CN209996254U

CN209996254U - washing equipment with novel structure

Info

Publication number: CN209996254U
Application number: CN201822211827.3U
Authority: CN
Inventors: 朱泽春; 胡鹏; 陈宁涛; 杨夫健
Original assignee: Joyoung Co Ltd
Current assignee: Hangzhou Jiuchuang Home Appliances Co ltd
Priority date: 2018-12-26
Filing date: 2018-12-26
Publication date: 2020-01-31
Anticipated expiration: 2028-12-26

Abstract

The utility model relates to a washing equipment of novel structure, including washing chamber and electrolytic device, electrolytic device and washing chamber communicate with each other, its characterized in that, electrolytic device includes dissolves the chamber for holding the solute, it has the water inlet to dissolve the chamber, dissolves the solute from the water that the water inlet got into in order to form electrolyte solution, the electrolysis chamber, it carries electrolyte solution to dissolve the chamber to the electrolysis chamber, be equipped with the electrolysis electrode that is used for electrolyzing electrolyte solution in order to form electrolyte in the electrolysis chamber, the electrolysis chamber is equipped with the play water interface that communicates washing chamber, pressure channel communicates with the electrolysis chamber, through pressure channel lets in fluid to the electrolysis intracavity to make electrolyte discharge to the washing intracavity through a play water interface.

Description

washing equipment with novel structure

Technical Field

The utility model relates to a kitchen tableware food cleaning and sterilizing equipment technical field, concretely relates to kinds of washing equipment of novel structure.

Background

However, the high temperature may damage tableware or food materials, and ozone may destroy nutrition of the food materials, and further consider treatment and absorption of residual ozone, in the prior art, washing chambers for washing tableware or food materials by using electrolyte, such as sodium chloride electrolyte, are generally connected to the front side of the washing chamber, the electrolyte solution is electrolyzed into the electrolyte after being introduced into the electrolysis device, and then the electrolyte is discharged into the washing chamber to wash the tableware or food materials.

SUMMERY OF THE UTILITY MODEL

The utility model aims to reach the purpose that provides kinds of novel structure's washing equipment to the electrolyte discharges the high efficiency to the washing chamber, plays the disinfection of disinfecting, removes effect such as incomplete farming to the fruit vegetables in the washing chamber, tableware etc. and long when can also having guaranteed the solute use simultaneously, avoids needing the user frequently to add, has improved user experience.

In order to achieve the purpose, the utility model adopts the following technical scheme that washing equipment with a novel structure comprises a washing cavity and an electrolysis device, wherein the electrolysis device is communicated with the washing cavity, and the electrolysis device is characterized in that the electrolysis device comprises a dissolving cavity, an electrolysis cavity and a pressure channel, wherein the dissolving cavity is used for containing solute, the dissolving cavity is provided with a water inlet, the solute is dissolved by water entering from the water inlet to form electrolyte solution, the electrolyte solution is conveyed to the electrolysis cavity by the dissolving cavity, an electrolysis electrode used for electrolyzing the electrolyte solution to form electrolyte is arranged in the electrolysis cavity, the electrolysis cavity is provided with a water outlet port communicated with the washing cavity, and the pressure channel is communicated with the electrolysis cavity and is used for introducing fluid into the electrolysis cavity through the pressure channel so as to discharge the electrolyte into the washing cavity through the water outlet port.

, the pressure channel is isolated from the dissolving chamber, the electrolysis chamber has a inlet, the inlet is connected to the pressure channel, and fluid is introduced into the electrolysis chamber from the pressure channel to discharge the electrolyte.

And , the dissolving cavity is communicated with the electrolysis cavity in a one-way mode through a solution flow channel, the outlet of the solution flow channel forms a second inlet of the electrolysis cavity, and the inlet of the solution flow channel forms a water outlet of the dissolving cavity.

, the dissolving chamber and the electrolyzing chamber are physically arranged and separated by a partition wall, the solution flow channel is located on the side of the partition wall facing the dissolving chamber , the second inlet is located on the partition wall, and the water outlet is located on the other outer wall of the electrolyzing chamber.

, the pressure channel extends along the side of the dissolution chamber, and the inlet is also located on the dividing wall.

, the solution flow channel is in a vertically circuitous shape, a vertical isolation rib is arranged in the solution flow channel, the flow directions of the flow channels on the two sides of the vertical isolation rib are opposite, and a one-way valve is arranged behind the vertical isolation rib.

And , a water inlet interface and a second water inlet flow channel communicated with the water inlet interface are arranged on the outer wall of the dissolving cavity, a water inlet valve is arranged on the second water inlet flow channel, the water inlet interface is communicated with the water inlet of the dissolving cavity through the second water inlet flow channel under the state of the water inlet valve, and the water inlet interface is communicated with the pressure channel through the second water inlet flow channel under the second state of the water inlet valve.

And , the pressure channel is formed by the dissolving cavity, and fluid is introduced into the electrolysis cavity through the dissolving cavity, so that the electrolyte is discharged into the washing cavity through the water outlet interface.

, a partition board for dividing the dissolving cavity into a sub-cavity and a second sub-cavity is arranged in the dissolving cavity, the sub-cavity contains solute, a through hole for water supply exchange in the sub-cavity and the second sub-cavity is arranged on the partition board, and water entering the dissolving cavity is in the sub-cavity and/or enters the electrolysis cavity after flowing through the second sub-cavity.

And , the water inlet and the water outlet of the dissolving cavity are both positioned in the second sub-cavity, and the water entering the dissolving cavity flows through the through hole into the sub-cavity from the second sub-cavity and then flows back to the second sub-cavity through the through hole.

The utility model discloses in, electrolytic device includes the communicating pressure channel with the electrolysis chamber, let in fluid to the electrolysis chamber through pressure channel, so that electrolyte discharges to the washing intracavity through water outlet port, the discharge efficiency of electrolyte has been improved steps, pressure channel is isolated with dissolving the chamber, make the electrolyte discharge stage need not to consume dissolve the solute in the intracavity, avoid the user to need frequently to add solute to dissolving the intracavity, improve product experience, in order to discharge electrolyte into the washing chamber completely, pressure channel needs to inject the clear water yield that is greater than the electrolysis chamber capacity into the electrolysis chamber, in addition, aspect, the washing water yield in the washing chamber is far greater than the capacity in electrolysis chamber, and, the effective component concentration of electrolyte also can reach the washing effect that satisfies the requirement in the lower scope, therefore, clear water from pressure channel injection is discharged electrolyte to the washing chamber after, still can continue the water injection, so that reach the washing water yield requirement in washing chamber, it is obvious, if electrolyte discharges to accomplish through injecting water into dissolving the chamber water injection, the consumption of solute can be favorable to the electrolyte again to form the electrolyte solution after the electrolysis chamber, the washing chamber is still can be favorable to the electrolyte is washed for a long time, the electrolyte discharge the water outlet port is still can be shortened separately.

Drawings

The present invention is further described in with reference to the following drawings:

FIG. 1 is a schematic view of the structure of the electrolyzer of the present invention;

FIG. 2 is a cross-sectional view A-A of FIG. 1;

FIG. 3 is a cross-sectional view taken along line B-B of FIG. 1;

FIG. 4 is a cross-sectional view taken along line D-D of FIG. 2;

FIG. 5 is a schematic view of the exploded structure of the electrolyzer shown in FIG. 1;

FIG. 6 is a schematic view of a bottom cover of the chamber shown in FIG. 5;

FIG. 7 is a schematic diagram of the middle portion of the chamber of FIG. 5;

fig. 8 is a cross-sectional view taken along line C-C of fig. 1.

Detailed Description

So that the manner in which the above recited objects, features and advantages of the present invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to the embodiments thereof which are illustrated in the appended drawings, which are not intended to limit the scope of the invention, but which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

A washing device with new structure comprises a washing chamber and an electrolysis device, wherein the electrolysis device is shown in figures 1-8 and comprises a dissolving chamber 10 and an electrolysis chamber 20, the dissolving chamber 10 is used for containing solute, the dissolving chamber 10 is provided with a water inlet 14, the solute is dissolved by water entering from the water inlet 14 to form electrolyte solution, an electrolysis electrode 23 for electrolyzing the electrolyte solution to form electrolyte solution is arranged in the electrolysis chamber 20, wherein the electrolysis electrode 23 is a sheet electrode, the electrolysis electrode 23 is arranged along the horizontal direction, and a through hole is arranged on the electrolysis electrode 23.

The electrolysis electrode 23 electrolyzes the electrolyte solution to form an electrolyte solution, wherein the electrolyte solution is a sodium chloride solution, hypochlorite ions are generated after electrolysis, the hypochlorite has good sterilization, decontamination, pesticide residue removal and other effects so as to achieve a good washing effect, and sodium chloride solute is easy to obtain for a user and has low cost.

The electrolysis device also comprises a pressure channel 30 communicated with the electrolysis cavity 20, and fluid is introduced into the electrolysis cavity 20 through the pressure channel 30 so that the electrolyte is discharged into the washing cavity through the water outlet port 24. The pressure channel is used for releasing pressure when the electrolysis cavity is drained, and the pressure can be released through liquid extrusion discharge or through gas extrusion or supplement. Specifically, a vent hole connected with the air pump can be arranged on the wall of the electrolytic chamber, air is conveyed into the electrolytic chamber through the air pump, and the electrolyte is pressed out from the water outlet.

In this embodiment, the pressure channel 30 is isolated from the dissolution cavity 10 and is communicated with the electrolysis cavity 20, specifically, the electrolysis cavity 20 has the -th inlet 22, the -th inlet 22 is connected with the pressure channel 30, and water is fed into the electrolysis cavity 20 from the pressure channel 30 to discharge the electrolyte, by providing the pressure channel 30 isolated from the dissolution cavity 10, the solute in the dissolution cavity 10 is not consumed in the electrolyte discharge stage, the user is prevented from frequently adding the solute into the dissolution cavity 10, and the product experience is improved.

It should be added that, in order to completely discharge the electrolyte into the washing chamber, the pressure channel 30 needs to inject the clean water amount larger than the capacity of the electrolysis chamber 20 into the electrolysis chamber 20, and in addition , the washing water amount in the washing chamber is often much larger than the capacity of the electrolysis chamber 20, and the effective component concentration of the electrolyte can also achieve the washing effect meeting the requirement in a lower range, so the clean water injected from the pressure channel 30 discharges the electrolyte into the washing chamber, and then the water is continuously injected to achieve the washing water amount requirement of the washing chamber.

Based on the structure, after the electrolyte is adopted to clean the tableware or the food materials, clear water can be injected into the washing cavity through the pressure channel 30 to wash the tableware or the food materials so as to remove the residual electrolyte, a water inlet pipeline does not need to be additionally connected onto the washing cavity, and the front liquid injection system of the washing cavity is simplified.

It can be understood that, as another embodiments of the pressure channel, the pressure channel can be formed by a dissolving cavity, and fluid is introduced into the electrolytic cavity through the dissolving cavity, so that the electrolyte is discharged into the washing cavity through the water outlet, specifically, clear water is continuously introduced into the dissolving cavity, the electrolyte solution is formed in the dissolving cavity and then introduced into the electrolytic cavity, and the electrolyte in the electrolytic cavity is pressed out from the water outlet.

The solution flow passage in this embodiment has an inlet 15 and an outlet 21, the inlet 15 is communicated with the dissolution chamber 10, the outlet 21 is communicated with the electrolysis chamber, that is, the outlet 21 of the solution flow passage forms the second inlet 21 of the electrolysis chamber 20, and the inlet 15 of the solution flow passage forms the outlet 15 of the dissolution chamber, wherein, in the aspect of the buffer chambers 50 and for forming a liquid flow between the inlet 15 and the outlet 21, the water flow entering from the dissolution chamber 10 is buffered, and the water flow at the outlet 21 is kept smooth, so that the liquid level in the electrolysis chamber 20 is smooth, in the aspect of , tiny particles in the electrolyte solution are precipitated in the buffer chamber 50 to be prevented from entering the electrolysis chamber 20. of course, the solution flow passage can be a through hole on the two chambers except for the form of the buffer chamber 50, in the case of the dissolution chamber and the electrolysis chamber being formed integrally, so as to communicate the two chambers.

Preferably, the buffer chamber 50 is a serpentine shape. When the electrolyte solution flows through the solution flow channel which is in a winding shape from top to bottom, the tiny particles in the electrolyte solution can be deposited in the lower corner of the solution flow channel under the action of gravity, and the tiny particles are prevented from entering the electrolytic cavity. And when the subsequent electrolyte solution continues to flow through the solution flow channel, the subsequent electrolyte solution can impact the micro-particles previously deposited in the lower corner to promote the micro-particles to be dissolved, so that the solution flow channel is prevented from being blocked by the deposition of a large amount of micro-particles.

In order to form a vertically circuitous solution flow passage, vertical isolation ribs are arranged in the buffer cavity 50, flow directions of the flow passages on two sides of the vertical isolation ribs are opposite, each vertical isolation rib comprises -th vertical isolation ribs 51 and a second vertical isolation rib 52 which are alternately arranged in sequence, the -th vertical isolation rib 51 extends downwards from the top wall of the electrolysis device, a lower circuitous opening 511 is formed by a gap between the extending tail end of the -th vertical isolation rib 51 and the bottom wall of the electrolysis device, the second vertical isolation rib 52 extends upwards from the bottom wall of the electrolysis device, a gap is formed between the extending tail end of the second vertical isolation rib 52 and the top wall of the electrolysis device, an upper circuitous opening 521 is formed by a gap, and the upper circuitous opening 521 is positioned at the upper part.

The buffer chamber 50 having such a structure not only makes the solution flow path take a vertically circuitous shape, but also makes the upper circuitous opening 521 located at the upper portion, so that the liquid level of the electrolyte solution in the dissolution chamber is higher than the bottom edge of the upper circuitous opening 521, and only then can it be ensured that the electrolyte solution can flow into the electrolysis chamber through the solution flow path. Thereby, the liquid level height and the water storage capacity in the dissolving cavity are ensured. When the water quantity meeting the requirements is added into the dissolving cavity, the addition of a large amount of water is beneficial to fully dissolving the electrolyte in the dissolving cavity and enabling the electrolyte solution in the dissolving cavity to reach the saturated concentration, so that the sterilizing ion concentration of the electrolyte is improved, and the sterilizing effect is improved.

In order to prevent the liquid from flowing back into the dissolution cavity 10 from the solution flow channel, the solution flow channel is in one-way communication with the dissolution cavity 10 and the electrolysis cavity 20, a one-way valve 53 is arranged behind the vertical isolation rib, the one-way valve 53 comprises a check port 531 arranged in a bottom-to-top flow section of the buffer cavity 50 and a gravity plug 532 arranged above the check port 531, when the flow of the electrolyte solution to the electrolysis cavity 20 is stopped, the gravity plug 532 blocks the check port 531 under the action of gravity, the solution flow channel is blocked, the solution in the electrolysis cavity cannot flow back into the dissolution cavity through the solution flow channel, when the electrolyte solution flows to the electrolysis cavity through the solution flow channel, under the action of fluid impact, the gravity plug 532 moves upwards away from the check port 531, the solution flow channel is communicated through the check port, and the electrolyte solution flows from the dissolution cavity 10 to the electrolysis cavity 20 through the solution flow channel, the one-way valve with the structure is matched with the structure of the solution flow channel, the structure is simple and easy to implement, it can be understood that the vertical isolation rib 51 is arranged in the structure based on the structure that the vertical isolation rib is arranged in the buffer cavity 50, for example, the second one-way, and the vertical isolation rib can be arranged in the traditional product, such as a vertical isolation spring , and only arranged in the second isolation rib.

For convenience of subsequent description, as shown in fig. 1, various directions of the electrolysis apparatus are specified, and according to the directions shown in fig. 1, the electrolysis apparatus has a front side wall 71, a rear side wall 72, a left side wall 73, a right side wall 74, a top wall 75, and a bottom wall 76, as shown in fig. 3 and 4.

In the present embodiment, the dissolution chamber 10 and the electrolysis chamber 20 are integrally formed, the dissolution chamber 10 and the electrolysis chamber 20 are separated by the partition wall 60, the dissolution chamber 10 and the electrolysis chamber 20 are respectively formed on both sides of the partition wall 60, the electrolysis apparatus has good integrity, small volume and high freedom of installation position selection, and the water leakage problem caused by water pipe connection between the parts is avoided, it is easily understood that the dissolution chamber and the dissolution chamber can also be formed in a split type, and the partition wall 60 is provided with a second inlet 21 communicating the solution passage with the electrolysis chamber, and the water outlet 24 is formed on the other outer wall of the electrolysis chamber 20, wherein the second inlet 21 is the outlet 21 of the solution passage, the second inlet 21 and the water outlet 24 are formed on different side walls of the electrolysis chamber 20, so as to extend the liquid flow path and improve the electrolysis efficiency of the electrolyte solution, in the present embodiment, the water outlet 24 and the second inlet 21 are formed on the opposite side walls of the electrolysis chamber 20, the water outlet 24 is formed on the upper side wall of the partition wall 20, the second inlet 21 is formed on the lower portion of the partition wall 60, so that the electrolyte solution flows into the electrolyte outlet 21 and the electrolyte outlet 21 is formed on the left side wall, when the electrolyte outlet 21 is formed on the electrolyte inlet 3524, the electrolyte outlet 21 is formed on the electrolyte inlet of the electrolyte flow path, so as to facilitate the electrolyte solution flowing into the electrolyte outlet of the electrolyte solution flowing into the electrolyte chamber, when the electrolyte inlet of the electrolyte inlet 3524, the electrolyte outlet 24, the electrolyte flowing out of the electrolyte chamber, the electrolyte outlet 24, the electrolyte flowing out of the electrolyte solution flowing structure, the electrolyte chamber, the electrolyte inlet of the electrolyte inlet 3524, the electrolyte is formed on the electrolyte inlet of the electrolyte chamber, so as to improve the electrolyte flowing out structure, so as to improve the electrolyte flowing into the.

When the electrolyte solution enters the electrolytic chamber 20 through the second inlet 21, the opening size of the second inlet 21 in the vertical direction is smaller than that in the horizontal direction in order to avoid the turbulence of the liquid in the electrolytic chamber 20 caused by the excessive flow velocity at the second inlet 21. Thus, the second inlet 21 is an aperture of a flat shape. The opening with the structure can reduce the flow velocity of liquid entering the electrolytic cavity, avoid the generation of up-down turbulence in the electrolytic cavity, ensure that the electrolyte solution at the downstream side can slowly flow through the electrolytic electrode 23 and ensure the sufficient electrolysis of the electrolyte solution.

The pressure channel 30 extends along the side of the dissolving chamber 20, the th inlet 22 is located on the partition wall 60, and the second inlet 21 and the th inlet 22 are respectively located on both sides of the partition wall 60. specifically, the second inlet 21 and the th inlet 22 are both located on the lower portion of the partition wall 60. in order to avoid the mixing of the clean water with the electrolyte solution, the second inlet 21 is located on the lower portion of the partition wall 60, the th inlet 22 is located on the lower portion of the partition wall 60 near the rear side wall 72 , and the second inlet 21 is located on the lower portion of the partition wall 60 near the front side wall 71 . in step , the th inlet 22 and the water outlet 24 are respectively located on the lower portion and the upper portion of the dissolving chamber 20. with such a structure, when the clean water needs to be added to the washing device to wash the dishes or food materials, the clean water entering from the th inlet 22 located on the lower portion can be firstly discharged to the washing device, and the clean water can enter the washing device after the electrolyte is emptied.

The outlet 24 is located at the upper part of the side wall of the electrolytic chamber 20 in this embodiment, and correspondingly the inlet 22 is located at the lower part of the side wall of the electrolytic chamber, such a structure prolongs the flow path between the inlet 22 and the outlet 24, which facilitates the sufficient discharge of the electrolyte, and in addition, if the outlet and the 0 inlet are located at the same side wall, the outlet and the inlet can be located at the upper and lower parts of the side wall on different sides, respectively, so that the outlet and the inlet are diagonally located at the same side wall, and the electrolytic chamber as a whole can be referred to, so that the outlet and the inlet are diagonally located.

it is noted that in this embodiment, the pressure channel 30 and the dissolution chamber 10 are located on the same side of the partition wall 60, the pressure channel 30 is located near the front side wall 71 of the electrolysis device and is physically located with the dissolution chamber 10 , and correspondingly, the solution flow channel is located near the rear side wall 71 of the electrolysis device to correspond to the aforementioned positions of the inlet and the second inlet 21.

In order to control water supply to the electrolysis device, the outer wall of the dissolution cavity 10 is provided with a water inlet interface 16 and a second water inlet flow channel 19 which is communicated with the water inlet interface 16 and the water inlet 14, the second water inlet flow channel 19 is provided with a water inlet valve 40, the water inlet valve 40 comprises a th state and a second state, under the th state of the water inlet valve 40, the water inlet interface 16 is communicated with the water inlet 14 of the dissolution cavity 10 through the second water inlet flow channel 19, under the second state of the water inlet valve 40, the water inlet interface 16 is communicated with the pressure channel 30 through the second water inlet flow channel 19, and through the arrangement of the water inlet valve 40, the water injection quantity into the dissolution cavity can be controlled automatically.

In the electrolytic device provided by the embodiment, the dissolving cavity 10 is provided with the partition board 13, the partition board 13 divides the dissolving cavity 10 into the th sub-cavity 11 and the second sub-cavity 12, solute is stored in the th sub-cavity 11, the partition board 13 is provided with the through hole 131, the through hole 131 is used for supplying water to exchange between the th sub-cavity 11 and the second sub-cavity 12, water entering the dissolving cavity 10 enters the electrolytic cavity 20 after flowing through the th sub-cavity 11 and/or the second sub-cavity 12, in specific use, the electrolytic device is usually connected to the front side of the washing device, and electrolyte formed by the electrolytic device enters the washing device to wash tableware or food materials.

The dissolving chamber 10 is divided into a th sub-chamber 11 and a second sub-chamber 12 by arranging the partition plate 13 in the dissolving chamber 10, and the solute is stored in the th sub-chamber 11, so that a storage space special for is provided for the solute.

Based on the structure of the sub-chambers for dissolving, the pressure channel 30 in this embodiment is located on the side of the second sub-chamber 12 close to the front side wall 71 and located on the side of the -th sub-chamber 11 close to the bottom wall 53976 2.

It is easily understood that in practical implementation, the feeding direction is generally from top to bottom, therefore, in this embodiment, the isolation plate 13 is transversely disposed, the th sub-chamber 11 and the second sub-chamber 12 are vertically distributed, that is, the th sub-chamber 11 is located above the second sub-chamber 12, and the feeding port 400 for feeding the solute is arranged on the dissolving chamber, such arrangement facilitates the feeding of the solute, and, as the water gradually fills the dissolving chamber from bottom to top, during the water filling the dissolving chamber from bottom to top, the water in the th sub-chamber 11 through the through hole 131 in the second sub-chamber 12 will generate a large upward impact force on the solute located in the th sub-chamber 11, thereby generating an impact stirring effect on the solute, the step accelerates the dissolution of the solute, and the step accelerates the production of the electrolyte solution.

In practical implementation, the water inlet and the water outlet of the dissolving cavity can be arranged as required. The following setting modes are mainly adopted:

(1) the water inlet is arranged in the th sub-cavity, the water outlet is arranged in the second sub-cavity, at the moment, water entering the th sub-cavity from the water inlet can enter the second sub-cavity through the through hole in the partition plate and flows into the electrolytic cavity through the water outlet in the second sub-cavity, and by adopting the arrangement mode, larger solute particles in the th sub-cavity can be prevented from entering the second sub-cavity, so that the electrolyte solution entering the electrolytic cavity contains the solute particles, the channel blockage and the failure of a washing device caused by the electrolyte solution are avoided, and the electrolytic effect and the electrolyte quality in the electrolytic cavity are ensured.

(2) The water inlet sets up at the second minute chamber, and the delivery port setting is in the branch chamber of th, and at this moment, the water that gets into the second minute chamber by the water inlet can get into the th minute chamber through the through-hole on the division board to in the delivery port through the branch chamber of th flows into electrolyte, such mode of setting, the water impact power that gets into the second minute chamber by the water inlet is great, thereby, when water gets into the branch chamber of through the through-hole on the division board, can produce great impact stirring effect to the solute, promote the solute to dissolve, accelerate the formation of electrolyte solution.

(3) The water inlet and the water outlet are both arranged in the -th sub-cavity, at the moment, water entering the -th sub-cavity from the water inlet enters the second sub-cavity through the through holes in the partition plate, then water in the second sub-cavity flows back to the -th sub-cavity through the through holes in the partition plate, and then flows into electrolyte through the water outlet.

(4) The water inlet and the water outlet are arranged in the second sub-cavity, at the moment, water entering the second sub-cavity from the water inlet can enter the th sub-cavity through the through hole in the isolating plate, then the water in the th sub-cavity flows back to the second sub-cavity through the through hole in the isolating plate, and flows into electrolyte through the water outlet in the second sub-cavity.

In this embodiment, the water inlet 14 of the dissolution chamber is located in the second sub-chamber 12, and the water entering the dissolution chamber passes through the through hole 131 from the second sub-chamber 12 to enter the th sub-chamber 11, the water inlet 14 is located in the second sub-chamber 12, the water inlet 14 has a higher pressure, and the water entering the second sub-chamber 12 also has a higher pressure, so that, when the water in the second sub-chamber 12 enters the th sub-chamber 11 through the through hole 131 on the partition board 13, a higher upward impact force is generated on the solute in the th sub-chamber 11, the upward impact force is matched with the gravity of the solute particles, so that the solute particles are in a floating and sinking motion state, thereby promoting dissolution of the solute, accelerating the generation of the electrolyte solution, and increasing the finally obtained electrolyte concentration.

In the embodiment, the water outlet 15 of the dissolution cavity is located in the second sub-cavity 12, after the water entering the dissolution cavity passes through the through hole 131 from the second sub-cavity 12 and enters the sub-cavity 11, the water flows back to the second sub-cavity 12 through the through hole 131, the electrolyte solution in the dissolution cavity flows from the second sub-cavity 12 to the electrolysis cavity through the water outlet 15, and the solute is stored in the sub-cavity 11, so that the larger solute particles in the sub-cavity 11 can be prevented from entering the second sub-cavity 12, the electrolyte solution entering the electrolysis cavity can be prevented from containing the larger solute particles, the channel blockage and the failure of the washing device caused by the larger solute particles can be avoided, and the electrolysis effect and the quality of the electrolyte in the electrolysis cavity can be ensured.

In order to further , the water inlet 14 and the water outlet 15 of the dissolution chamber may be located on opposite sides of the second chamber 12. the water inlet and the water outlet are located on opposite sides of the second chamber, so that the distance between the water inlet and the water outlet is relatively long, thereby prolonging the flow path of water from the water inlet 14 to the water outlet 15, helping to promote the full dissolution of the solute, facilitating the obtaining of a higher concentration electrolyte solution, and increasing the electrolyte concentration of the electrolyte solution.

In this embodiment, the water inlet 14 is disposed at the middle position of the front side of the second sub-chamber, and the water outlet 15 is disposed at the middle position of the rear side of the second sub-chamber, the arrow in fig. 4 indicates the flowing direction of the water, as can be seen from fig. 4, the flowing path of the water from the water inlet 14 to the water outlet 15 is long, and after the water enters the sub-chamber from the second sub-chamber, in order to flow from the sub-chamber to the water outlet, the water needs to flow through each corner of the second sub-chamber, so that it can be ensured that the solute located at each corner of the sub-chamber can be dissolved by the impact of the water, and the dissolving effect of the solute is improved.

In other embodiments, the water inlet and the water outlet are respectively located at the front side and the rear side of the second sub-chamber, meaning that the water inlet is located at the front side and the water outlet is located at the rear side, or the water inlet is located at the rear side and the water outlet is located at the front side and the water outlet is located at the left side of the second sub-chamber, meaning that the water inlet is located at the right side and the water outlet is located at the left side, meaning that the water inlet is located at the left side, or that the water inlet is located at the left side and the water outlet is located at the right side.

As shown in fig. 5, in the present embodiment, the electrolytic device is formed by fastening a middle cavity 100, a bottom cavity cover 200 and a top cavity cover 300, wherein the bottom cavity cover 200 is fastened below the middle cavity 100, and the bottom cavity cover 300 is fastened above the middle cavity 100. Referring to fig. 2 and 3, the cavity bottom cover 200 and the cavity bottom cover 300 are respectively provided with longitudinal ribs corresponding to the cavity middle part 100, and the longitudinal ribs on the cavity middle part 100, the cavity bottom cover 200 and the cavity top cover 300 are correspondingly matched with each other to decompose the electrolysis device into a dissolution cavity and an electrolysis cavity and define a water inlet and a water outlet. It is easily understood that, in the specific implementation, the electrolytic device is not limited to be formed by buckling the middle cavity 100, the bottom cavity 200 and the top cavity 300, and the manufacturing method of the electrolytic device can be designed according to the requirements of the manufacturing process, as long as the specific structure of the electrolytic device of the embodiment of the present invention can be produced.

As can be seen from FIG. 6,

th supporting ribs

121 and 122 second supporting ribs 122 are provided in the second sub-chamber 12 and supported between the bottom wall 76 and the partition plate 13. the arrangement of

th supporting ribs

121 and 122 second supporting ribs can improve the structural stability of the partition plate 13 and prevent the partition plate 13 from being deformed due to long-term use.

In order to ensure that the flow path of the solution entering the dissolving chamber is water inlet → second chamber 12 → chamber 11 → second chamber 12 → water outlet, in the embodiment, as shown in fig. 6, a side clamp is provided in the second chamber 12, the side clamp divides the second chamber into a region and a second region separated from each other, the water inlet 14 is located in the region, and the water outlet 15 is located in the second region, such a structure is adopted that the water entering the dissolving chamber from the water inlet 14 flows to the water outlet 15 only from the region through the corresponding through hole 131 to the chamber 11, and then the solution in the chamber 11 flows to the second region through the through hole 131 corresponding to the second region and then to the water outlet 15, and the flow path of the solution in the dissolving chamber is water inlet → second chamber 12 → chamber 11 → second chamber 12 → water outlet.

In this embodiment, the -th support rib 121 and the -th support rib 122 are both arranged along the longitudinal direction, and the side clamp includes a connection rib 123 connecting the -th support rib 121 and the second support rib 122, so that the -th support rib 121, the second support rib 122 and the connection rib 123 together form the side clamp, and the second sub-cavity is divided into a -th region and a second region which are separated from each other.

In order to prevent the undissolved solute from entering the second sub-chamber 12 along with the solution, in the present embodiment, the aperture of the through hole 131 is 0.3mm to 0.6 mm. Thus, even if there are dissolved solute particles entering the second compartment 12 and into the electrolytic chamber, such sized particles will not block the liquid passage, since the solute particles have a maximum particle size of only 0.6mm, thereby not causing the washing apparatus to fail.

In this embodiment, the water entering the dissolution chamber enters the th sub-chamber 11 from the second sub-chamber 12 through the through hole 131, and in order to increase the impact force generated after the water passes through the through hole 131, the aperture of the through hole 131 near the th sub-chamber 11 side is smaller than the aperture near the th sub-chamber 12. with such a through hole structure, when the water flows from the second sub-chamber ( side where the aperture is larger) to the th sub-chamber ( side where the aperture is smaller), the opening of the through hole through which the water flows is gradually reduced, so that the impact force on the th sub-chamber side can be increased to promote the dissolution of the solute, and with such a through hole structure, can be further prevented to allow undissolved particles to fall into the second sub-chamber through the through.

In the present embodiment, the through-hole 131 has a bar shape. In specific implementation, the shape of the through hole can be set according to needs, and the through hole can also be set to be circular, oval and the like.

The preferred embodiments of the present invention have been described in detail, but it should be understood that various changes and modifications can be made by those skilled in the art after reading the above teaching of the present invention. Such equivalents are intended to fall within the scope of the claims appended hereto.

Claims

Washing equipment with a novel structure of , comprising a washing cavity and an electrolysis device, wherein the electrolysis device is communicated with the washing cavity, and the electrolysis device is characterized by comprising:

a dissolution chamber for containing a solute, the dissolution chamber having a water inlet from which the solute is dissolved by water to form an electrolyte solution,

the dissolving cavity conveys electrolyte solution to the electrolysis cavity, an electrolysis electrode for electrolyzing the electrolyte solution to form electrolyte is arranged in the electrolysis cavity, the electrolysis cavity is provided with a water outlet interface communicated with the washing cavity,

and the pressure channel is communicated with the electrolysis cavity, and fluid is introduced into the electrolysis cavity through the pressure channel so that the electrolyte is discharged into the washing cavity through the water outlet interface.
2. The washing apparatus as claimed in claim 1 wherein the pressure channel is isolated from the dissolution chamber, the electrolysis chamber having an th inlet, the th inlet being connected to the pressure channel, fluid being passed from the pressure channel into the electrolysis chamber to remove electrolyte.
3. The washing apparatus as claimed in claim 2, wherein the dissolution chamber and the electrolysis chamber are in one-way communication via a solution flow path, an outlet of the solution flow path forming a second inlet of the electrolysis chamber, and an inlet of the solution flow path forming a water outlet of the dissolution chamber.
4. The washing apparatus as claimed in claim 3, wherein the dissolution chamber and the electrolysis chamber are physically arranged and separated by a partition wall, the solution flow path is located on the side of the partition wall facing the dissolution chamber , the second inlet is located on the partition wall, and the water outlet port is located on the other outer wall of the electrolysis chamber.
5. The washing apparatus as claimed in claim 4 wherein the pressure channel extends along the side of the dissolution chamber, the inlet also being located on the dividing wall.
6. The electrolysis device according to claim 3, wherein the solution flow channel is in a vertically circuitous shape, a vertical isolation rib is arranged in the solution flow channel, the flow channels on both sides of the vertical isolation rib flow in opposite directions, and a one-way valve is arranged behind the vertical isolation rib.
7. The washing apparatus as claimed in claim 2, wherein the outer wall of the dissolution chamber is provided with a water inlet port and a second water inlet channel communicated with the water inlet port, the second water inlet channel is provided with a water inlet valve, the water inlet port is communicated with the water inlet port of the dissolution chamber through the second water inlet channel in state of the water inlet valve, and the water inlet port is communicated with the pressure channel through the second water inlet channel in the second state of the water inlet valve.
8. The washing apparatus as claimed in claim 1, wherein the pressure channel is formed by a dissolution chamber through which fluid is introduced into the electrolysis chamber to discharge the electrolyte into the washing chamber through the outlet port.
9. The washing apparatus as claimed in , wherein the dissolution chamber is provided with a partition board for dividing the dissolution chamber into th sub-chamber and second sub-chamber, the th sub-chamber contains solute, the partition board is provided with through holes for water exchange in th sub-chamber and second sub-chamber, and water entering the dissolution chamber enters the electrolysis chamber after flowing through th sub-chamber and/or the second sub-chamber.
10. The washing apparatus as claimed in claim 6, wherein the water inlet and the water outlet of the dissolution chamber are both located in the second sub-chamber, and the water entering the dissolution chamber flows from the second sub-chamber through the through hole into the th sub-chamber and then flows back to the second sub-chamber through the through hole.