CN112137551A - Wire outlet structure of electrolysis assembly, electrolysis device and dish washing machine - Google Patents

Abstract

The invention provides a wire outlet structure of an electrolysis assembly, an electrolysis device and a dish washing machine, wherein the wire outlet structure of the electrolysis assembly comprises a first shell; the second shell is matched with the first shell to form an accommodating cavity suitable for accommodating an electrolytic component, a protective groove is arranged on one side, back to the first shell, of the second shell, and a conduction opening communicated with the protective groove and the accommodating cavity is formed in the second shell; the protective cover is arranged on the second shell or the first shell and has a first state for covering the protective groove and a second state for opening the protective groove. The wire outlet structure of the electrolytic assembly provided by the invention can ensure the normal wire outlet use of the electrolytic assembly and can protect the electrolytic assembly when the electrolytic assembly is not used.

Description

Wire outlet structure of electrolysis assembly, electrolysis device and dish washing machine

Technical Field

The invention relates to the technical field of household appliances, in particular to an outlet structure of an electrolysis assembly, an electrolysis device and a dish washing machine.

Background

With the improvement of living standard, the dish washing machine gradually enters into the ordinary family, and the living quality of people is improved.

Generally, the main core components of existing dishwashers generally include: the water pump comprises a liner assembly, a water cup assembly, a spray arm assembly, a filter assembly, a washing pump, a drainage pump, a pipeline and the like. The dish washer in the market generally carries out main cleaning and tableware disinfection through high temperature (usually about 70 ℃), and some dish washers are also provided with modes of UVC ultraviolet lamp disinfection, silver ion bacteriostasis added in part materials, steam high-temperature disinfection, hot air drying and the like.

Disclosure of Invention

Therefore, the technical problem to be solved by the invention is to provide a wire outlet structure of an electrolysis assembly of a novel dish washing machine, an electrolysis device and the novel dish washing machine.

The invention provides a wire outlet structure of an electrolytic component, which comprises:

a first housing;

the second shell is matched with the first shell to form an accommodating cavity suitable for accommodating an electrolytic component, a protective groove is arranged on one side, back to the first shell, of the second shell, and a conduction opening communicated with the protective groove and the accommodating cavity is formed in the second shell;

the protective cover is arranged on the second shell or the first shell and has a first state for covering the protective groove and a second state for opening the protective groove.

One end of the protective cover is connected with the second casing in a rotatable manner, and the other end of the protective cover is connected with the second casing in a detachable manner.

The connecting end is rotatably connected with the second shell through an easy-to-break structure.

The easy-to-break structure comprises an easy-to-break body and a first through groove, wherein the first through groove is formed in one side, opposite to the notch of the protective groove, of the easy-to-break body.

The easy-to-break structure further comprises a second through groove, and the second through groove is formed in one side, facing the same direction, of the easy-to-break body and the notch of the protective groove.

The protective cover, the easy-to-break structure and the second shell are integrally formed.

The free end and the second shell are detachably connected through a buckle structure.

The buckle structure includes:

the first buckle comprises a first buckle body arranged on the groove wall of the protective groove and a clamping groove formed between the first buckle body and the groove bottom of the protective groove; a first guide inclined plane is formed on one side, back to the clamping groove, of the first buckle body;

the second buckle comprises a second buckle body and a yielding groove which are respectively arranged on the protective cover, a second guide inclined plane matched with the first guide inclined plane is arranged on the second buckle body, and the yielding groove is suitable for containing the first buckle body when the second buckle body is clamped against the clamping groove; the second buckle body is clamped in the clamping groove when the protective cover is in the first state, and is separated from the clamping groove when the protective cover is in the second state.

The bottom of the protective groove is provided with at least one sinking groove, and the conducting opening is communicated with the sinking groove and the accommodating cavity.

The invention provides a wire outlet structure of an electrolytic assembly, which further comprises a wire blocking structure arranged in the protective groove.

The stop line structure is arranged on a stop line lug on the bottom of the protective groove, and the stop line lug is close to the sink groove.

The second housing is detachably connected with the first housing.

The first housing is a first tank sidewall of a dishwasher tank and the second housing is a second tank sidewall of the dishwasher tank.

The invention also provides an electrolysis device which comprises the wire outlet structure of the electrolysis assembly and the electrolysis assembly arranged in the accommodating cavity.

The invention also provides a dishwasher, which comprises the electrolysis device.

The technical scheme of the invention has the following effects:

1. the invention provides a wire outlet structure of an electrolytic assembly, comprising a first shell; the second shell is matched with the first shell to form an accommodating cavity suitable for accommodating an electrolytic component, a protective groove is arranged on one side, back to the first shell, of the second shell, and a conduction opening communicated with the protective groove and the accommodating cavity is formed in the second shell; the protective cover is arranged on the second shell or the first shell and has a first state for covering the protective groove and a second state for opening the protective groove. By arranging the protective cover, when the electrolytic component is not needed, the protective cover can be in the first state for covering the protective groove, so that external liquid and the like are not easy to enter the accommodating cavity, and the electrical safety of the electrolytic component arranged in the accommodating cavity can be protected; when the electrolytic assembly needs to be used, the protective cover can be in the second state of opening the protective groove, so that the lead wire led out from the electrolytic assembly can extend out of the protective groove to be electrically connected with a power supply, and the electrolytic assembly can work normally. The wire outlet structure of the electrolytic assembly provided by the invention can ensure the normal wire outlet use of the electrolytic assembly and can protect the electrolytic assembly when the electrolytic assembly is not used.

2. The invention provides an outgoing line structure of an electrolytic assembly, which comprises an easy-to-break body and a first through groove, wherein the first through groove is arranged on one side of the easy-to-break body, which is opposite to the direction of a notch of a protective groove. Only need make the protective cover like this use first logical groove department to overturn for the axle towards one side of keeping away from the link of protective groove, or make the protective cover keep at natural state, alright realize making the protective cover switch between first state and second state, have simple structure, the advantage of easily realizing.

3. The invention provides an outgoing line structure of an electrolytic component, which comprises: the first buckle comprises a first buckle body arranged on the groove wall of the protective groove and a clamping groove formed between the first buckle body and the groove bottom of the protective groove; a first guide inclined plane is formed on one side, back to the clamping groove, of the first buckle body; the second buckle comprises a second buckle body and a yielding groove which are respectively arranged on the protective cover, a second guide inclined plane matched with the first guide inclined plane is arranged on the second buckle body, and the yielding groove is suitable for containing the first buckle body when the second buckle body is clamped against the clamping groove; the second buckle body is clamped in the clamping groove when the protective cover is in the first state, and is separated from the clamping groove when the protective cover is in the second state. Only need detain the body card with the second like this and go into in the draw-in groove or deviate from the draw-in groove, alright in order to realize the locking of protective cover at first state and remove the locking, simple structure, convenient operation, and the locking effect is firm.

4. The invention provides a wire outlet structure of an electrolytic assembly, which further comprises a wire blocking structure arranged in the protective groove. Through setting up the stop line structure, can guide spacing to the wire that the electrolysis subassembly was drawn forth, make the wiring in the guard bath more neat standard.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a cross-sectional view of an electrolytic device provided by the present invention;

FIG. 2 is an enlarged view of a portion of area A of FIG. 1;

FIG. 3 is an enlarged view of a portion of area B of FIG. 1;

FIG. 4 is a schematic view of a protective cover according to the present invention on an electrolyzer;

FIG. 5 is a schematic view of a second construction of a protective cover according to the present invention on an electrolysis apparatus;

description of reference numerals:

b 901-water tank chamber; b904 — first tank sidewall; b 905-a second water tank side wall; b 9051-protective groove, b 9052-conducting opening,

c 0-electrolytic component, c 10-insulating separator, c 11-first insulating frame, c 111-abdicating through hole, c 12-second insulating frame, c 13-first insulating boss, c 131-first insulating cavity, c 14-second insulating boss, c 141-second insulating cavity, c 15-third insulating boss, c 151-first positioning hole, c 16-fourth insulating boss, c 161-second positioning hole, c 17-clamping hook, c 171-handle, c 172-hook,

c 2-electrolytic structure, c 201-sheet-like body, c 202-electrolytic through-hole, c 21-first electrode, c 211-first opening, c 22-second electrode, c 221-second opening,

c301 terminal, c302 conductive body, c303 wire fixing structure, c3031 first nut, c3032 second nut, c31 first conductive structure, c32 second conductive structure,

c 4-wire, c 41-mounting hole,

c 5-third seal, c 51-seal body, c 52-tapered seal,

c 6-protective cover, c 61-connecting end, c 62-free end,

c 71-a frangible body, c 72-a first through groove, c 73-a second through groove,

c 811-a first buckle body, c 812-a card slot, c 813-a first guiding inclined plane, c 821-a second buckle body, c 822-an abdicating slot, c 823-a second guiding inclined plane,

c91 sink groove, c92 stop line lug.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, the technical features involved in the different embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

Examples

As shown in fig. 1 to 5, the embodiment provides an electrolytic component of a dishwasher, which has the following specific structure, and the electrolytic component c0 comprises:

a mounting structure;

an electrolytic structure comprising at least two electrodes, wherein at least one first electrode c21 and at least one second electrode c22 are arranged on the mounting structure at intervals;

at least two conductive structures sequentially penetrating the first electrode c21 and the second electrode c 22; and at least two of the conductive structures are provided with at least one first conductive structure c31 and at least one second conductive structure c32, wherein the first conductive structure is electrically connected with the first electrode, and the second conductive structure is electrically connected with the second electrode.

In use, one of the first conductive structure c31 and the second conductive structure c32 is electrically connected to a positive electrode, and the other is electrically connected to a negative electrode, so that the first electrode c21 electrically connected to the first conductive structure c31 is an anode and the second electrode c22 electrically connected to the second conductive structure c32 is a cathode, or the first electrode c21 is a cathode and the second electrode c22 is an anode, by disposing the first electrode c21 and the second electrode c22 on the mounting structure at intervals, bacteria in the dishwasher can be killed through electrolysis, so that the dishware can be stored and kept in the dishwasher for a long time, and at the same time, since the first conductive structure c31 sequentially penetrates through the first electrode c21 and the second electrode c22 and the second conductive structure c32 sequentially penetrates through the first electrode c21 and the second electrode c22, the first conductive structure c31 is only required to be selectively electrically connected to the positive electrode or the negative electrode, and the second conductive structure c32 is selectively electrically connected to the positive electrode or the negative electrode 32, that is, it is ensured that the polarities of the power supplies connected to the first conductive structure c31 and the second conductive structure c32 are different, so that the first electrode c21 can be selectively connected to positive electrode electricity or negative electrode electricity, and the second electrode c22 can be selectively connected to negative electrode electricity or positive electrode electricity having a polarity different from that of the first electrode c21, which is convenient for a user to electrically connect the first electrode c21, the second electrode c22 and the positive and negative electrodes of the power supplies.

The specific electrolysis principle is as follows:

cathode 2 Cl-2 e ═ Cl2

Anode 2H2O +2e- ═ H2+2OH-

And (3) total reaction: 2Cl- +2H2O ═ H2+ Cl2+2OH-

A disproportionation reaction will occur between chlorine and water: cl2+ H2O is HCl + HClO, and the generated HClO has certain oxidability, so that the effect of killing bacteria and viruses is realized.

In the embodiment, the adopted salt is NaCl which is non-toxic and stable in property, is not easy to deteriorate, and is convenient to store and carry out electrolytic disinfection operation. Other chlorates, such as KCl, CaCl, etc., are not recommended because of their own potential for harm to the human body.

In this embodiment, in order to implement the installation operation of the electrolytic component, the installation structure and the electrolytic structure of the electrolytic component are disposed in the water tank chamber, and the conductive structure partially extends out of the water tank chamber b 901.

Further, in order to realize the conductive operation, one end of each conductive structure, which is far away from the electrode, is a terminal, and the terminal of each conductive structure is respectively connected with a lead c 4; the mounting structure includes an insulating spacer, the first electrode is located on a side of the insulating spacer adjacent to the terminal, and the second electrode is located on a side of the insulating spacer remote from the terminal.

In this embodiment, the mounting structure further includes:

the first insulating frame c11 is located on one side of the first electrode, which faces away from the insulating partition plate, and the first insulating frame is provided with abdicating through holes through which the first conductive structure and the second conductive structure respectively pass;

a second insulating frame c12 located on the side of the second electrode facing away from the insulating spacer;

a first insulating boss c13, where the first insulating boss is disposed on the insulating partition and/or the first insulating frame, the first electrode is provided with a first opening c211 suitable for accommodating the first insulating boss, the first insulating boss is provided with a first insulating cavity c131, and the second conductive structure passes through the first insulating cavity and contacts with the second electrode;

and the second insulating boss c14 is arranged on the second insulating frame and/or the insulating partition plate, a second opening suitable for accommodating the second insulating boss is arranged on the second electrode, a second insulating cavity is arranged on the second insulating boss, and the first conductive structure penetrates through the first electrode and is accommodated in the second insulating cavity.

By arranging the first insulation boss and the second insulation boss, the corresponding electrode is only contacted with the corresponding conductive structure, so that the stability of current transmission can be ensured.

Specifically, the first insulation boss and the insulation partition plate are integrally formed, and the second insulation boss and the second insulation frame are integrally formed. As a modification, the first insulation boss and the second insulation boss may be provided in the form of a gasket.

In this embodiment, the mounting structure further includes:

a third insulation boss c15, disposed on the second insulation frame and extending in a direction away from the electrode, wherein the third insulation boss is provided with a first positioning hole adapted to accommodate the second conductive structure; a fourth insulation boss c16 arranged on the second insulation frame and extending out in the direction far away from the electrode, wherein a second positioning hole communicated with the second insulation cavity is arranged on the fourth insulation boss; one surface of the fourth insulation boss back to the electrode is flush with one surface of the third insulation boss back to the electrode.

In this embodiment, the mounting structure further includes at least one hook c17, and the hook includes: a handle c171 provided on the second insulating frame and extending toward the first insulating frame; and the hook part c172 is arranged at one end of the handle part far away from the second insulating frame and is abutted against one side of the first insulating frame back to the second insulating frame.

Through setting up the pothook, can press from both sides first insulation frame, second insulation frame, the first electrode that is located between first insulation frame and the second insulation frame, second electrode and insulating barrier tightly, make a plurality of subassemblies form a complete structure to avoid taking place to scatter.

In this embodiment, the electrode is an electrolytic sheet, the electrolytic sheet includes a sheet body and a plurality of electrolytic through holes disposed on the sheet body, and by disposing the electrolytic through holes, the contact area between the salt solution and the current can be increased, and further the reaction rate can be increased. Specifically, the electrolytic through holes are arranged in a circular manner. The plurality of electrolytic through holes may be arranged in a scattered manner without being limited to a specific arrangement, and in a preferred embodiment, the plurality of electrolytic through holes are uniformly distributed on the sheet-like body.

In this embodiment, the first electrode and the second electrode are parallel to each other. An anode reaction is carried out on one of the first electrode and the second electrode, and a cathode reaction is carried out on the other of the first electrode and the second electrode.

In this embodiment, the conductive structure includes: the conductive body is electrically connected with the corresponding electrode; and the wire fixing structure is arranged at one end of the conductive body, which is far away from the electrode, and is used for fixing the lead. Through setting up electrically conductive body, carry out electric energy transport to corresponding electrode.

Specifically, the conductive body is a bolt. The wire fixing structure comprises a first nut and a second nut which are respectively screwed on the bolt, and the wire is clamped between the first nut and the second nut.

In this embodiment, the wire itself may be directly wound around the conductive body, and as a preferred embodiment, a mounting hole is formed at one end of the wire, and the wire is sleeved on the conductive body through the mounting hole. Specifically, the mounting hole is arranged in a circular hole, and the mounting hole is sleeved on the bolt, so that the conducting operation is performed.

The present embodiment also provides an electrolysis apparatus, comprising:

a water tank body, which is formed with a water tank chamber b901, and a side wall of the water tank body b9 away from the terminal c301 is a first water tank side wall b904, and a side wall close to the terminal c301 is a second water tank side wall b 905;

the electrolytic assembly, the mounting structure of the electrolytic assembly c0 and the electrolytic structure c2 are arranged in the water tank chamber b901, and the conductive structure partially extends out of the water tank chamber b 901;

and at least two sealing pieces c5 arranged between the second water tank side wall b905 and the mounting structure and corresponding to the conductive structure.

The sealing member c5 is a sealing ring and includes a sealing body c51 in a sheet shape, and a tapered sealing portion c52 extending from the sealing body c51 toward the terminal c 301; the sealing body c51 and the conical sealing part c52 are integrally formed, a sealing hole which sequentially penetrates through the conical sealing part c52 and the sealing body c51 is formed in the sealing ring, and the sealing hole is suitable for the conductive structure to penetrate through.

Further, in the present embodiment, in order to realize a stable mounting operation of the entire electrolytic apparatus, the following arrangement is adopted:

the water tank body comprises a first water tank side wall and a second water tank side wall which are arranged oppositely, the first water tank side wall and the second water tank side wall are matched to enclose an accommodating cavity suitable for accommodating an electrolytic component c0, a protective groove b9051 is arranged on one side, back to the first shell, of the second shell, and a conduction opening b9052 for communicating the protective groove b9051 with the accommodating cavity is formed in the second shell;

the protective cover c6 is disposed on the first and second tank sidewalls, and has a first state of closing the protective bath b9051 and a second state of opening the protective bath b 9051. Through setting up the protective cover, can shelter from the electrically conductive body that is located the inside of protective tank to can avoid during external water directly enters into the protective tank, lead to electrically conductive body self to take place the short circuit. Meanwhile, the pollution to the conductive body caused by external dust entering the protective groove can be avoided.

Specifically, one end of the protecting cover c6 is a connecting end c61 rotatably connected with the second housing, and the other end is a free end c62 detachably connected with the second housing.

By the above operation, the space of the opening in the shield groove can be fully utilized. As a modification, in addition to the form of rotatably disposing the protective cover, a form of drawing and disposing the protective cover may be employed, and at this time, a slide way may be disposed on the first tank sidewall or the second tank sidewall, and the protective cover may be embedded in the slide way. In a preferred embodiment, the connecting end c61 is rotatably connected to the second tank sidewall by a flexible structure.

In this embodiment, the easy-folding structure includes an easy-folding body c71 and a first through groove c72, and the first through groove c72 is disposed on a side of the easy-folding body c71 opposite to the notch of the protection groove b 9051.

Specifically, the first through groove is arranged in a semicircular groove mode, and as a modification, the first through groove can also be arranged in a triangular mode. Only need make the protective cover like this use first logical groove department to overturn for the axle towards one side of keeping away from the link of protective groove, or make the protective cover keep at natural state, alright realize making the protective cover switch between first state and second state, have simple structure, the advantage of easily realizing.

In this embodiment, the easy-folding structure further includes a second through groove c73, and the second through groove c73 is disposed on a side of the easy-folding body c71, which faces the same direction as the notch of the protection groove b 9051.

Through setting up the second and leading to the groove, can increase protective cover self rotation convenience once more, avoid taking place to rotate the back at the second and lead to the groove position to take place elasticity and concentrate when the protective cover, lead to protective cover self to have the impetus of taking place to open the action.

As an alternative embodiment, the breakable structure may be made of a flexible material or an elastic material.

In this embodiment, the protective cover c6, the frangible structure and the second housing are integrally formed. As a variant, it is also possible to arrange a protective cover or the like on the second housing in a splicing manner.

In this embodiment, in order to stabilize the protecting cover on the second tank sidewall, the free end c62 is detachably connected to the second tank sidewall through a snap structure.

Specifically, the snap structure includes: the first buckle comprises a first buckle body c811 arranged on the groove wall of the protection groove b9051 and a clamping groove c812 formed between the first buckle body c811 and the groove bottom of the protection groove b 9051; a first guiding inclined plane c813 is formed on one side of the first buckle body c811 facing away from the clamping groove c 812; the second buckle comprises a second buckle body c821 and a yielding groove c822 which are respectively arranged on the protective cover c6, a second guiding inclined plane c823 which is matched with the first guiding inclined plane c813 is arranged on the second buckle body c821, and the yielding groove c822 is suitable for accommodating the first buckle body c811 when the second buckle body c821 is clamped in the clamping groove c 812; the second buckle body c821 is clamped in the clamping groove c812 when the protective cover c6 is in the first state, and is separated from the clamping groove c812 when the protective cover c6 is in the second state.

Only need detain the body card with the second like this and go into in the draw-in groove or deviate from the draw-in groove, alright in order to realize the locking of protective cover at first state and remove the locking, simple structure, convenient operation, and the locking effect is firm.

In this embodiment, at least one sinking groove c91 is disposed at the bottom of the protection groove b9051, and the through opening b9052 communicates the sinking groove c91 with the accommodating cavity. Through setting up the recess, can conveniently screw up or relax the operation first nut and second nut to improve the convenience of operation.

In this embodiment, the device further includes a line blocking structure disposed in the protective groove b 9051. Through setting up the stop line structure, can guide spacing to the wire that the electrolysis subassembly was drawn forth, make the wiring in the guard bath more neat standard.

Specifically, the wire blocking structure is a projection arranged on the protective groove, the specific shape and size of the wire blocking structure are not limited too much, the wire blocking structure acts at the front position of the wire rotating path, and the wire stops rotating continuously after being rotated to the wire blocking structure by external force. In this embodiment, the line blocking protrusion c92 is disposed near the sinking groove c 91. As a modification, it may be disposed appropriately away from the groove as long as the blocking action of the wire can be achieved, and is not excessively limited in the present embodiment.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications therefrom are within the scope of the invention.

Claims (15)

1. An outlet structure of an electrolytic assembly, comprising:

a first housing;

the second shell is matched with the first shell to enclose an accommodating cavity suitable for accommodating an electrolytic component (c0), a protective groove (b9051) is arranged on one side, back to the first shell, of the second shell, and a conduction opening (b9052) for communicating the protective groove (b9051) with the accommodating cavity is formed in the second shell;

and a protective cover (c6) disposed on the second housing or the first housing, and having a first state of closing the protective groove (b9051) and a second state of opening the protective groove (b 9051).

2. The tapping structure of an electrolysis assembly according to claim 1, wherein the protecting cover (c6) has one end being a connecting end (c61) rotatably connected to the second housing and the other end being a free end (c62) detachably connected to the second housing.

3. The outlet structure of an electrolytic module according to claim 2, wherein the connection end (c61) is rotatably connected to the second housing by a frangible structure.

4. The outlet structure of an electrolysis assembly according to claim 3, wherein the easy-folding structure comprises an easy-folding body (c71) and a first through groove (c72), and the first through groove (c72) is arranged on the side of the easy-folding body (c71) opposite to the notch of the protection groove (b 9051).

5. The outlet structure of an electrolysis assembly according to claim 4, wherein the easy-to-break structure further comprises a second through groove (c73), and the second through groove (c73) is arranged on one side of the easy-to-break body (c71) which is in line with the notch of the protection groove (b 9051).

6. The tapping structure of an electrolysis assembly according to claim 3, wherein the protective cover (c6), the frangible structure and the second housing are integrally formed.

7. The tapping structure of an electrolysis assembly according to any one of claims 2 to 6, wherein the free end (c62) is detachably connected to the second housing by a snap-fit arrangement.

8. The electrolytic assembly outlet structure of claim 7, wherein the snap structure comprises:

the first buckle comprises a first buckle body (c811) arranged on the groove wall of the protection groove (b9051) and a clamping groove (c812) formed between the first buckle body (c811) and the groove bottom of the protection groove (b 9051); a first guide inclined plane (c813) is formed on one side of the first buckle body (c811) back to the clamping groove (c 812);

the second buckle comprises a second buckle body (c821) and a yielding groove (c822) which are respectively arranged on the protective cover (c6), a second guide inclined plane (c823) matched with the first guide inclined plane (c813) is arranged on the second buckle body (c821), and the yielding groove (c822) is suitable for accommodating the first buckle body (c811) when the second buckle body (c821) is clamped in the clamping groove (c 812); the second buckle body (c821) is clamped in the clamping groove (c812) when the protective cover (c6) is in the first state, and is pulled out of the clamping groove (c812) when the protective cover (c6) is in the second state.

9. The tapping structure of an electrolysis module according to any one of claims 1 to 6, wherein the bottom of the protective bath (b9051) is provided with at least one sink (c91), and the conducting opening (b9052) communicates the sink (c91) with the accommodating cavity.

10. The outlet structure of an electrolytic assembly according to claim 9, further comprising a stopper structure provided in the guard bath (b 9051).

11. The lead-out structure of an electrolysis assembly according to claim 10, wherein the lead-blocking structure is a lead-blocking bump (c92) provided on the bottom of the protection groove (b9051), and the lead-blocking bump (c92) is provided adjacent to the sinking groove (c 91).

12. The outlet structure of an electrolytic assembly according to any one of claims 1 to 6, wherein the second housing is detachably connected to the first housing.

13. The outlet structure of an electrolytic assembly according to any one of claims 1 to 6, wherein said first housing is a first tank side wall (b904) of a dishwasher tank and said second housing is a second tank side wall (b905) of the dishwasher tank.

14. An electrolysis device, comprising an outlet structure of an electrolysis assembly according to any one of claims 1 to 13, and an electrolysis assembly (c0) disposed in the housing chamber.

15. A dishwasher, comprising the electrolyzer of claim 14.

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