CN216073163U - Water electrolysis device and purification equipment - Google Patents

Abstract

The utility model discloses an electrolytic water device and a purifying device, wherein the electrolytic water device comprises: the shell is provided with an accommodating cavity and a liquid inlet communicated with the accommodating cavity; and the electrode piece assembly is accommodated in the accommodating cavity and is used for electrolyzing the liquid in the accommodating cavity. The water electrolysis device is convenient to carry, use and place in order, is not limited to a container and a use place, can reduce the volume of the water electrolysis device, and reduces the production process and the cost of the water electrolysis device.

Description

Water electrolysis device and purification equipment

Technical Field

The utility model relates to the technical field of water purification, in particular to an electrolytic water device and purification equipment.

Background

With the development of society, people are pursuing high-quality life more and more strongly, wherein the people pay special attention to the safety of food at the entrance, this is more because at present in the fruit and vegetable production process, the grower sprays a large amount of pesticide on the fruit and vegetable plants in order to eliminate insect pest and guarantee the output, leads to the pesticide residue on the food to exceed standard, and such news reports are not in a few. Meanwhile, as the environment is polluted by modern industry and by being discarded at will, the garbage is not easy to degrade (can not be) degraded, and the safety of the edible materials eaten by people has greater risk. The electrolysis water equipment is the purifier that volume ratio is great usually, and the device is from taking big water tank for wash the edible material, however the device is bulky, only is fit for using at fixed position, takes inconveniently and occupies the position.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims to provide an electrolytic water device and purification equipment, aiming at reducing the volume of the electrolytic water device and improving the use convenience of the electrolytic water device.

To achieve the above object, the present invention provides an electrolytic water device, comprising:

the shell is provided with an accommodating cavity and a liquid inlet communicated with the accommodating cavity; and the number of the first and second groups,

and the electrode piece assembly is accommodated in the accommodating cavity and is used for electrolyzing the liquid in the accommodating cavity.

Optionally, the water electrolysis apparatus further comprises:

the power supply assembly is contained in the shell and is electrically connected with the electrode plate assembly so as to provide working voltage for the electrode plate assembly.

Optionally, the power supply assembly comprises:

an energy storage device;

the energy storage device comprises an electric control board, wherein a control module and a charging circuit are arranged on the electric control board, and the control module is electrically connected with the charging circuit and the energy storage device respectively; the control module is used for controlling the charging circuit to store the received electric energy to the energy storage device.

Optionally, a middle shell is further arranged in the shell, and the middle shell is arranged on one side, back to the liquid inlet, of the electrode plate assembly;

the power supply assembly is isolated from the electrode pad assembly by the middle shell.

Optionally, a support plate is further arranged in the shell, the support plate isolates the middle shell to form a first mounting groove and a second mounting groove, the electric control plate is arranged in the first mounting groove, and the energy storage device is arranged in the second mounting groove.

Optionally, the water electrolysis device is further provided with a fixing plate, and the fixing plate is fixedly mounted on one side of the shell along the length direction of the shell;

the charging circuit is a wireless charging circuit, and a wireless receiving coil of the wireless charging circuit is arranged on the fixing plate.

Optionally, the water electrolysis device is further provided with a display board, and the display board is fixedly mounted on the middle shell.

Optionally, a through hole is further formed in the position, corresponding to the display panel, of the shell, a key is further arranged on the display panel, the key penetrates through the through hole and extends out of the shell, and the key is electrically connected with the control module; wherein the content of the first and second substances,

when the key is triggered by a user, outputting a corresponding key instruction;

and the control module receives the key instruction, and controls the electrode plate assembly to work in a working mode corresponding to the key instruction when determining that the current key instruction is the selected working mode according to the key instruction.

Optionally, the water electrolysis apparatus further comprises:

the balancing weight is arranged on one side, far away from the liquid inlet, in the shell.

Optionally, the electrode sheet assembly comprises:

at least two electrode plates, wherein at least one electrode plate is a cathode electrode plate, and at least one electrode plate is an anode electrode plate;

the cathode electrode plate and the anode electrode plate are separated by a spacer.

Optionally, the number of the cathode electrode sheet and the anode electrode sheet is plural;

the anode electrode plate is clamped between every two cathode electrode plates;

or the cathode electrode plate and the anode electrode plate are sequentially stacked;

or one cathode electrode plate is clamped between every two anode electrode plates.

Optionally, the casing includes drain pan and upper cover, drain pan and upper cover enclose to close and are formed with the holding chamber, the upper cover is provided with the feed liquor grid that has that the confession liquid got into.

Optionally, the upper cover is detachably connected with the bottom case.

The utility model also provides a purification device which comprises the water electrolysis device.

Optionally, the purification apparatus further comprises a water tap, the water tap being detachably and electrically connected to the electrolysis device.

Optionally, a wireless charging device is arranged in the faucet, and the wireless charging device is in wireless electrical connection with a wireless charging circuit arranged in the water electrolysis device.

Optionally, a user input assembly is further arranged on the shell of the water faucet, and the user input assembly is wirelessly connected with a power supply assembly of the water electrolysis device;

when the user input assembly is triggered by a user, the corresponding control signal is output so as to control the water electrolysis device to work.

The electrolytic water device is not required to be provided with a container for containing electrolytic liquid, only the integral electrolytic water device is required to be placed in the container to be cleaned, the shell of the electrolytic water device is provided with the containing cavity and the liquid inlet communicated with the containing cavity, the electrode plate assembly contained in the containing cavity of the shell electrolyzes the liquid entering the containing cavity from the liquid inlet to generate micro bubbles and strong oxidizing substances, and the gas with the cleaning function is discharged from the liquid inlet, so that the washing effect is greatly enhanced, the cleaning, the sterilization and the pesticide residue removal are realized, meanwhile, the water can be saved, and the cleaning is easier and cleaner. Compared with the electrolysis device with a water tank, the electrolysis device has the advantages that the volume of the electrolysis device is larger, the electrolysis device is only suitable for being used at a fixed position, and is inconvenient to take and occupies a larger position.

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, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural view of an embodiment of an apparatus for electrolyzing water according to the present invention;

FIG. 2 is a schematic cross-sectional view A-A of the water electrolysis apparatus of FIG. 1;

FIG. 3 is a schematic view of another aspect of the water electrolysis apparatus of the present invention;

FIG. 4 is an exploded view of an embodiment of the water electrolysis apparatus of the present invention;

FIG. 5 is a schematic diagram of an electrical circuit of an embodiment of the water electrolysis apparatus of the present invention;

FIG. 6 is a schematic view showing the structure of the water electrolysis apparatus of the purification apparatus of the present invention removed from the faucet;

FIG. 7 is a schematic view showing the structure of the water electrolysis apparatus of the purification apparatus of the present invention mounted to a faucet;

fig. 8 is a schematic view of the water electrolysis apparatus of fig. 7 assembled to a faucet from another perspective.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				10	Shell body	334	Voltage detection circuit
11	Bottom shell	34	Charging circuit
				12	Upper cover	40	Middle shell
13	Fixing support	40a	First mounting groove
				14	End cap	40b	Second mounting groove
20	Electrode sheet assembly	50	Supporting plate
				21	First electrode sheet	60	Fixing plate
22	Second electrode sheet	70	Display panel
				23	Spacer	71	Push-button
24	Electrode plate fixing plate	72	Sealing cover
				25	Fastening piece	80	Balancing weight
30	Power supply assembly	100	Water electrolysis device
				31	Energy storage device	200	Water tap
32	Electric control board	210	Tap shell
				33	Control module	220	Water outlet part
331	Main controller	230	Valve gate
				332	Charge and discharge management circuit	240	Electric control part
333	Constant current circuit	250	User input assembly

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in 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 obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. 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.

The utility model provides an electrolytic water device.

Referring to fig. 1 to 8, in an embodiment of the present invention, the water electrolysis apparatus 100 includes:

the shell 10 is provided with an accommodating cavity and a liquid inlet 10a, and the liquid inlet 10a is used for communicating the outside and the accommodating cavity; and

and the electrode plate assembly 20 is arranged in the accommodating cavity, and the electrode plate assembly 20 is used for electrolyzing liquid entering the accommodating cavity.

At present, people generally directly use tap water to clean food materials, and a conditional family can install a water purifier and then use the primary domestic water of the water purifier to clean the food materials. However, whether the food is cleaned directly by tap water or by using domestic water primarily filtered by a water purifier, the food is mainly cleaned of large-particle impurities (some water purifier can remove residual chlorine in the tap water), but the food is ineffective to microorganisms such as pesticide residues and bacteria on the surface of the food.

Therefore, in the embodiment, the tap water is electrolyzed by the device, so that a large amount of micro bubbles and strong oxidizing substances are generated in the tap water, the washing effect is greatly enhanced, and the purposes of cleaning, sterilizing, removing pesticide residues, saving water and cleaning more easily and cleanly are achieved. Specifically, the water electrolysis device 100 has an operating state and an idle state, when a user needs to use the water electrolysis device 100, the water electrolysis device 100 can be placed into a container containing liquid and an object to be cleaned, after the user starts the water electrolysis device 100, the water electrolysis device 100 electrolyzes the liquid to form an active ingredient, and the active ingredient formed by the electrode plate assembly 20 flows out of the housing 10 from the liquid inlet 10a, so that the object to be cleaned is cleaned. After the electrolysis is completed, the user can take the electrolytic water device 100 out of the container, and the user can perform subsequent cleaning work on the object to be cleaned.

The housing 10 has opposite sides facing the liquid surface and facing away from the liquid surface, and the liquid inlet 10a is disposed facing the liquid surface when the electrolytic water device 100 is placed in the liquid. The side of the housing 10 facing the liquid surface may be provided partially or entirely as the liquid inlet 10 a. When the water electrolysis device 100 is placed in a container, such as a water tank or a water basin, containing liquid and food, the water electrolysis device 100 sinks to the bottom of the container, the liquid enters from the liquid inlet 10a under the action of gravity, and is electrolyzed by the electrode plate assembly 20 to generate gas with a cleaning function, and the gas with the cleaning function is discharged from the liquid inlet 10 a.

This electrode slice subassembly 20 can electrolyze liquid, for example running water, the pure water of drinking or other liquid that are used for washing, and electrode slice subassembly 20 can make a large amount of microbubbles (hydrogen and oxygen) increase in aqueous on the one hand at the in-process of electrolysis water, when recycling the water washing of taking the microbubble, because the little physical characteristics and the surface tension effect of microbubble, can break impurity and cohere to make impurity more drop from the object surface. In addition, as the micro bubbles collide with each other, break and fuse with each other, impact is formed on the surface of the object, and impurities fall off and are washed away or float to the water surface under the driving of the bubbles, so that a more thorough cleaning effect is achieved. On the other hand, in the process of electrolyzing water, the water is decomposed into a large number of hydroxide ions (OH-) with strong oxidizing property and hydrogen ions (H +) with reducing property, the pesticide and bacteria on the surface of the food material are heavily surrounded by the hydroxide ions by virtue of bubbles, and the pesticide and the hydrogen ions on the cell walls of the bacteria are removed by the hydroxide ions to be destroyed, so that the effects of sterilizing and removing pesticide residues are finally achieved.

The water electrolysis device 100 does not need to be provided with a container for containing electrolytic liquid, the whole water electrolysis device 100 is only needed to be placed in the container to be cleaned, the shell 10 of the water electrolysis device 100 is provided with a containing cavity and a liquid inlet 10a communicated with the containing cavity, the electrode plate assembly 20 contained in the containing cavity of the shell 10 is used for electrolyzing liquid entering the containing cavity from the liquid inlet 10a to generate micro bubbles and strong oxidizing substances, and the gas with the cleaning function is discharged from the liquid inlet 10a, so that the washing effect is greatly enhanced, the cleaning, the sterilization and the pesticide residue removal are realized, meanwhile, water can be saved, and the cleaning is easier and cleaner. Compared with an electrolysis device with a water tank, the electrolysis device 100 is large in size, is only suitable for being used at a fixed position, is inconvenient to take and occupies a large position, is convenient to carry, use and place, is not limited to a container and a use place, can reduce the size of the electrolysis device 100, and reduces the production process and the cost of the electrolysis device 100.

Referring to fig. 1 to 5, in an embodiment, the water electrolysis apparatus 100 further includes:

and a power supply assembly 30 accommodated in the housing 10, the power supply assembly 30 being electrically connected to the electrode pad assembly 20 for supplying an operating voltage to the electrode pad assembly 20.

In this embodiment, the power supply assembly 30 may be electrically connected to the electrode sheet assembly 20 through a wire, an FPC, or the like, and supplies power to the electrode sheet assembly 20 when the electrode sheet assembly 20 operates. The power supply assembly 30 can control the power of the motor sheet assembly by controlling the voltage, the current magnitude, the power supply duration and the like of the power supply for the electrode sheet assembly 20, and meanwhile, different cleaning working modes can be realized, for example, according to the difference of food materials, the required cleaning duration and the cleaning frequency are different, and the embodiment can set a fruit and vegetable cleaning mode, a fish cleaning mode, a shellfish cleaning mode and the like according to the requirements of practical application. The power supply assembly 30 can also be provided with a wireless communication module capable of realizing wireless signal transmission and reception, such as a bluetooth module and a WIFI module, and the wireless communication module can ensure that the water electrolysis device 100 performs data interaction with an external terminal, a purification device, the intelligent faucet 200 and the like, so as to realize wireless control of the water electrolysis device 100.

Referring to fig. 2 to 5, in an embodiment, the power supply assembly 30 includes:

an energy storage device 31;

the electronic control board 32 is provided with a control module 33 and a charging circuit 34, the control module 33 is electrically connected with the charging circuit 34, and the control module 33 is also electrically connected with the energy storage device 31; the control module 33 is configured to control the charging circuit 34 to operate, so as to convert the received electric energy into electric energy and store the electric energy in the energy storage device 31.

In this embodiment, the energy storage device 31 may be a rechargeable battery, a disposable dry battery, or other devices capable of storing energy. The control module 33 can be wirelessly connected to an external terminal, such as a mobile phone, a remote controller, or a water purifier, and the control module 33 can control the operation of the electrode plate assembly 20 according to a control command output by the external terminal. The charging circuit 34 may be a wired charging circuit 34, a wireless charging circuit 34, or both the wired charging circuit 34 and the wireless charging circuit 34. When setting up to wired charging circuit 34, can also be provided with the interface that charges on casing 10, for example USB charges interface, Type-C charge interface etc. and charge the power that the interface can pass through the charger and insert to export the power to charging circuit 34, charging circuit 34 will insert the power and carry out power conversion, for example DC-DC conversion, store the electric energy to energy storage device 31 after filtering processing etc.. The wireless charging circuit 34 may be provided with a wireless receiving coil, a rectifying circuit, a filter circuit, and the like. Correspondingly, a charging seat for charging the water electrolysis device 100 can be further provided, the shape and size of the charging seat are matched with the size of the shell 10 of the water electrolysis device 100, a wireless transmitting coil is arranged in the charging seat, electric energy is transmitted to the wireless receiving coil after resonance is generated between the wireless transmitting coil and the wireless receiving coil, and the received alternating current is rectified, filtered and the like through a rectifying circuit and a filtering circuit and then is stored in the energy storage device 31. The utility model can select a wireless charging mode to charge the water electrolysis device 100, can save the complex operation of connecting by using a connecting wire, and can avoid electric leakage because a charging interface is not required to be arranged, thereby leading the water electrolysis device 100 to be more convenient and safer to use.

Energy storage device 31 can save certain electric quantity for water electrolysis device 100 also can use under the condition of external power not, also when the user removes the incomplete sterilization of farming like vegetables melon and fruit in the object that needs to be in containers such as basin, only need place water electrolysis device 100 in the container that holds liquid and treat clean object, thereby carry out the electrolysis to the liquid in the container. Thus, the water electrolysis apparatus 100 can be turned on without an external power source.

The control module 33 further includes a main controller 331, a charge-discharge management circuit 332, and a constant current circuit 333, the main controller 331 is electrically connected to the controlled terminal of the charge-discharge management circuit 332, the output terminal of the main controller 331 is further connected to the input terminal of the constant current circuit 333, and the output terminal of the constant current circuit 333 is electrically connected to the electrode plate assembly 20.

In this embodiment, the main controller 331 may be a microprocessor such as a DSP, a single chip, an FPGA, etc., and the main controller 331 is a control center of the water electrolysis apparatus 100, and is connected to each part of the whole water electrolysis apparatus 100 by using various interfaces and lines, and executes various functions and processing data of the water electrolysis apparatus 100 by operating software programs and/or modules stored therein and calling data stored therein, thereby integrally monitoring the water electrolysis apparatus 100. The charge and discharge management circuit 332 may control the charge and discharge of the energy storage device 31, and the charge and discharge management circuit 332 may be implemented by a power management chip. The constant current circuit 333 may be formed by discrete devices such as a triode, a comparator, a resistor, a voltage regulator tube, and the like, and the current output to the electrode plate assembly 20 is processed by the constant current circuit 333 and then becomes constant power supply. The main controller 331 may control and adjust the magnitude of the voltage output to the electrode pad assembly 20, the time, frequency, etc. of outputting the electric energy of the electrode pad assembly 20 according to the operation mode selected by the user, so as to respond to the control instruction of the user.

Referring to fig. 5, in an embodiment, the control module 33 further includes a voltage detection circuit 334, the voltage detection circuit 334 has two detection terminals, one of the two detection terminals is electrically connected with the first electrode piece 21, and the other of the two detection terminals is electrically connected with the second electrode piece 22; and a voltage detection circuit 334 for detecting the voltage value between the first electrode sheet 21 and the second electrode sheet 22.

In this embodiment, the voltage detection circuit 334 may use a detection circuit formed by a resistor, a voltage sensor, and the like to detect voltages at two ends of the first electrode sheet 21 and the second electrode sheet 22, and output a detected voltage value to the main controller 331, so that the main controller 331 performs corresponding control according to the received voltage value. For example, when it is determined that the dirt present on the first electrode sheet 21 and the second electrode sheet 22 is greater than the second preset dirt value according to the detected voltage value, the main controller 331 may control the charge and discharge management circuit 332 to stop supplying power to the electrode sheet assembly 20. Or, when determining that the dirt of the first electrode sheet 21 and the second electrode sheet 22 is larger than the second preset dirt value, controlling the constant current circuit 333 to reverse the polarity of the voltage output to the first electrode sheet 21 and the second electrode sheet 22, so as to automatically clean the electrode sheet assembly 20.

Referring to fig. 2 to 4, in an embodiment, a middle shell 40 is further disposed in the housing 10, and is disposed on a side of the electrode plate assembly 20 facing away from the liquid inlet 10 a;

the middle case 40 serves to block a physical space between the power supply module 30 and the electrode pad module 20.

In this embodiment, the middle case 40 is equivalent to an electric control box, and can separate the power supply assembly 30 from the electrode plate assembly 20, form an accommodating space for the power supply assembly 30, and fix the electric control board 32 and the energy storage device 31. It will be appreciated that the electrode pad assembly 20 needs to be in contact with a liquid, such as tap water, purified drinking water, etc., for electrolysis, and the power supply assembly 30 is electrically connected to the electrode pad assembly 20. In order to prevent the liquid from the liquid inlet 10a from entering the power supply module 30 and ensure the safe operation of the electronic control module, a middle shell 40 is further installed in the housing 10, and the middle shell 40 can isolate the electronic control module from the liquid inlet 10 a.

Referring to fig. 2 to 4, in an embodiment, a supporting plate 50 is further disposed in the housing 10, the supporting plate 50 separates the middle shell 40 to form a first mounting groove 40a, and a second mounting groove 40b, the electric control plate 32 is received in the first mounting groove 40a, and the energy storage device 31 is received in the second mounting groove 40 b.

In the present embodiment, the support plate 50 partitions the middle case 40 to form a first mounting groove 40a for mounting the electric control board 32 and a second mounting groove 40b for mounting the energy storage device 31, and the volumes of the first mounting groove 40a and the second mounting groove 40b may be set according to the volumes of the electric control board 32 and the energy storage device 31. In a further embodiment, the supporting plate 50 is further provided with supporting ribs for supporting the electronic control board 32, so as to prevent the electronic control board 32 from directly contacting the supporting plate 50, and increase the heat dissipation space of the electronic components on the supporting plate 50, so as to improve the heat dissipation effect of the electronic control board 32. Meanwhile, when the electric control board 32 is a double-sided board, the stress surface of the electronic element on the electric control board 32 can be reduced, and the electronic element on the electric control board 32 is prevented from being damaged in the carrying or using process. It is understood that the supporting plate 50 and the electric control board 32 can be fixed by screws, snaps, etc. to prevent the electric control board 32 from moving relatively in the middle case 40 to damage the electronic components on the electric control board 32.

The supporting plate 50 and the middle shell 40 can be integrally formed, or the supporting plate 50 and the middle shell 40 can be detachably connected, when the supporting plate 50 and the middle shell 40 are integrally formed, a mold can be firstly molded, and then the supporting plate 50 and the middle shell 40 are injected into the mold to form the integral structure of the supporting plate 50 and the middle shell 40. When the support plate 50 and the middle shell 40 are separately arranged, the periphery of the inner wall surface of the middle shell 40 can be further provided with convex ribs, and the support plate 50 is fixedly arranged at a corresponding position in the middle shell 40 through the convex ribs. The supporting plate 50 and the middle shell 40 may be made of a relatively light material such as plastic, or a material with a relatively good heat dissipation effect such as aluminum or aluminum alloy, and the supporting plate 50 and the middle shell 40 may be configured to have a non-conductive structure according to safety regulations. The inner wall surface of the middle shell 40 is also provided with a fixing protrusion, the electric control board 32 is fixed by the matching arrangement of the support board 50 and the fixing protrusion, and the relative movement between the electric control board 32 and the middle shell 40 can be avoided.

Referring to fig. 2 to 4, in one embodiment, the water electrolysis apparatus 100 is further provided with a fixing plate 60 fixedly mounted to one side of the housing 10 along a length direction thereof;

the charging circuit 34 is a wireless charging circuit 34, and a wireless receiving coil of the wireless charging circuit 34 is fixedly mounted on the fixing plate 60.

In this embodiment, the fixing plate 60 is used to fix a wireless receiving coil of the wireless charging circuit 34, and the wireless receiving coil may be wound on the fixing plate 60, or fixed on the fixing plate 60 by glue, a buckle, or the like. The fixing plate 60 may be fixed on the housing 10 by a snap-fit connection provided on the housing 10, and an end cap 14 may be further provided on a side of the wireless receiving coil away from the housing 10, so that the wireless receiving coil is sealed into the housing 10 through the end cap 14. The end cover 14 is fastened on the casing 10, and the end cover and the casing 10 are tightly matched to form a sealing structure, so that external hazards such as dust, water, mosquitoes and the like can be prevented from falling onto the wireless receiving coil, and the safe operation of the wireless charging circuit 34 is guaranteed. The size and shape of the end cap 14 is adapted to the size and shape of the housing 10, and may be square, but is not limited to square. Further, a sealing ring, i.e., a sealing gasket, is disposed between the housing 10 and the end cap 14 to seal the wireless receiving coil by isolating the wireless receiving coil from the outside.

Referring to fig. 2 to 4, in one embodiment, the water electrolysis apparatus 100 is further provided with a display panel 70 fixedly mounted on the middle case 40.

In this embodiment, the display panel 70 is provided with a display lamp, the display lamp may be implemented by an LED lamp or other light emitting devices, the number of the display lamps may be one or multiple, and when the number of the display lamps is one, the operating state of the water electrolysis apparatus 100 may be displayed according to the flashing condition of the LED lamp, for example, the normal lighting indicates that the water electrolysis apparatus 100 is normally operated, and the flashing times indicate that the water electrolysis apparatus 100 is operated in different operating modes. When a plurality of the display units are provided, the operating state of the electrolytic water device 100 can be displayed with different color representations.

Referring to fig. 2 to 4, in an embodiment, the housing 10 further includes a through hole (not shown) corresponding to the display panel 70, the display panel 70 further includes a key 71, the key 71 extends out of the housing 10 through the through hole, and the key 71 is electrically connected to the control module 33; wherein the content of the first and second substances,

when the key 71 is triggered by a user, outputting a corresponding key instruction;

the control module 33 receives the key instruction, and controls the electrode sheet assembly 20 to operate in the working mode corresponding to the key instruction when determining that the current key instruction is the selected working mode according to the key instruction.

In this embodiment, the button 71 and the display lamp can be configured as an independent component, for example, the display lamp is embedded on the button 71, one end of the button 71 is fixed on the display panel 70, and the other end extends from the display panel 70 to the outside of the housing 10 through the through hole, so as to be touched by a user. The water electrolysis device 100 is further provided with a sealing cover, the sealing cover and the display panel 70 form a closed space, the key 71 and the display lamp are accommodated in the closed space, and the influence on the normal use of the key 71 and the display lamp caused by the falling of external hazards such as dust, water, mosquitoes and the like on the key 71 and the display lamp can be prevented.

When the key 71 is triggered by a user, a corresponding key instruction is output, and the user can input different key instructions through the times of keying 71, the duration of keying 71 and the like. The corresponding food varieties are different, the cleaning force requirements are different, for example, a fruit and vegetable cleaning mode, a fish cleaning mode, a shellfish cleaning mode and the like can be set, and the corresponding electrolysis time, electrolysis force, electrolysis frequency and the like are different. The key commands can be that the key 71 is pressed 1 time to indicate that the user selects the fruit and vegetable cleaning mode, the key 7 is pressed 12 times to indicate that the user selects the meat cleaning mode, and the key 7 is pressed 13 times to indicate that the user selects the shellfish cleaning mode. Or, pressing for 2 seconds for a short time indicates that the user selects the fruit and vegetable cleaning mode, pressing for 5 seconds for a long time indicates that the user selects the meat cleaning mode, and pressing for 10 seconds for a long time indicates that the user selects the shellfish cleaning mode. The electric control assembly responds to a key instruction selected and input by a user, and executes a corresponding cleaning program after selecting a corresponding working mode.

Referring to fig. 2 to 4, in an embodiment, the water electrolysis apparatus 100 further includes:

the weight block 80 is accommodated in the housing 10, and the weight block 80 is disposed at a side away from the liquid inlet 10 a.

In this embodiment, balancing weight 80 and inlet 10a set up in the both sides of casing 10 relatively, when electrolytic water device 100 was placed in the container that holds liquid, under balancing weight 80's effect, make the whole sinking to the container bottom that can be better of electrolytic water device 100, thereby make the inflow that liquid can be better to inlet 10a, and take place the electrolytic reaction with electrode slice subassembly 20, produce and increase a large amount of microbubbles, it has a large amount of hydroxyl ions that have strong oxidizing property and has reductive hydrogen ion to decompose water into, improve electrode slice subassembly 20's electrolysis effect.

Referring to fig. 2 to 4, in an embodiment, the electrode sheet assembly 20 includes:

at least two electrode plates, wherein at least one electrode plate is a cathode electrode plate 21, and at least one electrode plate is an anode electrode plate 22;

the cathode electrode sheet 21 and the anode electrode sheet 22 are separated by a separator 23. In this embodiment, the cathode electrode tab 21 may be referred to as a first electrode tab 21, and the anode electrode tab 22 may be referred to as a second electrode tab 22, the anode electrode tab and the cathode electrode tab being spaced apart from each other within the casing 10. The anode electrode plate is connected with the anode of the power supply output end of the power supply assembly 30 through a conductive piece, the cathode electrode plate is connected with the cathode of the power supply output end of the power supply assembly 30 through a conductive piece, when water liquid is accumulated in the shell 10, the anode electrode plate and the cathode electrode plate are immersed in the water, hydrogen radicals (H +) and hydroxyl radicals (OH-) generated by electrolytic reaction respectively generate reduction reaction and oxidation reaction on the working surfaces of the anode electrode plate and the cathode electrode plate when the anode electrode plate and the cathode electrode plate generate electrolytic reaction with the water, a large amount of micro bubbles (hydrogen and oxygen) containing oxygen and hydrogen are generated, the bubbles rise through the liquid inlet 10a and enter the container, and when the water with the micro bubbles is used for cleaning, due to the micro physical property and the surface tension effect of the micro bubbles, the adhesion of impurities can be broken, so that the impurities can fall off from the surface of an object more easily. In addition, as the micro bubbles collide with each other, break and fuse with each other, impact is formed on the surface of the object, and impurities fall off and are washed away or float to the water surface under the driving of the bubbles, so that a more thorough cleaning effect is achieved. The anode electrode plate and the cathode electrode plate can decompose water into a large number of hydroxide ions with strong oxidizing property and hydrogen ions with reducing property in the process of electrolyzing water, the pesticide and bacteria on the surface of the food material are heavily surrounded by the hydroxide ions depending on bubbles, meanwhile, the pesticide and the hydrogen ions on the cell walls of the bacteria are removed by the hydroxide ions to be destroyed, and finally, the effects of sterilizing and removing pesticide residues are achieved.

The anode electrode plate and the cathode electrode plate are separated by a spacer 23, so that a certain distance is kept between the anode electrode plate and the cathode electrode plate, and the anode electrode plate and the cathode electrode plate can be adjusted as required.

It should be noted that, in the above embodiments, the substrate of the electrode sheet may be titanium, and the ruthenium iridium oxide catalyst layer is plated on the outer layer of the substrate, in practical applications, the substrate may be made of various conductive materials such as graphite, nickel, tungsten, copper, iron, and the like, and the catalyst layer may be made of various metal oxides such as platinum, manganese, zinc, palladium, and the like, which may be selected in practical situations to meet different practical requirements.

The electrode plate in the above embodiment may be a porous electrode plate, and in practical application, a plate-shaped electrode plate, a mesh electrode plate, etc. may also be adopted, and the mesh electrode plate has various hole structures such as circular holes, rhombic holes, quadrilateral holes, triangular holes, etc., and different electrode plate structure forms may be selected according to actual needs.

Referring to fig. 2 to 4, in one embodiment, the number of the cathode and anode electrode tabs 21 and 22 is plural;

the anode electrode plate 22 is clamped between every two cathode electrode plates 21;

alternatively, the cathode electrode sheet 21 and the anode electrode sheet 22 are sequentially stacked;

alternatively, one cathode electrode sheet 21 is interposed between every two anode electrode sheets 22.

In this embodiment, when the cathode electrode sheets 21 and the anode electrode sheets 22 are sequentially stacked, a plurality of sets of the first electrode sheets 21 and the second electrode sheets 22 are arranged at intervals in the casing 10, each set of the electrode sheets includes an anode electrode sheet and a cathode electrode sheet which are oppositely arranged, the plurality of sets of the electrode sheets are arranged at equal intervals in the casing 10, for example, the plurality of sets of the electrode sheets are sequentially arranged in parallel along the vertical direction of the electrolysis apparatus, so as to form an arrangement of cathode-anode-cathode-anode … … cathode-anode electrode sheets.

Two adjacent electrode plates (anode electrode plates and cathode electrode plates) of each group of electrode plates keep a certain distance, of course, a plurality of groups of electrode plates can also be arranged in parallel along the horizontal direction or in other arrangement modes (for example, inclined arrangement in the casing 10, etc.), a plurality of groups of electrode plates can also be arranged in the casing 10 at unequal intervals, the arrangement form and the distance of the electrode plates can be selected according to different practical applications, and the details are not repeated here.

In another embodiment, when one anode electrode sheet 22 is sandwiched between every two cathode electrode sheets 21, the anode electrode sheets may be double-sided coated, that is, both sides of the anode electrode sheet are coated with an electrolytic material, and at this time, one anode electrode sheet and two adjacent cathode electrode sheets may form two sets of electrolytic electrodes, thereby forming a cathode-anode-cathode … … anode-cathode electrode sheet arrangement. Therefore, the utilization rate of the electrode plate can be improved, and the size of the electrode plate assembly 20 can be reduced. The anode electrode plate can be isolated from two adjacent cathode electrode plates through a spacer 23, and the spacer 23 can be made of an insulating material to increase the distance between the anode electrode plate and the cathode electrode plate and improve the electrolysis efficiency, so that the two electrode plates can normally work to generate electrolyzed water for reaction. Alternatively, in another embodiment, one cathode electrode sheet 21 may be sandwiched between every two anode electrode sheets 22, and in this case, the anode-cathode-anode-cathode … … cathode-anode electrode sheets are arranged. In practical applications, the number of the electrode sheets may be an even number, such as 2, 4, 6, 8, etc., and when the number is 2, one of the electrode sheets is the cathode electrode sheet 21, and the other electrode sheet is the anode electrode sheet 22. When 4 or more than 4 pieces of sheets are provided in an even number, half is a cathode and half is an anode, and the cathode electrode sheet and the anode electrode sheet are sequentially stacked. Alternatively, an odd number of sheets such as 3 or 5 sheets may be used, and each anode electrode sheet may be provided so as to be sandwiched between two adjacent cathode electrode sheets 21 in sequence. Alternatively, each cathode electrode sheet 21 may be arranged to be sandwiched between two adjacent anode electrode sheets 22 in turn.

The electrode plate assembly 20 further includes an electrode plate fixing plate 24 and a fastener 25, and the first electrode plate 21 and the second electrode plate 22 are fixed in the housing 10 by the electrode plate fixing plate 24 and the fastener 25. Specifically, an electrical connection fixing portion is extended from one side of the first electrode sheet 21 (in the width direction), an electrical connection fixing portion is extended from one side of the second electrode sheet 22 opposite to the first electrode sheet 21, two opposite sides of the electrode sheet fixing plate 24 are provided with slits, and the electrical connection fixing portions of the first electrode sheet 21 and the second electrode sheet 22 are respectively clamped in the electrode sheet fixing plate 24 and fixedly connected to the housing 10 by a fastening member 25.

A fixing bracket 13 is further disposed in the housing 10, the fixing bracket 13 is used for supporting and fixing the first electrode plate 21 and the second electrode plate 22, and specifically, a fastener 25 may fix the first electrode plate 21 and the second electrode plate 22 on the fixing bracket 13. The other end of the housing 10, which is opposite to the electrically connecting and fixing portion of the first electrode plate 21 and the second electrode plate 22, is further provided with a limiting protrusion, the first electrode plate 21 and the second electrode plate 22 are fixed in the housing 10 through the fixing bracket 13 and the limiting protrusion, and the limiting protrusion is used for preventing the first electrode plate 21 and the second electrode plate 22 from moving relative to the housing 10 in the height direction of the housing 10. A groove is formed between the fixing bracket 13 and the side wall of the casing 10, the electrode plate fixing plate 24 is partially arranged in the groove, and under the action of the electrode plate fixing plate 24 and the groove, the relative movement of the first electrode plate 21 and the second electrode plate 22 with respect to the casing 10 in the length direction of the casing 10 can be limited. The inner wall surface of the housing 10 may be provided with a fixing protrusion at a position corresponding to the electrode pad fixing plate 24, and the fixing protrusion may be used to fix the electrode pad fixing plate 24.

One side of the electrode plate fixing plate 24 in the height direction abuts against the bottom wall of the groove, the other side of the electrode plate fixing plate 24 in the height direction abuts against the inner wall surface of the housing 10, and an isolation space is formed between the electrode plate fixing plate 24, the groove and the housing 10, so that the electric connection fixing part of the first electrode plate 21 and the second electrode plate 22 is isolated from liquid.

The fasteners 25 may be screws 25a, the number of the screws 25a is two, and the two screws 25a fix the first electrode plate 21 and the second electrode plate 22 on the fixing bracket 13, respectively. In some embodiments, the screws 25a may also achieve electrical connection between the first electrode plate 21 and the second electrode plate 22 and the power supply assembly 30, and specifically, two through holes are further provided on the fixing bracket 13, and the two screws 25a for fixing the first electrode plate 21 and the second electrode plate 22 are passed through the through holes correspondingly provided on the fixing bracket 13 to be electrically connected with the power supply assembly 30 disposed in the middle shell 40, and are locked by the nuts 25a, so as to achieve fixing the first electrode plate 21 and the second electrode plate 22 and achieving electrical connection with the power supply assembly 30.

Referring to fig. 2 to 4, in an embodiment, the casing 10 includes a bottom shell 11 and an upper cover 12, the bottom shell 11 and the upper cover 12 enclose to form an accommodating cavity, and the upper cover 12 is provided with a liquid inlet grid for liquid to enter.

In this embodiment, establish the inlet grille on the terminal surface of upper cover 12, the inlet grille sets up in inlet department, and the grid can form the filtration pore of align to grid, and a plurality of filtration pores are the matrix and arrange. The liquid inlet grating can enable electrolyte or gas after electrolysis to be diffused upwards through the filter holes more intensively, so that the diffusion speed of the electrolyte can be increased, and gas trapping is reduced. The filtering holes can be rectangular, rhombic, circular or in any shape, so that electrolyte or gas can be more concentrated, and the diffusion area of the filtering holes arranged in a matrix manner is increased, so that the electrolyte or gas can be smoothly diffused outwards after passing through the filtering holes, and the purification of foods such as fruits and vegetables is accelerated. In addition, the filtering holes can be used for separating sundries of the cleaned fruits and vegetables, so that the sundries are prevented from entering the shell 10, ions generated by the water electrolysis device 100 are prevented from flowing uniformly, and the cleaning efficiency is improved. The rhombic matrix type filtering holes can be quickly contacted and fused with water, the electrolysis volatilization work of a deep water area from bottom to top is started, and high-activity substances are quickly lifted and diffused to the whole water container, so that the effect of omnibearing full-water-area purification coverage is achieved. At the bottom shell 11 and the two ends of the upper cover 12, water chutes are formed, and by arranging the water chutes, water flow at the periphery of the cavity enters the accommodating cavity through the water chutes at the side (at the same side of the display panel 70 and the end cover 14) so as to continuously supplement the water flow entering the water chutes and form a circulating channel with rising air flow, thereby being beneficial to improving the reaction speed of the electrolyzed water, generating more rising air flow containing effective components, and improving the sterilization and disinfection effects. And when the water in the accommodating cavity needs to be completely drained, the water can be drained through the water chute type water, and cannot be accumulated in the accommodating cavity.

Referring to fig. 2 to 4, in an embodiment, the upper cover 12 and the bottom case 11 are detachably coupled.

In this embodiment, the upper cover 12 and the bottom case 11 may be rotatably connected or slidably connected, and one end of the upper cover 12 may be fixed on the bottom case 11, or the upper cover 12 may be removed from the bottom case 11 when the upper cover 12 and the bottom case 11 are slidably connected. Can dismantle between upper cover 12 and the drain pan 11 for the user can wash, change the electrode slice, perhaps overhauls automatically controlled subassembly etc.. In order to fix the upper cover 12 and the bottom case 11, a latch and a sliding slot are further disposed on the bottom case 11, when the upper cover 12 is covered on the opening of the bottom case 11, the bottom case 11 is covered through the sliding slot, and the upper cover 12 is fixed through the latch, so that relative movement between the upper cover 12 and the bottom case 11 is prevented.

In some embodiments, a limiting flange may be further disposed on the inner sidewall of the upper cover 12, and the limiting flange abuts against the electrode plate assembly 20, and the relative movement between the electrode plate assembly 20 and the bottom case 11 may be further limited by the limiting flange. The upper cover 12 of the present embodiment can be detached from the bottom case 11 by a sliding cover, and after detaching the upper cover 12, the impurities attached to the surface of the electrode plate can be effectively cleaned.

The utility model also provides a purifying device which comprises the water electrolysis device 100.

Referring to fig. 6 to 8, the purification apparatus includes the above electrolytic water device 100. The detailed structure of the water electrolysis device 100 can refer to the above embodiments, and is not described herein; it can be understood that, because the water electrolysis device 100 is used in the purification apparatus of the present invention, the embodiment of the purification apparatus of the present invention includes all technical solutions of all embodiments of the water electrolysis device 100, and the achieved technical effects are also completely the same, and are not described herein again. Wherein, the purifying equipment can be a water dispenser, a water purifier and the like.

Referring to fig. 6 to 8, in an embodiment, the purification apparatus further includes a water tap 200, and the electrolyzed water apparatus 100 is detachably electrically connected thereto.

In this embodiment, the faucet 200 includes a faucet housing 210, a water outlet portion 230, a valve 240, and an electric control portion 250. The valve 240 may manually control the valve 240, so that when the user opens the valve 240, the purifying apparatus body outputs purified water from the water outlet part 230. The number of the manual valves 240 may be two, and the two manual valves may be respectively used to control cold water or hot water, and may also be used to control water with different purification degrees, for example, one manual valve may be used to control domestic water, and the other manual valve may be used to control drinking water. The electric control part 250 is provided with a wireless communication module, such as a bluetooth module, a WIFI module, an infrared module, etc. Correspondingly, wireless communication modules such as a Bluetooth module, a WIFI module and an infrared module are also arranged in the water electrolysis device 100, and the water faucet 200 and the water electrolysis device 100 can communicate information in a wireless signal transmission mode. For example, whether the water electrolysis device 100 is on-line or not is displayed according to the relative distance between the water tap 200 and the water electrolysis device 100, and specifically, if the container for placing the water electrolysis device 100 is far away from the water tap 200 and the wireless signal is difficult to connect, a corresponding prompt is displayed on the display screen of the water tap 200. For example, showing "the water electrolysis apparatus 100 is in an off-line operation mode". In the off-line operation mode, there is no signal interaction between the water electrolysis apparatus 100 and the water tap 200. The faucet 200 can also be wirelessly connected with a purifying device body and a mobile terminal, such as a mobile phone, a remote controller, etc., and a user can control the valve 240 of the faucet 200 to open or close in a wireless remote control manner. An internet of things system can be further established among the water faucet 200, the mobile terminal, the purifying equipment cup body and the water electrolysis device 100, and a user can control the other end or multiple ends by controlling any one end in the internet of things system so as to control the water electrolysis device 100 and realize the operation convenience of the water electrolysis device 100. At the tip of tap shell 210, be provided with the storage tank that supplies to be placed by water electrolysis device 100, the protruding installation department with this storage tank adaptation that is equipped with of tip that supplies water electrolysis device 100 that corresponds, when water electrolysis device 100 was out of work, can correspond the installation department of supplying water electrolysis device 100 with the storage tank on the tap, and place water electrolysis device 100 on tap 200, facilitate the use and put in order.

Referring to fig. 6 to 8, in one embodiment, a wireless charging device is disposed in the faucet 200, and a wireless connection is disposed between the water electrolysis devices 100.

In this embodiment, a charging device for supplying power to the electrolytic water device 100 is provided in the electric control portion 250 of the water faucet 200, and the charging device may be a wired charging device or a wireless charging device, and when the wired charging device is provided, the wired charging device may be provided with a DC-DC circuit, a power management circuit, and a charging interface, which may be a dedicated charging interface, a USB interface, a Type-C interface, or the like. When the wireless charging device is arranged, the top end of the water faucet 200 is provided with a wireless charging module transmitting end, and the lower end of the water electrolysis device 100 is provided with a wireless charging module receiving end. The wireless charging device includes a wireless transmission circuit, such as a resonant capacitor, a wireless transmission coil, an inverter circuit, a control chip, and the like. The resonance circuit composed of the wireless transmitting coil and the resonance capacitor and the resonance circuit composed of the wireless receiving coil, the resonance capacitor and the like arranged in the wireless charging circuit 34 in the water electrolysis device 100 resonate with each other, so that the electric energy of the water tap 200 is transmitted to the water electrolysis device 100 to supply power to the water electrolysis device 100. In practical application, the groove of the faucet 200 can be set as a wireless charging base, and the wireless charging transmitting circuit part can be accommodated in the base; under the mode of charging the water electrolysis device 100, the base can provide 12V charging voltage for the water electrolysis device 100 through the power adapter, the wireless charging transmitting circuit in the base converts the electric signal into the magnetic signal, the wireless charging receiving circuit in the water electrolysis device 100 receives the magnetic signal at the moment and converts the magnetic signal into the electric signal, the electric signal reaches the energy storage device 31 after passing through the charging and discharging management circuit 332, and the charging and discharging management circuit 332 stops supplying power to the battery after detecting that the energy storage device 31 is fully charged, so as to stop charging the battery. The water electrolysis apparatus 100 can display the water by the display lamp when charging, for example, when charging, the light of the display lamp is set to be in a red flashing state, and after the water electrolysis apparatus is fully charged, the light of the display lamp is in a green normally-on state. The charging voltage of the base of the faucet 200 can be adjusted by a program and related components, and the voltage input to the base during charging can also be 5V.

Referring to fig. 6 to 8, in an embodiment, the housing 210 of the faucet 200 is further provided with a user input assembly 260, which is connected to the power supply assembly 30 in a wireless communication manner;

when triggered by a user, the user input assembly 250 outputs a corresponding control signal to the electronic control assembly 30, so that the electronic control assembly 30 in the water electrolysis device 100 controls the electrode plate assembly 20 and the like to work, and wireless control of the water electrolysis device 100 is realized.

In this embodiment, the user input component 260 may be a touch panel, a key 71, or the like, the touch panel, the key 71, or the like may be disposed on the housing 10, the touch panel, the key 71, or the like is electrically connected to the electric control portion 250, and when the user needs to use the water electrolysis apparatus 100, the user may output a control instruction, such as control of starting, ending, and selecting a function mode of the water electrolysis apparatus 100, by disposing the touch panel, the key 71, or the like on the housing 10. The touch pad can also be a touch display screen, the function of the water electrolysis device 100 can be controlled on the touch display screen of the water tap 200, and the working state of the water electrolysis device 100 can be displayed at the same time, so that the operation is simple and convenient, and the operation is clear at a glance. Thus, the wireless control of the water electrolysis device 100 can be realized through the water tap 200, and when the water electrolysis device 100 is used, a user can firstly place the water electrolysis device 100 in a water tank and then click and start the water electrolysis device 100 on a touch screen on the water tap 200 to work. A plurality of electrolysis modes can be selected on the display screen of the water faucet 200, and the selection control can be carried out on the touch screen of the water faucet 200 in a wireless signal control mode, such as a fruit and vegetable cleaning mode, a fish cleaning mode and a shellfish cleaning mode. The vegetable cleaning mode can be selected on the display screen of the water faucet 200 when the fruits and the vegetables are cleaned, the fish cleaning mode can be selected on the display screen of the water faucet 200 when the fish is cleaned, and the shellfish cleaning mode can be selected on the display screen of the water faucet 200 when the shellfish is cleaned. When the water electrolysis device 100 works, the indicator lamp on the top button 71 is on and flickers. The working time of each working mode is different, a timer can be further arranged in the water electrolysis device 100 and/or the water faucet 200, when the water electrolysis device 100 works, the remaining electrolysis time duration can be displayed on a display screen of the water faucet 200, for example, counting down can be performed, after the work is finished, namely after the work of each functional mode is finished, the water electrolysis device 100 automatically stops working, the top indicator light is turned off, meanwhile, the display screen of the water faucet 200 can also display that the work of the water electrolysis device 100 is finished, and when the water faucet 200 or the water electrolysis device 100 is provided with a loudspeaker, a user can be reminded through voice broadcast.

The above description is only an alternative embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (16)

1. An electrolytic water device, characterized in that it comprises:

the shell is provided with an accommodating cavity and a liquid inlet communicated with the accommodating cavity; and the number of the first and second groups,

the electrode slice assembly is accommodated in the accommodating cavity and is used for electrolyzing liquid in the accommodating cavity;

the water electrolysis apparatus further comprises:

the power supply assembly is contained in the shell and is electrically connected with the electrode plate assembly so as to provide working voltage for the electrode plate assembly, and the power supply assembly comprises an energy storage device.

2. The water electrolysis device of claim 1, wherein said power supply assembly comprises:

the energy storage device comprises an electric control board, wherein a control module and a charging circuit are arranged on the electric control board, and the control module is electrically connected with the charging circuit and the energy storage device respectively; the control module is used for controlling the charging circuit to store the received electric energy to the energy storage device.

3. The water electrolysis device according to claim 2, wherein a middle shell is further arranged in the shell, and the middle shell is arranged on one side of the electrode plate assembly, which faces away from the liquid inlet;

the power supply assembly is isolated from the electrode pad assembly by the middle shell.

4. The water electrolysis device according to claim 3, wherein a support plate is further disposed in the housing, the support plate separates the middle housing into a first mounting groove and a second mounting groove, the electric control plate is disposed in the first mounting groove, and the energy storage device is mounted in the second mounting groove.

5. The apparatus of claim 4, further comprising a fixing plate fixedly mounted to one side of said housing along a length thereof;

the charging circuit is a wireless charging circuit, and a wireless receiving coil of the wireless charging circuit is arranged on the fixing plate.

6. The water electrolysis device according to claim 4, further provided with a display panel fixedly mounted on said middle case.

7. The water electrolysis device according to claim 6, wherein the housing further comprises a through hole corresponding to the display panel, the display panel further comprises a key, the key extends out of the housing through the through hole, and the key is electrically connected to the control module; wherein the content of the first and second substances,

when the key is triggered by a user, outputting a corresponding key instruction;

the control module is used for receiving a key instruction and controlling the electrode plate assembly to work in a working mode corresponding to the key instruction when the current key instruction is determined to be the selected working mode according to the key instruction.

8. The electrolytic water device of claim 6, further comprising:

the balancing weight is arranged on one side, far away from the liquid inlet, in the shell.

9. The electrolytic water device of any one of claims 1 to 8, wherein the electrode tab assembly comprises:

at least two electrode plates, wherein at least one electrode plate is a cathode electrode plate, and at least one electrode plate is an anode electrode plate;

the cathode electrode plate and the anode electrode plate are separated by a spacer.

10. The water electrolysis apparatus according to claim 9, wherein the number of said cathode and anode electrode tabs is plural;

the anode electrode plate is clamped between every two cathode electrode plates;

or the cathode electrode plate and the anode electrode plate are sequentially stacked;

or one cathode electrode plate is clamped between every two anode electrode plates.

11. The water electrolysis device according to any one of claims 1 to 8, wherein the housing comprises a bottom shell and an upper cover, the bottom shell and the upper cover enclose to form an accommodating cavity, and the upper cover is provided with a liquid inlet grid for liquid to enter.

12. The water electrolysis apparatus of claim 11, wherein said upper cover is removably connected to said base.

13. A purification apparatus comprising the electrolytic water device according to any one of claims 1 to 12.

14. The purification apparatus of claim 13, further comprising a water tap, wherein the water tap is removably electrically connected to the electrolyzed water device.

15. The purification apparatus of claim 14, wherein a wireless charging device is disposed within the faucet, the wireless charging device being in wireless electrical connection with a wireless charging circuit disposed within the electrolysis device.

16. The purification apparatus of claim 15, wherein a user input assembly is further provided on the housing of the faucet, the user input assembly being wirelessly connected to the power supply assembly of the electrolysis device;

when the user input assembly is triggered by a user, the corresponding control signal is output so as to control the water electrolysis device to work.

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