阅读说明：本技术 食盐滴定电解液冲洗体系及方法 (Salt titration electrolyte flushing system and method ) 是由 刘鹏 季春峰 王雪东 于 2020-03-20 设计创作，主要内容包括：本发明食盐滴定电解液冲洗体系,包括依次相连通的供水单元、中和滴定单元、法拉第电解池和输出单元,原水自供水单元进入,饱和液滴定的流量与原水流量的比值为1.0-2.0∶100,然后经法拉第电解池输出含有微量次氯酸和氢气的食盐水溶液到输出单元的冲洗探头。本发明还提供了食盐滴定电解液冲洗的方法。其优点在于：提供了至少四种冲洗探头供用户选择,可以用于多种场合,含有微量次氯酸和氢气的食盐水溶液可以消炎抑菌,提高抗病能力,缩短病程。解决老年人护理困难,推出了合理、适用并具有卫生保健效果的护理设备。同时有效减轻护理人员劳动条件和强度,大大减少环境污染,体积小、成本低、使用方便,具有广泛应用前景。(The salt titration electrolyte flushing system comprises a water supply unit, a neutralization titration unit, a Faraday electrolytic cell and an output unit which are sequentially communicated, raw water enters from the water supply unit, the ratio of the titration flow of saturated solution to the raw water flow is 1.0-2.0: 100, and then salt solution containing trace hypochlorous acid and hydrogen is output to a flushing probe of the output unit through the Faraday electrolytic cell. The invention also provides a method for flushing the salt titration electrolyte. The advantages are that: at least four flushing probes are provided for users to select, the flushing probe can be used in various occasions, and the saline solution containing trace hypochlorous acid and hydrogen can diminish inflammation and inhibit bacteria, improve disease resistance and shorten the course of disease. Solves the problem of nursing difficulty of the old, and provides reasonable and applicable nursing equipment with health care effect. Meanwhile, the labor condition and the intensity of nursing personnel are effectively reduced, the environmental pollution is greatly reduced, the volume is small, the cost is low, the use is convenient, and the method has a wide application prospect.)

1. A salt titration electrolyte rinse system comprising a faraday cell (400), characterized in that: still include water supply unit (100), neutralization titration unit (500) and output unit (200), water supply unit (100), neutralization titration unit (500), Faraday electrolytic bath (400) and output unit (200) are connected gradually, wherein:

the neutralization titration unit (500) comprises a cylinder body, an upper cover (202), a lower cover (502) and a partition board (504), and further comprises a first tee joint (104), a first communicating pipe (301), a second communicating pipe (105), a titration water flow regulator (800), a separating device (700) and a through clamp sleeve (40), wherein the cylinder body comprises a framework (505), an upper cylinder body (201), a lower cylinder body (501) and the partition board (504), the partition board (504) is horizontally positioned between the upper cylinder body (201) and the lower cylinder body (501), the upper cylinder body (201), the lower cylinder body (501) and the partition board (504) are hermetically arranged on the inner side of the framework (505), salt (200) is stored in the upper cylinder body (201), and the lower cylinder body (501) is a salt water neutralization pond; the upper cover (202) and the lower cover (502) are respectively and correspondingly and hermetically arranged at the upper end of the upper cylinder body (201) and the lower end of the lower cylinder body (501); a first through hole (K1) and a fourth through hole (K4) are uniformly distributed on the lower cover (502), a second through hole (K2) and a third through hole (K3) are uniformly distributed on the isolation plate (504), and the first through hole (K1), the second through hole (K2), the third through hole (K3) and the fourth through hole (K4) are respectively positioned on the same axis; the lower end of a straight-through pipeline of the first tee joint (104) is hermetically inserted into the first through hole (K1), the upper end of the straight-through pipeline of the first tee joint (104) is hermetically inserted into the second through hole (K2), the upper end of the straight-through pipeline of the first tee joint (104) is opened in the inner cavity of the upper barrel body (201), and the lower end of the straight-through pipeline of the first tee joint (104) is opened outside the lower cover (502); the separating device (700) is provided with a groove-shaped clamping sleeve (705), the groove-shaped clamping sleeve (705) is hermetically inserted in the third through hole (K3), and openings are respectively arranged on the upper side and the lower side of the isolating plate (504);

the first communicating pipe (301) is in an inverted U shape, and two ends of the first communicating pipe are respectively communicated with the upper end of the first tee joint (104) and the titration water flow regulator (800) in a sealing way; the titration water flow regulator (800) comprises a threaded pipe (801), a threaded rod (802), a sealing ring (803) and a basin-shaped hand wheel (804) which are matched with each other, wherein a water inlet of the threaded pipe (801) is communicated with an outlet of the first communication pipe (301), the threaded rod (802) extends out of a water outlet of the threaded pipe (801) and is installed in an inner cavity of the basin-shaped hand wheel (804) through the sealing ring (803), and the titration water flow regulator (800) and the separation device (700) are coaxially installed; a salt blocking cap (704) is mounted at the upper end of the groove-shaped clamping sleeve (705), the groove-shaped clamping sleeve (705) is in threaded fit with the salt blocking cap (704), an axial saline groove (703) is formed in the outer wall of the groove-shaped clamping sleeve (705), the lower end of the groove-shaped clamping sleeve (705) is communicated with the third communicating pipe (706), a horizontal outlet of the first tee joint (104) is communicated with one end of the second communicating pipe (105) in a sealing manner, and the other end of the second communicating pipe (105) is orthogonally opposite to an opening at the lower end of the third communicating pipe (706); the straight-through clamping sleeve (40) is hermetically inserted in the fourth through hole (K4), and openings are respectively arranged on the upper side and the lower side of the lower cover (502);

the Faraday electrolytic cell (400) comprises an electrolytic cell shell (410), a core column (408), a platinum rod electrolytic electrode pair (409), a liquid inlet pipe (401), a second clamping nut (406), a third clamping nut (407), a fourth clamping nut (411), a fourth communicating pipe (604) and a constant current power supply (405), wherein the liquid inlet pipe (401) is in sealed communication with the through clamping sleeve (40), the core column (408) is hermetically installed at the lower end of the electrolytic cell shell (410) through the third clamping nut (407), the platinum rod electrolytic electrode pair (409) is respectively installed in two positioning through holes of the core column (408), an outgoing line of the platinum rod electrolytic electrode pair (409) is led out from the lower end of the core column (408) and is electrically connected with the constant current power supply (405), the liquid inlet pipe (401) is hermetically installed at an inlet of the electrolytic cell shell (410) through the second clamping nut (406), the fourth communicating pipe (604) is hermetically installed at the outlet of the electrolytic cell shell (410) through the fourth clamping nut (411);

the water supply unit (100) comprises a valve (101), an elbow (102) and a first clamping nut (103), wherein the inlet of the valve (101) is connected with a water inlet pipe (10), and the outlet of the valve (101) is hermetically communicated with the first tee joint (104) through the elbow (102) through the first clamping nut (103);

the output unit (200) comprises a 360-degree rotating device (600) and a plurality of flushing probes, and water inlet pipes of the flushing probes are communicated with the 360-degree rotating device (600);

raw water is injected into the upper cylinder body (201) from the valve (101), flows to salt in a dissolving cavity above the salt blocking cap from an outlet of the titration water flow regulator (800), and salt saturated liquid enters the separating device (700) from the salt water tank (703) and enters a titration tank through the third communicating pipe (706); meanwhile, raw water is injected into the lower barrel (501) from the second communicating pipe (105), and saturated liquid with the ratio of the titration flow to the raw water flow being 1.0-2.0: 100 is output to a saline solution containing micro hypochlorous acid and hydrogen through the Faraday electrolytic tank (400) and the output unit (200).

2. The saline titration electrolyte flushing system according to claim 1, wherein: wherein the neutralization titration unit (500) and the Faraday electrolytic cell (400) are transparent bodies which are welded and sealed by plastics.

3. The saline titration electrolyte flushing system according to claim 2, characterized in that: the constant current power supply (405) adopts a 5V/220mA constant current power supply.

4. A saline titration electrolyte flushing system according to claim 3, characterized in that: the 360-degree rotating device (600) comprises a first clamping sleeve (603), a fifth clamping nut (605) matched with the first clamping sleeve (603), a funnel-shaped sealing sleeve (602) and a protective cover (601), wherein the funnel-shaped sealing sleeve (602) is located in an upper cavity of the first clamping sleeve (603), the fourth communicating pipe (604) is communicated with the first clamping sleeve (603) through the fifth clamping nut (605), an opening is formed in an inner cavity of the funnel-shaped sealing sleeve (602), a water inlet pipe of the flushing probe penetrates through a middle hole of the protective cover (601) and is movably inserted into the funnel-shaped sealing sleeve (602), and the protective cover (601) is buckled at the upper end of the first clamping sleeve (603).

5. The saline titration electrolyte flushing system according to claim 4, wherein: the washing probe is a first probe (901), the first probe (901) adopts a special-shaped washing probe pipe, and a water inlet pipe of the first probe (901) is movably inserted into an outlet of the funnel-shaped sealing sleeve (602).

6. The saline titration electrolyte flushing system according to claim 4, wherein: the flushing probe is a second probe (902), the second probe (902) adopts a spraying assembly (92), and a water inlet pipe of the spraying assembly (92) is movably inserted into an outlet of the funnel-shaped sealing sleeve (602).

7. The saline titration electrolyte flushing system according to claim 4, wherein: the flushing probe is a third probe (903), the third probe (903) adopts an inner cavity flushing probe and comprises a movable joint (906), a supporting pipe (905) and a nipple pipe (904) which are sequentially communicated, a water inlet pipe of the movable joint (906) is movably inserted into a water outlet of the funnel-shaped sealing sleeve (602), and a water outlet pipe of the movable joint (906) is inserted into an inner hole of the nipple pipe (904).

8. The saline titration electrolyte flushing system according to claim 4, wherein: wherein the flushing probe is a fourth probe (98), the fourth probe adopts a rubber ripple draw-pull trouser suit hydrogen-retaining probe, the fourth probe comprises a liquid inlet pipe (933), a second tee joint (932), a rubber ripple pull-up pants cover (93-5), two pants legs (93-3, 93-4), a reducing opening (93-6) and a reducing belt (93-7), wherein one end of the liquid inlet pipe (933) is movably inserted into the outlet of the funnel-shaped sealing sleeve (602), the other end of the liquid inlet pipe (933) is communicated with an inlet of the second tee joint (932), two liquid outlet pipes (93-1, 93-2) of the second tee joint (932) are respectively and correspondingly communicated with two trouser legs (93-4, 93-3), the reducing openings (93-6) and the reducing belts (93-7) are positioned at the upper end parts of the rubber ripple stretch-draw panties (93-5).

9. A method of using a saline titration electrolyte washing system according to any of claims 1 to 8, wherein: the method is provided with a water supply unit, a neutralization titration unit, a Faraday electrolysis cell and an output unit, wherein the Faraday electrolysis cell comprises a titration water flow regulator, and the method comprises the following steps:

(1) presetting the opening degree of a titration water flow regulator, leading raw water into a neutralization titration unit through a water supply unit, dissolving salt in an upper cavity of the neutralization titration unit, generating a neutralization titration solution by the constant flow rate of saturated liquid drops and the flow rate of the raw water according to the ratio of 1.0-2.0: 100 after the obtained salt saturated solution enters a titration tank, and then fixing the titration water flow regulator to keep the opening degree;

(2) connecting a water supply unit and a neutralization titration unit, connecting a power supply of an electrolytic cell, enabling a neutralization titration solution flowing out of an upper cavity of the neutralization titration unit to enter a Faraday electrolytic cell, electrolyzing to generate micro hypochlorous acid and hydrogen, and enabling a salt solution containing the micro hypochlorous acid and the hydrogen to enter an output unit;

(3) selecting a washing probe according to the requirement, connecting the washing probe to the outlet of the output unit, and starting to wash the object:

(4) after the washing is finished, the water supply unit is closed, the upper cover of the neutralization titration unit is unscrewed, and salt is added to a sufficient amount and the upper cover is buckled for subsequent use.

10. The saline titration electrolyte washing method according to claim 9, wherein: wherein the step (3) of selecting the washing probe according to the requirement at least comprises the following steps:

replacing the first probe, and flushing in a special shape;

replacing the second probe, and carrying out spray rinsing;

replacing the third probe and flushing the inner cavity;

and the fourth probe is replaced, a user enters the rubber ripple pull-draw hydrogen-retaining probe connected with the trousers, and the size of the variable-diameter port is changed by the variable-diameter belt by increasing or reducing the position of the variable-diameter port, so that a plurality of parts of the human body are washed.

Technical Field

The invention relates to a health care product, in particular to a salt titration electrolyte flushing system and a method.

Background

In 2019, from 19 months 10 to 26 months 10, the applicant applied in Suzhou for the nursing home witnessed the condition of bed-ridden care for the elderly. See that they are close to nursing workers for feeding and bathing, especially for defecation, and also close to nursing workers. The male urinates in a plastic bag, and when the nurse sees that the plastic bag is full of urine, the nurse changes the plastic bag again. The female urinates to use the diaper. When in defecation, a user needs to stretch fingers into the anus to pick out hard and smelly defecates. Many elderly people call loudly and develop anal bleeding.

How to solve the problem of the nursing work of the old people, in particular to improve the nursing requirements of the old people in the aspect of washing the anus cavity, the vagina and the like, and to provide nursing equipment which is reasonable and suitable and has the health care effect, and simultaneously can effectively reduce the labor condition and the intensity of nursing personnel, greatly reduce the influence of the excrement, the urine and the like of the nursed people on the living room environment and the sanitation, and develop a brand new and suitable nursing washing device, which is a topic with a particularly important significance.

Meanwhile, in nursing, the inflammation of the anal cavity is eliminated, the pathological process is shortened, the original damaged physiological equilibrium state is recovered, the phagocytic function of leukocytes and reticuloendothelial cells of the body is enhanced, the aims of diminishing inflammation and inhibiting bacteria are fulfilled, and the disease resistance of the local part and the whole body is improved, which is also very necessary for any normal person. It is well known that gargling has become a habit of all people. The sanitation of the anal cavity is important, and the flushing of the anal cavity after defecation can remove the residual in the anus like gargling, thereby being beneficial to health. Including female vaginal irrigation, lumen irrigation devices are an urgent item of market product demand in the area of sanitary protection. However, no suitable product in this respect has been found at home and abroad after being inquired.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, and provides a saline titration electrolyte flushing system, which can solve the problem of nursing difficulty of old people, is suitable for the nursing requirements in flushing of anal lumens, vaginas and the like, has the health care effects of eliminating inflammation and shortening the pathological process, effectively lightens the labor condition and intensity of nursing personnel, and greatly reduces environmental pollution. The flushing device has the advantages of small volume, high nursing quality, obvious effect, low cost, convenient use and wide popularization and application prospect.

In order to achieve the above object, the present invention provides a saline titration electrolyte flushing system, comprising: still include water supply unit, neutralization titration unit and output unit, water supply unit, neutralization titration unit, Faraday electrolytic bath and output unit link gradually, wherein:

the neutralizing titration unit comprises a cylinder, an upper cover, a lower cover and a partition plate, and further comprises a first tee joint, a first communicating pipe, a second communicating pipe, a titration water flow regulator, a separating device and a straight-through clamping sleeve, wherein the cylinder comprises a framework, an upper cylinder, a lower cylinder and the partition plate, the partition plate is horizontally positioned between the upper cylinder and the lower cylinder, the upper cylinder, the lower cylinder and the partition plate are hermetically arranged on the inner side of the framework, salt is stored in the upper cylinder, and the lower cylinder is a salt water neutralizing tank; the upper cover and the lower cover are respectively and correspondingly and hermetically arranged at the upper end of the upper cylinder body and the lower end of the lower cylinder body; the lower cover is uniformly provided with a first through hole and a fourth through hole, the isolation plate is uniformly provided with a second through hole and a third through hole, and the first through hole, the second through hole, the third through hole and the fourth through hole are respectively positioned on the same axis; the lower end of a straight-through pipeline of the first tee joint is hermetically inserted in the first through hole, the upper end of the straight-through pipeline of the first tee joint is hermetically inserted in the second through hole, the upper end of the straight-through pipeline of the first tee joint is opened in the inner cavity of the upper barrel body, and the lower end of the straight-through pipeline of the first tee joint is opened on the outer side of the lower cover; the separating device is provided with a groove-shaped clamping sleeve which is inserted in the third through hole in a sealing manner, and openings are respectively arranged on the upper side and the lower side of the isolating plate;

the first communicating pipe is in an inverted U shape, and two ends of the first communicating pipe are respectively communicated with the upper end of the first tee joint and the titration water flow regulator in a sealing way; the titration water flow regulator comprises a threaded pipe, a threaded rod, a sealing ring and a basin-shaped hand wheel which are matched with each other, wherein a water inlet of the threaded pipe is communicated with an outlet of the first communication pipe, the threaded rod extends out of a water outlet of the threaded pipe and is installed in an inner cavity of the basin-shaped hand wheel through the sealing ring, and the titration water flow regulator and the separation device are coaxially installed; a salt blocking cap is mounted at the upper end of the groove-shaped clamping sleeve, the groove-shaped clamping sleeve is in threaded fit with the salt blocking cap, an axial saline tank is arranged on the outer wall of the groove-shaped clamping sleeve, the lower end of the groove-shaped clamping sleeve is communicated with the third communicating pipe, a horizontal outlet of the first tee is communicated with one end of the second communicating pipe in a sealing manner, and the other end of the second communicating pipe is orthogonally opposite to an opening at the lower end of the third communicating pipe; the straight-through clamping sleeve is inserted in the fourth through hole in a sealing mode, and openings are formed in the upper side and the lower side of the lower cover respectively;

the Faraday electrolytic cell comprises an electrolytic cell shell, a core column, a platinum rod electrolytic electrode pair, a liquid inlet pipe, a second clamping nut, a third clamping nut, a fourth communicating pipe and a constant current power supply, wherein the liquid inlet pipe is communicated with the through clamping sleeve in a sealing mode, the core column is installed at the lower end of the electrolytic cell shell in a sealing mode through the third clamping nut, the platinum rod electrolytic electrode pair is installed in two positioning through holes of the core column respectively, an outgoing line of the platinum rod electrolytic electrode pair is led out from the lower end of the core column and is electrically connected with the constant current power supply, the liquid inlet pipe is installed at an inlet of the electrolytic cell shell in a sealing mode through the second clamping nut, and the fourth communicating pipe is installed at an outlet of the electrolytic cell shell in a sealing mode through the fourth clamping nut;

the water supply unit comprises a valve, an elbow and a first clamping nut, wherein the inlet of the valve is connected with a water inlet pipe, and the outlet of the valve is hermetically communicated with the first tee joint through the elbow and the first clamping nut;

the output unit comprises a 360-degree rotating device and a plurality of flushing probes, and water inlet pipes of the flushing probes are communicated with the 360-degree rotating device;

raw water is injected into the upper barrel from the valve, flows to salt in the dissolving cavity above the salt blocking cap from an outlet of the titration water flow regulator, and a salt saturated liquid enters the separating device from the salt water tank and enters the titration tank through the third communicating pipe; meanwhile, raw water is injected into the lower barrel from the second communicating pipe, and saturated liquid with the ratio of the titration flow to the raw water flow of 1.0-2.0: 100 is output to a salt solution containing trace hypochlorous acid and hydrogen through the Faraday electrolytic cell and the output unit.

The invention relates to a salt titration electrolyte flushing system, wherein a neutralization titration unit and a Faraday electrolytic cell are transparent bodies which are welded and sealed by plastics.

The invention relates to a salt titration electrolyte flushing system, wherein a constant current power supply adopts a 5V/220mA constant current power supply.

The invention relates to a salt titration electrolyte flushing system, wherein a 360-degree rotating device comprises a first clamping sleeve, a fifth clamping nut matched with the first clamping sleeve, a funnel-shaped sealing sleeve and a protective cover, wherein the funnel-shaped sealing sleeve is positioned in an upper cavity of the first clamping sleeve, a fourth communicating pipe is communicated with the first clamping sleeve through the fifth clamping nut and is opened in an inner cavity of the funnel-shaped sealing sleeve, a water inlet pipe of a flushing probe penetrates through a middle hole of the protective cover to be movably inserted into the funnel-shaped sealing sleeve, and the protective cover is buckled at the upper end of the first clamping sleeve.

The salt titration electrolyte flushing system comprises a flushing probe, wherein the flushing probe is a first probe, the first probe adopts a special-shaped flushing probe pipe, and a water inlet pipe of the first probe is movably inserted into an outlet of a funnel-shaped sealing sleeve.

The salt titration electrolyte flushing system comprises a flushing probe, wherein the flushing probe is a second probe, the second probe adopts a spraying assembly, and a water inlet pipe of the spraying assembly is movably inserted into an outlet of the funnel-shaped sealing sleeve.

The salt titration electrolyte flushing system comprises a flushing probe, a supporting tube and a nipple tube, wherein the flushing probe is a third probe, the third probe adopts an inner cavity flushing probe and comprises a movable joint, the supporting tube and the nipple tube which are sequentially communicated, a water inlet pipe of the movable joint is movably inserted into a water outlet of the funnel-shaped sealing sleeve, and a water outlet pipe of the movable joint is inserted into an inner hole of the nipple tube.

The salt titration electrolyte flushing system comprises a flushing probe, wherein the flushing probe is a fourth probe, the fourth probe adopts a rubber ripple drawing and connecting trousers clothes hydrogen-retaining probe, the fourth probe comprises a liquid inlet pipe, a second tee joint, the rubber ripple drawing and connecting trousers clothes, two trousers legs, a reducing port and a reducing belt, one end of the liquid inlet pipe is movably inserted into an outlet of a funnel-shaped sealing sleeve, the other end of the liquid inlet pipe is communicated with an inlet of the second tee joint, two liquid outlet pipes of the second tee joint are respectively communicated with the two trousers legs correspondingly, and the reducing port and the reducing belt are positioned at the upper end part of the rubber ripple drawing and connecting trousers clothes.

In order to achieve the above object, the present invention further provides a method for flushing a common salt titration electrolyte, which comprises a water supply unit, a neutralization titration unit, a faraday electrolysis cell and an output unit, wherein the method comprises a titration water flow regulator, and comprises the following steps:

(1) presetting the opening degree of a titration water flow regulator, leading raw water into a neutralization titration unit through a water supply unit, dissolving salt in an upper cavity of the neutralization titration unit, generating a neutralization titration solution by the constant flow rate of saturated liquid drops and the flow rate of the raw water according to the ratio of 1.0-2.0: 100 after the obtained salt saturated solution enters a titration tank, and then fixing the titration water flow regulator to keep the opening degree;

(2) connecting a water supply unit and a neutralization titration unit, connecting a power supply of an electrolytic cell, enabling a neutralization titration solution flowing out of an upper cavity of the neutralization titration unit to enter a Faraday electrolytic cell, electrolyzing to generate micro hypochlorous acid and hydrogen, and enabling a saline solution containing the micro hypochlorous acid and the hydrogen to enter an output unit;

(3) selecting a washing probe according to the requirement, connecting the washing probe to the outlet of the output unit, and starting to wash the object:

(4) after the washing is finished, the water supply unit is closed, the upper cover of the neutralization titration unit is unscrewed, and salt is added to a sufficient amount and the upper cover is buckled for subsequent use.

The invention relates to a method for flushing a common salt titration electrolyte, wherein in the step (3), a flushing probe is selected according to requirements, and the method at least comprises the following steps:

replacing the first probe, and flushing in a special shape;

replacing the second probe, and carrying out spray rinsing;

replacing the third probe and flushing the inner cavity;

and the fourth probe is replaced, a user enters the rubber ripple pull-draw hydrogen-retaining probe connected with the trousers, and the size of the variable-diameter port is changed by the variable-diameter belt by increasing or reducing the position of the variable-diameter port, so that a plurality of parts of the human body are washed.

The salt titration electrolyte flushing system and method have the advantages and positive effects that: the device is provided with a 360-degree rotating device and at least four flushing probes for selection of a user, and can be used for cleaning pesticides and chemical fertilizer residues such as vegetables and fruits, general bacterial disinfection, surface flushing of skin diseases, flushing of constipation heads in anal cavities, vaginal flushing and other occasions. Solves the problem of nursing difficulty of the old people, meets various nursing requirements of the old people, and provides reasonable and applicable nursing equipment with health care effect. Meanwhile, the labor condition and the intensity of nursing personnel are effectively reduced, and the pollution to the living room environment and the sanitation is greatly reduced.

The washing device has the advantages of small volume, high nursing quality, obvious effect, low cost, convenient water supply, salt addition and operation in use, and wide popularization and application prospect.

The technical scheme of the saline titration electrolyte flushing system and method provided by the invention is described in detail with reference to the embodiment.

Drawings

FIG. 1 is a schematic diagram of the salt titration electrolytic system of the present invention;

FIG. 2 is a schematic view of a Faraday cell configuration;

FIG. 3 is a schematic diagram of the structure of the titration unit;

FIG. 4 is a schematic of the backbone structure of the titration unit;

FIG. 5 is a schematic view of the construction of the 360 degree steering apparatus;

FIG. 6 is a schematic diagram of a configuration employing a first probe;

FIG. 7 is a schematic diagram of a configuration employing a second probe;

FIG. 8 is a schematic diagram of a configuration employing a third probe;

fig. 9 is a schematic diagram of a structure using a fourth probe.

Detailed Description

Common salt is an indispensable seasoning in human diet and is an indispensable substance component in human body. The main component of common salt is sodium chloride, and the pH value of water is 7-8 by using salt buffer agent. The experiment demonstrated that adding 1% common salt to acidic water with a pH of 3.4 increased the pH to 7.3. In order to be simple and convenient to use and low in price, the salt titration solution is adopted for electrolysis, the effect is good, and the obtained hypochlorous acid solution has the functions of clearing away heat and toxic materials, cooling blood and moistening dryness, nourishing kidney and relaxing bowels, killing parasites and diminishing inflammation, and promoting vomiting and stopping diarrhea.

Production of chloride ion Cl by electrolysis of salt water^-With OH⁺The principle of generating a trace hypochlorous acid aqueous solution,

HOCl_{total amount of}＝HOCl_{Background of the invention}+ΔHOCl------(1)

In the formula: HOCl_{Background of the invention}-background in tap water;

Δ HOCl- -is abbreviated in this specification as standard hypochlorous acid increment.

Wherein the standard hypochlorous acid increment generated by the Faraday electrolytic cell is as follows:

ΔHOCl＝i/V (μg/L)------(2)

in the formula: i- -electrolytic Current mA

The water flow in the V-flushing system is 1250mL/min

The standard hypochlorous acid increment in the system at different electrolysis currents can be calculated by formula (2). Experiments prove that the principle of generating trace hypochlorous acid and hydrogen by electrolyzing the salt water is reliable.

The technical scheme of the saline solution electrolytic rinsing system and method provided by the invention is described in detail with reference to the following embodiments.

Referring to fig. 1, the saline titration electrolyte flushing system provided by the invention comprises a water supply unit 100, a neutralization titration unit 500, a faraday electrolytic cell 400 and an output unit 200, wherein:

referring to fig. 4 in combination, the neutralization and titration unit 500 includes a cylinder, an upper cover 202, a lower cover 502 and a partition plate 504, and further includes a first tee 104, a first communication pipe 301, a second communication pipe 105, a titration water flow regulator 800, a partition 700 and a through clamp sleeve 40. The barrel comprises a framework 505, an upper barrel 201, a lower barrel 501 and a partition plate 504, wherein the partition plate 504 is horizontally arranged between the upper barrel 201 and the lower barrel 501, the upper barrel 201, the lower barrel 501 and the partition plate 504 are hermetically installed on the inner side of the framework 505, salt is stored in the upper barrel 201, and the lower barrel 501 is a salt water neutralizing pool. The upper cover 202 and the lower cover 502 are respectively and hermetically mounted at the upper end of the upper cylinder 201 and the lower end of the lower cylinder 501.

The lower cover 502 is evenly provided with a first through hole K1 and a fourth through hole K4, the partition plate 504 is evenly provided with a second through hole K2 and a third through hole K3, and the first through hole K1, the second through hole K2, the third through hole K3 and the fourth through hole K4 are respectively located on the same axis.

Referring to fig. 3, the lower end of the straight-through pipe of the first tee 104 is hermetically inserted into the first through hole K1, the upper end is hermetically inserted into the second through hole K2, the upper end is opened in the inner cavity of the upper cylinder 201, and the lower end is opened outside the lower cover 502. The separating device 700 is provided with a groove-shaped clamping sleeve 705, the groove-shaped clamping sleeve 705 is hermetically inserted in the third through hole K3, and the openings are respectively arranged at the upper side and the lower side of the isolating plate 504.

The first communicating pipe 301 is in an inverted U shape, and both ends thereof are respectively in sealed communication with the upper end of the first tee 104 and the titration water flow regulator 800. The titration water flow regulator 800 comprises a threaded pipe 801, a threaded rod 802, a sealing ring 803 and a basin-shaped hand wheel 804 which are mutually matched, wherein a water inlet of the threaded pipe 801 is communicated with an outlet of the first communication pipe 301, and the threaded rod 802 extends out of a water outlet of the threaded pipe 801 and is installed in an inner cavity of the basin-shaped hand wheel 804 through the sealing ring 803. The titration water flow regulator 800 is mounted coaxially with the partition 700.

The upper end of the groove-shaped clamping sleeve 705 is provided with a salt blocking cap 704, the groove-shaped clamping sleeve 705 is in threaded fit with the salt blocking cap 704, and the outer wall of the groove-shaped clamping sleeve 705 is provided with an axial brine tank 703. The lower end of the groove-shaped clamping sleeve 705 is communicated with a third communicating pipe 706. The horizontal outlet of the first three-way pipe 104 is in sealed communication with one end of the second communication pipe 105, and the other port of the second communication pipe 105 is orthogonally opposed to the opening at the lower end of the third communication pipe 706. The straight-through cutting sleeve 40 is hermetically inserted in the fourth through hole K4, and the openings are respectively arranged at the upper side and the lower side of the lower cover 502.

The water supply unit 100 includes a valve 101, an elbow 102 and a first nut 103, and the valve 101 is provided with a water inlet pipe 10 connected to raw water, i.e., tap water. The outlet of the valve 101 is in sealed communication with a first tee 104 via an elbow 102 via a first nut 103.

Referring to fig. 2, the secondary faraday electrolytic cell 400 includes an electrolytic cell case 410, a stem 408, a platinum rod electrolytic electrode pair 409, a liquid inlet pipe 401, a second nut 406, a third nut 407, a fourth nut 411, a fourth communicating pipe 604, and a constant current power supply 405, wherein:

the liquid inlet pipe 401 is hermetically communicated with the straight-through clamping sleeve 40, the core column 408 is hermetically installed at the lower end of the electrolytic cell shell 410 through a third clamping nut 407, the platinum rod electrolytic electrode pair 409 is respectively installed in two positioning through holes of the core column 408, an outgoing line of the platinum rod electrolytic electrode pair 409 is led out from the lower end of the core column 408 and is electrically connected with the constant current power supply 405, the liquid inlet pipe 401 is hermetically installed at an inlet of the electrolytic cell shell 410 through a second clamping nut 406, and a fourth communicating pipe 604 is hermetically installed at an outlet of the electrolytic cell shell 410 through a fourth clamping nut 411 to form a Faraday electrolytic cell.

In the embodiment provided by the invention, the neutralization titration unit 500 and the faraday electrolytic cell 400 are transparent bodies made of plastics by welding and sealing.

Referring to fig. 5 and 6 in combination, the output unit 200 includes a 360-degree rotation device 600 and a plurality of washing probes, and the water inlet pipes of the probes are communicated with the 360-degree rotation device 600.

The 360-degree rotating device 600 comprises a first clamping sleeve 603, a fifth clamping nut 605 matched with the first clamping sleeve 603, a funnel-shaped sealing sleeve 602 and a protective cover 601, wherein the funnel-shaped sealing sleeve 602 is located in an upper cavity of the first clamping sleeve 603, a fourth communication pipe 604 is communicated with the first clamping sleeve 603 through the fifth clamping nut 605, an opening is formed in an inner cavity of the funnel-shaped sealing sleeve 602, a connecting pipe of the first probe 901 penetrates through a middle hole of the protective cover 601 to be inserted into the funnel-shaped sealing sleeve 602, and the protective cover 601 is buckled at the upper end of the first clamping sleeve 603.

The irrigation probe may have a variety of configurations. The first probe 901 adopts a special-shaped washing probe tube, and a water inlet pipe of the first probe tube 901 is movably inserted into an outlet of the funnel-shaped sealing sleeve 602;

the first probe 901 can be replaced with another probe, and the invention provides three other embodiments of the probe with different structures:

referring to fig. 7, a second probe 902 employs a spray assembly 92, the inlet conduit of the spray 92 being removably inserted into the outlet of the funnel-shaped gland 602;

referring to fig. 8, the third probe 903 is an intracavity washing probe, and includes an union 906, a support tube 905 and a nipple pipe 904 which are sequentially communicated, wherein a water inlet pipe of the union 906 is directly inserted into a water outlet of the funnel-shaped sealing sleeve 602, a water outlet pipe of the union 906 is movably inserted into an outlet of the funnel-shaped sealing sleeve 602, and a water outlet pipe of the union 906 is inserted into an inner hole of the nipple pipe 904.

Referring to fig. 9, the fourth probe adopts a rubber bellows pull-up diaper hydrogen-retaining probe 98, and comprises a liquid inlet pipe 033, a second tee joint 932, a rubber bellows pull-up diaper 93-5, two trouser legs 93-3, 93-4, a reducing port 93-6 and a reducing belt 93-7, wherein one end of a liquid inlet pipe 933 is movably inserted into an outlet of the funnel-shaped sealing sleeve 602, the other end of the liquid inlet pipe 933 is communicated with an inlet of the second tee joint 932, two liquid outlet pipes 93-1, 93-2 of the second tee joint 932 are respectively communicated with the two trouser legs 93-4, 93-3 correspondingly, and the reducing port 93-6 and the reducing belt 93-7 are positioned at the upper end of the rubber bellows pull-up diaper 93-5.

In the salt titration electrolyte flushing system, the working process is as follows: raw water is injected into the upper cylinder body 201 from the valve 101, flows to the upper part of the salt blocking cap from the outlet of the titration water flow regulator 800 to dissolve salt in the cavity, salt saturated liquid enters the separating device 700 from the salt water tank 703 and enters the titration cell through the third communicating pipe 706, and the salt saturated liquid is dripped into the lower cylinder body 501 by utilizing the gravity of the earth under the isobaric sealed environment; meanwhile, raw water is injected from the second communication pipe 105 into the lower cylinder 501. The opening degree of the titration water flow regulator 800 is changed to make the ratio of the titration flow of the saturated solution to the raw water flow of the second communicating pipe 105 be 1.0-2.0: 100, and then the opening degree of the titration water flow regulator 800 at the ratio is fixed, which is usually verified before the product leaves the factory. Saturated solution with the ratio of the titration flow rate to the raw water flow rate of 1.0-2.0: 100 reaches the output unit 200 through the Faraday electrolytic cell 400, and salt solution containing trace hypochlorous acid and hydrogen is output through the 360-degree rotating device 600 and the flushing probe.

In summary, the invention provides a method for flushing a salt titration electrolyte, which is provided with a water supply unit, a neutralization titration unit, a Faraday electrolysis cell and an output unit, wherein the method comprises a titration water flow regulator, and the method comprises the following steps:

(1) presetting the opening degree of a titration water flow regulator, leading raw water into a neutralization titration unit through a water supply unit, dissolving salt in an upper cavity of the neutralization titration unit, generating a neutralization titration solution by the constant flow rate of saturated liquid drops and the flow rate of the raw water according to the ratio of 1.0-2.0: 100 after the obtained salt saturated solution enters a titration tank, and then fixing the titration water flow regulator to keep the opening degree;

(2) connecting a water supply unit and a neutralization titration unit, switching on a power supply of an electrolytic cell, feeding a neutralization titration solution flowing out of an upper cavity of the neutralization titration unit into a Faraday electrolytic cell, electrolyzing to generate micro hypochlorous acid and hydrogen, and feeding a salt solution containing the micro hypochlorous acid and the hydrogen into an output unit;

(3) selecting a washing probe according to needs, connecting the washing probe to an outlet of the output unit, and starting to wash different target parts:

the first probe is replaced, a warm water source is connected, and special-shaped flushing is carried out;

replacing the second probe, and carrying out spray rinsing;

replacing the third probe, flushing the inner cavity, enabling the patient to lie on a bed for flushing, and wiping the patient with a white towel after flushing;

the fourth probe is replaced, the hydrogen-preserving probe with the rubber ripple and the trousers is connected to a warm water source, a user enters the fourth probe, the position of the reducing port is increased or decreased, the size of the reducing port is changed by the reducing belt, the reducing port can be lifted from the foot to the neck, and a plurality of parts on the human body are washed for relieving leg pain, waist pain and shoulder pain, the human body achieves the effect of activating blood from bottom to top by trace hydrogen, and when the hydrogen flows vertically upwards, the effect of activating blood by contacting the joints of the hands and the like with the hydrogen is ensured, and the washing time is kept for more than 30 minutes.

(4) After the washing is finished, the water supply unit is closed, the upper cover is unscrewed, and salt is added to a sufficient amount and the upper cover is buckled for subsequent use.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention and do not limit the spirit and scope of the present invention. Various modifications and improvements of the technical solutions of the present invention may be made by those skilled in the art without departing from the design concept of the present invention, and the technical contents of the present invention are all described in the claims.