CN212293763U - Ozone electrolysis generator - Google Patents

Abstract

The utility model discloses an ozone electrolysis generator has solved the incrustation scale that produces in the water service tank of present electrolysis intracavity and can influence the contact of conductive film and negative pole piece completely at last, can lead to electrolytic ozone's stability, and its technical scheme is: an ozone electrolysis generator comprises an electrolysis cavity, wherein a cathode pole piece, an anode pole piece and a proton exchange membrane between the cathode pole piece and the anode pole piece are arranged in the electrolysis cavity, and the cathode pole piece, the proton exchange membrane and the anode pole piece are vertically stacked; the shell is also provided with a water inlet and a water outlet, and water flows form a water flow direction flowing to the water outlet in the electrolytic cavity after passing through the water inlet; the water flowing grooves are arranged in the height direction of the cathode pole piece and the anode pole piece in a penetrating mode, and therefore the effects that scales are not easy to form and the ozone electrolysis concentration is stable are achieved.

Description

Ozone electrolysis generator

Technical Field

The utility model relates to an ozone electrolysis generator.

Background

Ozone water is ozone water having bactericidal activity obtained by dissolving colorless gas ozone (O3) in nature in water by a special technique. Has no influence on natural environment and high safety to human body, and is a biological activation principle for improving autoimmunity.

The ozone water is widely used in medical institutions due to its strong bactericidal power and high safety, and particularly has a good curative effect on diseases which are difficult to be cured radically, such as infection, skin diseases, immune insufficiency, auxiliary treatment of cancer, atopic dermatitis and the like.

Beneficial bacteria and harmful bacteria exist on the surface of human skin, and the weakly acidic ozone water can remove the harmful bacteria and provide a good growth environment for the beneficial bacteria. The ozone water can improve the skin environment of the user from inside to outside, enables the skin to be regenerated and arouses the vitality of the skin.

There are two common uses of current ozone electrolysis generators, one is to electrolyze ozone in static water, as disclosed in CN209668840U, for electrolysis of water in a vessel to produce ozonated water for use by a user, but such ozonated water produced in a standing state has limitations.

For another example, CN104278289A discloses an ozone electrolysis device in a flowing state, which provides users with continuously flowing ozone water, and compared with ozone water in a static state, the flowing ozone water can continuously act on the surface to be cleaned, so that the application field and range are wider, and the user experience is better. Further, patent document discloses that a water passage 14d is formed in the lower surface 14c (electrode side) of the plate-like cathode (electrode) 14, and the conductive film can be more rapidly brought into a wet state at the initial stage of operation, and further, when the conductive film has been wetted and expanded, the wet and expanded portion of the conductive film blocks the water passage 14d and the water passage 13 d. However, the above design does not consider the influence of the scale generated during the electrolysis process on the electrolysis, and the long-term scale accumulation at the position of the water can be caused due to the blockage and narrowing of the water passage 14d and the water passage 13d, and referring to fig. 1 and fig. 2, the scale formation state on the pole piece under the electron microscope is shown, and the scale finally and completely influences the contact between the conductive film and the cathode pole piece, not only the wetting function of the work starting state is influenced, but also the stability of the electrolytic ozone is caused.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an ozone electrolysis generator which is not easy to scale and has stable ozone electrolysis concentration.

The above technical purpose of the present invention can be achieved by the following technical solutions: an ozone electrolysis generator comprises a shell, wherein the shell comprises a base and an upper cover, an electrolysis cavity is formed between the base and the upper cover, a cathode pole piece, an anode pole piece and a proton exchange membrane between the cathode pole piece and the anode pole piece are arranged in the electrolysis cavity, and the cathode pole piece, the proton exchange membrane and the anode pole piece are vertically stacked; the shell is also provided with a water inlet and a water outlet, and water flows form a water flow direction flowing to the water outlet in the electrolytic cavity after passing through the water inlet; and the cathode pole piece and the anode pole piece are both provided with water passing grooves in the same direction as the water flow direction, and the water passing grooves are arranged in a penetrating manner in the height direction of the cathode pole piece and the anode pole piece.

Further, the water passage grooves are provided in plurality in the width direction of the cathode electrode sheet, the proton exchange membrane, and the anode electrode sheet.

Furthermore, the inner side of the base and/or the upper cover is provided with a raised limiting rib, and the limiting rib and the water passing groove are arranged in a staggered manner.

Further, still include negative pole conductive needle and positive pole conductive needle, the one end and the negative pole piece of negative pole conductive needle contact, the one end and the positive pole piece of positive pole conductive needle contact, negative pole conductive needle and positive pole conductive needle all include conductive needle body and warhead, warhead and conductive needle body elastic connection are with the butt in the pole piece.

Furthermore, the conductive needle body is provided with a concave cavity, one end of the warhead extending into the concave cavity is provided with a limiting ring, a spring connected with the bottom of the warhead is arranged in the concave cavity, and one end of the warhead extending out of the concave cavity is connected with the pole piece.

Furthermore, one end of the cathode conductive pin and one end of the anode conductive pin penetrate through the base or the outer part of the upper cover, and the cathode conductive pin, the anode conductive pin and the base are integrally formed in an injection molding mode.

Furthermore, avoidance holes are formed in corresponding positions of the cathode pole piece and the proton exchange membrane, and the other end of the anode conductive needle penetrates through the avoidance holes to be abutted against the anode pole piece; or the like, or, alternatively,

and the corresponding positions of the anode pole piece and the proton exchange membrane are provided with avoidance holes, and the other end of the cathode conductive needle penetrates through the avoidance holes to be abutted against the anode pole piece.

Furthermore, a limiting clamp for limiting the warhead is arranged in the electrolytic cavity.

Further, the connection mode of the upper cover and the base can be any one of the following modes: buckle, bolt, ultrasonic bonding.

By adopting the technical scheme, the utility model discloses following beneficial effect has:

1. through the arrangement of the water through tank communicated with the proton exchange membrane, the proton exchange membrane can be quickly wetted in the initial stage of electrolysis work, and more stable ozone concentration is achieved;

2. the water through grooves which are always communicated are arranged in the height direction of the cathode pole piece and the anode pole piece, the water through grooves are arranged along with the direction of water flow, water flow can continuously wash the water through grooves in the electrolytic process, the rapid accumulation of scale is avoided, the proton exchange membrane can be always contacted with the cathode pole piece and the anode pole piece, the generation of scale at the contacted position is avoided, and the stable electrolytic state is kept;

3. the proton exchange membrane can be contacted with the cathode pole piece and the anode pole piece through the water passing groove without additionally forming a groove, so that the process difficulty is reduced, the assembly is simpler, and the service life of the proton exchange membrane is longer;

4. be provided with spacing muscle, spacing muscle can the butt in the pole piece part of not slotting, let electrolytic device fix in the electrolysis intracavity and stabilize to can let positive pole piece, negative pole piece and proton exchange membrane three's range upon range of keep the inseparable state, and reduce the breeding of incrustation scale in gap department, keep stable ozone electrolysis state.

5. The bullet head can enable the conductive needle to be always in elastic contact with the pole piece, and the phenomenon that the conductive needle cannot work normally due to poor contact is avoided;

6. the negative pole piece or the positive pole piece is provided with the avoidance hole, and the avoidance hole can conveniently allow the conductive needle to pass through and then contact with the conductive needle, so that the structure is simple, the structure is compact, and the assembly is convenient;

7. the cathode conductive pin and the anode conductive pin are integrally injection-molded with the base, and are integrally injection-molded with the base in a mold, so that the best waterproof effect can be achieved.

Drawings

FIG. 1 is a schematic view of the scaling of a cathode plate (left side) under an electron microscope and a proton exchange membrane (right side) covering the upper part of an anode plate;

FIG. 2 is a schematic view of scale formation on a proton exchange membrane above an anode plate under an electron microscope;

FIG. 3 is a schematic view of an ozone electrolysis generator as a whole;

FIG. 4 is a schematic overall view of another embodiment of an ozone electrolysis generator;

FIG. 5 is a sectional view taken along line A-A of FIG. 3;

FIG. 6 is a schematic exploded view of a base and an upper cover of an ozone electrolysis generator;

FIG. 7 is a perspective view in section taken along the line B-B of FIG. 3;

FIG. 8 is a sectional view taken along line B-B of FIG. 3;

FIG. 9 is a schematic diagram of the initial stage of fouling of an electrolyzer;

FIG. 10 is a schematic diagram of a second stage of electrolyzer fouling;

FIG. 11 is a schematic illustration of a third stage of electrolyzer fouling;

FIG. 12 is an exploded view of the base and top cover of the concealed electrolyzer;

FIG. 13 is a schematic view of the other exploded side of the base and upper cover of the concealed electrolyzer;

FIG. 14 is a schematic isolated view of an electrolyzer;

FIG. 15 is an exploded view of the electrolyzer;

fig. 16 is an exploded view of the cathode conductor pin and the anode conductor pin.

Reference numerals: 1. a housing; 11. a base; 12. an upper cover; 13. an electrolysis chamber; 14. a water inlet; 15. a water outlet; 16. a silica gel socket; 17. a quick connector; 18. limiting ribs; 2. an electrolysis device; 21. a cathode plate; 22. an anode plate; 23. a proton exchange membrane; 3. the direction of the water flow; 31. a water trough; 4. scale formation; 5. a cathode conductive pin; 6. an anode conductive pin; 7. a warhead; 71. a concave cavity; 72. an elastic device; 73. a limiting ring; 8. avoiding holes; 9. a limiting card; 91. and a through hole.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

An ozone electrolysis generator, which can directly obtain flowing ozone water by electrolyzing water to obtain ozone in flowing water environment, and the ozone and water are dissolved to form ozone water, has the function of convenient cleaning, can be used in the field of household cleaning, such as cleaning and disinfection of daily necessities, can also be used for personal skin care, cleaning skin, deep beauty and sterilization, has no side effect, can also be used in the field of medical treatment, and can be widely applied to the sterilization and disinfection of medical instruments, nursing and food disinfection. The utility model aims to provide an ozone electrolysis generator which can stably operate for a long time and has stable concentration of electrolytic ozone water.

Referring to fig. 1 to 3, the ozone electrolysis generator includes a housing 1, the housing 1 may have any shape, in this embodiment, it is preferably a flat rectangular parallelepiped, the specific shape of the housing 1 is not limited, the housing 1 includes a base 11 and an upper cover 12, an electrolysis chamber 13 is formed between the base 11 and the upper cover 12, i.e. inside the housing 1, in addition, the housing 1 further includes a water inlet 14 and a water outlet 15, water flows into the electrolysis chamber 13 from the water inlet 14, after water is electrolyzed into ozone by the electrolysis device 2 in the electrolysis chamber 13, the ozone and the water are quickly dissolved into ozone water, and the ozone water finally flows out from the water outlet 15, so that ozone water with stable concentration can be continuously generated in an operating state. In the case of the rectangular parallelepiped case 1, the water inlet 14 and the water outlet 15 may be provided on the same side surface, that is, both the upper cover 12 and the base 11, and when the water inlet 14 and the water outlet 15 are provided on the same side surface, the distance between the water inlet 14 and the water outlet 15 should be as far as possible. As another embodiment, the water inlet 14 and the water outlet 15 may be provided on opposite sides. The water inlet 14 and the water outlet 15 can be provided with silica gel sockets 16, so that the direct insertion of a silica gel tube can be facilitated, and the quick connection joint 17 of a hard tube can be arranged, so that the quick connection of a pipeline can be facilitated.

Referring to fig. 7 and 8, 12 and 13, in the electrolytic chamber 13, there are provided a cathode plate 21, an anode plate 22 and a proton exchange membrane 23 disposed between the cathode plate 21 and the anode plate 22, the cathode plate 21, the proton exchange membrane 23 and the anode plate 22 are three independent pieces, and are stacked, the cathode plate 21, the anode plate 22 and the proton exchange membrane 23 may be the same or different in size, and in order to maintain a sufficient contact area, the three pieces are preferably the same in size and are shaped as a flat plate.

In this embodiment, the water inlet 14 and the water outlet 15 are preferably disposed on the upper cover 12 and disposed on two opposite edges of the upper cover 12, so as to ensure a larger distance, and since the base 11 needs to be fixed, it is disposed on the upper cover 12, so that it is easy to detach and convenient to use.

Referring to fig. 5 and 6, in the electrolytic chamber 13, a water flowing direction (hereinafter referred to as a water flowing direction 3) is formed along the water inlet 14 toward the water outlet 15, water passing grooves 31 are provided in parallel along the water flowing direction 3 on both the cathode pole piece 21 and the anode pole piece 22, and in this embodiment, a plurality of water passing grooves 31 are provided on both the cathode pole piece 21 and the anode pole piece 22 and the proton exchange membrane 23, and it is understood that the plurality of water passing grooves 31 are also parallel to each other and preferably located on the same horizontal plane.

Referring to fig. 7 and 8, the water passing grooves 31 of the cathode pole piece 21 and the anode pole piece 22 are arranged to penetrate in the height direction, so that the water passing grooves 31 are always penetrated in the operating state. It should be noted that the water passage grooves 31 are preferably not provided so as to penetrate in the longitudinal direction, and this is designed because the ends of the cathode sheet 21 and the anode sheet 22 (both ends in the water flow direction 3) do not extend, that is, are not provided so as to penetrate in the longitudinal direction, in view of the strength after lamination. Of course, if the strength is acceptable, the water passage grooves 31 of the cathode electrode sheet 21, the anode electrode sheet 22 and the proton exchange membrane 23 may be provided so as to penetrate in the longitudinal direction (i.e., the water flow direction 3), which may provide a further advantage.

In addition, the size of the proton exchange membrane 23 is set to be 20 μm to 200 μm, and the size is very thin, so in this embodiment, the proton exchange membrane 23 is not provided with the groove or the hole corresponding to the water passing groove 31, which greatly reduces the processing difficulty, because the slotting process on the proton exchange membrane 23 is very complicated and the assembly difficulty is high, thereby resulting in the low stability of the product of the slotted proton exchange membrane 23.

Since the conductivity varies with the variation of the water content of the proton exchange membrane 23 during a period of time after the start of the water supply after the start of the ozone electrolysis generator, the ozone water is difficult to be generated and the concentration of the generated ozone water does not reach the standard in the initial stage of operation, and the user experience is reduced, that is, the ozone water with a stable concentration cannot be obtained quickly.

In the present embodiment, since the plurality of water passing grooves 31 are formed along the water flow direction 3, water can rapidly enter the proton exchange membrane 23 through the water passing grooves 31 after entering from the water inlet 14, and the proton exchange membrane 23 is brought into a wet state, so that the proton exchange membrane 23 can be brought to a more stable electric conductivity at the beginning, and after being wetted, the proton exchange membrane 23 becomes large in size as a whole, and expands irregularly upward or downward, or upward and downward at the water passing grooves 31.

Referring to FIGS. 1 to 2, 9 to 11, since in the electrolytic operating state, as shown by the electron microscope of FIGS. 1 and 2, scale 4 is generated, according to experimental tests, referring to fig. 9, the scale 4 generally forms scale on the cathode plate 21 and the proton exchange membrane 23, because the surface of the anode pole piece 22 has the diamond film, the surface of the anode pole piece 22 will not form scale, referring to figure 10, and further scaling will occur at the position where the proton exchange membrane 23 is not in contact with the cathode pole piece 21 and the anode pole piece 22 (i.e. the position corresponding to the water through slot 31), referring to fig. 11, finally scaling will eventually occur at the contact surface of the proton exchange membrane 23 and the cathode pole piece 21, the structure will greatly affect the contact between the proton exchange membrane 23 and the anode pole piece 22 or the cathode pole piece 21, thereby affecting the electrolysis operation and finally causing the unstable concentration of the ozone electrolysis.

In the present embodiment, since the through water channels 31 are provided on both the cathode plate 21 and the anode plate 22, when the water flows into the electrolytic chamber 13, the water flow continuously washes the scale 4 that has been scaled along the water flow direction 3 while electrolyzing the ozone by the electrolysis device 2, thereby effectively avoiding the residue of the scale 4 and effectively suppressing the unstable electrolysis caused by the continuous accumulation of the scale 4.

Referring to fig. 12 and 13, the inner sides of the base 11 and/or the upper cover 12 are provided with protruding limiting ribs 18, in this embodiment, the inner sides of the base 11 and the upper cover 12 are provided with the limiting ribs 18, the limiting ribs 18 are set to be protruding long strips, and are consistent with the water flow direction 3, the limiting ribs 18 are abutted to the parts of the cathode plate 21 and the anode plate 22 that are not provided with the water tank 31, so that the electrolysis apparatus 2 is fixed and stable in the electrolysis chamber 13, the lamination of the anode plate 22, the cathode plate 21 and the proton exchange membrane 23 can be kept in a tight state, the breeding of the scale 4 at the gap is reduced, and a stable ozone electrolysis state is kept.

Of course, after the usage time reaches a certain period, or under the condition that there is no water flow to wash for a long time, there is still a possibility of scaling at the contact surface of the proton exchange membrane 23 and the cathode plate 21, or the proton exchange membrane 23 and the anode plate 22, in this case, a cleaning liquid may be introduced at the water inlet 14, and the cleaning liquid may be an acidic liquid or other acidic liquid with the same efficacy, such as citric acid or white vinegar, and the scale 4 may be cleaned, so as to remove the scale 4 deeply, and ensure the stable contact of the proton exchange membrane 23 and the cathode plate 21 and the anode plate 22.

Referring to fig. 14 to 16, the cathode plate 21 and the anode plate 22 are connected to the cathode conductive needle 5 and the anode conductive needle 6 respectively, wherein the cathode conductive needle 5 and the cathode plate 21 are separated, and the anode conductive needle 6 and the anode plate 22 are separated.

The positive pole leads electrical needle 6 and negative pole and leads electrical needle 5 and all adopts pin needle, the positive pole leads electrical needle 6 and negative pole and leads electrical needle 5 one end respectively in positive pole piece 22 and negative pole piece 21 butt, wherein the mode of contact chooses for use in this embodiment for elastic contact, be provided with warhead 7 on the position of positive pole piece 22 and negative pole piece 21 contact at positive pole conductive needle 6 and negative pole conductive needle 5, warhead 7's material is pin material equally, under this warhead 7's effect, can make positive pole lead electrical needle 6 and negative pole lead electrical needle 5 contact positive pole piece 22 and negative pole piece 21 all the time, thereby avoid the unable normal work that leads to because of the contact failure.

Specifically, a cavity 71 is provided at one end of the cathode conductive pin 5 and the anode conductive pin 6, the bullet 7 is disposed in the cavity 71, and an elastic device 72 is provided between the bullet 7 and the bottom wall of the cavity 71, wherein the elastic device 72 may be a spring or an elastic rubber member, and the like, and can give an outward elastic force to the bullet 7. Under the action of the elastic device 72, the warhead 7 can be always abutted against the anode pole piece 22 or the cathode pole piece 21, so that the working stability and the service life of the ozone electrolysis device 2 are kept.

The part of the bullet 7 extending into the concave cavity 71 can be provided with a limiting ring 73 outwards in the circumferential direction, and the size of the limiting ring 73 is larger than that of the opening of the concave cavity 71, so that the bullet 7 can be prevented from accidentally falling off and can be always kept in the concave cavity 71.

The cathode plate 21 and the anode plate 22 are connected to the conductive needle in a specific manner, in the electrolytic cavity 13, the anode plate 22 and the cathode plate 21 are both in a block shape and are arranged in an up-down mutual overlapping manner, and of course, the proton exchange membrane 23 is arranged between the anode plate 22 and the cathode plate 21. When cathode plate 21 is located the top, anode plate 22 is located the below, and negative pole conducting pin 5 is from the top to the vertical setting in below, has warhead 7's one end and the negative pole plate 21 looks elasticity butt, has still seted up on cathode plate 21 and has dodged hole 8, and positive pole conducting pin 6 is from the top to the vertical setting in below, dodges hole 8 and can supply positive pole conducting pin 6 to pass to positive pole conducting pin 6 can with the anode plate 22 looks elastic contact who is located the top. It should be noted that, a relief hole 8 is also provided at a corresponding position of the proton exchange membrane 23, through which the anode conductive pin 6 can pass.

As another embodiment, when the anode plate 22 is located above, the cathode plate 21 is located below, the anode conductive pin is vertically disposed from above to below, one end having the bullet 7 elastically abuts against the cathode plate 21, the cathode plate 21 is further provided with the avoiding hole 8, the cathode conductive pin 5 is vertically disposed from above to below, and the avoiding hole 8 can be penetrated by the cathode conductive pin 5, so that the cathode conductive pin can elastically contact with the cathode plate 21 located below. It should be noted that, a relief hole 8 is also provided at a corresponding position of the proton exchange membrane 23, through which the anode conductive pin 6 can pass.

The other ends of the anode conductive pin 6 and the cathode conductive pin 5 penetrate through the outer side of the upper cover 12 and are used for being connected with a low-voltage power supply, and the low-voltage power supply is used for providing safe and stable voltage to realize the ozone electrolysis. The user uses and does not have high pressure hidden danger, and factor of safety is high.

The positive pole leads electrical needle 6 and the negative pole leads electrical needle 5 and upper cover 12 injection moulding as an organic whole, and integrative injection moulding just carries out integrative injection moulding when the mould is moulded plastics promptly to avoid the secondary operation in later stage, technology is simpler, and for current fixed mode such as glue of beating, the leakproofness behind the integrative injection moulding is better, and the effectual emergence of avoiding the condition such as leaking can bring and experience the sense for more use of consumer.

The above-mentioned upper penetrating is because the upper penetrating is disposed on the upper cover 12, which facilitates the assembly of the cathode conductive pin 5 and the anode conductive pin 6, of course, the embodiment is not limited thereto, and the upper penetrating may be disposed on the base 11 in a manner similar to that described above, and will not be described again here.

In addition, a limiting clamp 9 used for limiting the bullet 7 is further arranged in the electrolytic cavity 13, two through holes 91 are formed in the limiting clamp 9, the size of each through hole 91 is slightly larger than the size of the cross section of the bullet 7, the limiting clamp 9 is fixed in the electrolytic cavity 13, the limiting clamp can be fixedly clamped with the inner side of the upper cover 12 above the limiting clamp in a fixing mode, or can be welded in an ultrasonic mode, or can be fixed with a pole piece close to the side above the limiting clamp, after the limiting clamp 9 is arranged, the cathode conductive needle 5 and the anode conductive needle 6 can keep more stable positions, and therefore the situation that the position deviation occurs to influence the conductive work is avoided.

It should be noted that directional terms, such as "upper", "lower", "front", "rear", "left", "right", etc., mentioned in the embodiments are only directions referring to the drawings, and are not intended to limit the protection scope of the present invention. In addition, unless steps are specifically described or must occur in sequence, the order of the steps is not limited to that listed above and may be changed or rearranged as desired by the desired design. The embodiments described above may be mixed and matched with each other or with other embodiments based on design and reliability considerations, i.e., technical features in different embodiments may be freely combined to form further embodiments.

The word "comprising" does not exclude the presence of elements or steps not listed in a claim. The word "a" or "an" preceding an element does not exclude the presence of a plurality of such elements. The invention can be implemented by means of hardware comprising several distinct elements, and by means of a suitably programmed computer. In the unit claims enumerating several means, several of these means may be embodied by one and the same item of hardware.

Furthermore, the use of ordinal numbers such as "first," "second," "third," etc., in the specification and claims to modify a corresponding element is not intended to imply any ordinal numbers for the element, nor the order in which an element is sequenced or methods of manufacture, but are used to distinguish one element having a certain name from another element having a same name.

It should be noted that throughout the drawings, like elements are represented by like or similar reference numerals. In the following description, some specific embodiments are for illustrative purposes only, and should not be construed as limiting the invention in any way, but merely as exemplifications of embodiments of the invention. Conventional structures or constructions will be omitted when they may obscure the understanding of the present invention. It should be noted that the shapes and sizes of the respective components in the drawings do not reflect actual sizes and proportions, but merely illustrate the contents of the embodiments of the present invention.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent laws within the scope of the claims of the present invention.

Claims (9)

1. The ozone electrolysis generator is characterized by comprising a shell (1), wherein the shell (1) comprises a base (11) and an upper cover (12), an electrolysis cavity (13) is formed between the base (11) and the upper cover (12), a cathode pole piece (21) and an anode pole piece (22) and a proton exchange membrane (23) between the cathode pole piece (21) and the anode pole piece (22) are arranged in the electrolysis cavity (13), and the cathode pole piece (21), the proton exchange membrane (23) and the anode pole piece (22) are stacked up and down; the shell (1) is also provided with a water inlet (14) and a water outlet (15), and water flows form a water flow direction (3) flowing to the water outlet (15) in the electrolytic cavity (13) after passing through the water inlet (14); and the cathode pole piece (21) and the anode pole piece (22) are both provided with water passing grooves (31) consistent with the water flow direction (3), and the water passing grooves (31) are arranged in a penetrating manner in the height direction of the cathode pole piece (21) and the anode pole piece (22).

2. The ozone electrolysis generator according to claim 1, wherein a plurality of the water passing grooves (31) are provided in the width direction of the cathode sheet (21), the proton exchange membrane (23), and the anode sheet (22).

3. The ozone electrolysis generator according to claim 1 or 2, characterized in that the inner side of the base (11) and/or the upper cover (12) is provided with a raised limiting rib (18), and the limiting rib (18) and the water trough (31) are arranged in a staggered manner.

4. The ozone electrolysis generator according to claim 1, further comprising a cathode conductive needle (5) and an anode conductive needle (6), wherein one end of the cathode conductive needle (5) is in contact with the cathode pole piece (21), one end of the anode conductive needle (6) is in contact with the anode pole piece (22), the cathode conductive needle (5) and the anode conductive needle (6) each comprise a conductive needle body and a bullet (7), and the bullet (7) is elastically connected with the conductive needle body to abut against the pole piece.

5. The ozone electrolysis generator as claimed in claim 4, wherein the conductive needle body is provided with a concave cavity (71), a limiting ring (73) is arranged at one end of the bullet (7) extending into the concave cavity (71), a spring connected with the bottom of the bullet (7) is arranged in the concave cavity (71), and one end of the bullet (7) extending out of the concave cavity (71) is connected with the pole piece.

6. The ozone electrolysis generator according to claim 5, wherein one end of the cathode conductive needle (5) and one end of the anode conductive needle (6) are inserted into the base (11) or the outer part of the upper cover (12), and the cathode conductive needle (5) and the anode conductive needle (6) are integrally injection-molded with the base (11).

7. The ozone electrolysis generator according to claim 4, wherein the cathode pole piece (21) and the proton exchange membrane (23) are provided with an avoidance hole (8) at corresponding positions, and the other end of the anode conductive needle (6) passes through the avoidance hole (8) to be abutted against the anode pole piece (22); or the like, or, alternatively,

avoidance holes (8) are formed in corresponding positions of the anode pole piece (22) and the proton exchange membrane (23), and the other end of the cathode conductive needle (5) penetrates through the avoidance holes (8) and abuts against the anode pole piece (22).

8. The ozone electrolysis generator according to claim 5, characterized in that a limit clip (9) for limiting the bullet (7) is further arranged in the electrolysis chamber (13).

9. The ozone electrolysis generator according to claim 1, wherein the connection mode of the upper cover (12) and the base (11) can be any one of the following: buckle, bolt, ultrasonic bonding.

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