CN106430453B - Electrolysis water cup - Google Patents

Abstract

The invention discloses an electrolytic water cup, which comprises a cup body, wherein the cup body comprises a drinking area, a frame cover is arranged in the drinking area, an electrolytic device is arranged in the frame cover, the electrolytic device comprises at least one diaphragm and at least one electrode group, the diaphragm is vertically arranged and separates the frame cover into at least one anode chamber and at least one cathode chamber, the electrode group comprises an anode electrode vertically arranged in the anode chamber and a cathode electrode vertically arranged in the cathode chamber, the diaphragm is positioned between the anode electrode and the cathode electrode, one ends of the cathode chamber and the anode chamber are respectively provided with a through hole, the through holes arranged in the cathode chamber and the anode chamber are respectively communicated with the drinking area, or the through holes arranged in the cathode chamber are respectively communicated with the drinking area, and the through holes arranged in the anode chamber are respectively communicated with the outside of the cup body. The technical scheme improves the solubility of the hydrogen and generates water quality which is more beneficial to the health of human bodies.

Description

Electrolysis water cup

Technical Field

The invention relates to the technical field of water treatment, in particular to an electrolytic water cup.

Background

Water is a life source, the water accounts for seventy percent of a human body, the water quality influences physique, the water quality determines health, and the drinking water quality is related to the life health of the whole family and cannot be ignored.

With the progress of human society, people are paying more attention to the problem of physical health, water is an important resource for survival as the most important component of human body, and the health of drinking water is also paying more attention to human beings. The hydrogen has the function of antioxidation, the hydrogen water is also called as hydrogen-rich water, and the name is that the water contains hydrogen ions, the hydrogen ions can neutralize redundant active oxygen in the body, and the hydrogen ions are combined into water to be discharged out of the body, so that the metabolism of cells is assisted, and the immunity of a human body, whitening, freckle removing and the like can be enhanced.

According to 6 standards of good water of the world health organization:

1. the water does not contain germs, impurities, organic matters and heavy metals, and is pollution-free water;

2. the water contains minerals and microelements in proper proportion and exists in an ionic state;

3. is alkalescent and has a pH value of 7-9;

4. small molecular group water has strong permeability and good solubility;

5. negative potential can eliminate redundant free radicals in the body;

6. contains a proper amount of oxygen (about 5 mg/L).

At present, the electrolysis drinking cup, electrode slice adopts about horizontal arrangement structure more for in the transparent cup, can observe the bubble of electrolysis output: the oxygen-hydrogen-oxygen interval is upward or the hydrogen-oxygen overlap is vertically upward, the two bubble rising processes are mutually interfered, the oxygen bubbles collide with the hydrogen bubbles upward more seriously, in particular, the hydrogen-oxygen overlap is vertically upward, the bubbles are concentrated in the central part of the cup body, and the part close to the circumference of the cup body 10 is a blank area. Because the anode plate is arranged below, the produced oxygen is influenced by water pressure and the like, and hydrogen bubbles are easier to push upwards and release faster and more easily.

The hydrogen-rich water thus produced has poor effect.

Disclosure of Invention

The invention mainly aims to provide an electrolytic water cup which aims at improving the solubility of hydrogen and generating water quality which is more beneficial to human health.

In order to achieve the above object, the invention provides an electrolytic water cup, which comprises a cup body and an electrolytic device accommodated in the cup body, wherein the cup body comprises a drinking area, a frame cover is arranged in the drinking area, the electrolytic device is arranged in the frame cover, the electrolytic device comprises at least one diaphragm and at least one electrode group, the diaphragm is vertically installed and separates the frame cover into at least one anode chamber and at least one cathode chamber, the electrode group comprises an anode electrode vertically installed in the anode chamber and a cathode electrode vertically installed in the cathode chamber, the diaphragm is positioned between the anode electrode and the cathode electrode, through holes are formed in one end of the cathode chamber and one end of the anode chamber, the through holes formed in the cathode chamber and the anode chamber are communicated with the drinking area, or the through holes formed in the cathode chamber are communicated with the drinking area, and the through holes formed in the anode chamber are communicated with the outside of the cup body.

Preferably, the electrolytic water cup further comprises a cup cover covered on the cup body, a negative oxygen ion generator is arranged in the cup cover, the negative oxygen ion generator comprises a negative oxygen ion release head, and the negative oxygen ion release head faces the cup body.

Preferably, through holes are formed in the top ends of the cathode chamber and the anode chamber.

Preferably, the electrolysis device comprises two electrode groups and two diaphragms, the two diaphragms divide the frame cover to form two cathode chambers and an anode chamber, and through holes are formed in the top ends of the two cathode chambers and the anode chamber.

Preferably, the electrolytic device comprises four electrode groups and four diaphragms, the four diaphragms are connected end to form a square area, an anode chamber is arranged in the square area, a cathode chamber is arranged outside the square area, and through holes are formed in the top ends of the cathode chamber and the anode chamber.

Preferably, when the electrolytic device comprises two pairs of electrodes, the two diaphragms divide the frame cover to form two cathode chambers and an anode chamber, the anode chamber is positioned between the cathode chambers, through holes are arranged at the top ends of the two cathode chambers, and one anode chamber is provided with the through holes and is communicated with the outside of the cup body.

Preferably, when the electrolytic device comprises four pairs of electrodes, four diaphragms form a square area, an anode chamber is arranged in the square area, a cathode chamber is arranged outside the square area, a through hole is arranged at the top end of the cathode chamber, and the anode chamber is provided with a through hole and is communicated with the outside of the cup body.

Preferably, the cup body further comprises a drainage area separated from the drinking area, the through hole formed in the cathode chamber is communicated with the drinking area, and the through hole formed in the anode chamber is communicated with the drainage area.

Preferably, the frame cover is of a double-layer net cover structure, a containing space is formed between the double-layer net covers, and active carbon or ceramic particles are contained in the containing space.

Preferably, the electrolytic water cup further comprises a power supply and a PCB board, wherein the PCB board is provided with a control circuit module, the power supply is electrically connected with the PCB board, and the control circuit module controls the voltage output by the power supply to be constant voltage; or the control circuit module controls the voltage output by the power supply to gradually decrease from a preset maximum value; or the control circuit module controls the voltage output by the power supply to continuously and circularly reduce from a preset maximum value to zero.

According to the technical scheme, the frame cover is arranged, the frame cover is divided into the cathode chamber and the anode chamber by the diaphragm, the anode electrode and the cathode electrode are respectively and vertically arranged in the cathode chamber and the anode chamber, and when the cathode chamber and the anode chamber are respectively provided with through holes which are communicated with the drinking water area, rising channels of oxygen bubbles and hydrogen bubbles generated by electrolyzed water are separated; when the cathode chamber is provided with a through hole communicated with the drinking water area, and the anode chamber is provided with a through hole communicated with the outside of the cup body, the drinking water area only has hydrogen bubbles. So that oxygen bubbles and hydrogen bubbles generated by electrolysis of water are separated.

Therefore, the two schemes lighten the influence of oxygen on hydrogen retention and dissolution, and thus, the solubility of the hydrogen is improved. And the electrode is vertically arranged, so that the occupied area is smaller, the electrolytic contact area is larger, and the electrolytic effect is good.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are necessary for the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention and that other drawings can be obtained from the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view showing the structure of an electrolytic water cup according to the first embodiment of the present invention, in which a pair of electrodes are provided;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a schematic view of the structure of the electrolytic water cup according to the first embodiment of the present invention, in which two pairs of electrodes are provided;

FIG. 4 is a top view of FIG. 3;

FIG. 5 is a schematic view of the structure of the electrolytic water cup according to the first embodiment of the present invention when four pairs of electrodes are provided;

FIG. 6 is a top view of FIG. 5;

FIG. 7 is a schematic view of the structure of an electrolytic cup according to the second embodiment of the present invention in which the middle frame cover is provided with two pairs of electrodes;

FIG. 8 is a control schematic diagram of a control circuit module;

FIG. 9 is a schematic diagram of the supply voltage control of the electrolytic water cup.

Reference numerals illustrate:

reference numerals	Name of the name	Reference numerals	Name of the name
				100	Electrolysis water cup	51	Anode electrode
10	Cup body	52	Diaphragm
				11	Water drinking area	53	Cathode electrode
30	Frame cover	310	Through hole
				301	Accommodating space	70	Cup cover
31	Anode chamber	90	Negative oxygen ion generator
				32	Cathode chamber	91	Negative oxygen ion release head
50	Electrolysis device

The realization of the object, the functional characteristics and the advantages of the invention will be further described with reference to the accompanying drawings in connection with the embodiments.

Detailed Description

The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, based on the embodiments of the invention, which would be apparent to one of ordinary skill in the art without inventive effort are within the scope of the invention.

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the invention are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicators are changed accordingly.

Furthermore, the description of "first," "second," etc. in the present invention is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed by the invention.

Referring to fig. 1 to 9, the present disclosure proposes an electrolytic water cup 100, which comprises a cup body 10 and an electrolytic device 50 accommodated in the cup body 10, wherein the cup body 10 comprises a drinking area 11, a frame cover 30 is disposed in the drinking area 11, the electrolytic device 50 is disposed in the frame cover 30, the electrolytic device 50 comprises at least one diaphragm 52 and at least one electrode group, the diaphragm 52 is vertically installed and separates the frame cover 30 into at least one anode chamber 31 and at least one cathode chamber 32, the electrode group comprises an anode electrode 51 vertically installed in the anode chamber 31 and a cathode electrode 53 vertically installed in the cathode chamber 32, the diaphragm is disposed between the anode electrode and the cathode electrode, through holes 310 are respectively formed at one ends of the cathode chamber 32 and the anode chamber 31, the through holes 310 respectively formed in the cathode chamber 32 and the anode chamber 31 are respectively communicated with the drinking area 11, or the through holes 310 formed in the cathode chamber 32 are respectively communicated with the drinking area 11, and the through holes 310 formed in the anode chamber 31 are respectively communicated with the outside of the cup body 10.

According to the technical scheme, the frame cover 30 is arranged, the frame cover 30 is divided left and right through the diaphragm 52 to form the cathode chamber 32 and the anode chamber 31, the anode electrode 51 and the cathode electrode 53 are respectively vertically arranged in the cathode chamber 32 and the anode chamber 31, and when the cathode chamber 32 and the anode chamber 31 are respectively provided with the through holes 310 to be communicated with the drinking water area 11, rising channels of oxygen bubbles and hydrogen bubbles generated by electrolyzed water are separated; when the cathode chamber 32 is provided with the through hole 310 communicated with the drinking area 11, and the anode chamber 31 is provided with the through hole 310 communicated with the outside of the cup body 10, the drinking area 11 only has hydrogen bubbles. So that oxygen bubbles and hydrogen bubbles generated by electrolysis of water are separated.

Therefore, the two schemes lighten the influence of oxygen on hydrogen retention and dissolution, and thus, the solubility of the hydrogen is improved. And the electrode is vertically arranged, so that the occupied area is smaller, the electrolytic contact area is large, and the electrolytic effect is good.

It will be appreciated that the membrane 52 generally can only penetrate positive ions of various substances, block negative ions, and prevent chlorine ions in water from generating harmful substances such as chlorine gas. And when the anode chamber 31 is provided with a through hole 310 communicating with the outside of the cup body 10, the diaphragm 52 is provided to be permeable to a minute amount of water to serve as an electrolyte of the anode chamber 31, wherein preferably the area of the anode chamber 31 is small, a minute amount of acidic water generated by electrolysis of the anode chamber 31 is vaporized by heat generated by an electrode reaction, and the vaporized gas is discharged from the through hole 310 provided in the anode chamber 31 together with the generated oxygen.

In the present embodiment, the anode electrode 51 and the cathode electrode 53 are preferably provided in a plate-type mesh structure or a plate-type porous structure. The electrode is arranged to be of a flat-plate net-shaped structure or a plate-shaped porous structure, so that the contact area of the electrode is large, the electrolysis effect is good, more micro bubbles can be generated, and water is more active.

In this embodiment, the anode electrode 5122 and the cathode electrode 5320 are disposed adjacent to the cationic membrane 5221. The close arrangement of the anode electrode 5122 and the cathode electrode 5320 can reduce the impact of water on the cationic membrane 5221, and can enable the voltage to be lower, so that the energy saving and environment protection effects are achieved.

Further, in order to extend the life of the electrode and improve the electrolysis efficiency, the anode electrode 5122 is coated with an oxide coating of titanium, ruthenium, etc. or a platinum metal (platinum) coating; the cathode 5320 is made of stainless steel mesh, and the cathode 5320 is coated with a nickel coating, so that the cathode 5320 has the characteristics of catalyzing, accelerating electrolytic reaction and reducing hydrogen evolution overpotential.

Two examples are listed below:

embodiment one:

when the anode chamber 31 is provided with a through hole 310 communicated with the drinking water area 11; realizing separation of an ascending channel of oxygen bubbles and hydrogen bubbles generated by electrolyzed water;

the electrolytic water cup 100 is provided with a negative oxygen ion generator 90, and preferably, the negative oxygen ion generator 90 is provided on the cup cover 70,

specifically, the negative oxygen ion generator 90 includes a negative oxygen ion release head 91, and the negative oxygen ion release head 91 faces the cup 10 to ionize oxygen into negative oxygen ions;

the reaction principle in the electrolytic water cup 100 by introducing the negative oxygen ion generator 90 is as follows:

1. tap water contains various minerals, is weak electrolyte, and can ionize trace H ⁺ (Hydrogen ions) and OH ^- (hydroxide ions).

①H ₂ O＝H ⁺ +OH ^- ②H ⁺ +OH ^- ＝H ₂ O

2. Oxygen is generated in the anode reaction chamber under the action of positive potential of direct current and meanwhile due to OH ^- The reduction of (hydroxyl ions) and the reduction of the pH value of water, the weak acidity.

Anode reaction: (4 OH) ^- )-(4e ^- )＝2H ₂ O+O ₂ And ∈, and releasing oxygen.

3. The oxygen rises to the drinking water area 11 to form compressed gas, and the oxygen is generated under the action of the negative potential of the negative oxygen ion generator 9050(negative oxygen ions).

Ionization reaction:

4. of compressed gas zones(negative oxygen ions) react with water to form OH- (hydroxide ions). Negative oxygen ions react with water: />

5、(negative oxygen ions) OH formed by reaction with water ^- (hydroxide ions) to supplement OH consumed by the anode chamber 31 ^- (hydroxide ions) to change the weakly acidic water produced by the anodic reaction into neutral water.

6. H of anode chamber 31 ⁺ (hydrogen ions) permeate the cation exchange membrane 30 to reach the cathode chamber 32 and the original H ⁺ (Hydrogen ions) together with the generation of hydrogen under the action of a DC negative potential, while due to OH ^- The increase of (hydroxyl ions) and the increase of the pH value of water, the alkalescence is evident.

Cathode reaction: 2H (H) ⁺ +2e ^- ＝H ₂ ↑

7. The water molecules are composed of hydrogen atoms and oxygen atoms (or water is composed of hydrogen and oxygen), and after the water molecules are electrified, the water molecules are destroyed and decomposed into hydrogen atoms and oxygen atoms; two hydrogen atoms constitute one hydrogen molecule; two oxygen atoms form an oxygen molecule; many hydrogen molecules are clustered together as hydrogen; many oxygen molecules are clustered together as oxygen.

Total reaction:

the electrolytic water is in negative potential alkalescence comprehensively, a large amount of oxygen and hydrogen are generated by electrolysis due to limited solubility of the water, the hydrogen and the oxygen exist in the water in the form of micro bubbles, the hydrogen and the oxygen continuously float upwards and become larger gradually and burst on the water surface finally, the effect of nano bubble water is formed, and water molecules all show small molecular groups due to the action of the negative potential. The decomposed living water of the small molecular group has strong permeability and good solubility.

The oxygen content of the water can be increased due to the existence of pressure, and according to 6 standards of good water of the world health organization, the oxygen content in the water is one of the standards of good water, and the dissolved amount of hydrogen is correspondingly increased due to the existence of pressure; the hydrogen ions can neutralize redundant active oxygen in the body, combine with water to be discharged out of the body, help the metabolism of cells, and can also enhance the immunity of the human body, whiten the skin, remove the spots and the like. Further, the presence of pressure also allows the nanobubbles in the water to last longer in the water.

In this embodiment, the weak acid water and the burst of the micro-bubbles generated in the anode chamber 31 can kill the bacteria in the water, and other harmful microorganisms, and the negative oxygen ion generator 90 ionizes to also have a sterilizing effect, thereby increasing the sterilizing effect.

In the present embodiment, the setting of the number of electrode groups has three embodiments as follows:

referring to fig. 1 and 2, when the electrolyzer 50 is provided with a pair of electrodes, a diaphragm 52 separates the frame cover 30 to form a cathode chamber 32 and an anode chamber 31, and a through hole 310 is formed at the top ends of the cathode chamber 32 and the anode chamber 31.

Referring to fig. 3 and 4, when the electrolyzer 50 is provided with two pairs of electrodes, the two diaphragms 52 divide the frame cover 30 to form two cathode chambers 32 and an anode chamber 31, the anode chamber 31 is located between the cathode chambers 32, and the cathode chambers 32 and the anode chamber 31 and the cathode chamber 32 are arranged from left to right. The top ends of both the cathode chamber 32 and the anode chamber 31 are provided with through holes 310.

Referring to fig. 5 and 6, when the electrolytic device 50 is provided with four pairs of electrodes, four of the diaphragms 52 form a square area, an anode chamber 31 is arranged in the square area, a cathode chamber 32 is arranged outside the square area, and through holes 310 are formed in the top ends of the cathode chamber 32 and the anode chamber 31.

In this embodiment, three embodiments are provided for different pairs of electrodes, and the obtained effects are different and may be specifically set according to specific situations.

Embodiment two:

when the anode chamber 31 is provided with a through hole 310 communicated with the outside of the cup body 10; the separation of oxygen bubbles and hydrogen bubbles generated by electrolysis of water is realized.

It will be appreciated that the exterior of the cup 10 means that oxygen is removed from the electrolysis reaction zone, i.e., the anode chamber 31, although the electrolysis cup 100 may be provided with an additional zone for oxygen storage.

In the technical scheme of the embodiment, the acidic water is separated, so that the electrolyzed water in the drinking water area 11 is also in negative potential alkalescence.

In this embodiment, the following three embodiments are provided for the arrangement of the number of electrodes:

referring to fig. 7, when the electrolytic device 50 includes two pairs of electrodes, the two diaphragms 52 divide the frame cover 30 to form two cathode chambers 32 and an anode chamber 31, the anode chamber 31 is located between the cathode chambers 32, through holes 310 are formed at the top ends of the two cathode chambers 32, and the through holes 310 are formed in one of the anode chambers 31 to communicate with the outside of the cup 10.

When the electrolytic device 50 includes four pairs of electrodes, the four diaphragms 52 form a square area, the square area is internally provided with an anode chamber 31, the square area is externally provided with a cathode chamber 32, the top end of the cathode chamber 32 is provided with a through hole 310, and one anode chamber 31 is provided with the through hole 310 and is communicated with the outside of the cup body 10.

The cup body 10 further comprises a water draining area separated from the water drinking area 11, when the electrolysis device 50 comprises a pair of electrodes, a diaphragm 52 separates the frame cover 30 to form a cathode chamber 32 and an anode chamber 31, the cathode chamber 32 is provided with a through hole 310 communicated with the water drinking area 11, and the anode chamber 31 is provided with a through hole 310 communicated with the water draining area.

In summary, referring to fig. 1, 3, 5, and 7, the frame cover 30 may be configured as a double-layer mesh enclosure, and a receiving space 301 is formed between the double-layer mesh enclosures, where the receiving space 301 receives activated carbon or ceramic particles to form a water filtering layer. When the activated carbon is filled, the activated carbon can adsorb heavy metals and remove peculiar smell, and when the ceramic particles are filled, the ceramic particles can be filled with mineral elements. Of course, other substances may be filled to assist in water quality.

The frame cover 30 may have a multi-layer mesh cover structure, and may be filled with activated carbon and ceramic particles at the same time, or may be filled with a plurality of substances at the same time.

Preferably, the housing 30 is provided in a conical Fuji mountain shape, which is both aesthetic and also benefits water entering the electrolysis zone (anode chamber 31 and cathode chamber 32) through the water filtering layer.

Referring to fig. 9, preferably, the electrolytic water cup 100 further includes a power supply and a PCB board, the PCB board is provided with a control circuit module, the power supply is electrically connected with the PCB board, and the control circuit module controls the output voltage of the power supply to be a constant voltage; or the control circuit module controls the voltage of the power supply output voltage gradually decreasing from a preset maximum value; or the control circuit module controls the power supply output voltage to continuously and circularly reach zero from a preset maximum value.

In these three modes, when the electrode is supplied with a constant voltage and current, the micro-bubbles slowly rise. When the voltage of the electrode is changed from large to small, the micro-bubble mushroom cloud rises, and when the voltage of the electrode is changed from large to non-large, the micro-bubble mushroom cloud repeatedly rises like a cloud. All three modes prevent the membrane from burning out and make the water more active.

Referring to fig. 8, the cup cover 70 is also provided with a PCB board, the PCB board is provided with a control circuit module, the negative oxygen ion generator 90 is connected with the control circuit module of the PCB board, and the cup cover 70 is also provided with an indicator lamp, when the negative oxygen ion generator 90 is turned on, the control circuit module controls the indicator lamp to be on, and when the negative oxygen ion generator 90 is turned off, the indicator lamp is turned off. The electrolyzer 50 is also connected to the control circuit module, and an indicator lamp is provided to indicate the opening and closing of the electrolyzer 50. Of course, the electrolytic water cup is also provided with a power supply charging interface for charging a power supply. The power source can be a mobile power source or a battery. The portable device is portable by setting the power supply by setting the indicator lamp for observing whether the device is in an operating state or an off state.

In this embodiment, the electrolysis water cup 100 can be automatically controlled to perform electrolysis, that is, when the electrolysis water cup 100 is filled with water to a certain water level (a sensor is arranged and connected with a control circuit module), the electrolysis device 50 and the negative oxygen ion generator 90 are automatically turned on, and when the running time reaches a set time, the electrolysis device is automatically turned off. Wherein, the electrolytic water cup 100 also has a protection setting for preventing the negative oxygen ion releasing head 91 which is normally operated from soaking when the water level is too high. Specifically, the cup body is provided with a water level sensor, and when the water level is too high, the control circuit module controls the negative oxygen ion generator 90 to be disconnected or not started.

Of course, the electrolytic water cup 100 of the present invention may also be provided with a button, which is connected to the control circuit module and is manually controlled to be opened or closed.

In this embodiment, the electrolytic water cup 100 may be a plastic cup, a rubber cup, a glass cup, a crystal cup, a ceramic cup, etc. in terms of material; for application, the electrolytic water cup 100 may be a portable hand-held water cup or a household water cup.

The foregoing description is only of the preferred embodiments of the invention, and is not intended to limit the scope of the invention, but rather, the equivalent structural changes made by the description of the invention and the accompanying drawings or the direct/indirect application in other related technical fields are included in the scope of the invention.

Claims (9)

1. The electrolytic water cup is characterized by comprising a cup body and an electrolytic device accommodated in the cup body, wherein the cup body comprises a drinking area, a frame cover is arranged in the drinking area, the electrolytic device is arranged in the frame cover, the electrolytic device comprises at least one diaphragm and at least one electrode group, the diaphragm is vertically installed and separates the frame cover into at least one anode chamber and at least one cathode chamber, the electrode group comprises an anode electrode vertically installed in the anode chamber and a cathode electrode vertically installed in the cathode chamber, the diaphragm is positioned between the anode electrode and the cathode electrode, through holes are formed in one ends of the cathode chamber and the anode chamber, the through holes formed in the cathode chamber and the anode chamber are communicated with the drinking area, or the through holes formed in the cathode chamber are communicated with the drinking area, and the through holes formed in the anode chamber are communicated with the outside of the cup body;

the frame cover is of a double-layer net cover structure, an accommodating space is formed between the double-layer net covers, and active carbon or ceramic particles are accommodated in the accommodating space;

wherein the anode electrode and the cathode electrode are arranged in a plate-type net structure or a plate-type porous structure.

2. The electrolytic water cup as claimed in claim 1, further comprising a cap covering the cup body, wherein a negative oxygen ion generator is provided in the cap, and wherein the negative oxygen ion generator comprises a negative oxygen ion release head facing the cup body.

3. The electrolytic water cup according to claim 1 or 2, wherein the top ends of the cathode chamber and the anode chamber are provided with through holes.

4. The electrolytic water cup according to claim 1 or 2, wherein the electrolytic device comprises two electrode groups and two diaphragms, the two diaphragms divide the frame cover to form two cathode chambers and an anode chamber, and through holes are formed at the top ends of the two cathode chambers and the anode chamber.

5. The electrolytic water cup according to claim 1 or 2, wherein the electrolytic device comprises four electrode groups and four diaphragms, the four diaphragms are connected end to form a square area, an anode chamber is arranged in the square area, a cathode chamber is arranged outside the square area, and through holes are formed in the top ends of the cathode chamber and the anode chamber.

6. The electrolytic water cup as claimed in claim 1, wherein when the electrolytic device comprises two pairs of electrodes, two diaphragms divide the frame cover to form two cathode chambers and an anode chamber, the anode chamber is located between the cathode chambers, through holes are formed at the top ends of the two cathode chambers, and one anode chamber is provided with a through hole communicated with the outside of the cup body.

7. The electrolytic water cup according to claim 1, wherein when the electrolytic device comprises four pairs of electrodes, four of the diaphragms form a square area, an anode chamber is arranged in the square area, a cathode chamber is arranged outside the square area, a through hole is arranged at the top end of the cathode chamber, and the anode chamber is provided with a through hole communicated with the outside of the cup body.

8. The electrolytic water cup as recited in claim 1, wherein the cup body further comprises a drain region spaced from the drinking region, the through-hole formed in the cathode chamber communicates with the drinking region, and the through-hole formed in the anode chamber communicates with the drain region.

9. The electrolytic water cup according to claim 1, further comprising a power supply and a PCB board, wherein the PCB board is provided with a control circuit module, the power supply is electrically connected with the PCB board, and the control circuit module controls the voltage output by the power supply to be a constant voltage; or the control circuit module controls the voltage output by the power supply to gradually decrease from a preset maximum value; or the control circuit module controls the voltage output by the power supply to continuously and circularly reduce from a preset maximum value to zero.