CN106868541B - Electrical control system of SPE hydrogen generator - Google Patents

Abstract

The invention belongs to the technical field of drinking water, and particularly relates to an electrical control system of an SPE hydrogen generator. The electric control system of the SPE hydrogen generator adopts a rechargeable 7.4V/2200mA lithium battery (1524) positioned on the back surface (1527) of a circuit board of the control system to supply power; two ends of the control system circuit board (1500) are respectively provided with an external charging USB interface (1518) and a sensing system (1530) of a touch switch; after a finger presses the sensing touch pad (1531) for one second, the sensing amplifying circuit (1520) is triggered and the power source adapter circuit (1519) is activated to start, and after the continuous operation for five minutes, the SPE hydrogen generator automatically stops working; the sensing touch pad (1531) is pressed for five seconds, the time electromagnetic valve J2 can be forcibly switched, and the machine stops working; the control system circuit board (1500) is mounted on a mounting column (1506) below the generator lower cover (15); the SPE hydrogen generator has the advantages of quick reaction, large gas production rate and simple structure, and the hydrogen saturation of the hydrogen-rich water can reach more than 1500 ppm; with a little improvement, green products such as hydrogen-rich soybean milk, hydrogen-rich fruit juice, hydrogen-rich vegetable juice and the like can be developed.

Description

Electrical control system of SPE hydrogen generator

Technical Field

The invention belongs to the technical field of drinking water, and particularly relates to an electrical control system of an SPE hydrogen generator.

Background

The human body can generate excessive active oxygen free radicals due to ultraviolet irradiation, environmental pollution, violent exercises, smoking and drinking, fatigue, excessive psychological pressure, medicines and the like; the increase of active oxygen free radicals can cause oxidative damage and is an important cause of various diseases and aging of human bodies; scientific research finds that hydrogen gas can remove active oxygen or free radicals in vivo through medical actions of resisting oxidation, resisting aging, resisting inflammation and selectively removing free radicals.

The hydrogen-rich water is novel high-tech drinking water with hydrogen saturation of more than 1200 ppm. After drinking hydrogen-rich water, hydrogen is absorbed by stomach and intestinal tract and enters blood more quickly than water, and is transported to various organ tissues of the whole body through blood circulation; compared with antioxidants such as vitamin E, vitamin C, carotene, tea polyphenol and the like, the hydrogen-rich water has the advantages of selective antioxidation, namely, toxic free radicals are only eliminated, and benign free radicals required by a human body are not damaged; the hydrogen has another great characteristic of biological safety, high-concentration hydrogen has been applied to human diving for more than 50 years, and no obvious toxic and side symptoms are generated by over-breathing high-pressure hydrogen. The list of food additives is listed in Japan, European Union and China.

The working principle of the hydrogen-rich water cup is divided into two types, namely a chemical reaction and an electrolytic reaction, for example, a hydrogen-rich water rod is the chemical reaction, and Mg + H2O- - > Mg (OH)2+ H2. This method has the drawback, however, that the hydrogen-rich water rod is replaced from time to time. In the current society, the rhythm of life is fast, and is lazy world, and the hydrogen stick can not accord with fast rhythm life demand.

The strong electrolysis hydrogen production technology has appeared in the 19 th century, and in the 60 th century of the 20 th century, Japan develops the water ionizer by utilizing the technology and successfully pushes the water ionizer to the market. By-products such as ozone, hydrogen peroxide and the like are easily generated in the strong electrolysis process, so that the hydrogen water has peculiar smell. In addition, strong electrolytic hydrogen production has strict requirements on water sources, pure water and hot water cannot be used, and the drinking habit of Chinese people is not met. The direct current electrolytic hydrogen production technology adopts platinum or ruthenium iridium noble metal as an electrode coating material, and direct current is introduced to carry out strong electrolytic hydrogen production on water. Because the noble metal coating electrode and the circuit board are adopted for control, the manufacturing cost is relatively high, and the product selling price is also high.

The principle of the hydrogen-rich water cup and the hydrogen-rich water machine which are hot sold at present is electrolysis, and the electrolysis of a USB interface is convenient and quick. The hydrogen-rich water cup is used, the on-off key is pressed, hydrogen is immediately generated, and hydrogen-rich water with the saturation of more than 1200ppm is generated in a few minutes. The European pasteur hydrogen-rich water cup produced in Taiwan recently appeared in the market solves the problem that pure water can not be electrolyzed, can use boiled water of 100 ℃, adopts the hydrogen-oxygen separation technology, has higher hydrogen content, does not generate residual chlorine, has certain improvement compared with the Japanese hydrogen-rich water electrolysis technology, and has lower price compared with the Japanese products.

The purpose of the present invention is to solve the above mentioned disadvantages, and to adopt a further improvement scheme; an electrical control system for an SPE hydrogen generator is disclosed to the society.

Disclosure of Invention

The invention belongs to the technical field of drinking water, and particularly relates to an electrical control system of an SPE hydrogen generator. The electric control system of the SPE hydrogen generator adopts a rechargeable 7.4V/2200mA lithium battery (1524) positioned on the back surface (1527) of a circuit board of the control system to supply power; two ends of the control system circuit board (1500) are respectively provided with an external charging USB interface (1518) and a sensing system (1530) of a touch switch; after a finger presses the sensing touch pad (1531) for one second, the sensing amplifying circuit (1520) is triggered and the power source adapter circuit (1519) is activated to start, and after the continuous operation for five minutes, the SPE hydrogen generator automatically stops working; the sensing touch pad (1531) is pressed for five seconds, the time electromagnetic valve J2 can be forcibly switched, and the machine stops working; the control system circuit board (1500) is mounted on a mounting column (1506) below the generator lower cover (15); the SPE hydrogen generator has the advantages of quick reaction, large gas production rate and simple structure, and the hydrogen saturation of the hydrogen-rich water can reach more than 1500 ppm; with a little improvement, green products such as hydrogen-rich soybean milk, hydrogen-rich fruit juice, hydrogen-rich vegetable juice and the like can be developed.

The invention has the advantages that:

1. a rechargeable 7.4V/2200mA lithium battery (1524) is adopted for supplying power;

2. two stable generating cavities are formed on the positive pole and the negative pole by adopting a compression-resistant proton membrane and hydrogen-oxygen separation gas production technology;

3. the hydrogen production amount is large, and the hydrogen saturation of the drinking water can reach more than 1500 ppm;

4. the hydrogen is produced quickly, and hydrogen-rich water is produced immediately by pressing a switch;

5. the use is convenient, the gas and the water are separated, the air permeability is realized, the water drainage is avoided, and the ageing temptation caused by pipelines is avoided;

6. the appearance is luxurious, the structure is compact, and the time trend is followed;

7. advocate the concepts of scientific drinking, healthy drinking, convenient drinking and reassuring drinking, benefit human beings,

8. with a little improvement, green products such as hydrogen-rich soybean milk, hydrogen-rich fruit juice, hydrogen-rich vegetable juice and the like can be developed.

The technical route of the invention is realized in this way.

The electrical control system of the SPE hydrogen generator comprises an assembly framework member (01), the SPE hydrogen-oxygen separation generator (02) and a hydrogen-rich water generator (03); the device comprises a stainless steel wire drawing upper decorative sleeve (1), an assembly ring frame sleeve (2), a stainless steel wire drawing lower decorative sleeve (3), a locking bottom plate (4), an external interface sealing ring (5), a generator upper cover (6), a generation chamber sealing ring A (7), a cathode platinum titanium plate (8), a micro grid proton membrane (9), an anode platinum titanium plate (10), a generation chamber sealing ring B (11), a vent plug (12), a vent sealing ring (13), a breathable film (14), a generator lower cover (15), a generator sealing ring (16), absorbent cotton (17), a cup cover (18), a vacuum cup body (19), a hydrogen generation assembly (20), a control system circuit board (1500), a connection notch (1501), a connection screw hole (1502), an inner concave hole (1503), a sealing ring step (1504), an absorbent cotton containing groove (1505), a power supply control panel mounting column (1506) and a breathable channel (1507), The device comprises a rib (1508), a central hole (1509), a groove (1510), a USB interface hole (1511), a reserved hole of an induction switch (1512), an installation slot rack of the induction switch (1513), a bottom plate locking sleeve column (1514), an air vent (1515), a step assembly upright column (1516), an electrode extending slot hole (1517), a USB interface (1518), a power adapter circuit (1519), a sensing amplification circuit (1520), a signal display circuit (1521), a negative socket (1522), a positive socket (1523), a lithium battery (1524), a 555 singlechip (1525), a circuit board notch (1526), a circuit board reverse side (1527), a sensing element (1528), a sensing spring (1529), a sensing system (1530), a charging socket (1531), a circuit board installation hole (1532) and a sensing touch pad (1533); the control system circuit board (1500) is powered by a rechargeable 7.4V/2200mA lithium battery (1524) positioned on the back surface (1527) of the control system circuit board; two ends of the control system circuit board (1500) are respectively provided with an external charging USB interface (1518) and a sensing system (1530) of a touch switch; the sensing system (1530) comprises a switch board mounting groove frame (1513), a sensing amplifying circuit (1520), a sensing original piece (1528), a sensing spring (1529) and a sensing touch pad (1533); the sensing touch pad (1533) is positioned on the switch mounting groove frame (1513); the sensing spring (1529) is pressed against the sensing touch pad (1533) to form the front end of the sensing amplifying circuit (1520); the sensing touch pad (1533) triggers the sensing amplifying circuit (1520) after the sensing touch pad (1533) is pressed by a human finger for one second, the parallel excitation time relay J1 is opened, the positive socket (1523) and the negative socket (1522) of the lithium battery (1524) are connected, the power adapter circuit (1519) is started, when the rechargeable 7.4V/2200mA lithium battery (1524) supplies power to the SPE hydrogen-oxygen separation generator (02), a blue lamp and a buzzer in the signal display circuit (1521) are lightened to sound to prompt the SPE hydrogen-oxygen separation generator (02) to start working, the instantly generated hydrogen continuously supplies hydrogen to the hydrogen-rich water generator (03), and after the SPE hydrogen-oxygen separation generator (02) continuously works for five minutes, a time solenoid valve J1 in the power supply adapting circuit (1519) is switched, the blue lamp is turned off, the buzzer sounds, and the SPE hydrogen generator stops working; when the SPE hydrogen-oxygen separation generator (02) works normally, if the sensing touch pad (1533) is pressed for five seconds, the time electromagnetic valve J2 can be switched forcibly, and the machine stops working; a rechargeable 7.4V/2200mA lithium battery (1524), an anode socket (1523) and a cathode socket (1522) are arranged on the back surface (1527) of the control system circuit board; a charging socket (1531) of a rechargeable 7.4V/2200mA lithium battery (1524) is also arranged on the back surface (1527) of the control system circuit board; circuit board mounting holes (1532) matched with the power control board mounting columns (1506) positioned below the generator lower cover (15) are formed in four corners of the reverse side (1500) of the control system circuit board, and the control system circuit board (1500) is mounted on the circuit board mounting holes; the locking bottom plate (4) locks the stainless steel drawing lower decorative sleeve (3) on the assembly ring frame sleeve (2) through the bottom plate locking sleeve column (1514) to form the whole body of the hydrogen generation assembly (20); the hydrogen generating assembly (20) is connected with a vacuum cup body (19) with a cup cover (18) to form an integral body of the hydrogen-enriched water generator (03).

The micro-grid proton membrane (9) is in a disc shape, and two surfaces of the membrane are provided with criss-cross micro-grid reinforcing ribs; the upper and lower parts of the micro-grid proton membrane (9) are provided with a cathode platinized titanium plate (8) and an anode platinized titanium plate (10).

Due to the function of the micro-grid, a micro-generation cavity which can enable the electrolyte water to be separated from hydrogen and oxygen is formed between the micro-grid proton membrane (9) and the anode platinized titanium plate (10).

And the SPE hydrogen-oxygen separation generator (02) with the hydrogen-oxygen separation function is arranged in a mounting cavity of the hydrogen-oxygen separation generator formed after the generator upper cover (6) and the generator lower cover (15) are tightly combined.

A connecting notch (1501) connected with a connecting convex port of the hydrogen-enriched water generator (03) is arranged in the center above the generator upper cover (6); the generator upper cover (6) is provided with a connecting notch (1501) above the center, and the bottom of the connecting notch (1501) is provided with a sealing ring groove for accommodating an external interface sealing ring (5).

And the generator upper cover (6) and the generator lower cover (15) are provided with symmetrical connecting screw holes (1502) which are not less than four and act on the upper cover and the lower cover to be tightly closed and inner concave holes (1503) which are distributed at an angle of 90 degrees and used for positioning a power supply board and an SPE hydrogen-oxygen separation generator (02).

And sealing ring steps (1504) for accommodating the generation chamber sealing ring A (7) and the generation chamber sealing ring B (11) are arranged on the opposite surfaces of the generator upper cover (6) and the generator lower cover (15), and the generation chamber sealing ring A (7) and the generation chamber sealing ring B (11) are accommodated in the sealing ring steps.

And the opposite surfaces of the generator upper cover (6) and the generator lower cover (15) are also provided with an electrode extending slotted hole (1517) and a generator sealing ring (16) accommodating shallow groove.

The center of the generator lower cover (15) is provided with a water absorption cotton containing groove (1505), water absorption cotton (17) is contained in the water absorption cotton containing groove to absorb infinitesimal water seepage, and the infinitesimal water seepage is discharged through a ventilation channel (1507) positioned at the side of the water absorption cotton containing groove (1505) under the action of heat generated by electric medium.

The tail end of the ventilation channel (1507) is respectively provided with a ventilation film (14), a ventilation hole sealing ring (13) and a ventilation hole plug (12) so as to realize the technical route of ventilation and no drainage.

The center of the assembly ring frame sleeve (2) is provided with a preformed hole (1509) which can enable a lower convex opening arranged at the center of the bottom of the vacuum cup body (19) to be connected with a notch (1501) of the hydrogen-rich water assembly (03).

In the assembly ring frame sleeve (2), step type assembling upright columns (1516) are distributed at an angle of 90 degrees.

Step assembly upright (1516) total height is 1/2 that total ring frame cover (2) is high, short step height is 1/2 that step assembly upright (1516) is high, SPE oxyhydrogen separation generator (02) and locking bottom plate (4) are installed on step assembly upright (1516) in proper order.

The circumference of the upper surface of the assembly ring frame sleeve (2) is larger than that of the assembly ring frame, and after the stainless steel wiredrawing upper decorative sleeve (1) is installed, the circumference of the upper surface of the assembly ring frame sleeve (2) is just flush with the circumference of the upper surface of the assembly ring frame sleeve.

The stainless steel wire drawing upper decorative sleeve (1) is positioned on the assembly ring frame sleeve (2), matched with a groove (1510) which is distributed at 90 degrees below the vacuum cup body (19) through a convex edge (1508) which is distributed at 90 degrees and arranged at the inner side of the stainless steel wire drawing upper decorative sleeve (1), and sleeved below the vacuum cup body (19) on the assembly ring frame sleeve (2) so as to shield the internal structure of the SPE hydrogen-oxygen separation generator (02) and improve the aesthetic impression of the product.

The assembly ring frame sleeve (2) and the stainless steel wire drawing lower decorative sleeve (3) are mutually sleeved by a rib (1508) which is arranged on the inner side of the stainless steel wire drawing lower decorative sleeve (3) and is distributed at 90 degrees and a groove (1510) which is arranged on the assembly ring frame sleeve (2) and is distributed at 90 degrees.

The assembly ring frame sleeve (2) and the stainless steel wire drawing lower decoration sleeve (3) are correspondingly provided with a USB interface hole (1511) and an inductive switch preformed hole (1512), and sliding protective soft flaps are arranged outside the USB interface hole (1511) and the inductive switch preformed hole (1512).

The micro-grid proton membrane (9) has the functions of pressure resistance, stable formation of a hydrogen-oxygen separation generation cavity, ventilation and water tightness.

The design purpose of criss-cross micro grids is distributed on the upper surface and the lower surface of the micro grid proton membrane (9): one is to increase the physical strength of the membrane and the other is to form a micro-generation chamber for hydrogen and oxygen separation.

When the micro-grid proton membrane (9) starts to prepare hydrogen when the power supply is switched on, along with the increase of the hydrogen yield, the acting force of the water body in the hydrogen-rich water generator (03) on the micro-grid proton membrane (9) is gradually increased; because the micro-grid proton membrane (9) has great water resistance, the surfaces of the micro-grid proton membrane only present a micro-wet state, and the micro-grid proton membrane (9) bears two pressures, namely, the gravity of a water body and the gas expansion pressure after the hydrogen yield is increased, wherein the sum of the two pressures is P1; the ability of the micro-grid proton membrane (9) to resist P1 is P2; the micro-grid proton membrane (9) is reinforced by grids, meets the requirement that the membrane resistance P2 is not less than the water body acting force P1, and realizes the compression resistance and hydrogen-oxygen separation technical route of the pressure change membrane without deformation.

Due to the action of the micro-grid, a stable dielectric water micro-generation cavity with separated hydrogen and oxygen is formed between the micro-grid proton membrane (9) and the anode platinized titanium plate (10).

Further, under the action of a strong electromagnetic field, the micro-generation cavity for separating hydrogen and oxygen can generate hydrogen and oxygen, due to the great molecular weight difference relationship, the hydrogen with small molecular weight can pass through the micro-grid proton membrane (9) and rise into the water body of the hydrogen-rich water generator (03) to generate hydrogen-rich water, and the oxygen with large molecular weight can only pass through the circular hole of the anode platinized titanium plate (10) and enter the ventilation channel (1507) due to the fact that the oxygen cannot pass through the micro-grid proton membrane (9), and is discharged into the atmosphere after being filtered by the ventilation film (14), so that the technical route of separating hydrogen and oxygen, ventilating and water-tight discharging is realized.

The SPE hydrogen-oxygen separation generator (02) adopts the SPE technology, the reaction is rapid, the gas production rate is large, and the hydrogen saturation of hydrogen-rich water can reach more than 1500 ppm.

And a power control panel mounting column (1506) is arranged below the generator lower cover (15), and the power control panel adopts a 12V rechargeable lithium battery USB interface and an inductive switch.

The vacuum cup body (19) is made of quartz glass, and a convex port of the vacuum cup body (19) connected with a connecting notch (1501) above the center of the upper cover (6) of the generator is arranged in the center of the bottom of the vacuum cup body (19).

The assembly framework piece (01) consists of an assembly ring framework sleeve (2), a stainless steel wire drawing lower decorative sleeve (3) and a locking bottom plate (4); a preformed hole (1509) which can enable a lower convex opening arranged at the center of the bottom of the vacuum cup body (19) to be connected with a notch (1501) of the hydrogen-rich water assembly (03) is arranged at the center of the integrated ring frame sleeve (2); in total ring frame cover (2), be 90 degrees angular distribution and have step assembly stand (1516), step stand overall height is 1/2 that total ring frame cover (2) is high, and short step height is 1/2 that the step stand is high, and SPE oxyhydrogen separation generator (02) and locking bottom plate (4) are installed in step assembly stand (1516) in proper order.

The circumference of the upper surface of the assembly ring frame sleeve (2) is larger than the circumference of the assembly ring frame, and after the stainless steel wiredrawing upper decorative sleeve (1) or the stainless steel wiredrawing lower decorative sleeve (3) is installed, the circumference is just flush with the circumference of the upper surface of the assembly ring frame sleeve (2).

The stainless steel wire drawing upper decorative sleeve (1) is positioned on the assembly ring frame sleeve (2), matched with a groove (1510) which is distributed at 90 degrees below the vacuum cup body (19) through a convex edge (1508) which is distributed at 90 degrees and arranged at the inner side of the stainless steel wire drawing upper decorative sleeve (1), and sleeved below the vacuum cup body (19) sleeved on the assembly ring frame sleeve (2) so as to shield the internal structure of the SPE hydrogen-oxygen separation generator (02) and improve the aesthetic impression of products.

The assembly ring frame sleeve (2) and the stainless steel wire drawing lower decorative sleeve (3) are mutually sleeved through a convex edge (1508) which is arranged on the inner side of the stainless steel wire drawing lower decorative sleeve (3) and is distributed at 90 degrees and a groove (1510) which is arranged on the assembly ring frame sleeve (2) and is distributed at 90 degrees.

The general ring frame sleeve (2) and the stainless steel wire drawing lower decorative sleeve (3) are correspondingly provided with a USB interface hole (1511) and an inductive switch preformed hole (1512); and sliding protective soft flaps are arranged outside the USB interface hole (1511) and the induction switch preformed hole (1512).

The locking bottom plate (4) locks the stainless steel drawing lower decorative sleeve (3) on the assembly ring frame sleeve (2) through the bottom plate locking sleeve column (1514) to form a hydrogen generation assembly (20) whole.

The hydrogen generating assembly (20) is connected with a vacuum cup body (19) of mineral water which is inverted and provided with a bottom removed; the hydrogen generating assembly (20) and the vacuum cup body (19) with the cup cover (18) on the upper part are integrated into a whole of the hydrogen-enriched water generator (03).

The hydrogen generating assembly (20) is an independent and complete hydrogen generator and is connected with hydrogen-rich generating devices of different types, including mineral water, coca-cola, fruits and vegetable juice which are popular in the market, so that a plurality of hydrogen-rich products can be developed.

Drawings

FIG. 1 is a schematic diagram of an electrical control system according to the present application.

FIG. 2 is a schematic diagram of the assembly process and the partial row structure of the present application.

Fig. 3 is a schematic diagram of the overall structure of the present application.

The reference designations in the attached figures 1-3 are uniformly: the hydrogen-rich water generator comprises an assembly framework member (01), an SPE hydrogen-oxygen separation generator (02) and a hydrogen-rich water generator (03); the device comprises a stainless steel wire drawing upper decorative sleeve (1), an assembly ring frame sleeve (2), a stainless steel wire drawing lower decorative sleeve (3), a locking bottom plate (4), an external interface sealing ring (5), a generator upper cover (6), a generation chamber sealing ring A (7), a cathode platinum titanium plate (8), a micro grid proton membrane (9), an anode platinum titanium plate (10), a generation chamber sealing ring B (11), a vent plug (12), a vent sealing ring (13), a breathable film (14), a generator lower cover (15), a generator sealing ring (16), absorbent cotton (17), a cup cover (18), a vacuum cup body (19), a hydrogen generation assembly (20), a control system circuit board (1500), a connection notch (1501), a connection screw hole (1502), an inner concave hole (1503), a sealing ring step (1504), an absorbent cotton containing groove (1505), a power supply control panel mounting column (1506) and a breathable channel (1507), The device comprises a rib (1508), a central hole (1509), a groove (1510), a USB interface hole (1511), a reserved hole of an induction switch (1512), an induction switch mounting groove frame (1513), a bottom plate locking sleeve column (1514), an air vent (1515), a stepped assembly upright column (1516), an electrode extending groove hole (1517), a USB interface (1518), a power adapter circuit (1519), a sensing amplification circuit (1520), a signal display circuit (1521), a negative socket (1522), a positive socket (1523), a lithium battery (1524), a 555 single chip microcomputer (1525), a circuit board notch (1526), a circuit board reverse side (1527), a sensing element (1528), a sensing spring (1529), a sensing system (1530), a charging socket (1531), a circuit board mounting hole (1532) and a sensing touch pad (1533).

Detailed Description

The present invention is described in detail below with reference to the attached drawings.

As shown in FIG. 1, the control system circuit board (1500) is powered by a rechargeable 7.4V/2200mA lithium battery (1524) located on the back surface (1527) of the control system circuit board.

As shown in fig. 1, two ends of the control system circuit board (1500) are respectively provided with an external charging USB interface (1518) and a sensing system (1530) of a touch switch.

As shown in fig. 1, the sensing system (1530) includes a switch board mounting slot frame (1513), a sensing amplifying circuit (1520), a sensing element (1528), a sensing spring (1529) and a sensing touch panel (1533).

As shown in fig. 1, the sensor touch pad (1533) is located on the switch mounting slot rack (1513); the sensing spring (1529) is pressed against the sensing touch pad (1533) to form the front end of the sensing amplifying circuit (1520).

As shown in fig. 1, the sensing touch panel (1533) triggers the sensing amplifying circuit (1520) after the sensing touch panel (1533) is pressed by a human finger for one second, the parallel excitation time relay J1 is opened, the positive socket (1523) and the negative socket (1522) of the lithium battery (1524) are connected, the power adapter circuit (1519) is started, when the rechargeable 7.4V/2200mA lithium battery (1524) supplies power to the SPE hydrogen-oxygen separation generator (02), a blue lamp and a buzzer in the signal display circuit (1521) are lightened to sound to prompt the SPE hydrogen-oxygen separation generator (02) to start working, the instantly generated hydrogen continuously supplies hydrogen to the hydrogen-rich water generator (03), and after the SPE hydrogen-oxygen separation generator (02) continuously works for five minutes, a time electromagnetic valve J1 in the power supply adapting circuit (1519) is switched, the blue lamp is turned off, the buzzer sounds, and the SPE hydrogen generator stops working.

As shown in fig. 1, when SPE hydrogen-oxygen separation generator (02) works normally, if sensing touch pad (1533) is pressed for five seconds, time electromagnetic valve J2 can be switched forcibly, and the machine stops working.

As shown in fig. 1, a rechargeable 7.4V/2200mA lithium battery (1524), an anode socket (1523) and a cathode socket (1522) are arranged on the back surface (1527) of the control system circuit board.

As shown in fig. 1, a charging socket (1531) for a rechargeable 7.4V/2200mA lithium battery (1524) is further disposed on the back surface (1527) of the control system circuit board.

As shown in fig. 1, circuit board mounting holes (1532) matched with the power control board mounting posts (1506) located below the generator lower cover (15) are arranged at four corners of the back surface (1500) of the control system circuit board, and the control system circuit board (1500) is mounted on the circuit board mounting holes.

As shown in fig. 1, the locking bottom plate (4) locks the stainless steel wire drawing lower decorative sleeve (3) on the assembly ring frame sleeve (2) through the bottom plate locking sleeve column (1514) to form the whole body of the hydrogen generation assembly (20).

The hydrogen generating assembly (20) is connected with a vacuum cup body (19) with a cup cover (18) to form an integral body of the hydrogen-enriched water generator (03).

As shown in fig. 1, the micro-grid proton membrane (9) is in a disc shape, and two surfaces of the membrane are provided with criss-cross micro-grid reinforcing ribs; the upper and lower parts of the micro-grid proton membrane (9) are provided with a cathode platinized titanium plate (8) and an anode platinized titanium plate (10).

As shown in figure 1, the micro-grid proton membrane (9) and the anode platinized titanium plate (10) form a micro-generation cavity which can separate water and hydrogen by electric dielectric water due to the action of the micro-grid.

As shown in figure 1, the SPE hydrogen-oxygen separation generator (02) with hydrogen-oxygen separation function is arranged in a mounting cavity of the hydrogen-oxygen separation generator formed by tightly combining an upper generator cover (6) and a lower generator cover (15).

As shown in fig. 1, a connecting notch (1501) connected with a connecting convex port of a hydrogen-enriched water generator (03) is arranged at the center above the generator upper cover (6); the generator upper cover (6) is provided with a connecting notch (1501) above the center, and the bottom of the connecting notch (1501) is provided with a sealing ring groove for accommodating an external interface sealing ring (5).

As shown in figure 1, the generator upper cover (6) and the generator lower cover (15) are provided with at least four symmetrical connecting screw holes (1502) which are used for tightly closing the upper cover and the lower cover and inner concave holes (1503) which are distributed at an angle of 90 degrees and used for positioning a power supply board and an SPE hydrogen-oxygen separation generator (02).

As shown in fig. 1, the generator upper cover (6) and the generator lower cover (15) are provided with seal steps (1504) for accommodating the generation chamber seal ring a (7) and the generation chamber seal ring B (11), and the generation chamber seal ring a (7) and the generation chamber seal ring B (11) are accommodated therein.

As shown in figure 1, the opposite surfaces of the generator upper cover (6) and the generator lower cover (15) are also provided with an electrode extending groove hole (1517) and a generator sealing ring (16) accommodating shallow groove.

As shown in fig. 1, the generator lower cover (15) is provided at the center thereof with a water absorbent cotton receiving groove (1505) in which water absorbent cotton (17) is received to absorb a very small amount of water, and the very small amount of water is discharged through a ventilation channel (1507) located at the side of the water absorbent cotton receiving groove (1505) by the heat generated by the dielectric.

As shown in figure 1, the tail end of the ventilation channel (1507) is respectively provided with a ventilation film (14), a ventilation hole sealing ring (13) and a ventilation hole plug (12) so as to realize the technical route of ventilation and water drainage.

As shown in figure 1, the center of the assembly ring frame sleeve (2) is provided with a preformed hole (1509) which can enable a lower convex opening arranged at the center of the bottom of the vacuum cup body (19) to be connected with a concave opening (1501) of the hydrogen-rich water assembly (03).

As shown in fig. 1, step-type assembling columns (1516) are distributed in the overall annular frame sleeve (2) at an angle of 90 degrees.

As shown in FIG. 1, the total height of the step assembly upright (1516) is 1/2 the total height of the ring frame sleeve (2), the short step height is 1/2 the height of the step assembly upright (1516), and the SPE hydrogen-oxygen separation generator (02) and the locking bottom plate (4) are sequentially arranged on the step assembly upright (1516).

As shown in figure 1, the circumference of the upper part of the assembly ring frame sleeve (2) is larger than that of the assembly ring frame, and after the stainless steel wiredrawing upper decorative sleeve (1) is installed, the circumference is just flush with the circumference of the upper part of the assembly ring frame sleeve (2).

As shown in figure 1, the stainless steel wire drawing upper decorative sleeve (1) is positioned on the assembly ring frame sleeve (2), and is matched with a groove (1510) which is distributed at 90 degrees below a vacuum cup body (19) through a convex rib (1508) which is distributed at 90 degrees and is arranged at the inner side of the stainless steel wire drawing upper decorative sleeve (1), and is sleeved below the vacuum cup body (19) on the assembly ring frame sleeve (2) so as to shield the internal structure of the SPE hydrogen-oxygen separation generator (02) and improve the aesthetic appearance of the product.

As shown in fig. 1, the assembly ring frame sleeve (2) and the stainless steel wire drawing lower decorative sleeve (3) are mutually sleeved with a rib (1508) which is arranged on the inner side of the stainless steel wire drawing lower decorative sleeve (3) and is distributed at 90 degrees and a groove (1510) which is arranged on the assembly ring frame sleeve (2) and is distributed at 90 degrees.

As shown in fig. 1, the assembly ring frame sleeve (2) and the stainless steel wire drawing lower decoration sleeve (3) are correspondingly provided with a USB interface hole (1511) and an inductive switch preformed hole (1512), and sliding protective soft flaps are arranged outside the USB interface hole (1511) and the inductive switch preformed hole (1512).

As shown in figure 2, the micro-grid proton membrane (9) has the functions of resisting pressure, stably forming a hydrogen-oxygen separation generating cavity and ventilating and preventing water from being drained.

As shown in fig. 2, the micro-grid proton membrane (9) has criss-cross micro-grids distributed on its upper and lower surfaces: one is to increase the physical strength of the membrane and the other is to form a micro-generation chamber for hydrogen and oxygen separation.

As shown in fig. 1, when the micro-grid proton membrane (9) starts to produce hydrogen when the power is turned on, the water body in the hydrogen-rich water generator (03) has an increasing force on the micro-grid proton membrane (9) with the increase of the hydrogen yield.

As shown in figure 1, because the micro-grid proton membrane (9) has great water-blocking capacity, the two surfaces of the membrane only present a micro-wet state, and the micro-grid proton membrane (9) bears two pressures, namely, the gravity of the water body and especially the gas expansion pressure after the hydrogen yield is increased, and the sum of the two pressures is P1.

As shown in fig. 1, the ability of the micro-grid proton membrane (9) to counterbalance P1 is P2; the micro-grid proton membrane (9) is reinforced by grids, meets the requirement that the membrane resistance P2 is not less than the water body acting force P1, and realizes the compression resistance and hydrogen-oxygen separation technical route of the pressure change membrane without deformation.

As shown in figure 2, a stable dielectric water micro-generation cavity with separated hydrogen and oxygen is formed between the micro-grid proton membrane (9) and the anode platinized titanium plate (10) due to the action of the micro-grid.

As shown in fig. 2, further, under the action of a strong electromagnetic field, the micro-generation cavity for separating hydrogen and oxygen can generate hydrogen and oxygen, due to the relationship of a great molecular weight difference, hydrogen with a small molecular weight can pass through the micro-grid proton membrane (9) and rise into the water body of the hydrogen-rich water generator (03), so that hydrogen-rich water is generated, while oxygen with a large molecular weight can only pass through the circular hole of the anode platinized titanium plate (10) because the oxygen cannot pass through the micro-grid proton membrane (9), and then bypasses the circular hole to enter the ventilation channel (1507), and is filtered by the ventilation film (14) and then discharged into the atmosphere, thereby realizing the technical route of separating hydrogen and oxygen, ventilating and non-draining.

As shown in figure 2, the SPE hydrogen-oxygen separation generator (02) has the advantages of rapid reaction, large gas production rate and hydrogen saturation of hydrogen-rich water reaching more than 1500 ppm.

As shown in fig. 2, a power control board mounting column (1506) is arranged below the generator lower cover (15), and the power control board adopts a 12V rechargeable lithium battery USB interface hole (1511) and an inductive switch.

As shown in figure 2, the vacuum cup (19) is made of quartz glass, and the center of the bottom of the vacuum cup (19) is provided with a convex interface of the vacuum cup (19) which is connected with a connecting notch (1501) above the center of the upper cover (6) of the generator.

As shown in fig. 2, the assembly frame member (01) is composed of a stainless steel wire drawing upper decorative sleeve (1), an assembly ring frame sleeve (2), a stainless steel wire drawing lower decorative sleeve (3) and a locking bottom plate (4).

As shown in figure 2, the center above the assembly ring frame sleeve (2) is provided with a preformed hole (1509) which can enable a lower convex opening arranged at the center of the bottom of the vacuum cup body (19) to be connected with a concave opening (1501) of the hydrogen-rich water assembly (03).

As shown in fig. 2, the assembly ring frame sleeve (2) and the stainless steel wire drawing lower decorative sleeve (3) are mutually sleeved with a rib (1508) which is arranged on the inner side of the stainless steel wire drawing lower decorative sleeve (3) and is distributed at 90 degrees and a groove (1510) which is arranged on the assembly ring frame sleeve (2) and is distributed at 90 degrees.

As shown in fig. 2, the locking bottom plate (4) locks the stainless steel wire drawing lower decorative sleeve (3) on the assembly ring frame sleeve (2) through the bottom plate locking sleeve column (1514) to form a hydrogen generation assembly (20); the hydrogen generating assembly (20) is connected with a vacuum cup body (19) of a reverse-buckled mineral water bottle with a bottom removed.

As shown in figure 2, the assembly frame member (01) is internally provided with an SPE oxyhydrogen separation generator (02) and a vacuum cup body (19) with an upper bearing cup cover (18), and the SPE oxyhydrogen separation generator and the vacuum cup body are integrated into a whole of a hydrogen-rich water generator (03).

As shown in FIG. 3, the hydrogen generating assembly (20) is an independent and complete hydrogen generator, and is connected with hydrogen-rich generating devices of different types, including mineral water, coca-cola, fruit and vegetable juice, which are popular in the market, so that a plurality of hydrogen-rich products can be developed.

Claims (5)

1. An electrical control system of an SPE hydrogen generator comprises an SPE hydrogen-oxygen separation generator assembly (02) and a hydrogen-rich water generator (03); the SPE hydrogen-oxygen separation generator assembly (02) comprises a generator lower cover (15), a control system circuit board (1500) and a locking bottom plate (4); the control system circuit board (1500) is powered by a rechargeable 7.4V/2200mA lithium battery (1524) positioned on the back surface (1527) of the control system circuit board; two ends of the control system circuit board (1500) are respectively provided with an external charging USB interface (1518) and a sensing system (1530) of a touch switch; the sensing system (1530) comprises a switch board mounting groove frame (1513), a sensing amplifying circuit (1520), a sensing original piece (1528), a sensing spring (1529) and a sensing touch pad (1533); the sensing touch pad (1533) is positioned on the switch mounting groove frame (1513); the sensing spring (1529) is positioned on the sensing touch pad (1533) and forms the front end of the sensing amplifying circuit (1520); the sensing touch pad (1533) triggers the sensing amplifying circuit (1520) after the sensing touch pad (1533) is pressed by a human finger for one second, the parallel excitation time relay J1 is opened, the anode (1523) and the cathode (1522) of the lithium battery (1524) are switched on, the power adapter circuit (1519) is started, when a rechargeable 7.4V/2200mA lithium battery (1524) supplies power to the SPE hydrogen-oxygen separation generator assembly (02), a blue lamp and a buzzer in the signal display circuit (1521) are lightened and sounded to prompt the SPE hydrogen-oxygen separation generator assembly (02) to start working, the instantly generated hydrogen continuously supplies hydrogen to the hydrogen-rich water generator (03), and after the SPE hydrogen-oxygen separation generator assembly (02) continuously works for five minutes, a time relay J1 in the power supply adapting circuit (1519) is switched, the blue lamp is turned off, the buzzer sounds, and the SPE hydrogen generator stops working; when the SPE hydrogen-oxygen separation generator assembly (02) works normally, if the sensing touch pad (1533) is pressed for five seconds, the time relay J2 can be switched forcibly, and the machine stops working; a rechargeable 7.4V/2200mA lithium battery (1524) and a socket of an anode (1523) and a cathode (1522) are arranged on the back surface (1527) of the control system circuit board; a charging socket (1531) of a rechargeable 7.4V/2200mA lithium battery (1524) is also arranged on the back surface (1527) of the control system circuit board; circuit board mounting holes (1532) matched with the power control board mounting columns (1506) positioned below the generator lower cover (15) are formed in four corners of the reverse side (1527) of the control system circuit board, and the control system circuit board (1500) is mounted on the circuit board mounting holes; the locking bottom plate (4) locks the stainless steel drawing lower decorative sleeve (3) on the assembly ring frame sleeve (2) through the bottom plate locking sleeve column (1514) to form the whole body of the hydrogen generation assembly (20); the hydrogen generating assembly (20) is connected with a vacuum cup body (19) with a cup cover (18) to form an integral body of the hydrogen-enriched water generator (03).
2. 2. The SPE hydrogen generator electrical control system according to claim 1, wherein the assembly frame member (01) comprises a stainless steel wiredrawing upper decorative sleeve (1), an assembly ring frame sleeve (2), a stainless steel wiredrawing lower decorative sleeve (3), a locking bottom plate (4), a USB interface hole (1511), an inductive switch preformed hole (1512), an inductive switch mounting groove frame (1513), a bottom plate locking sleeve column (1514) and a vent hole (1515), an electrode protruding slotted hole (1517) and a stepped assembly upright post (1516); the SPE hydrogen-oxygen separation generator assembly (02) comprises an external interface sealing ring (5), a generator upper cover (6), a generation chamber sealing ring A (7), a cathode platinum-plated titanium plate (8), a micro-grid proton membrane (9), an anode platinum-plated titanium plate (10), a generation chamber sealing ring B (11), an air vent plug (12), an air vent sealing ring (13), an air permeable membrane (14), a generator lower cover (15), a generator sealing ring (16), absorbent cotton (17), a cup cover (18), a vacuum cup body (19), a hydrogen generation assembly (20), a connecting notch (1501), a connecting screw hole (1502), an inner concave hole (1503), a sealing ring step (1504), an absorbent cotton accommodating groove (1505), a power supply control plate mounting column (1506), an air permeable channel (1507), a convex edge (1508), a central hole (1509) and a groove (1510); the micro-grid proton membrane (9) is in a wafer shape, and two sides of the membrane are provided with criss-cross micro-grid reinforcing ribs; the upper part and the lower part of the micro-grid proton membrane (9) are provided with a cathode platinized titanium plate (8) and an anode platinized titanium plate (10); a hydrogen-oxygen separation generating cavity for electrolyzing water is formed between the micro-grid proton membrane (9) and the anode platinized titanium plate (10); an SPE hydrogen-oxygen separation generator assembly (02) with a hydrogen-oxygen separation function is arranged in an SPE hydrogen-oxygen separation generator assembly (02) installation cavity formed by tightly combining an upper generator cover (6) and a lower generator cover (15); a connecting notch (1501) connected with a connecting convex port of the hydrogen-enriched water generator (03) is arranged in the center above the generator upper cover (6); a connecting notch (1501) is formed above the center of the generator upper cover (6), and a sealing ring groove for accommodating an external interface sealing ring (5) is formed in the bottom of the connecting notch (1501); the generator upper cover (6) and the generator lower cover (15) are provided with at least four symmetrical connecting screw holes (1502) which are used for tightly closing the upper cover and the lower cover and inner concave holes (1503) which are distributed at an angle of 90 degrees and used for positioning a power supply board and an SPE hydrogen-oxygen separation generator assembly (02); the generator upper cover (6) and the generator lower cover (15) are provided with sealing ring steps (1504) for accommodating a generation chamber sealing ring A (7) and a generation chamber sealing ring B (11) on opposite surfaces, and the generation chamber sealing ring A (7) and the generation chamber sealing ring B (11) are accommodated in the sealing ring steps; the generator upper cover (6) and the generator lower cover (15) are provided with electrode extending slotted holes (1517) and generator sealing rings (16) on the opposite surfaces thereof with shallow accommodating grooves; the center of the generator lower cover (15) is provided with a water absorption cotton containing groove (1505), water absorption cotton (17) is contained in the water absorption cotton containing groove to absorb trace seepage water, and the trace seepage water is discharged through a ventilation channel (1507) positioned at the side of the water absorption cotton containing groove (1505) under the action of heat generated by electrolysis; the tail end of the ventilation channel (1507) is respectively provided with a ventilation film (14), a ventilation hole sealing ring (13) and a ventilation hole plug (12); the technical route of air permeability and water non-drainage is realized; the center of the assembly ring frame sleeve (2) is provided with a center hole (1509) which can enable a lower convex opening arranged at the center of the bottom of the vacuum cup body (19) to be connected with a connecting notch (1501) of the SPE hydrogen-oxygen separation generator assembly (02); step type assembling upright posts (1516) are distributed in the overall ring frame sleeve (2) at an angle of 90 degrees, the total height of the step upright posts is 1/2 which is the height of the overall ring frame sleeve (2), the height of a short step upright post is 1/2 which is the height of the step upright post, and the SPE hydrogen-oxygen separation generator assembly (02) and the locking bottom plate (4) are sequentially arranged on the step type assembling upright posts (1516); the circumference of the upper surface of the assembly ring frame sleeve (2) is larger than the circumference of the assembly ring frame, and after the stainless steel wiredrawing upper decorative sleeve (1) or the stainless steel wiredrawing lower decorative sleeve (3) is installed, the circumference is just flush with the circumference of the upper surface of the assembly ring frame sleeve (2); the stainless steel wire drawing upper decorative sleeve (1) is positioned on the assembly ring frame sleeve (2), matched with a groove (1510) distributed at 90 degrees below the vacuum cup body (19) through a convex edge (1508A) distributed at 90 degrees at the inner side of the stainless steel wire drawing upper decorative sleeve (1), and sleeved below the vacuum cup body (19) on the assembly ring frame sleeve (2) to shield the internal structure of the SPE oxyhydrogen separation generator assembly (02); the general ring frame sleeve (2) and the stainless steel wire drawing lower decorative sleeve (3) are mutually sleeved with a groove (1510B) which is distributed on the general ring frame sleeve (2) at 90 degrees through a convex edge (1508B) which is distributed at 90 degrees and is arranged on the inner side of the stainless steel wire drawing lower decorative sleeve (3); the assembly ring frame sleeve (2) and the stainless steel wire drawing lower decoration sleeve (3) are correspondingly provided with a USB interface hole (1511) and an inductive switch preformed hole (1512), and sliding protective soft flaps are arranged outside the USB interface hole (1511) and the inductive switch preformed hole (1512).
3. 3. The SPE hydrogen generator electrical control system according to claim 2, wherein the micro-grid proton membrane (9) is disk-shaped, and criss-cross micro-grid reinforcing ribs are arranged on the membrane surface; the upper and lower parts of the micro-grid proton membrane (9) are provided with a cathode platinized titanium plate (8) and an anode platinized titanium plate (10); due to the action of the micro-grid, a micro-generation cavity for separating electrolytic water from hydrogen and oxygen can be formed between the micro-grid proton membrane (9) and the anode platinized titanium plate (10); under the action of a strong electromagnetic field, hydrogen and oxygen generated by a micro-generation chamber for separating hydrogen and oxygen can pass through a micro-grid proton membrane (9) and rise to a water body of a hydrogen-rich water generator (03) due to the great molecular weight difference, so that hydrogen-rich water is generated, while oxygen with a large molecular weight can only pass through a round hole in an anode platinized titanium plate (10) because the oxygen cannot pass through the micro-grid proton membrane (9) and then enter a ventilation channel (1507) in a bypassing way, and is discharged into the atmosphere after being filtered by a ventilation film (14), thereby realizing the technical route of separating hydrogen and oxygen, ventilating and draining; the micro-grid proton membrane (9) has the functions of pressure resistance, stable formation of a hydrogen-oxygen separation generation cavity, ventilation and water tightness; the SPE hydrogen-oxygen separation generator assembly (02) adopts SPE technology, the reaction is rapid, the gas production rate is large, and the hydrogen saturation of hydrogen-rich water can reach more than 1500 ppm; criss-cross micro grids are distributed on the upper surface and the lower surface of the micro grid proton membrane (9); design objective of the criss-cross micro grid: firstly, the physical strength of the membrane is increased, and secondly, a micro-generation chamber for separating hydrogen and oxygen is formed; when the power supply is switched on to start to prepare hydrogen, along with the increase of the hydrogen yield, the acting force of the water body in the hydrogen-rich water generator (03) on the micro-grid proton membrane (9) is gradually increased; because the micro-grid proton membrane (9) has great water resistance, the surface of the membrane only presents a micro-wet state, and the micro-grid proton membrane (9) bears two pressures, namely, the gravity of a water body and the gas expansion pressure after the hydrogen yield is increased, and the sum of the two pressures is P1; the ability of the micro-grid proton membrane (9) to resist P1 is P2; the micro-grid proton membrane (9) meets the requirement of membrane resistance P2 water body acting force P1 by grid reinforcement, and realizes a pressure-resistant and hydrogen-oxygen separation technical route with a non-deformable pressure change membrane.
4. 4. SPE hydrogen generator electrical control system according to claim 1, characterized in that the vacuum cup (19) is made of quartz glass, and the center of the bottom of the vacuum cup (19) is provided with a convex interface of the vacuum cup (19) which is connected with the connecting notch (1501) above the center of the generator upper cover (6).
5. 5. Electrical SPE hydrogen generator control system, according to claim 1, characterized in that said hydrogen generating assembly (20) is connected to a vacuum cup (19) in the form of a bottomed, inverted bottle of mineral water; the hydrogen generating assembly (20) is a vacuum cup body (19) provided with a cup cover (18) on the upper part, and the three positions are integrated into a whole of the hydrogen-enriched water generator (03).

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