium hypochlorite that comes from the aquatic of disinfection pipe 3, carbon dioxide gas mechanism 5 is used for providing carbon dioxide gas and retrieving the carbon dioxide gas after clearing up to clearing up hypochlorite mechanism.
Specifically, the machine body 1 is a vertical cabinet, and a split door is arranged on the front side (in the reference direction of fig. 3, the same below) of the vertical cabinet, and the split door is opened, so that the interior of the machine body 1 can be maintained conveniently, and sodium chloride and soft water required for generating sodium hypochlorite can be added into the sodium hypochlorite generator 4 conveniently; an operation interface is arranged on one group of door surfaces, and a touch screen type display screen is preferably selected according to the technical scheme, so that water treatment parameters can be conveniently input and alarms can be conveniently displayed.
A water inlet nozzle 25 is arranged on the left side of the machine body 1, the water inlet nozzle 25 is communicated with a pump body 2 through a water pipe, the pump body 2 and a sodium hypochlorite generator 4 are respectively communicated with a disinfection pipe 3 through water pipes, water (to be digested for short) of sodium hypochlorite is pumped into the disinfection pipe 3 through the pump body 2, and meanwhile, a sodium hypochlorite solution is pumped into the disinfection pipe 3 by the sodium hypochlorite generator 4 (the sodium hypochlorite generator 4 is the prior art and is not described in detail here), so that the water to be digested is mixed with the sodium hypochlorite solution, and the water to be digested is disinfected to obtain disinfected water; wherein, the body of the preferred heliciform structure of disinfection pipe 3 can increase the tube length of disinfection pipe 3 in limited space, improves the disinfection effect of treating the water of dispelling.
A water outlet nozzle 26 is arranged on the right side of the machine body 1 and is communicated with a water outlet end of the sodium hypochlorite digestion mechanism; it is specific, clear up sodium hypochlorite mechanism and include that vertical setting is at mixing tube 6 in organism 1, clear up pipe 7, aeration pipe 8, fluorescent tube 9, still include inlet tube 17 and water wheel room 18, mixing tube 6 through communicating pipe 10 with clear up pipe 7 intercommunication, clear up pipe 7 through 12 and 8 intercommunications of aeration pipe of buckling.
Wherein, the mixing pipe 6 is communicated with a water inlet pipe 17 through a water wheel chamber 18; specifically, a water inlet pipe 17 is communicated with a water wheel chamber 18 in a tangent mode, a mixing pipe 6 is coaxially and vertically arranged on the water wheel chamber 18, the water wheel chamber 18 is communicated with the mixing pipe 6 through a branch pipe 19, meanwhile, the water inlet pipe 17 is communicated with an exhaust end of a carbon dioxide gas mechanism 5, so that carbon dioxide gas enters the water inlet pipe 17 to react with disinfectant water, redundant sodium hypochlorite in the disinfectant water reacts with the carbon dioxide to generate sodium carbonate and hypochlorous acid, and water generated after the carbon dioxide gas reacts with the disinfectant water is called as the disinfectant water for short; simultaneously through being located inlet tube 17 the lower extreme of mixing tube 6, and mixing tube 6 is vertical in organism 1 to make the sterile water flow from the bottom up, and then guarantee that sterile water and carbon dioxide are sufficient to react.
In order to further improve the reaction efficiency and the reaction effect of the sterilized water and the carbon dioxide, a water wheel 21 is rotatably connected in the water wheel chamber 18 through a rotating shaft 20, the rotating shaft 20 penetrates into the mixing pipe 6, and a plurality of groups of stirring paddles 22 are arranged on the rotating shaft 20; after the sterilizing water enters the water wheel chamber 18 along the water inlet pipe 17, the rotating shaft 20 is driven to rotate by the water wheel 21, so that the sterilizing water in the mixing pipe 6 is stirred by the stirring paddle 22, and the sterilizing water and the carbon dioxide are sufficiently reacted.
The pipe diameter of the mixing pipe 6 is smaller than that of the digestion pipe 7, and the digestion pipe 7 is a transparent pipe body, in the technical scheme, the digestion pipe 7 is preferably made of transparent toughened glass; specifically, the communicating pipe 10 includes a thin pipe 1001 and a thick pipe 1002 communicated therewith, the pipe diameter of the thin pipe 1001 is smaller than that of the thick pipe 1002, the pipe diameter of the thin pipe 1001 is consistent with that of the mixing pipe 6, the thin pipe 1001 is communicated with the mixing pipe 6, the pipe diameter of the thick pipe 1002 is consistent with that of the digestion pipe 7, and the thick pipe 1002 is consistent with that of the digestion pipe 7.
After the digestion water enters the digestion pipe 7 through the communicating pipe 10, the cross section of the digestion water flowing along the digestion pipe 7 is smaller than that of the digestion pipe 7, and an air passage is provided for the subsequently generated oxygen and carbon; when the digestion water flowing in the digestion tube 7 meets the light emitted by the lamp tube 9, the hypochlorous acid in the digestion water is decomposed with the light to form hydrochloric acid and oxygen, and the oxygen flows upwards along the digestion tube 7 and is discharged out of the machine body 1 through the oxygen discharge tube 11 arranged on the thick tube 1002; meanwhile, after the digestion water flowing into the digestion pipe 7 from the communicating pipe 10 is subjected to photoreaction, hypochlorous acid on the same water flow section cannot be completely decomposed, namely, a certain amount of hypochlorous acid in the same water flow section is decomposed in a photoreaction manner, and the hypochlorous acid on one side close to the inner wall of the digestion pipe 7 is blocked by the upper liquid, so that the hypochlorous acid on one side close to the inner wall of the digestion pipe 7 is not subjected to enough illumination, the concentration of hydrochloric acid on the same water flow section is smaller than that of sodium carbonate on the same water flow section, the hydrochloric acid reacts with excessive sodium carbonate to generate sodium bicarbonate and hydrochloric acid, and the solution is called as aeration water for short.
In order to ensure that the sodium hypochlorite with the same water flow section can be illuminated, the digestion tube 7 adopts a tube body with a spiral structure, and the tube length of the digestion tube 7 can be increased in a limited space; simultaneously for avoiding the hypochlorous acid of same rivers cross section to meet the complete decomposition of light for a long time, through dispelling 7 outer walls of pipe equidistance and being provided with photomask 14, make and form exposure area 27 between two sets of adjacent photomask 14, and form shading area in the region at photomask 14 place, thereby the sodium hypochlorite of same rivers cross section constantly passes through exposure area 27 and shading area, realize slowing down the sodium hypochlorite decomposition rate of same rivers cross section, simultaneously in the pipe 7 of dispelling of certain length, make the partial sodium hypochlorite of same rivers cross section obtain the decomposition. Wherein, it is inevitable to cause a small amount of sodium hypochlorite with the same water flow section to be completely decomposed (mainly concentrated at the end region of the digestion tube 7), so that the concentrations of the hydrochloric acid and the sodium carbonate with the same water flow section are equal, the hydrochloric acid and the sodium carbonate are generated into hydrochloric acid and carbon dioxide, and the small amount of carbon dioxide is still discharged out of the organism 1 from the oxygen discharge tube 11.
Simultaneously, in order to avoid external gas to clear up pipe 7 through oxygen row's pipe 11 entering, influence the photolysis of sodium hypochlorite, oxygen row pipe 11 is through first one-way discharge valve 15 and thick pipe 1002 intercommunication.
In the technical scheme, the diameters of the aeration pipe 8 and the bent pipe 12 are the same as the diameter of the digestion pipe 7, so that the cross section of the aerated water entering the aeration pipe 8 is smaller than that of the aeration pipe 8, and an air passage is provided for the carbon dioxide generated subsequently. Meanwhile, the aeration pipe 8 is also preferably made of transparent toughened glass; specifically, the bending pipe 12 includes a longitudinal pipe 1201 communicating with the digestion pipe 7 and an inclined pipe 1202 communicating with the aeration pipe 8.
When the aeration water of the digestion pipe 7 enters the aeration pipe 8 through the bent pipe 12, the aeration water continuously receives illumination, the sodium hypochlorite on the same water flow section is continuously decomposed to form hydrochloric acid, the hydrochloric acid reacts with the sodium bicarbonate to generate hydrochloric acid and carbon dioxide, so that clear water is obtained, and the clear water outlet nozzle 26 is connected with the fluid machine body 1; wherein, the generated carbon dioxide rises along the aeration pipe 8 and flows into the carbon dioxide gas mechanism 5 through the return pipe 13 arranged at the upper end part of the inclined pipe 1202 for recycling, thereby reducing the cost of digestion; meanwhile, the generated carbon dioxide gas is prevented from flowing into the digestion tube 7 through the longitudinal tube 1201, and waste of the carbon dioxide gas is further avoided.
In order to ensure that the aerated water is in sufficient contact with the illumination, the aeration pipe 8 is a pipe body with a spiral structure, and the spiral structure with small upper spiral and gradually enlarged downward spiral is adopted, so that the pipe length of the aeration pipe 8 can be increased in a limited space, and the sodium hypochlorite in the aerated water is completely decomposed; meanwhile, in order to avoid turbidity of the recovered carbon dioxide gas caused by the inflow of the external air from the water outlet nozzle 26 to the aeration pipe 8, the water outlet nozzle 26 is communicated with the aeration pipe 8 through the U-shaped pipe 16.
In this technical scheme, carbon dioxide gas mechanism 5 includes first gas holder 501, second gas holder 502, carbon dioxide gas pitcher 503 and carbon dioxide compressor 504, first gas holder 501 can end, second gas holder 502 can end and carbon dioxide gas pitcher 503 can end communicate respectively has first electromagnetism three-way valve 505, second electromagnetism three-way valve 506 and electromagnetism four-way valve 507, first electromagnetism three-way valve 505 and second electromagnetism three-way valve 506 are respectively through first trachea 508 and second trachea 509 and electromagnetism four-way valve 507, electromagnetism four-way valve 507 communicates with inlet tube 17 through third trachea 510, carbon dioxide compressor 504 is given vent to anger the end and is communicated with first electromagnetism three-way valve 505 and second electromagnetism three-way valve 506 through three-way pipe 511 respectively, muffler 13 communicates with carbon dioxide compressor 504 inlet end.
The first gas storage tank 501 and the second gas storage tank 502 are used for recycling and storing carbon dioxide gas, and the carbon dioxide gas tank 503 can be replaced with a purchased carbon dioxide gas tank.
When the gas in the carbon dioxide gas tank 503 is sufficient, the controller controls the first three-way solenoid valve 505, the second three-way solenoid valve 506 and the four-way solenoid valve 507, so that the gas in the carbon dioxide gas tank 503 enters the water inlet pipe 17 from the third gas pipe 510, and the recovered carbon dioxide gas flows into the first gas tank 501 or the second gas tank 502 through the carbon dioxide compressor 504.
When the gas in the carbon dioxide gas tank 503 is insufficient, the alarm sound in the machine body 1 gives an alarm prompt, and meanwhile, the alarm display is carried out on a touch screen type display screen to prompt that the carbon dioxide gas tank 503 needs to be replaced; meanwhile, the controller controls the first electromagnetic three-way valve 505, the second electromagnetic three-way valve 506 and the electromagnetic four-way valve 507, so that carbon dioxide gas of the first gas storage tank 501 enters the water inlet pipe 17 through the third gas pipe 510, recovered carbon dioxide gas flows into the second gas storage tank 502 through the carbon dioxide compressor 504, or carbon dioxide gas of the second gas storage tank 502 enters the water inlet pipe 17 through the third gas pipe 510, recovered carbon dioxide gas flows into the first gas storage tank 501 through the carbon dioxide compressor 504, so that the carbon dioxide gas tank 503 is emptied, preparation is made for subsequent replacement of the carbon dioxide gas tank 503, meanwhile, the whole digestion process is guaranteed to be continuously carried out, interruption is avoided, and continuous intelligent digestion and disinfection are further realized.
In order to prevent the solution in the water inlet pipe 17 from entering the third air pipe 510 and simultaneously facilitate the control of the flow of the carbon dioxide entering the water inlet pipe 17 through the third air pipe 510, an electric gas flow regulating valve 23 and a second one-way exhaust valve 24 are sequentially communicated between the third air pipe 510 and the water inlet pipe 17.
This equipment passes through hypochlorite generator 4, disinfect to water, let in carbon dioxide through the aquatic to after the hypochlorite disinfection, and through with water through dispelling pipe 7 and aeration pipe 8, the time of segmentation control solution contact illumination, thereby make the remaining hypochlorite of aquatic generate hypochlorous acid earlier, regenerate a small amount of hydrochloric acid, later generate oxygen and carbon dioxide in proper order, the realization is cleared up remaining hypochlorite of aquatic fast, and then can use the water after the hypochlorite disinfection fast, and through recycling carbon dioxide, reduce the cost of dispelling.
The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the corresponding technical solutions.
Claims (9)
1. The utility model provides a sodium hypochlorite intelligence disinfecting equipment for water treatment, includes organism (1), its characterized in that: the machine body (1) is internally and sequentially provided with a pump body (2), a disinfection tube (3), a sodium hypochlorite generator (4), a sodium hypochlorite digestion mechanism and a carbon dioxide gas mechanism (5), wherein the pump body (2) is used for pumping water into the disinfection tube (3), the sodium hypochlorite generator (4) is used for adding a sodium hypochlorite solution into the disinfection tube (3), the sodium hypochlorite digestion mechanism is used for digesting sodium hypochlorite in water from the disinfection tube (3), and the carbon dioxide gas mechanism (5) is used for providing carbon dioxide gas for the sodium hypochlorite digestion mechanism and recovering the digested carbon dioxide gas;
wherein, clear up sodium hypochlorite mechanism including vertically set up mixing tube (6) in organism (1), clear up pipe (7), aeration pipe (8) and fluorescent tube (9), mixing tube (6) through communicating pipe (10) with clear up pipe (7) intercommunication, mixing tube (6) pipe diameter is less than respectively and clears up pipe (7) pipe diameter and aeration pipe (8) pipe diameter, the intercommunication has oxygen discharging pipe (11) on communicating pipe (10), it is transparent material body to clear up pipe (7) and aeration pipe (8), clears up pipe (7) through buckling pipe (12) and aeration pipe (8) intercommunication, buckle pipe (12) including with clear up vertical pipe (1201) of pipe (7) intercommunication and with the slope pipe (1202) of aeration pipe (8) intercommunication, slope pipe (1202) top portion passes through muffler (13) and carbon dioxide gas mechanism (5) intercommunication.
2. The intelligent sodium hypochlorite disinfection device for water treatment as claimed in claim 1, wherein the disinfection tube (3) and the digestion tube (7) and the aeration tube (8) are all arranged in a spiral structure.
3. Sodium hypochlorite intelligent disinfection apparatus for water treatment according to claim 1, characterized in that the outer wall of said digestion tube (7) is equidistantly provided with light shielding films (14).
4. The intelligent sodium hypochlorite disinfection apparatus for water treatment as claimed in claim 1, wherein said communicating pipe (10) is communicated with the oxygen exhaust pipe (11) through a first one-way exhaust valve (15).
5. The sodium hypochlorite intelligent disinfection device for water treatment as claimed in claim 1, wherein one end of the aeration pipe (8) far away from the bent pipe (12) is communicated with a U-shaped pipe (16).
6. The sodium hypochlorite intelligent disinfection device for water treatment as claimed in claim 1, wherein said sodium hypochlorite digestion mechanism further comprises a water inlet pipe (17) and a water wheel chamber (18), said water inlet pipe (17) is tangentially communicated with said water wheel chamber (18), said mixing pipe (6) is coaxially and vertically arranged on said water wheel chamber (18), said water wheel chamber (18) is communicated with said mixing pipe (6) through a branch pipe (19).
7. The intelligent sodium hypochlorite disinfection device for water treatment according to claim 6, wherein a water wheel (21) is rotatably connected in the water wheel chamber (18) through a rotating shaft (20), the rotating shaft (20) penetrates into the mixing pipe (6), and a plurality of groups of stirring paddles (22) are arranged on the rotating shaft (20).
8. The sodium hypochlorite intelligent disinfection device for water treatment according to claim 6, wherein the carbon dioxide gas mechanism (5) comprises a first gas storage tank (501), a second gas storage tank (502), a carbon dioxide gas tank (503) and a carbon dioxide compressor (504), a first electromagnetic three-way valve (505), a second electromagnetic three-way valve (506) and an electromagnetic four-way valve (507) are respectively communicated with the end of the first gas storage tank (501), the end of the second gas storage tank (502) and the end of the carbon dioxide gas tank (503), the first electromagnetic three-way valve (505) and the second electromagnetic three-way valve (506) are respectively communicated with the electromagnetic four-way valve (507) through a first gas pipe (508) and a second gas pipe (509), the electromagnetic four-way valve (507) is communicated with the water inlet pipe (17) through a third gas pipe (510), and the air outlet of the carbon dioxide compressor (504) is respectively communicated with the first electromagnetic three-way valve (505) and the second electromagnetic three-way valve (506) through a three-way pipe (511) ) And the air return pipe (13) is communicated with the air inlet end of the carbon dioxide compressor (504).
9. The intelligent sodium hypochlorite disinfection device for water treatment as claimed in claim 8, wherein an electric gas flow regulating valve (23) and a second one-way exhaust valve (24) are sequentially communicated between the third gas pipe (510) and the water inlet pipe (17).
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JP2001232370A (en) * | 2000-02-21 | 2001-08-28 | Shoei:Kk | Liquid sterilization equipment |
US20050070752A1 (en) * | 2001-11-08 | 2005-03-31 | Ryuji Kojima | Method for treating cyanide waste liquid |
JP2005349382A (en) * | 2004-05-11 | 2005-12-22 | Tatsuo Okazaki | Method and apparatus for producing high concentration sterilization water using carbon dioxide filled tank |
JP2012187443A (en) * | 2011-03-08 | 2012-10-04 | Kotobuki Kakoki Kk | Water treatment apparatus |
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