CN111099701A - Cleaning machine assembly and cleaning machine - Google Patents

Abstract

The embodiment of the application provides a cleaning machine assembly and a cleaning machine. In the embodiment of the application, the utility model provides a can become cleaning machine subassembly of active oxygen water with liquid ionization, and use this cleaning machine subassembly in the cleaning machine, the cleaning machine subassembly has been increased on the liquid circulation route of cleaning machine promptly, this cleaning machine subassembly can become active oxygen water with the liquid ionization that flows through on it, and then usable active oxygen water treats the cleaning object and cleans, and the disinfection of disinfecting of treating the cleaning object is realized to the disinfection of disinfecting of utilizing active oxygen water, need not to use reagent such as antiseptic solution or cleaning solution, and then can reduce the pollution of the sewage of cleaning machine emission to the environment.

Description

Cleaning machine assembly and cleaning machine

Technical Field

The application relates to the technical field of cleaning machines, in particular to a cleaning machine assembly and a cleaning machine.

Background

At present, cleaning equipment is widely applied to daily life by people. People can use cleaning equipment with different functions to complete corresponding cleaning operation, such as washing clothes by using a washing machine, cleaning glasses by using a glasses cleaning machine, cleaning the ground by using a ground cleaning machine and the like.

For these cleaning apparatuses, cleaning and sterilization are mainly performed using a cleaning liquid or a disinfecting liquid at present. However, after the cleaning operation is completed, the cleaning waste liquid is often discharged to a natural environment such as a sewer, which undoubtedly causes environmental pollution.

Disclosure of Invention

Aspects of the application provide a cleaning machine subassembly and cleaning machine for reduce the pollution of the sewage that the washing produced to the environment.

The embodiment of the application provides a cleaning machine subassembly includes: at least one ionizing assembly;

wherein each ionizing assembly comprises: the insulation support is used for electrically insulating the first conducting layer and the second conducting layer;

the at least one ionization component is used for ionizing the liquid flowing through the at least one ionization component to form the active oxygen water.

The embodiment of the present application further provides a cleaning machine assembly, including: the insulating support part is arranged on the first conductive grid and the second conductive grid; the electrical polarity of the first conductive mesh is opposite to the electrical polarity of the second conductive mesh; the projection area of the insulating support member on the horizontal plane is smaller than the projection areas of the first conducting layer and the second conducting layer on the horizontal plane; the first conductive grid and the second conductive grid are used for ionizing liquid flowing through the first conductive grid and the second conductive grid to form active oxygen water.

The embodiment of the present application further provides a cleaning machine, including: the cleaning machine comprises a cleaning machine main body, and a solution barrel, a water diversion device and a nozzle which are arranged on the main body and connected in sequence; liquid in the solution barrel is sent into the nozzle through the water diversion device so that the nozzle sprays the liquid on the object to be cleaned;

the cleaning machine further includes: a washer assembly disposed on the liquid flow path for ionizing the liquid into active oxygen water before the liquid is sprayed to the object to be cleaned by the nozzle to clean the object to be cleaned with the active oxygen water.

In the embodiment of the application, the utility model provides a can become cleaning machine subassembly of active oxygen water with liquid ionization, and use this cleaning machine subassembly in the cleaning machine, the cleaning machine subassembly has been increased on the liquid circulation route of cleaning machine promptly, this cleaning machine subassembly can become active oxygen water with the liquid ionization that flows through on it, and then usable active oxygen water treats the cleaning object and cleans, and the disinfection of disinfecting of treating the cleaning object is realized to the disinfection of disinfecting of utilizing active oxygen water, need not to use reagent such as antiseptic solution or cleaning solution, and then can reduce the pollution of the sewage of cleaning machine emission to the environment.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

FIG. 1a is a schematic diagram of a washer module according to an embodiment of the present disclosure;

fig. 1b is a schematic perspective view of an insulating supporting member according to an embodiment of the present application;

FIG. 1c is a front view of an insulating support according to an embodiment of the present application;

FIG. 1d is a top view of an insulating support according to an embodiment of the present application;

FIG. 2a is a schematic diagram of a cleaning machine according to an embodiment of the present disclosure;

fig. 2b is a partial structural schematic view of a cleaning machine when the cleaning machine assembly is disposed between the solution tank and the water diversion device according to an embodiment of the present disclosure;

FIG. 2c is a schematic view of a portion of a washing machine with a washing machine assembly disposed in a water diversion device according to an embodiment of the present disclosure;

fig. 2d is a partial structural schematic view of a cleaning machine provided in an embodiment of the present application, when the cleaning machine assembly is disposed between the water diversion device and the nozzle;

fig. 3 is a schematic structural diagram of a cleaning machine assembly according to an embodiment of the present disclosure.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be described in detail and completely with reference to the following specific embodiments of the present application and the accompanying drawings. It should be apparent that the described embodiments are only some of the embodiments of the present application, 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 application.

The existing cleaning equipment mainly adopts cleaning solution or disinfectant to carry out cleaning, sterilization and disinfection. However, after the cleaning operation is completed, the cleaning waste liquid is often discharged to a natural environment such as a sewer, which undoubtedly causes environmental pollution. Taking a floor cleaning machine as an example, the cleaning method generally includes mixing cleaning liquid or disinfectant with tap water, spraying the mixture onto the floor by a water pump, sucking water on the floor into a sewage tank by a suction motor, wherein the water in the sewage tank contains the cleaning liquid or the disinfectant, and when the sewage in the sewage tank is discharged into a sewer, the water body is polluted.

Need adopt cleaning solution or antiseptic solution to wash and disinfect and cause the technical problem of pollution to the environment to current cleaning equipment, the embodiment of the application provides a can become the cleaning machine subassembly of active oxygen water with liquid ionization, and use this cleaning machine subassembly in the cleaning machine, the cleaning machine subassembly has been increased on the liquid circulation route in the cleaning machine promptly, this cleaning machine subassembly can become active oxygen water with the liquid ionization that flows through it on, and then the object of treating cleaning is cleaned to usable active oxygen water, and the disinfection of disinfecting of the object of treating is realized to the disinfection of utilizing active oxygen water, need not to use reagent such as antiseptic solution or cleaning solution, and then can reduce the pollution of the sewage of cleaning machine emission to the environment.

The technical solutions provided by the embodiments of the present application are described in detail below with reference to the accompanying drawings.

It should be noted that: like reference numerals refer to like objects in the following figures and embodiments, and thus, once an object is defined in one figure, further discussion thereof is not required in subsequent figures.

An embodiment of the present application provides a cleaning machine subassembly, includes: at least one ionizing assembly. Wherein each ionizing assembly comprises: at least one first conductive layer, at least two second conductive layers of opposite electrical polarity to the first conductive layers, and at least one insulating support; the insulating support is used for electrically insulating the first conducting layer and the second conducting layer. In this way, when the first and second conductive layers are energized, the at least one ionizing assembly may ionize liquid flowing thereover to form oxygenated water.

Optionally, the first conductive layer is a positive electrode, and the second conductive layer is a negative electrode. Or the first conducting layer is a negative electrode, and the second conducting layer is a positive electrode.

Optionally, the insulating support is a hollow structure, and a hole is formed on the insulating support.

Optionally, the first conductive layer and the second conductive layer are regular metal conductive grids. Or the first conducting layer and the second conducting layer are irregular metal conducting grids. Further, the meshes in the first conductive layer and the second conductive layer may be arranged in a staggered manner, regardless of whether the metal conductive meshes are regular or not.

Optionally, a projection area of the insulating support member on a horizontal plane is smaller than a projection area of the first conductive layer and a projection area of the second conductive layer on the horizontal plane.

In addition, based on the above description, the ionizing assembly capable of implementing the ionization function may have a variety of implementation structures, which are not limited in the embodiments of the present application, and several structural forms of the ionizing assembly are listed below:

structure 1: a first conducting layer is arranged between every two second conducting layers, and an insulating support piece is arranged between the first conducting layers and the second conducting layers. In this structure, the number of the second conductive layers is at least two, and the number of the first conductive layers is at least one. If the first conductive layer is an anode and the second conductive layer is a cathode, a structure of three or more layers can be formed in which two cathode conductive layers sandwich one anode conductive layer. If the first conductive layer is a negative electrode and the second conductive layer is a positive electrode, a structure of three or more layers can be formed in which two positive electrode conductive layers sandwich one negative electrode conductive layer. The number of the structural layers depends on the number of the first conductive layers, the second conductive layers and the insulating support pieces.

Structure 2: a second conducting layer is arranged between every two first conducting layers, and an insulating support piece is arranged between the first conducting layers and the second conducting layers. In this structure, the number of the second conductive layers is at least two, and the number of the first conductive layers is at least three. If the first conductive layer is a positive electrode and the second conductive layer is a negative electrode, a structure in which two positive electrode conductive layers sandwich one negative electrode conductive layer can be formed. If the first conductive layer is a negative electrode and the second conductive layer is a positive electrode, a structure in which two negative electrode conductive layers sandwich one positive electrode conductive layer can be formed. The number of the structural layers depends on the number of the first conductive layers, the second conductive layers and the insulating support pieces.

In the above structure, the number of the first conductive layer, the second conductive layer, and the insulating support is not limited. In order to more clearly understand the technical solution of the present application, in the following embodiments, the number of the insulating support members is 2, the number of the first conductive layers is 1, and the number of the second conductive layers is 2. It should be noted that the following description of the three-layer structure shown in fig. 1a can be extended to structures with more than three layers. As shown in fig. 1a, the washer module S10 includes: at least one ionizing assembly 100. Wherein each ionizing assembly 100 comprises: the two insulating supporting members 10a are respectively insulating supporting members 10a1 and 10a2, a first conductive layer 10b1 sandwiched between the two insulating supporting members 10a1 and 10a2, and two second conductive layers 10b2 and 10b3 disposed at both sides of the two insulating supporting members 10a1 and 10a 2. The electrical polarity of the first conductive layer 10b1 is opposite to the electrical polarity of the second conductive layers 10b2 and 10b 3.

Thus, when the first conductive layer 10b1, the second conductive layer 10b2, and 10b3 are energized, the at least one ionizing assembly 100 may ionize liquid flowing thereover to form activated oxygen water.

In this embodiment, the ionizing assembly in the washer module comprises: and the electric polarity of the middle conductive layer is opposite to that of the conductive layers at the two ends, so that when the conductive layers are electrified, the contact area of liquid and the conductive layers is increased, and the ionization efficiency of the liquid flowing through the cleaning machine component is improved. And when the ionized active oxygen water is sprayed on the object to be cleaned, the object to be cleaned can be cleaned by the active oxygen water, and the sterilization and disinfection of the object to be cleaned can be realized by the sterilization and disinfection characteristics of the active oxygen water. Therefore, chemical reagents such as cleaning solution or disinfectant are not needed, and the pollution of sewage generated when objects are cleaned to the environment is reduced.

In an alternative embodiment, taking the structure shown in fig. 1a as an example, the planar extension areas of the two insulating supporting members 10a1 and 10a2, the first conductive layer 10b1, and the second conductive layers 10b2 and 10b3 may be different from each other, or may be the same, which is not limited herein. Preferably, the planar areas of the two insulating supports 10a1 and 10a2 are the same. Further, the planar areas of the first conductive layer 10b1, the second conductive layer 10b2, and 10b3 are the same. To reduce the resistance of the two insulating supports 10a1 and 10a2 against liquid, the projected area of the two insulating supports 10a1 and 10a2 in the horizontal plane is smaller than the projected area of the first conductive layer 10b1, the second conductive layer 10b2, and the second conductive layer 10b3 in the horizontal plane. As another alternative, the projected areas of the two insulating supporting members 10a1 and 10a2, the first conductive layer 10b1, and the second conductive layers 10b2 and 10b3 on the horizontal plane are equal, so that the first conductive layer 10b1, the second conductive layers 10b2, and 10b3 are effectively prevented from contacting each other, and thus, a short circuit between the first conductive layer 10b1, the second conductive layers 10b2, and 10b3 is prevented.

In another alternative embodiment, still taking the structure shown in fig. 1a as an example, the first conductive layer 10b1 is fixed between the two insulating supporting members 10a1 and 10a2 by means of snap or glue dispensing; the second conductive layers 10b2 and 10b3 are fixed on two sides of the two insulating supports 10a1 and 10a2 by means of snap or glue, but not limited thereto. Wherein, fix the conducting layer on insulating support piece through the buckle, can avoid the corruption of liquid to lead to the emergence of the situation such as fixed not hard up appearing. It should be noted that the clips may be insulation clips, metal clips, etc., but are not limited thereto, and in the embodiment of the present application, the number of the clips may be flexibly set according to the size of the insulation supports 10a1 and 10a2, the first conductive layer 10b1, and the second conductive layers 10b2 and 10b3, so as to firmly fix the conductive layers on the insulation supports.

Further, considering that water is ionized to form ozone and is mainly concentrated on the positive electrode conductive layer, in order to further increase the contact area between the liquid and the conductive layer and improve the ionization efficiency of the cleaning machine component on the liquid, the first conductive layer 10b1 can be used as a positive electrode; accordingly, the second conductive layers 10b2 and 10b3 function as negative electrodes.

Further, in order to reduce the resistance to water flow without affecting the throughput of the liquid flowing through the washer module S10, the insulating support 10a may be implemented as a hollow structure having a hole. Among them, the shape of the insulating support 10a can be flexibly set according to the structure in the equipment to which the washer module S10 is applied. Alternatively, the insulating support member may be a hollow structure, and specifically, the insulating support member 10a may be a hollow frame structure, preferably a ring structure or a square structure, and the frame structure is provided with a hole.

Alternatively, the insulating support 10a may also be an integrally formed structure as shown in fig. 1b, wherein the insulating support comprises at least two insulating layers 10a3, shown as 2 insulating layers in fig. 1 b. As shown in fig. 1c, the insulating support 10a of the integrated structure is seen from the front view, the right sides of at least two insulating layers 10a3 are connected, and a certain distance is left between the connected insulating layers of at least two insulating layers 10a3, so that the first conductive layer or the second conductive layer is sandwiched between two adjacent insulating layers. The connection between the conductive layer and the insulating layer can be referred to the above description, and is not described herein again. When the insulating support 10a is an integrally formed structure, the conductive layers are arranged in the same manner as in fig. 1a, i.e. the electric polarities of two adjacent conductive layers are opposite.

Fig. 1d shows a top view of the insulating supporting member 10a with an integrally formed structure, and the structure of the at least two insulating layers 10b3 and the structure of the single insulating supporting member 10a may be configured in the same manner, which is not described herein again. It should be noted that fig. 1b and fig. 1d only illustrate the insulating layer with 4 rectangular holes, but the shape and number of the holes are not limited, and the holes can be flexibly arranged according to actual requirements.

Accordingly, in order to further reduce the resistance of the washer module S10 to water flow, and further increase the contact area of the liquid and the conductive layer, and improve the ionization efficiency of the liquid, the first conductive layer 10b1 and the second conductive layers 10b2 and 10b3 are regular metal conductive grids; the first conductive layer 10b1 and the second conductive layers 10b2, 10b3 are irregular conductive grids of metal. Optionally, the first conductive layer 10b1 and 10b3 in the second conductive layer have different grid shapes than 10b2 in the second conductive layer, which can better improve the ionization efficiency of the liquid. The first conductive layer 10b1 and the second conductive layer 10b3 are regular metal conductive grids, and the second conductive layer 10b2 are irregular metal conductive grids; or the first conductive layer 10b1 and the second conductive layer 10b3 are irregular metal conductive grids, and the second conductive layer 10b2 are regular metal conductive grids. It should be noted that the regular metal conductive grids are formed by continuously and uniformly distributing a single metal conductive grid with the same shape, and the irregular metal conductive grids are formed by continuously and uniformly distributing metal conductive grids with different shapes or non-uniformly distributing metal conductive grids with different shapes. The grid part is hollow, so that liquid can flow through the grid part conveniently, and resistance to water flow can be reduced.

Note that the hollow portions in the first conductive layer 10b1, the second conductive layers 10b2, and 10b3 may have any regular shape such as a rectangle, a square, a diamond, a circle, or a triangle, or may have any irregular shape. In the embodiment of the present invention, the hollowed-out metal conductive grids in the first conductive layer 10b1, the second conductive layer 10b2 and 10b3 are preferably square-shaped.

Alternatively, the grids in the first conductive layer 10b1, the second conductive layer 10b2, and 10b3 may be arranged in a staggered manner or in an aligned manner. The staggered arrangement means that the hollow parts of at least part of the grids on the first conductive layer 10b1, the second conductive layer 10b2 and the second conductive layer 10b3 are staggered with each other. The alignment means that the hollow parts of the corresponding grids of the first conductive layer 10b1, the second conductive layer 10b2 and the second conductive layer 10b3 are aligned with each other. In some embodiments of the present application, the hollowed-out metal conductive grids in the first conductive layer 10b1, the second conductive layer 10b2, and the second conductive layer 10b3 are arranged to be offset from each other.

It should be noted that the shapes, the numbers and the implementation forms of the ionizing assembly in the cleaning machine assembly and the conductive layer and the insulating support in the ionizing assembly provided in fig. 1a of the present embodiment are all exemplary and do not limit the cleaning machine assembly provided in the present application.

In the embodiment of the present application, the washing machine assembly provided in fig. 1a can be applied to washing machines such as floors, walls and ceilings, and various washing devices such as washing machines and dishwashers. The following is an exemplary description in which these cleaning apparatuses are collectively defined as a cleaning machine.

Fig. 2a is a schematic structural diagram of a cleaning machine according to an embodiment of the present application. As shown in fig. 2a, the washer S20 includes: a cleaning machine main body 20, and a solution barrel 21, a water diversion device 22 and a nozzle 23 which are arranged on the main body 20 and connected in sequence; the liquid in the solution tank 21 is sent to the nozzle 23 through the water diversion device 22, and sprayed onto the object to be cleaned by the nozzle 23.

As shown in fig. 2b, the washer S20 further includes: and a washer module 24 disposed on the liquid flow path. The washer module 24 serves to ionize the liquid into the active oxygen water before the liquid is sprayed to the object to be cleaned by the spray nozzle 23, so as to clean the object to be cleaned with the active oxygen water.

In this embodiment, add the cleaning machine subassembly on the liquid circulation route in its upper solution bucket in the cleaning machine, this cleaning machine subassembly can become the active oxygen water with the ionization of the liquid that flows through on it to spray to treating on the cleaning object through the nozzle on the cleaning machine, and utilize the active oxygen water to treat cleaning object and clean, and utilize the disinfection and isolation characteristic realization of the disinfection and isolation of treating cleaning object of active oxygen water, need not to use reagent such as antiseptic solution or cleaning solution, and then can reduce the pollution of the sewage of cleaning machine emission to the environment.

For the structure schematic diagram of the cleaning machine assembly 24 provided in this embodiment, reference can be made to the related description of the cleaning machine assembly in the above embodiment. The washer module 24 includes: at least one ionizing assembly; wherein each ionizing assembly comprises: at least one first conductive layer, at least two second conductive layers of opposite electrical polarity to the first conductive layers, and at least one insulating support; the insulating support is used for electrically insulating the first conducting layer and the second conducting layer.

Thus, when the first conductive layer and the second conductive layer are electrified, the at least one ionization component can ionize liquid flowing through the ionization component to form the active oxygen water. For a detailed description of the washer module 24, reference may be made to the related description of the above embodiments, and the detailed description is omitted here.

Wherein, under the condition that the number of the insulating support members is 2, the number of the first conductive layers is 1, and the number of the second conductive layers is 2, as shown in fig. 1a, each ionizing assembly 100 has a structure comprising: two insulating support members 10a, respectively 10a1 and 10a2, a first conductive layer 10b1 sandwiched between the two insulating support members 10a1 and 10a2, and second conductive layers 10b2 and 10b3 disposed on both sides of the two insulating support members 10a1 and 10a 2. The electrical polarity of the first conductive layer 10b1 is opposite to the electrical polarity of the second conductive layers 10b2 and 10b 3.

In an alternative embodiment, the planar extension areas of the two insulating supporting members 10a1 and 10a2, the first conductive layer 10b1, and the second conductive layers 10b2 and 10b3 may be different from each other or the same, and are not limited herein. Optionally, the two insulating supports 10a1 and 10a2 are equal in area. Further, the planar areas of the first conductive layer 10b1, the second conductive layer 10b2, and 10b3 are the same. To reduce the resistance of the insulating support 10a to liquid, the projected area of the insulating support 10a in the horizontal plane is smaller than the projected areas of the first conductive layer 10b1, the second conductive layer 10b2, and 10b3 in the horizontal plane. Or, alternatively, the projected areas of the two insulating supporting members 10a1 and 10a2 in the horizontal plane and the projected areas of the first conductive layer 10b1 and the second conductive layers 10b2 and 10b3 in the horizontal plane are equal, so that the first conductive layer 10b1 and the second conductive layers 10b2 and 10b3 can be effectively prevented from contacting each other, and further, a short circuit can be prevented from occurring between the first conductive layer 10b1 and the second conductive layers 10b2 and 10b 3.

In another alternative embodiment, when there are 2 insulating supporting members, the first conductive layer 10b1 is fixed between the two insulating supporting members 10a1 and 10a2 by means of snap or glue dispensing; the second conductive layers 10b2 and 10b3 are fixed on two sides of the two insulating supports 10a1 and 10a2 by means of snap or glue, but not limited thereto. Wherein, fix the conducting layer on insulating support piece through the buckle, can avoid the corruption of liquid to lead to the emergence of the situation such as fixed not hard up appearing. It should be noted that the clips may be insulation clips, metal clips, etc., but are not limited thereto, and in the embodiment of the present application, the number of the clips may be flexibly set according to the size of the insulation supports 10a1 and 10a2, the first conductive layer 10b1, and the second conductive layers 10b2 and 10b3, so as to firmly fix the conductive layers on the insulation supports.

Further, considering that water ionization forms ozone mainly concentrated on the positive electrode conductive layer, in order to further increase the ionization efficiency of the washer assembly to liquid, the first conductive layer 10b1 may be used as a positive electrode to be electrically connected with the positive electrode power supply terminal of the cleaner S20; accordingly, the second conductive layers 10b2 and 10b3 serve as negative electrodes to be electrically connected with the negative power supply terminal of the cleaning machine S20.

Further, in order to reduce the resistance to water flow without affecting the throughput of the liquid flowing through the washer module S10, the insulating support 10a may be implemented as a hollow structure having a hole. Among them, the shape of the insulating support 10a can be flexibly set according to the structure in the equipment to which the washer module S10 is applied. Alternatively, the insulating support 10a may be a hollow ring structure, and the ring structure is provided with a hole.

Accordingly, in order to further reduce the resistance of the washer module S10 to water flow and further increase the ionization efficiency of the liquid, the first conductive layer 10b1, the second conductive layers 10b2 and 10b3 are regular metal conductive grids; the first conductive layer 10b1, the second conductive layer 10b2, and 10b3 are irregular conductive grids of metal. Optionally, the first conductive layer 10b1 and 10b3 in the second conductive layer have different grid shapes than 10b2 in the second conductive layer, which can better improve the ionization efficiency of the liquid. The first conductive layer 10b1 and the second conductive layer 10b3 are regular metal conductive grids, and the second conductive layer 10b2 are irregular metal conductive grids; or the first conductive layer 10b1 and the second conductive layer 10b3 are irregular metal conductive grids, and the second conductive layer 10b2 are regular metal conductive grids. It should be noted that the regular metal conductive grids are formed by continuously and uniformly distributing a single metal conductive grid with the same shape, and the irregular metal conductive grids are formed by continuously and uniformly distributing metal conductive grids with different shapes or non-uniformly distributing metal conductive grids with different shapes. The grid part is hollow, so that liquid can flow through the grid part conveniently, and resistance to water flow can be reduced.

Note that the hollow portions in the first conductive layer 10b1, the second conductive layers 10b2, and 10b3 may have any regular shape such as a rectangle, a square, a diamond, a circle, or a triangle, or may have any irregular shape.

Alternatively, the grids in the first conductive layer 10b1, the second conductive layer 10b2, and 10b3 may be arranged in a staggered manner or in an aligned manner. The staggered arrangement means that the hollow parts of at least part of the grids on the first conductive layer 10b1, the second conductive layer 10b2 and the second conductive layer 10b3 are staggered with each other. The alignment means that the hollow portions of the corresponding grids of the first conductive layer 10b1, the second conductive layer 10b2, and the third conductive layer 10b3 are aligned with each other. In some embodiments of the present application, the hollowed-out metal conductive grids in the first conductive layer 10b1, the second conductive layer 10b2, and the third conductive layer 10b3 are arranged in a staggered manner.

With the structure of the washer S20 shown in fig. 2a, the washer module 24 can be disposed at any position of the path through which the liquid in the solution tank 21 flows through the nozzle 23 to be sprayed onto the object to be cleaned, and the disposed position thereof will be exemplified below.

Embodiment 1: as shown in fig. 2b, the washer module 24 may be disposed inside the solution tank 21. Thus, the liquid in the solution tank 21 is ionized into the active oxygen water by the washer module 24, and then is sent to the nozzle 23 through the water diversion device 22. Accordingly, the nozzle 23 is used to spray the active oxygen water onto the object to be cleaned.

Optionally, as shown in fig. 2b, the cleaning machine S20 further includes a receiving cavity 25, which is conventionally called a transfer cavity when the receiving cavity 25 is disposed between the water outlet of the solution barrel 21 and the water diversion device 22, for connecting the solution barrel 21 and the water diversion device 22 excessively, that is, the water outlet of the solution barrel 21 is connected to the receiving cavity 25 and connected to one end of the water diversion device 22 through the receiving cavity 25. Based on this, the washer module 24 may be disposed in the accommodation chamber 25.

Embodiment 2: as shown in fig. 2c, the washer assembly 24 is disposed within the priming device 22. The liquid in the solution barrel 21 flows down into the water diversion device 22 under the guidance of the water diversion device 22, and enters the nozzle 23 after being ionized into the active oxygen water by the cleaning machine assembly 34. Accordingly, the nozzle 23 sprays the active oxygen water onto the object to be cleaned.

Optionally, as shown in fig. 2c, the cleaning machine S20 further includes a receiving cavity 25, the cleaning machine assembly 24 can be disposed in the receiving cavity 25, and the receiving cavity 25 can be disposed on the flow path of the liquid in the solution tank 21. Specifically, for the washer configuration shown in fig. 2c, the receiving chamber 25 is disposed within the water diversion device.

Embodiment 3: as shown in fig. 2d, the washer assembly 24 may be disposed between the water diversion device 22 and the nozzle 23. Thus, the liquid in the solution barrel 21 is sent to the cleaning assembly 24 through the water diversion device 22, ionized into the active oxygen water through the cleaning assembly 24, and then flows into the nozzle 23. Accordingly, the nozzle 23 sprays the active oxygen water onto the object to be cleaned.

Optionally, as shown in fig. 2d, the cleaning machine S20 further includes a receiving cavity 25, the cleaning machine assembly 24 can be disposed in the receiving cavity 25, and the receiving cavity 25 can be disposed on the flow path of the liquid in the solution tank 21. Specifically, the receiving chamber 25 for the washer configuration shown in fig. 2d, the receiving chamber 25 is arranged between the water directing device 22 and the nozzle 23 for connecting the water directing device 22 and the nozzle 23.

It should be noted that in this embodiment, the cleaning object acted by the washing machine S20 is different, and the water diversion device 22 is implemented in a different manner. For example, for a floor cleaning machine, the water diversion device 22 may include a water delivery pipe 22a, and optionally, the liquid in the solution bucket 21 may flow into the water delivery pipe 22a using gravitational force. In addition, in order to increase the flow speed of the water flowing into the water pipe 22a, the water diversion device 22 may further include a water pump 22b, wherein a water inlet of the water pump 22b is connected with a water outlet of the solution bucket 21, a water outlet of the water pump 22b is connected with one end of the water pipe 22a, and the other end of the water pipe 22a is connected with the nozzle 23. Thus, the water pump 22b can pump the liquid in the solution tank 21 into the water pipe 22a, and send the liquid into the nozzle 23 through the water pipe 22 a. For another example, for a wall cleaning machine or a ceiling cleaning machine, it cannot utilize gravity to guide the liquid in the solution tank 21 into the water duct 22a, and the water guiding device 22 may include a water duct 22a and a water pump 22b, wherein the specific connection manner may be referred to the related description of the floor cleaning machine including the water pump and the water duct, and is not described herein again.

Alternatively, in embodiments where the washer assembly 24 is disposed within the water directing device 22, if the water directing device 22 includes a water conduit 22a and a water pump 22b, the washer assembly 24 is disposed within the water conduit 22 a.

In the present embodiment, whichever of the above embodiments 1 to 3 is adopted, as shown in fig. 2a, the washer S20 further includes: a power module 26, a control component 27 and a detection component (not shown in fig. 2 a). Wherein, the control component 27 is respectively connected with the detection component and the power module 26, and the power module 26 is connected with the washing machine component 24. For example, for the washer module shown in FIG. 1a, the positive power supply is electrically connected to first conductive layer 10b1 and the negative power supply is electrically connected to second conductive layers 10b2 and 10b3 in washer module 24. In addition to providing power to the washer assembly 24, the power module 26 is also configured to provide power to the various components of the washer S20. Power module 26 may include a power management system, one or more power supplies, and other components associated with generating, managing, and distributing power for the devices in which the power components are located.

Further, to ensure that as long as there is liquid flowing through the cleaner assembly 24, the cleaner assembly 24 ionizes it to form oxygenated water. Alternatively, in the above embodiments 1 to 3, the detection member may be provided in the solution tank 21. When the detection component detects that liquid flows in the solution barrel 21, the control component 27 controls the power supply module 26 to supply power to the cleaning machine component 24 so as to drive the cleaning machine component 24 to ionize the liquid flowing on the cleaning machine component.

Alternatively, in the above embodiments 2 and 3, a detection component may be disposed in the water diversion device 22 and before the washing machine component 24, so that the liquid in the solution tank 21 passes through the detection component 28 before flowing to the washing machine component 24, and when the detection component detects that there is a liquid flowing, the detection component may trigger the control component 27 to control the power module 26 to supply power to the washing machine component 24, so as to drive the washing machine component 24 to ionize the liquid flowing thereon.

Further, the detection component may be, but is not limited to, a liquid level sensor, a fluid sensor, a liquid flow sensor, and the like.

Further, as shown in fig. 2a, the washing machine S20 may further include a water absorption device 28 and a recycling bin 29. Wherein the water absorption device 28 draws back the sewage on the object to be cleaned into the recovery tank 29.

Further, as shown in fig. 2a, the washing machine S20 further includes a rolling brush 210, a steering wheel 211, and other components. Only some of the components are schematically shown in fig. 2a, and it is not meant that the computer device comprises only the components shown in fig. 2 a.

It should be noted that the structure and implementation form of the cleaning machine provided in fig. 2a-2d of the present embodiment are only exemplary and not limiting.

Fig. 3 is a schematic structural diagram of another cleaning machine assembly S30 according to an embodiment of the present disclosure. As shown in fig. 3, the cleaning machine assembly S30 includes: an insulating support member 30a, a first conductive mesh 30b and a second conductive mesh 30c disposed at both sides of the insulating support member 30 a. Wherein the electrical polarity of the first conductive mesh 30b is opposite to the electrical polarity of the second conductive mesh 30 c.

Optionally, the insulating support 30a is a hollow ring structure, and a hole is formed on the ring structure. The insulating support 30a reduces the resistance to the liquid and improves the ionization efficiency of the washer module for the liquid.

Wherein the first and second conductive grids 30b and 30c are used to ionize the liquid flowing through the first and second conductive grids 30b and 30c to form the active oxygen water.

It should be noted that, in this embodiment, for specific descriptions of the specific implementation and installation manner of the insulating support 30a, the first conductive grid 30b, and the second conductive grid 30c, reference may be made to the related descriptions in the foregoing embodiments, and no further description is given here.

In this embodiment, the first conductive mesh and the second conductive mesh ionize liquid flowing therethrough into active oxygen water, and when the active oxygen water formed by ionization is sprayed onto the object to be cleaned, the object to be cleaned can be cleaned by using the active oxygen water, and the object to be cleaned can be sterilized and disinfected by using the sterilization and disinfection characteristics of the active oxygen water. Therefore, the cleaning object does not need to be cleaned by using chemical reagents such as cleaning solution or disinfectant, and the pollution of sewage generated when the object is cleaned to the environment is reduced.

Accordingly, the cleaning machine assembly S30 provided in fig. 3 can also be installed in the cleaning machine S20 shown in fig. 2a-2d, and the specific implementation thereof can refer to the detailed description of fig. 2a-2d in the above embodiments, and will not be described again here.

The following description will be made in detail with reference to the accompanying drawings, which illustrate the operation of the cleaning machine according to the embodiments of the present application, by taking a washing machine including the washing machine assembly described in the foregoing embodiments as an example.

In a floor cleaning application scenario, the washer assembly described in the foregoing embodiments is disposed between the solution tank and the water diversion device of the floor cleaning machine. When a user cleans the ground by using the ground cleaning machine, the user starts the ground cleaning machine to work after filling clear water into a solution barrel in the ground cleaning machine. The water pump in the ground cleaning machine can pump the clear water in the solution barrel to the transfer cavity, and the cleaning machine assembly in the transfer cavity ionizes the water in the cleaning machine assembly to form the active oxygen water which is pumped into the water delivery pipe by the water pump. The active oxygen water is guided by the water conveying pipe to flow downwards to the spray nozzle, and then the spray nozzle sprays the active oxygen water to the ground. Correspondingly, the bottom of the floor cleaning machine is generally provided with a rolling brush, so that the rolling brush can mop and clean the spraying part of the active oxygen water. The sewage remained on the floor after being mopped can be absorbed into the recycling bin through the absorption device on the floor cleaning machine. In the whole floor cleaning process, the cleaning machine component is used for ionizing clear water into active oxygen water to clean and disinfect the floor instead of using chemical reagents such as disinfectant or cleaning fluid. Thus, even if the sewage in the recovery barrel is discharged into a sewer or the like, the environment is not polluted.

In a laundry application scenario, the washer assembly described in the foregoing embodiments is disposed between a solution tank and a water diversion device of a washing machine. When a user washes clothes by using the washing machine, the user starts the washing machine to work after filling clean water into a solution barrel in the washing machine. The water pump in the washing machine can pump the clean water in the solution barrel to the transfer cavity, the cleaner assembly in the transfer cavity ionizes the water in the transfer cavity to form active oxygen water, and then the active oxygen water is pumped into the water delivery pipe by the water pump. The active oxygen water is guided by the water pipe to flow to the nozzle, and then the nozzle sprays the active oxygen water into the washing bucket. When the liquid level in the washing tub reaches a certain amount, the washing machine starts to rotate to perform washing, spin-drying and other operations on the clothes. The waste water after washing the laundry may be discharged through a drain assembly of the washing machine. In the whole washing process of the clothes, the washing machine component is utilized to ionize the clear water into the active oxygen water to clean and disinfect the clothes, and the like, but chemical reagents such as laundry detergent or washing powder are not used. Thus, even if the sewage after washing the clothes is discharged into a sewer or the like, the environment is not polluted.

In a floor cleaning application scenario, the washer assembly described in the foregoing embodiments is provided in the water diversion device of the floor cleaning machine. When a user cleans the ground by using the ground cleaning machine, the user starts the ground cleaning machine to work after filling clear water into a solution barrel in the ground cleaning machine. The water pump in the ground cleaning machine can pump the clean water in the solution barrel into the water delivery pipe of the water diversion device, and the cleaning machine component in the water delivery pipe ionizes the water in the water delivery pipe to form the active oxygen water. The active oxygen water is guided by the water conveying pipe to flow downwards to the spray nozzle, and then the spray nozzle sprays the active oxygen water to the ground. Correspondingly, the bottom of the floor cleaning machine is generally provided with a rolling brush, so that the rolling brush can mop and clean the spraying part of the active oxygen water. The sewage remained on the floor after being mopped can be absorbed into the recycling bin through the absorption device on the floor cleaning machine. In the whole floor cleaning process, the cleaning machine component is used for ionizing clear water into active oxygen water to clean and disinfect the floor instead of using chemical reagents such as disinfectant or cleaning fluid. Thus, even if the sewage in the recovery barrel is discharged into a sewer or the like, the environment is not polluted.

In a floor cleaning application scenario, the washer assembly described in the previous embodiments is provided between the water diversion device and the nozzle of the floor cleaning machine. When a user cleans the ground by using the ground cleaning machine, the user starts the ground cleaning machine to work after filling clear water into a solution barrel in the ground cleaning machine. The water pump in the ground cleaning machine can pump the clean water in the solution barrel to the water delivery pipe of the water diversion device. The cleaning machine component ionizes the clear water into the active oxygen water and conveys the active oxygen water into the nozzle, and then the nozzle sprays the active oxygen water to the ground. Correspondingly, the bottom of the floor cleaning machine is generally provided with a rolling brush, so that the rolling brush can mop and clean the spraying part of the active oxygen water. The sewage remained on the floor after being mopped can be absorbed into the recycling bin through the absorption device on the floor cleaning machine. In the whole floor cleaning process, the cleaning machine component is used for ionizing clear water into active oxygen water to clean and disinfect the floor instead of using chemical reagents such as disinfectant or cleaning fluid. Thus, even if the sewage in the recovery barrel is discharged into a sewer or the like, the environment is not polluted.

It should be noted that, the descriptions of "first", "second", etc. in this document are used for distinguishing different messages, devices, modules, etc., and do not represent a sequential order, nor limit the types of "first" and "second" to be different.

It should also be noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (19)

1. A washer assembly, comprising: at least one ionizing assembly;

wherein each ionizing assembly comprises: at least one first conductive layer, at least two second conductive layers of opposite electrical polarity to the first conductive layers, at least one insulating support; the insulating support is used for electrically insulating the first conducting layer from the second conducting layer;

the ionization assemblies are used for ionizing the liquid flowing through each ionization assembly to form the active oxygen water.

2. The washer assembly of claim 1, wherein the first conductive layer is a positive electrode; the second conductive layer is a negative electrode.

3. The washer assembly of claim 1, wherein the insulating support member is a hollow structure and is provided with a hole.

4. The washer assembly of claim 1, wherein the first and second conductive layers are regular metal conductive grids; or

The first conducting layer and the second conducting layer are irregular metal conducting grids.

5. The cleaning machine assembly of any one of claim 4 wherein the grids in the first and second conductive layers are staggered.

6. The washer assembly according to any one of claims 1-5, wherein a projected area of the insulating support in a horizontal plane is smaller than a projected area of the first conductive layer and the second conductive layer in a horizontal plane.

7. The washer assembly according to any one of claims 1-5, wherein one first conductive layer is disposed between every two second conductive layers, and wherein the insulating support is disposed between the first conductive layer and the second conductive layers.

8. A washer assembly, comprising: the insulating support part is arranged on the first conductive grid and the second conductive grid; the electrical polarity of the first conductive mesh is opposite to the electrical polarity of the second conductive mesh; the projection area of the insulating support member on the horizontal plane is smaller than the projection areas of the first conducting layer and the second conducting layer on the horizontal plane; the first conductive grid and the second conductive grid are used for ionizing liquid flowing through the first conductive grid and the second conductive grid to form active oxygen water.

9. The washer assembly of claim 8, wherein the insulating support member is a hollow ring structure with a hole therein.

10. A cleaning machine, comprising: the cleaning machine comprises a cleaning machine main body, and a solution barrel, a water diversion device and a nozzle which are arranged on the main body and connected in sequence; liquid in the solution barrel is sent into the nozzle through the water diversion device so that the nozzle sprays the liquid on the object to be cleaned;

the cleaning machine further includes: a washer assembly disposed on the liquid flow path for ionizing the liquid into active oxygen water before the liquid is sprayed to the object to be cleaned by the nozzle to clean the object to be cleaned with the active oxygen water.

11. The cleaning machine of claim 10 wherein said cleaning machine assembly is disposed within said solution tank;

liquid in the solution barrel is ionized into active oxygen water by the cleaning machine component and then is sent to the nozzle through the water diversion device, and the nozzle is used for spraying the active oxygen water to the object to be cleaned.

12. The cleaning machine of claim 10 wherein said cleaning machine assembly is disposed within said water diversion device;

the liquid in the solution barrel flows into the water diversion device under the guidance of the water diversion device, is ionized into the active oxygen water by the cleaning machine component and then enters the nozzle, and the nozzle is used for spraying the active oxygen water onto the object to be cleaned.

13. The washer of claim 10, wherein the washer assembly is disposed between the water diversion device and the nozzle;

liquid in the solution barrel is conveyed into the cleaning assembly through the water diversion device, ionized into active oxygen water through the cleaning assembly and then flows into the nozzle, and the nozzle is used for spraying the active oxygen water onto the object to be cleaned.

14. The cleaning machine of claim 10 wherein said cleaning machine assembly comprises: at least one ionizing assembly; each ionizing assembly comprising: at least one first conductive layer, at least two second conductive layers of opposite electrical polarity to the first conductive layer, and at least one insulating support; the at least one insulating support is used for electrically insulating the first conducting layer and the second conducting layer;

the at least one ionization component is used for ionizing the liquid flowing through the at least one ionization component to form the active oxygen water.

15. The washer assembly of claim 14, wherein the first conductive layer is electrically connected to a positive power supply terminal of the washer; the second conducting layer is electrically connected with a negative power supply end of the cleaning machine.

16. The washer assembly according to claim 14, wherein the insulating support member is a hollow structure with a hole therein.

17. The washer assembly of claim 14, wherein the first and second conductive layers are regular metal conductive grids; or

The first conducting layer and the second conducting layer are irregular metal conducting grids.

18. The cleaning machine of any one of claims 10-17, further comprising: the cleaning machine assembly is arranged in the accommodating cavity; the accommodating cavity is arranged on the liquid circulation path.

19. The cleaning machine of any one of claims 10-17, further comprising: the device comprises a power supply module, a control assembly and a detection assembly; the control assembly is respectively connected with the detection assembly and the power module, and the power module is connected with the cleaning machine assembly;

when the detection assembly detects that liquid flows in the solution barrel, the control assembly controls the power supply module to supply power to the cleaning machine assembly so as to drive the cleaning machine assembly to ionize the liquid flowing through the cleaning machine assembly.

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