CN217679447U

CN217679447U - Integrated water tank

Info

Publication number: CN217679447U
Application number: CN202221358708.0U
Authority: CN
Inventors: 陈敏; 陈猛; 戴九松; 汤文斌; 郑军妹; 郭国良
Original assignee: Ningbo Fotile Kitchen Ware Co Ltd
Current assignee: Ningbo Fotile Kitchen Ware Co Ltd
Priority date: 2022-05-31
Filing date: 2022-05-31
Publication date: 2022-10-28
Anticipated expiration: 2032-05-31

Abstract

The utility model discloses an integrated water tank, including the cabinet body (1), basin (2), garbage disposer (3) and brineelectrolysis generating device (7), its characterized in that: the electrolyzed water generating device (7) comprises an acidic water tank (75) used for storing acidic water and an alkaline water tank (76) used for storing alkaline water, the garbage disposer (3) comprises a treatment barrel (32) and an annular spray pipe (36) used for cleaning the treatment barrel (32), the annular spray pipe (36) is provided with a water inlet end and a water outlet end, the water inlet end of the annular spray pipe (36) is respectively communicated with the acidic water tank (75) and the alkaline water tank (76) through an acidic water pipe (751) and an alkaline water pipe (761), and the water outlet end of the annular spray pipe (36) faces to the inner cavity of the treatment barrel (32). Compared with the prior art, the utility model discloses an integrated basin grease is got rid of and is disinfected when can make things convenient for the garbage disposer automatically cleaning.

Description

Integrated water tank

Technical Field

The utility model relates to a kitchen equipment technical field specifically indicates an integrated basin.

Background

Current integrated sinks integrate a variety of products that are spatially or functionally associated with the sink, including cleaning machines, water purifiers, kitchen waste disposers, electrolyzed water generating devices, and the like.

For example, a multifunctional intelligent integrated water tank disclosed in a utility model patent with a patent application number of CN201721005040.0 (publication number of CN 207109957U) comprises a water tank body, and a top-open type dish washer, a water purifying device, an electrolytic water disinfecting device and an ultrasonic device which are arranged on the water tank body; the water tank body at least consists of two integrally formed sub-water tanks. The integrated water tank can almost cover all functions of kitchen water, and can effectively meet various requirements of people.

However, in the above-mentioned solutions, when the disinfection operation is required, the electrode assembly of the electrolytic water disinfection apparatus is immersed in the water in the cleaning container in a moving manner or directly immersed in the water in the second sub-tank for disinfection, and the functions of the acidic water and the alkaline water cannot be fully exerted; in addition, the cleaning machine and the electrolyzed water generating device are only integrated in physical space, and the functions of the cleaning machine and the electrolyzed water generating device are not related to each other.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the first technical problem to provide an integrated basin that grease got rid of and disinfect when can make things convenient for garbage disposer automatically cleaning to the current situation of prior art.

The second technical problem to be solved by the utility model is to provide an integrated sink with simplified structure and low cost.

The utility model provides a technical scheme that above-mentioned first technical problem adopted does: the utility model provides an integrated sink, includes that the top has the cabinet body of mesa, the main part is located basin under the mesa and locate the internal garbage disposer of cabinet and electrolytic water and take place the device, its characterized in that: the electrolyzed water generating device comprises an acidic water tank for storing acidic water and an alkaline water tank for storing alkaline water, the garbage disposer comprises a treatment barrel and an annular spray pipe for cleaning the treatment barrel, the annular spray pipe is provided with a water inlet end and a water outlet end, the water inlet end of the annular spray pipe is communicated with the acidic water tank and the alkaline water tank through an acidic water pipe and an alkaline water pipe respectively, and the water outlet end of the annular spray pipe faces the inner cavity of the treatment barrel.

To achieve the preparation of acidic and basic water, there are three schemes:

the first scheme is as follows:

the electrolyzed water generating device also comprises

The salt tank is used for mixing water and salt to generate saturated salt water, and is provided with a salt feeding port, a water inlet end and a water outlet end for discharging the saturated salt water, and the water inlet end of the salt tank is in fluid communication with a tap water supply pipeline;

the soft water tank is used for softening a water body and provided with a water inlet end for hard water to enter and a water outlet end for soft water to be discharged, and the water inlet end of the soft water tank is communicated with a tap water supply pipeline in a fluid mode;

the concentrated water tank is used for mixing saturated salt water and soft water to generate concentrated water and is provided with a first water inlet end, a second water inlet end and a water outlet end for discharging the concentrated water, the first water inlet end of the concentrated water tank is communicated with the water outlet end of the salt tank in a fluid mode, and the second water inlet end of the concentrated water tank is communicated with the water outlet end of the soft water tank in a fluid mode; and

the electrolysis chamber is used for electrolyzing concentrated water to generate acidic water and alkaline water and is provided with a water inlet end, a first water outlet end for discharging the acidic water and a second water outlet end for discharging the alkaline water, the water inlet end of the electrolysis chamber is communicated with the water outlet end of the concentrated water tank in a fluid mode, the first water outlet end of the electrolysis chamber is communicated with the acidic water tank in a fluid mode, and the second water outlet end of the electrolysis chamber is communicated with the alkaline water tank in a fluid mode.

In order to electrolyze the concentrated water into acidic water and alkaline water, the electrolytic chamber comprises

A box body;

the diaphragm is arranged in the box body and divides the inner cavity of the box body into an anode chamber and a cathode chamber;

the anode is arranged in the anode chamber; and

the cathode is arranged in the cathode chamber;

the water inlet end of the electrolysis chamber is communicated with the anode chamber and the cathode chamber, the first water outlet end of the electrolysis chamber is communicated with the anode chamber, and the second water outlet end of the electrolysis chamber is communicated with the cathode chamber.

In order to automatically supply saturated salt water and soft water by means of water pressure, the water inlet end of the salt tank is communicated with the tap water supply pipeline through a first tap water pipe;

the water inlet end of the soft water tank is communicated with the tap water supply pipeline through a second tap water pipe;

the first tap water pipe and the second tap water pipe are respectively provided with a valve, so that the integrated water tank has at least two states:

in a first state, the first tap water pipe is communicated, and the second tap water pipe is blocked;

in a second state, the second tap water pipe is communicated, and the first tap water pipe is blocked.

In order to further solve the second technical problem, a cleaning machine is arranged in the cabinet body, and the cleaning machine is provided with a water inlet end which is communicated with the water outlet end of the soft water tank in a fluid mode.

In order to facilitate the switching of two modes of supplying soft water to the concentrated water tank and the cleaning machine, the water outlet end of the soft water tank is communicated with the second water inlet end of the concentrated water tank through a first soft water pipe and is communicated with the water inlet end of the cleaning machine through a second soft water pipe;

the first and second flexible water pipes are provided with valves, so that the integrated sink has a third state:

in a second state, the first flexible water pipe is communicated and the second flexible water pipe is blocked;

in the third state, the second tap water pipe is communicated, the first tap water pipe is blocked, the second soft water pipe is communicated, and the first soft water pipe is blocked.

In order to facilitate the coarse adjustment of the concentration of the concentrated water, a temperature monitoring device for monitoring the temperature of the saturated brine is arranged in the salt tank, the integrated water tank is provided with a controller, and the temperature monitoring device and valves on the first tap water pipe and the second tap water pipe are electrically connected with the controller, so that the controller can receive signals collected by the temperature monitoring device and control the on-off of the first tap water pipe and the second tap water pipe.

In order to facilitate the fine adjustment of the concentration of the concentrated water, the electrolysis chamber further comprises a current monitoring device for monitoring the current between the cathode and the anode, and the current monitoring device is electrically connected with the controller, so that the controller can receive the signal collected by the current monitoring device and control the on-off of the first tap water pipe and the second tap water pipe.

In order to conveniently recover the replacement capacity of the soft water tank, the salt tank is communicated with the soft water tank through a backflushing channel, and a valve for controlling the on-off of the backflushing channel is arranged at the backflushing channel.

The second scheme is as follows:

the electrolyzed water generating device also comprises

The salt tank is used for mixing water supply and salt to generate saturated salt water, and is provided with a salt feeding port, a water inlet end, a water outlet end for discharging the saturated salt water and a water return end for recovering the salt water, wherein the water inlet end of the salt tank is in fluid communication with a tap water supply pipeline;

the soft water tank is used for softening a water body and provided with a water inlet end for hard water to enter and a water outlet end for soft water to be discharged, and the water inlet end of the soft water tank is communicated with a tap water supply pipeline in a fluid mode; and

the electrolysis chamber is used for electrolyzing saturated salt water and soft water to generate acidic water and alkaline water and is provided with a first water inlet end, a second water inlet end, a third water inlet end, a water discharging end, a first water outlet end for discharging acidic water and a second water outlet end for discharging alkaline water, wherein the first water inlet end of the electrolysis chamber is communicated with the water outlet end of the salt tank in a fluid mode, the second water inlet end and the third water inlet end of the electrolysis chamber are communicated with the water outlet end of the soft water tank in a fluid mode, the water discharging end of the electrolysis chamber is communicated with the water return end of the salt tank in a fluid mode, the first water outlet end of the electrolysis chamber is communicated with the acidic water tank in a fluid mode, and the second water outlet end of the electrolysis chamber is communicated with the alkaline water tank in a fluid mode.

In order to electrolyze the saturated brine and the soft water into acidic water and alkaline water, the electrolysis chamber comprises

A box body;

the two diaphragms which are arranged side by side are arranged in the box body and divide the inner cavity of the box body into an anode chamber, an intermediate chamber and a cathode chamber which are arranged in sequence;

the anode is arranged in the anode chamber; and

the cathode is arranged in the cathode chamber;

the first water inlet end and the first water outlet end of the electrolysis chamber are communicated with the intermediate chamber, the second water inlet end and the first water outlet end of the electrolysis chamber are communicated with the anode chamber, and the third water inlet end and the second water outlet end of the electrolysis chamber are communicated with the cathode chamber.

In order to further solve the second technical problem, a cleaning machine is arranged in the cabinet body, and the cleaning machine is provided with a water inlet end which is communicated with a water outlet end of the soft water tank in a fluid mode.

In order to facilitate the switching of two modes of supplying soft water to the electrolysis chamber and the cleaning machine, the water outlet end of the soft water tank is communicated with the second water inlet end and the third water inlet end of the electrolysis chamber through a first soft water pipe and is communicated with the water inlet end of the cleaning machine through a second soft water pipe;

the integrated water tank is characterized in that valves are arranged on the first water hose and the second water hose respectively, so that the integrated water tank has at least two states:

in the first state, the first flexible water pipe is communicated, and the second flexible water pipe is blocked;

in the second state, the second flexible water pipe is connected and the first flexible water pipe is blocked.

In order to conveniently recover the replacement capability of the soft water tank, the salt tank and the soft water tank are communicated through a backflushing channel, and a valve for controlling the on-off of the backflushing channel is arranged at the backflushing channel.

The third scheme is as follows:

a water purifier is arranged in the cabinet body, the purified water is provided with a water inlet end, a purified water end and a waste water end, and the water inlet end of the water purifier is in fluid communication with a tap water supply pipeline;

the electrolyzed water generating device also comprises

The soft water tank is used for softening a water body and is provided with a water inlet end for hard water to enter and a water outlet end for soft water to be discharged, and the water inlet end of the soft water tank is communicated with the wastewater end of the water purifier in a fluid mode so that wastewater enters the soft water tank to be softened and generate concentrated water;

a concentrate tank for storing concentrate water having a water inlet end and a water outlet end, the water inlet end of the concentrate tank being in fluid communication with the water outlet end of the soft water tank; and

A box body;

the anode is arranged in the anode chamber; and

the cathode is arranged in the cathode chamber;

In order to further solve the second technical problem, the cleaning machine is arranged in the cabinet body and provided with a water inlet end, the water inlet end of the soft water tank is in fluid communication with the tap water supply pipeline, and the water outlet end of the soft water tank is in fluid communication with the water inlet end of the cleaning machine.

In order to facilitate the switching between two modes of supplying concentrated water to the concentrated water tank and supplying soft water to the cleaning machine, the water inlet end of the water purifier is communicated with the tap water supply pipeline through a third tap water pipe, and the wastewater end of the water purifier is communicated with the water inlet end of the soft water tank through a wastewater pipe;

the water inlet end of the soft water tank is communicated with the tap water supply pipeline through a second tap water pipe, the water outlet end of the soft water tank is communicated with the water inlet end of the concentrated water tank through a first soft water pipe, and the water outlet end of the soft water tank is communicated with the water inlet end of the cleaning machine through a second soft water pipe;

the third tap water pipe, the second tap water pipe, the first soft water pipe and the second soft water pipe are respectively provided with a valve, so that the integrated water tank has at least two states:

in the first state, the third flexible water pipe is communicated with the first flexible water pipe, and the second flexible water pipe is blocked;

in the second state, the second tap water pipe is communicated with the second soft water pipe, and the third tap water pipe is blocked from the first soft water pipe.

In order to provide purified water for users conveniently, the table board is provided with a purified water faucet, the purified water faucet is provided with a water inlet end and a water outlet end, the water inlet end of the purified water faucet is communicated with the purified water end of the water purifier through a purified water pipe, and the water outlet end of the purified water faucet faces the top opening of the sink.

In order to avoid the mixing failure of the acidic water and the alkaline water, valves are arranged on the acidic water pipe and the alkaline water pipe respectively.

In order to ensure a sufficiently large spraying range, the circumferential wall of the annular spray pipe facing the inner cavity of the treatment barrel is provided with at least two spray holes which are arranged at intervals along the circumferential direction and form a water outlet end of the annular spray pipe.

In order to improve the cleaning effect by means of the original structure of the garbage disposer, a containing groove with an opening at the top is formed inside the treating barrel, and the garbage disposer further comprises a smashing device used for smashing garbage in the containing groove.

In order to crush the garbage in the accommodating groove and conveniently stir the electrolyzed water, the crushing device comprises

The cutter is rotatably connected to the bottom wall inside the treatment barrel; and

the driving piece is installed at the bottom of the treatment barrel, the power output end of the driving piece sequentially penetrates through the treatment barrel and extends into the accommodating groove, and the power output end of the driving piece is connected with the cutter in a detachable mode.

Compared with the prior art, the utility model has the advantages of:

(1) The acidic water and the alkaline water prepared by the electrolyzed water generating device are separately supplied to the garbage disposer, so that the first-time grease removal and the second-time sterilization during self-cleaning of the garbage disposer can be facilitated, and the functions of the acidic water and the alkaline water can be fully exerted;

(2) Through with brineelectrolysis emergence device and cleaning machine sharing salt case and softened water tank, perhaps through with brineelectrolysis emergence device and cleaning machine sharing softened water tank, utilize water purifier exhaust waste water simultaneously, under the condition that does not increase cost, guaranteed that the electrolysis chamber can produce acidity and alkaline brineelectrolysis, diaphragm and electrode are difficult for becoming invalid by incrustation scale jam simultaneously, have prolonged life greatly, above-mentioned scheme structure is simplified and with low costs.

Drawings

Fig. 1 is a schematic perspective view of an integrated sink of embodiment 1 of the present invention;

fig. 2 is a schematic perspective view of the cabinet of fig. 1 with a part of side panels omitted;

FIG. 3 is a schematic perspective view of the cap of FIG. 1 in another direction;

FIG. 4 is a schematic perspective view of the garbage disposer shown in FIG. 2;

FIG. 5 is a longitudinal cross-sectional view of the table and waste disposer of FIG. 2;

FIG. 6 is a schematic perspective view of the electrolyzed water forming apparatus shown in FIG. 2;

FIG. 7 is a longitudinal sectional view of FIG. 6 with the electrolytic cell, acid water tank and alkaline water tank omitted;

FIG. 8 is a longitudinal cross-sectional view of the electrolytic cell of FIG. 6;

fig. 9 is a schematic perspective view of the integrated sink of the present invention in which a part of the side plate of the sink body is omitted in embodiment 2;

FIG. 10 is a schematic perspective view of the electrolyzed water forming apparatus shown in FIG. 9;

FIG. 11 is a longitudinal sectional view of FIG. 10 with the electrolytic cell, acid water tank and alkaline water tank omitted;

FIG. 12 is a longitudinal cross-sectional view of the electrolytic cell of FIG. 10;

fig. 13 is a schematic perspective view of the integrated sink of the present invention in which a part of the side plate of the sink body is omitted in embodiment 3;

fig. 14 is a schematic perspective view of the electrolyzed water forming apparatus shown in fig. 13.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments.

Example 1:

as shown in fig. 1 to 8, it is a first preferred embodiment of the integrated sink of the present invention. The integrated water tank comprises a cabinet body 1, a water tank 2, a garbage processor 3, a cleaning machine 5, a kitchen utensil sterilizing machine 6 and an electrolytic water generating device 7.

Wherein, the top of the cabinet body 1 has a table top 11, the top of the table top 11 is partially recessed downwards to form a recessed portion 111, the left part of the bottom of the recessed portion 111 is provided with a garbage putting port 1111, the position of the bottom of the recessed portion 111 behind the garbage putting port 1111 is provided with a hinged seat 1112, the rear part of the middle surface of the table top 11 is provided with a water purifying tap 112, the water purifying tap 112 is provided with a water inlet end and a water outlet end, the water outlet end of the water purifying tap 112 faces the top opening of the sink 2, and the rear part of the left side surface of the table top 11 is provided with a mounting port 113; a top cover 12 is covered above the garbage input port 1111, the rear end of the top cover 12 is hinged on a hinge seat 1112 for opening and closing the garbage input port 1111, and the top surface of the top cover 12 is substantially flush with the top surface of the table 11 in a state that the top cover 12 closes the garbage input port 1111; a bracket 13 is arranged at the left side of the inner cavity of the cabinet body 1.

The sink 2 is embedded in the right part of the bottom surface of the concave part 111, the main body of the sink is arranged below the table-board 11 and is close to the garbage throwing-in port 1111, so that garbage can be conveniently thrown in, and the left part of the bottom surface of the sink 2 is provided with a water outlet 21.

The garbage disposer 3 is installed on the upper part of the bracket 13 and is arranged right opposite to the garbage input port 1111. In this embodiment, the garbage disposer 3 is a drying type garbage disposer, and as shown in fig. 4 and 5, includes a housing 31, a disposal bin 32, a pulverizing device 33, a heating device 34, an exhaust device 35, and a ring-shaped spray pipe 36, where the pulverizing device 33, the heating device 34, and the exhaust device 35 form a disposal assembly for disposing the kitchen garbage in the disposal bin 32 into dry garbage.

Specifically, the housing 31 is attached to the bracket 13.

The disposal container 32 is accommodated in the housing 31, the garbage input port 1111 is located corresponding to the top opening of the disposal container 32, a user can input garbage into the disposal container 32 through the garbage input port 1111, and the disposal container 32 can be taken out through the garbage input port 1111. The arrangement mode has the advantages that firstly, the kitchen space is reasonably utilized, and the floor or the space above the table top is not required to be additionally occupied; secondly, the user can directly put the kitchen garbage generated in the cleaning process into the treatment barrel 32 through the garbage putting port 1111, so that the operation is convenient; thirdly, the garbage after being treated is accumulated to a certain amount, and then can be conveniently taken out of the treatment barrel 32 through the garbage feeding port 1111, so that the dry garbage is convenient to transfer and treat, and the kitchen garbage is directly discharged, thereby being more environment-friendly.

The crushing device 33 is used for crushing the garbage in the treatment tank 32. In this embodiment, the crushing device 33 includes a cutter 331 and a driving member 332. The knife 331 is rotatably connected to the bottom wall inside the processing barrel 32; the driving member 332 is a motor, and is installed at the bottom of the housing 31, and a power output end of the driving member passes through the housing 31 and the processing barrel 32 in sequence and extends into the processing barrel 32, and the power output end of the driving member 332 is detachably connected with the cutter 331, so that the processing barrel 32 can be conveniently taken out from the housing 31.

The heating device 34 is used to heat the waste in the treatment tank 32. In this embodiment, the heating device 34 is a heating plate, which is installed at the bottom inside the housing 31, and the top surface of the heating plate is closely attached to the bottom surface of the processing tub 32.

The exhaust device 35 is used to extract the gas generated in the treatment tank 32 during the garbage treatment process. In this embodiment, the exhaust unit 35 includes a catalytic decomposition tube 351, an exhaust fan 352, and a heating jacket 353. A catalytic decomposition tube 351 is vertically arranged outside the housing 31, and has an odor inlet at the bottom thereof, a first clean gas outlet and a second clean gas outlet at the top thereof for catalytically decomposing odor to generate clean gas, and the odor inlet of the catalytic decomposition tube 351 is in fluid communication with the inner cavity of the above-mentioned treating barrel 32 through an exhaust tube 3511; the exhaust fan 352 is provided with an air suction port and an air exhaust port, and can suck air flow from the air suction port and exhaust the air flow through the air exhaust port, the second purified air outlet of the catalytic decomposition tube 351 is communicated with the air suction port of the exhaust fan 352 through a purified air tube 3512, and the air exhaust port of the exhaust fan 352 can be directly exposed in the cabinet body 1 or communicated with the air exhaust port of a kitchen; the heating jacket 353 is sleeved on the periphery of the catalytic decomposition tube 351 and used for heating the catalytic decomposition tube 351, and the catalytic efficiency is improved.

A ring-shaped spray pipe 36 for washing the treating tub 32 is installed at the top of the treating tub 32 and around the periphery of the top opening of the treating tub 32. The annular nozzle 36 has a water inlet end and a water outlet end, and the circumferential wall of the annular nozzle 36 facing the inner cavity of the processing barrel 32 is provided with at least two spray holes 361 arranged at intervals along the circumferential direction, and the spray holes 361 form the water outlet end of the annular nozzle 36.

The washing machine 5 is provided in the cabinet 1, directly below the tub 2, and on the right side of the rack 13, for washing dishes waiting for washing. The cleaning machine 5 and the water outlet 21 of the water tank 2 are arranged in a staggered manner in the vertical direction, so that the water outlet pipe of the water tank 2 is prevented from interfering with the cleaning machine 5, and the height of the inner cavity of the cleaning machine 5 is increased to the maximum extent. In this embodiment, the space is allocated according to the value, and the space such as the water tank 2, the drainer, the skirting line and the like is reserved in the cleaning machine 5, so that the volume of the cleaning machine 5 is remarkably increased, and the cleaning capacity is larger.

The kitchen sterilizer 6 is disposed in the cabinet 1 and faces the mounting opening 113.

The electrolyzed water generating apparatus 7 is installed at the lower portion of the bracket 13, and as shown in fig. 6 to 8, the electrolyzed water generating apparatus 7 includes a salt tank 71, a soft water tank 72, a thick water tank 73, an electrolysis chamber 74, an acidic water tank 75, and an alkaline water tank 76.

Specifically, the salt tank 71 is used for mixing water and salt to produce a saturated salt solution, and has a salt inlet 710, a water inlet end and a water outlet end. A rotary cover 7101 is detachably connected at the salt feeding port 710 of the salt box 71; the water inlet end of the salt tank 71 is connected to the tap water supply line through a first tap water pipe 711.

The soft water tank 72 is used to soften a body of water and has a water inlet end and a water outlet end. The soft water tank 72 has a water inlet end communicating with the tap water supply line through a second tap water pipe 721. In addition, the salt tank 71 and the soft water tank 72 are communicated through a backflushing channel 720, a valve for controlling the on-off of the backflushing channel 720 is arranged at the position of the backflushing channel 720, when the soft water tank 72 operates for a certain time, the soft water resin in the soft water tank 72 can reach exchange balance and lose replacement capacity, at the moment, the backflushing channel 720 can be opened, and saturated salt water in the salt tank 71 is led into the soft water tank 72 through the backflushing channel 720 to backflush the soft water resin.

The concentrate tank 73 is used for mixing saturated saline water and soft water to generate concentrated water, and has a first water inlet end, a second water inlet end and a water outlet end. The water outlet end of the salt tank 71 is communicated with the first water inlet end of the rich water tank 73 through a saturated salt water pipe 712; in addition, the above-mentioned washing machine 5 has a water inlet end, and the water outlet end of the soft water tank 72 is communicated with the second water inlet end of the rich water tank 73 through a first soft water pipe 722 and is communicated with the water inlet end of the washing machine 5 through a second soft water pipe 723.

The electrolytic chamber 74 is a single-diaphragm double-chamber electrolytic chamber for electrolyzing concentrated water to generate acidic water and alkaline water, and comprises a box 741, a diaphragm 742, an anode 743 and a cathode 744. The tank 741 has a water inlet end, a first water outlet end and a second water outlet end, the water outlet end of the concentrate tank 73 is communicated with the water inlet end of the tank 741 through a concentrate pipe 731, and the concentrate pipe 731 is provided with a first delivery pump 7311 capable of delivering water from an inlet to an outlet thereof; the diaphragm 742 is a cation exchange membrane and is arranged in the box body 741 to divide an inner cavity of the box body 741 into an anode chamber 7411 and a cathode chamber 7412, a water inlet end on the box body 741 is communicated with the anode chamber 7411 and the cathode chamber 7412, a first water outlet end on the box body 741 is communicated with the anode chamber 7411, and a second water outlet end on the box body 741 is communicated with the cathode chamber 7412; anode 743 is disposed in anode compartment 7411; cathode 744 is disposed in cathode chamber 7412.

The acid tank 75 is for storing acid water and has a water inlet end and a water outlet end. The inlet end of the sour water tank 75 is in fluid communication with a first outlet end of the electrolysis chamber 74, and the outlet end of the sour water tank 75 is in communication with the inlet end of the annular lance 36 via a sour water tube 751.

The alkaline water tank 76 is used for storing alkaline water and has a water inlet end and a water outlet end. The inlet end of the alkaline water tank 76 is in fluid communication with the second outlet end of the electrolysis chamber 74, and the outlet end of the alkaline water tank 76 is in communication with the inlet end of the annular nozzle 36 via an alkaline water line 761.

After the garbage disposer 3 finishes treating garbage, the interior of the treatment barrel 32 needs to be automatically cleaned.

Valves are provided on the first tap water pipe 711, the second tap water pipe 721, the saturated salt water pipe 712, the first soft water pipe 722, the second soft water pipe 723, the acidic water pipe 751 and the alkaline water pipe 761.

In this embodiment, the first tap water pipe 711 and the second tap water pipe 721 share the first valve 77. A first communicating pipeline is connected between the tap water supply pipeline and the first valve 77, a second communicating pipeline is connected between the first valve 77 and the water inlet end of the salt tank 71, a third communicating pipeline is connected between the first valve 77 and the water inlet end of the soft water tank 72, the first communicating pipeline and the second communicating pipeline form a first tap water pipe 711, and the first communicating pipeline and the third communicating pipeline form a second tap water pipe 721.

In this embodiment, the saturated salt water pipe 712, the first and second

flexible water pipes

722 and 723 share one second valve 78. The first water inlet end and the second water inlet end of the concentrated water tank 73 share the same water inlet end, a fourth communication pipeline is connected between the water outlet end of the salt tank 71 and the second valve 78, a fifth communication pipeline is connected between the water outlet end of the soft water tank 72 and the second valve 78, a sixth communication pipeline is connected between the second valve 78 and the water inlet end of the concentrated water tank 73, a seventh communication pipeline is communicated between the second valve 78 and the water inlet end of the cleaning machine 5, the fourth communication pipeline and the sixth communication pipeline form a saturated salt water pipe 712, the fifth communication pipeline and the sixth communication pipeline form a first soft water pipe 722, and the fifth communication pipeline and the seventh communication pipeline form a second soft water pipe 723.

By switching the first valve 77 and the second valve 78, the integrated water tank has at least three states:

in the first state, the inlets of the second communication ducts are communicated, the inlet of the third communication duct is blocked, so that the first tap water pipe 711 is communicated, and the second tap water pipe 721 is blocked; the inlet of the sixth communication passage is communicated and the inlet of the seventh communication passage is blocked so that the first soft water pipe 722 is communicated and the second soft water pipe 723 is blocked; thus, the tap water in the tap water supply line is introduced into the salt tank 71 through the first tap water pipe 711, and the saturated saline solution formed by mixing the water and the salt is introduced into the concentrate tank 73 through the saturated saline water pipe 712 under the hydraulic pressure;

in the second state, the inlet of the second communication duct is blocked, the inlet of the third communication duct is communicated so that the second tap water pipe 721 is communicated, and the first tap water pipe 711 is blocked; the inlet of the sixth communication passage is communicated and the inlet of the seventh communication passage is blocked so that the first soft water pipe 722 is communicated and the second soft water pipe 723 is blocked; thus, the tap water in the tap water supply line is introduced into the soft water tank 72 through the second tap water pipe 721, and the soft water formed by softening the tap water is introduced into the rich water tank 73 through the first soft water pipe 722 under the aforementioned water pressure;

in the third state, the inlet of the second communication pipe is blocked, the inlet of the third communication pipe is communicated so that the second tap water pipe 721 is communicated with the first tap water pipe 711; the inlet of the sixth communication passage is blocked and the inlet of the seventh communication passage is communicated such that the second soft water pipe 723 is communicated and the first soft water pipe 722 is blocked; thus, the tap water in the tap water supply line is introduced into the soft water tank 72 through the second tap water pipe 721, and the soft water formed by softening the tap water is introduced into the washing machine 5 through the second soft water pipe 723 under the above-mentioned water pressure.

In this embodiment, the sour water line 751 and the alkaline water line 761 share a common third valve 79. An eighth communication pipe is connected between the outlet end of the acidic water tank 75 and the third valve 79, a ninth communication pipe is connected between the outlet end of the alkaline water tank 76 and the third valve 79, a tenth communication pipe is connected between the third valve 79 and the inlet end of the annular nozzle 36, a second delivery pump 7511 capable of delivering water from the inlet to the outlet thereof is installed in the tenth communication pipe, the eighth communication pipe and the tenth communication pipe constitute an acidic water pipe 751, and the ninth communication pipe and the tenth communication pipe constitute an alkaline water pipe 761. Thus, the third valve 75 is switched to selectively connect the acidic water pipe 751 and the alkaline water pipe 761, and the acidic water or the alkaline water is supplied to the annular nozzle 36 by activating the second supply pump 7511.

In order to accurately prepare the required high-concentration concentrated water (in this embodiment, the concentration of NaCl in the concentrated water is 0.1 wt%), in this embodiment, a temperature monitoring device 713 for monitoring the temperature of the saturated brine is provided in the salt tank 71, the electrolysis chamber 74 further includes a current monitoring device 740 for monitoring the current between the cathode and the anode, and the integrated water tank has a controller, and the temperature monitoring device 713, the current monitoring device 740, the first valve 77 and the second valve 78 are electrically connected to the controller, so that the controller can receive signals collected by the temperature monitoring device 713 and the current monitoring device 740 and control the on/off of the first tap water pipe 711, the second tap water pipe 721, the saturated brine pipe 712, the first soft water pipe 722 and the second soft water pipe 723. In this embodiment, the temperature monitoring device 713 is a temperature probe and is installed at the bottom inside the salt tank 71; the current monitoring device 740 is a current monitor, is installed outside the case 741, and is electrically connected to the anode 743 and the cathode 744, thereby feeding back the current applied to the anode and the cathode in real time.

The design idea is as follows: the water provided by the salt tank 71 is saturated saline water, the water provided by the softening tank 72 is soft water (the concentration of NaCl in the soft water is 0), the volume of the thick water tank 73 is constant, the concentration of NaCl in the saturated saline water can be calculated through the temperature measured by the temperature monitoring device 713 because the concentration of NaCl in the saturated saline water is related to the temperature (see table 1 for details), then the introduction ratio of the saturated saline water to the soft water is determined, during actual operation, the supply time of the saturated saline water and the soft water is controlled by switching the first valve 77, the concentration of the thick water can be preliminarily realized to be about 0.1wt%, but because the flow of tap water fluctuates, the volume of the liquid obtained according to the flow time mode has certain errors, and the mode can only roughly adjust the concentration of NaCl in the thick water. When the concentration of NaCl in the concentrated water is 0.1wt%, the current measured by the current monitoring device 740 is 2A, when the concentration is higher than 2A, the concentration is higher, when the concentration is lower than 2A, the concentration is lower, when the concentration is higher, the second tap water pipe 721 can be opened by switching the first valve 77, a certain amount of soft water is supplemented until the current is reduced to 2A, when the concentration is lower, the first tap water pipe 711 can be opened by switching the first valve 77, a certain amount of saturated salt water is supplemented until the current is increased to 2A, and therefore the concentration of NaCl in the concentrated water can be finely adjusted.

TABLE 1 relationship between NaCl concentration in saturated brine and temperature

Temperature (. Degree.C.)	NaCl concentration (wt%) in saturated brine
		0±5	26.31
10±5	26.36
		20±5	26.47
30±5	26.63

The control method of the electrolyzed water forming apparatus 7 is as follows:

after the electrolyzed water generating device 7 is started, corresponding actions are carried out according to the instruction of a user:

(1) A first operating mode: when a user indicates to produce acidic water and alkaline water, the first valve 77 and the second valve 78 are sequentially switched to a first state and a second state, tap water enters the salt tank 71 through the first tap water pipe 711 and is mixed with salt to form saturated salt water, then the saturated salt water enters the concentrated water tank 73 through the saturated salt water pipe 712, tap water enters the soft water tank 72 through the second tap water pipe 721 and is softened into soft water, then the soft water enters the concentrated water tank 73 through the first soft water pipe 722, the saturated salt water and the soft water are mixed in the concentrated water tank 73 to form concentrated water, then under the action of the first delivery pump 7311, the concentrated water is delivered into the electrolysis chamber 74 through the concentrated water pipe 731 for electrolysis, acidic water is generated in the anode chamber 7411, alkaline water is generated in the cathode chamber 7412, and then the concentrated water flows out of the acidic water tank 75 and the alkaline water tank 76 through the first water outlet end and the second water outlet end respectively for storage;

in this process, the concentration of the concentrated water is roughly adjusted by the following means: the temperature monitoring device 713 measures the temperature of the saturated salt water in the salt tank 71, the controller calculates the concentration C of the saturated salt water according to the temperature measured by the temperature monitoring device 713, then the volume ratio V of the saturated salt water and the soft water introduced into the concentrated water tank 73 is determined according to the target concentration Ct of the concentrated water, and V = Ct/(C-Ct);

the concentration of the concentrated water is finely adjusted by the following method: the current monitoring device 740 detects a real-time current I between the cathode and the anode in the electrolysis chamber 74, the controller judges the magnitude between the real-time current I and a target current It, if I is smaller than It, saturated salt water is supplemented into the concentrated water tank 73, and if I is larger than It, soft water is supplemented into the concentrated water tank 73;

(2) A second operating mode: when the user instructs to supply soft water to the washing machine, the first and second valves 77 and 78 are switched to the third state, the tap water is introduced into the soft water tank 72 through the second tap water pipe 721 to be softened into soft water, and then the soft water is introduced into the washing machine 5 through the second soft water pipe 723;

(3) The third working mode is as follows: when a user indicates to supply alkaline water to the garbage disposer 3, the third valve 79 is switched to communicate the alkaline water pipe 761, the alkaline water in the alkaline water tank 76 is pumped into the annular spray pipe 36 through the alkaline water pipe 761 under the action of the second delivery pump 7511, then the alkaline water is uniformly sprayed on the wall surface of the treatment barrel 3 through the spray holes 361 to react with oily substances, and simultaneously the bottom of the treatment barrel 32 and the cutter 331 are cleaned in cooperation with the rotation of the cutter 331, so that grease can be quickly and efficiently washed away;

(4) The fourth working mode: when the user instructs to supply the acidic water to the garbage disposer 3, the third valve 79 is switched to connect the acidic water pipe 751, and the acidic water in the acidic water tank 75 is pumped into the annular nozzle 36 through the acidic water pipe 751 by the second delivery pump 7511, and then the acidic water is uniformly sprayed to the wall of the treating tub 3 through the spray holes 361 for sterilization, and simultaneously the bacteria on the bottom of the treating tub 32 and the cutter 331 are rapidly and efficiently killed in cooperation with the rotation of the cutter 331.

It can be seen that in the present embodiment, the salt tank 71 and the soft water tank 72 are shared by the electrolyzed water generating apparatus 7 and the cleaning machine 5, so that the electrolytic chamber 74 can generate acidic and alkaline electrolyzed water without increasing the cost, and the diaphragm and the electrodes are not easily blocked by the scale to be invalid, thereby greatly prolonging the service life.

Example 2:

as shown in fig. 9 to 12, which is a second preferred embodiment of the integrated sink of the present invention. The difference from example 1 is that:

in this embodiment, the electrolyzed water forming apparatus 7 omits the concentrate tank 73.

The electrolytic chamber 74 is a double-diaphragm three-chamber electrolytic chamber for electrolyzing the saturated saline and soft water to produce acidic water and alkaline water. Specifically, the box 741 has a first water inlet end, a second water inlet end, a third water inlet end, a water discharge end, a first water outlet end and a second water outlet end; the number of the diaphragms 742 is two, and the two diaphragms 742 are arranged side by side, the two diaphragms 742 are respectively an anion exchange membrane and a cation exchange membrane, and divide the inner cavity of the box 741 into an anode chamber 7411, an intermediate chamber 7413 and a cathode chamber 7412 which are arranged in sequence, a first water inlet end and a water outlet end on the box 741 are communicated with the intermediate chamber 7413, a second water inlet end and a first water outlet end on the box 741 are communicated with the anode chamber 7411, and a third water inlet end and a second water outlet end on the box 741 are communicated with the cathode chamber 7412. In addition, the anode 743 and the cathode 744 are electrically connected to an external power supply, which is a current-limiting power supply in this embodiment, so the design has the advantages that: for a double-diaphragm system, saturated saline solution is introduced into the intermediate chamber 7413, the concentration is very high, the current during the electrolytic reaction is very high, the reaction is too violent, the electrolyte consumption is high, the generated products and byproducts are uncontrollable, the current is limited within a certain range by a current-limiting power supply, the consumption of the electrolyte can be saved on the premise of ensuring that the required pH value is generated to obtain acid and alkaline electrolytic water, the safety of the reaction is ensured, and the energy-saving effect is achieved.

The salt tank 71 further has a return end, the outlet end of the salt tank 71 is connected to the first inlet end of the electrolysis chamber 74 through a saturated saline pipe 712, a third delivery pump 7121 capable of delivering water from the inlet to the outlet of the saturated saline pipe 712 is installed on the saturated saline pipe 712, and the return end of the salt tank 71 is connected to the drain end of the electrolysis chamber 74 through a return pipe 713.

The water outlet end of the soft water tank 72 communicates with the second and third water inlet ends of the electrolysis chamber 74 through the first soft water pipe 722, and communicates with the water inlet end of the washing machine 5 through the second soft water pipe 723.

In this embodiment, the first and second

flexible water pipes

722 and 723 share one second valve 78. A fifth communication pipeline is connected between the water outlet end of the soft water tank 72 and the second valve 78, a sixth communication pipeline is connected between the second valve 78 and the second water inlet end and the third water inlet end of the electrolysis chamber 74, a seventh communication pipeline is communicated between the second valve 78 and the water inlet end of the washing machine 5, the fifth communication pipeline and the sixth communication pipeline form a first soft water pipe 722, and the fifth communication pipeline and the seventh communication pipeline form a second soft water pipe 723.

By switching the first valve 77 and the second valve 78, the integrated water tank has at least two states:

in the first state, the inlets of the third communication pipes communicate to communicate the second tap water pipe 721; the inlet of the sixth communication passage is communicated and the inlet of the seventh communication passage is blocked so that the first soft water pipe 722 is communicated and the second soft water pipe 723 is blocked; thus, the tap water in the tap water supply line is introduced into the soft water tank 72 through the second tap water pipe 721, and the soft water formed by softening the tap water under the above-mentioned water pressure is introduced into the anode chamber 7411 and the cathode chamber 712 of the electrolysis chamber 74 through the first soft water pipe 722;

in the second state, the inlets of the third communicating pipes communicate to communicate the second tap water pipe 721; the inlet of the sixth communication passage is blocked and the inlet of the seventh communication passage is communicated to communicate the second soft water pipe 723 and the first soft water pipe 722; thus, the tap water in the tap water supply line is introduced into the soft water tank 72 through the second tap water pipe 721, and the soft water formed by softening the tap water is introduced into the washing machine 5 through the second soft water pipe 723 under the above-mentioned water pressure.

The electrolytic water generator 7 is controlled as follows:

(1) A first operating mode: when a user indicates to produce acidic water and alkaline water, the first valve 77 and the second valve 78 are switched to a first state, tap water enters the salt tank 71 through the first tap water pipe 711 and is mixed with salt to form saturated salt water, under the action of the third delivery pump 7121, the saturated salt water enters the intermediate chamber 7413 of the electrolysis chamber 74 through the saturated salt water pipe 712 and is filled, tap water enters the soft water tank 72 through the second tap water pipe 721 and is softened into soft water, then the soft water enters the anode chamber 7411 and the cathode chamber 712 of the electrolysis chamber 74 through the first soft water pipe 722 and is filled, the electrolysis chamber 74 carries out electrolysis on the saturated salt water, acidic water is generated in the anode chamber 7411, alkaline water is generated in the cathode chamber 7412, then the soft water flows out of the acidic water tank 75 and the alkaline water tank 76 through the first water outlet end and the second water outlet end respectively, and the low-concentration salt water obtained after electrolysis of the intermediate chamber 7413 returns to the salt tank 71 through the water pipe 713 and is mixed with salt to regenerate the saturated salt water;

(2) A second working mode: when the user instructs to supply soft water to the washing machine, the first valve 77 and the second valve 78 are switched to the second state, the tap water enters the soft water tank 72 through the second tap water pipe 721 to be softened into soft water, and then the soft water enters the washing machine 5 through the second soft water pipe 723;

Example 3:

as shown in fig. 13 and 14, it is a third preferred embodiment of the integrated sink of the present invention. The difference from example 1 is that:

in this embodiment, the electrolyzed water forming apparatus 7 omits the salt tank 71.

In addition, a water purifier 4 is arranged in the cabinet body 1, the water purifier 4 has a water inlet end, a water purifying end and a waste water end, the water inlet end of the water purifier 4 is communicated with the tap water supply pipeline through a third tap water pipe 41, the water purifying end of the water purifier 4 is communicated with the water inlet end of the water purifying tap 112 through a water purifying pipe 42, and the waste water end of the water purifier 4 is communicated with the water inlet end of the soft water tank 72 through a waste water pipe 43, so that the waste water enters the soft water tank 72 to be softened and generate concentrated water. It should be noted that: the water purifier (especially using reverse osmosis membrane) can generate waste water (the ratio of clean water to waste water is 1.

The outlet end of the soft water tank 72 is connected to the inlet end of the rich water tank 73 through a first soft water pipe 722, so that the rich water is stored in the rich water tank 73, and the outlet end of the soft water tank 72 is connected to the inlet end of the washing machine 5 through a second soft water pipe 723.

Valves are provided on the third tap water pipe 41, the second tap water pipe 721, the first soft water pipe 722 and the second soft water pipe 723.

In this embodiment, the third tap water pipe 41 and the second tap water pipe 721 share the first valve 77. A first communicating pipe is connected between the tap water supply pipe and the first valve 77, a second communicating pipe is connected between the first valve 77 and the water inlet end of the water purifier 4, a third communicating pipe is connected between the first valve 77 and the water inlet end of the soft water tank 72, the first communicating pipe and the second communicating pipe form a third tap water pipe 41, and the first communicating pipe and the third communicating pipe form a second tap water pipe 721.

In the present embodiment, the first and second

flexible water pipes

722 and 723 share one second valve 78. A fifth communication pipeline is connected between the water outlet end of the soft water tank 72 and the second valve 78, a sixth communication pipeline is connected between the second valve 78 and the water inlet end of the thick water tank 73, a seventh communication pipeline is communicated between the second valve 78 and the water inlet end of the cleaning machine 5, the fifth communication pipeline and the sixth communication pipeline form a first soft water pipe 722, and the fifth communication pipeline and the seventh communication pipeline form a second soft water pipe 723.

in the first state, the inlets of the second and third communication passages are communicated, the inlet of the third communication passage is blocked, the inlet of the sixth communication passage is communicated, and the inlet of the seventh communication passage is blocked, so that the third and first

soft water pipes

41 and 722 are communicated, and the second and second

soft water pipes

721 and 723 are blocked; thus, the tap water in the tap water supply line is supplied to the water purifier 4 through the third tap water pipe 41, the purified water produced by the water purifier 4 is supplied to the purification tap 112 through the purified water pipe 42 under the aforementioned water pressure, the wastewater produced by the water purifier 4 is supplied to the soft water tank 72 through the wastewater pipe 43, and the concentrated water formed by the softening is supplied to the concentrated water tank 73 through the first soft water pipe 722 for storage;

in the second state, the inlet of the second communication pipe is blocked, the inlet of the third communication pipe is communicated, the inlet of the sixth communication passage is blocked, and the inlet of the seventh communication passage is communicated to communicate the second tap water pipe 721 with the second soft water pipe 723, and the third tap water pipe 41 with the first soft water pipe 722 are blocked; thus, the tap water in the tap water supply line is introduced into the soft water tank 72 through the second tap water pipe 721, and the soft water formed by softening the tap water is introduced into the washing machine 5 through the second soft water pipe 723 by the aforementioned water pressure.

The control method of the electrolyzed water forming apparatus 7 is as follows:

(1) A first operating mode: when the user instructs to supply the purified water, the first valve 77 and the second valve 78 are switched to the first state, the tap water is introduced into the water purifier 4 through the third tap water pipe 41 to be purified to generate the purified water supplied to the user through the purified water pipe 42 to the purification tap 112, and the waste water is introduced into the soft water tank 72 through the waste water pipe 43 to be softened into the concentrated water to be stored in the concentrated water tank 73, and then the concentrated water is introduced into the concentrated water tank 73 through the first soft water pipe 722 to be stored;

(2) A second operating mode: when a user indicates to produce acidic water and alkaline water, under the action of the first delivery pump 7311, the concentrated water in the concentrated water tank 73 is delivered into the electrolysis chamber 74 through the concentrated water pipe 731 for electrolysis, so as to generate acidic water in the anode chamber 7411 and alkaline water in the cathode chamber 7412, and then flows out to the acidic water tank 75 and the alkaline water tank 76 through the first water outlet end and the second water outlet end respectively for storage;

(3) A third working mode: when the user instructs to supply soft water to the washing machine, the first valve 77 and the second valve 78 are switched to the second state, the tap water is introduced into the soft water tank 72 through the second tap water pipe 721 to be softened into soft water, and then the soft water is introduced into the washing machine 5 through the second soft water pipe 723;

(4) A fourth operating mode: when a user instructs to supply alkaline water to the garbage disposer 3, the third valve 79 is switched to enable the alkaline water pipe 761 to be communicated, under the action of the second delivery pump 7511, the alkaline water in the alkaline water tank 76 is pumped into the annular spray pipe 36 through the alkaline water pipe 761, then the alkaline water is uniformly sprayed onto the wall surface of the treatment barrel 3 through the spray holes 361 to react with oily substances, and meanwhile, the bottom of the treatment barrel 32 and the cutter 331 are cleaned in cooperation with the rotation of the cutter 331, so that grease can be quickly and efficiently washed away;

(5) A fifth working mode: when the user instructs to supply the acidic water to the garbage disposer 3, the third valve 79 is switched to connect the acidic water pipe 751, and the acidic water in the acidic water tank 75 is pumped into the circular spray pipe 36 through the acidic water pipe 751 by the second delivery pump 7511, and then the acidic water is uniformly sprayed to the wall of the disposal bucket 3 through the spray holes 361 for sterilization, and simultaneously the bacteria on the bottom of the disposal bucket 32 and the cutter 331 are rapidly and efficiently killed in cooperation with the rotation of the cutter 331.

It can be seen that in the present embodiment, the soft water tank 72 is shared by the electrolyzed water generating apparatus 7 and the cleaning machine 5, and the waste water discharged from the water purifier 4 is utilized, so that the electrolytic chamber 74 can generate acidic and alkaline electrolyzed water without increasing the cost, and the diaphragm and the electrode are not easily blocked by the scale, thereby greatly prolonging the service life.

The term "fluid communication" as used herein refers to a spatial relationship between two components or portions (hereinafter, referred to as a first portion and a second portion) that fluid (gas, liquid or a mixture thereof) can flow along a flow path from the first portion or/and be transported to the second portion, and may be the first portion and the second portion directly connected to each other or indirectly connected to each other through at least one third member, such as a fluid passage, e.g., a pipe, a channel, a duct, a flow guide member, a hole, a groove, or a chamber allowing fluid to flow therethrough, or a combination thereof.

Claims

1. The utility model provides an integrated water tank, includes that the top has cabinet body (1), the main part of mesa (11) to locate basin (2) under mesa (11) and locate garbage disposer (3) and electrolytic water generating device (7) in the cabinet body (1), its characterized in that: the electrolyzed water generating device (7) comprises an acidic water tank (75) used for storing acidic water and an alkaline water tank (76) used for storing alkaline water, the garbage disposer (3) comprises a treatment barrel (32) and an annular spray pipe (36) used for cleaning the treatment barrel (32), the annular spray pipe (36) is provided with a water inlet end and a water outlet end, the water inlet end of the annular spray pipe (36) is respectively communicated with the acidic water tank (75) and the alkaline water tank (76) through an acidic water pipe (751) and an alkaline water pipe (761), and the water outlet end of the annular spray pipe (36) faces to the inner cavity of the treatment barrel (32).

2. The integrated sink of claim 1, wherein: the electrolyzed water generating device (7) also comprises

A salt tank (71) for mixing water and salt to produce a saturated salt solution, having a water inlet end and a water outlet end for discharging the saturated salt solution, the water inlet end of the salt tank (71) being in fluid communication with a tap water supply line;

the soft water tank (72) is used for softening the water body and is provided with a water inlet end for hard water to enter and a water outlet end for soft water to be discharged, and the water inlet end of the soft water tank (72) is communicated with a running water supply pipeline in a fluid mode;

the concentrated water tank (73) is used for mixing saturated salt water and soft water to generate concentrated water, and is provided with a first water inlet end, a second water inlet end and a water outlet end for discharging the concentrated water, the first water inlet end of the concentrated water tank (73) is communicated with the water outlet end of the salt tank (71) in a fluid mode, and the second water inlet end of the concentrated water tank (73) is communicated with the water outlet end of the soft water tank (72) in a fluid mode; and

an electrolysis chamber (74) for electrolyzing concentrated water to generate acidic water and alkaline water, having a water inlet end, a first water outlet end for discharging acidic water and a second water outlet end for discharging alkaline water, the water inlet end of the electrolysis chamber (74) being in fluid communication with the water outlet end of the concentrated water tank (73), the first water outlet end of the electrolysis chamber (74) being in fluid communication with the acidic water tank (75), the second water outlet end of the electrolysis chamber (74) being in fluid communication with the alkaline water tank (76).

3. The integrated sink of claim 2, wherein: the electrolytic chamber (74) comprises

A case (741);

a diaphragm (742) provided in the tank (741) and dividing an inner cavity of the tank (741) into an anode chamber (7411) and a cathode chamber (7412);

an anode (743) disposed in the anode chamber (7411); and

a cathode (744) disposed in the cathode chamber (7412);

the water inlet end of the electrolysis chamber (74) is communicated with the anode chamber (7411) and the cathode chamber (7412), the first water outlet end of the electrolysis chamber (74) is communicated with the anode chamber (7411), and the second water outlet end of the electrolysis chamber (74) is communicated with the cathode chamber (7412).

4. The integrated sink of claim 2, wherein: the water inlet end of the salt tank (71) is communicated with the tap water supply pipeline through a first tap water pipe (711);

the water inlet end of the soft water tank (72) is communicated with the tap water supply pipeline through a second tap water pipe (721);

valves are arranged on the first tap water pipe (711) and the second tap water pipe (721) respectively, so that the integrated water tank has at least two states:

in the first state, the first tap water pipe (711) is communicated, and the second tap water pipe (721) is blocked;

in a second state, the second tap water pipe (721) is connected and the first tap water pipe (711) is blocked.

5. The integrated sink of claim 4, wherein: the cleaning machine (5) is arranged in the cabinet body (1), the cleaning machine (5) is provided with a water inlet end, and the water inlet end is communicated with the water outlet end of the soft water tank (72) through fluid.

6. The integrated sink of claim 5, wherein: the water outlet end of the soft water tank (72) is communicated with the second water inlet end of the concentrated water tank (73) through a first soft water pipe (722), and is communicated with the water inlet end of the cleaning machine (5) through a second soft water pipe (723);

the first and second flexible water pipes (722, 723) are provided with valves, so that the integrated water tank has a third state:

in the second state, the first soft water pipe (722) is communicated, and the second soft water pipe (723) is blocked;

in the third state, the second tap water pipe (721) is connected, the first tap water pipe (711) is blocked, the second soft water pipe (723) is connected, and the first soft water pipe (722) is blocked.

7. The integrated sink of claim 4, wherein: the salt tank (71) is internally provided with a temperature monitoring device (713) for monitoring the temperature of saturated saline water, the integrated water tank is provided with a controller, and the temperature monitoring device (713) and valves on the first tap water pipe (711) and the second tap water pipe (721) are electrically connected with the controller, so that the controller can receive signals collected by the temperature monitoring device (713) and control the on-off of the first tap water pipe (711) and the second tap water pipe (721).

8. The integrated sink of claim 7, wherein: the electrolytic chamber (74) also comprises a current monitoring device (740) for monitoring the current between the cathode and the anode, and the current monitoring device (740) is electrically connected with the controller, so that the controller can receive signals collected by the current monitoring device (740) and control the on-off of the first tap water pipe (711) and the second tap water pipe (721).

9. The integrated sink of claim 2, wherein: the salt tank (71) is communicated with the soft water tank (72) through a backflushing channel (720), and a valve for controlling the on-off of the backflushing channel (720) is arranged at the backflushing channel.

10. The integrated sink of claim 1, wherein: the electrolyzed water generating device (7) also comprises

The salt tank (71) is used for mixing water and salt to generate saturated salt water, and is provided with a water inlet end, a water outlet end for discharging the saturated salt water and a water return end for recovering the salt water, and the water inlet end of the salt tank (71) is in fluid communication with a tap water supply pipeline;

the soft water tank (72) is used for softening a water body and is provided with a water inlet end for hard water to enter and a water outlet end for soft water to be discharged, and the water inlet end of the soft water tank (72) is in fluid communication with a tap water supply pipeline; and

an electrolysis chamber (74) for electrolyzing saturated salt water and soft water to generate acidic water and alkaline water, having a first water inlet end, a second water inlet end, a third water inlet end, a water discharge end, a first water outlet end for discharging acidic water, and a second water outlet end for discharging alkaline water, the first water inlet end of the electrolysis chamber (74) being in fluid communication with the water outlet end of the salt tank (71), the second water inlet end and the third water inlet end of the electrolysis chamber (74) being in fluid communication with the water outlet end of the soft water tank (72), the water discharge end of the electrolysis chamber (74) being in fluid communication with the water return end of the salt tank (71), the first water outlet end of the electrolysis chamber (74) being in fluid communication with the acidic water tank (75), the second water outlet end of the electrolysis chamber (74) being in fluid communication with the alkaline water tank (76).

11. The integrated sink of claim 10, wherein: the electrolytic chamber (74) comprises

A case (741);

two diaphragms (742) arranged side by side are arranged in the box body (741) and divide the inner cavity of the box body (741) into an anode chamber (7411), an intermediate chamber (7413) and a cathode chamber (7412) which are arranged in sequence;

an anode (743) disposed in the anode chamber (7411); and

a cathode (744) disposed in the cathode chamber (7412);

the first water inlet end and the water outlet end of the electrolysis chamber (74) are communicated with the intermediate chamber, the second water inlet end and the first water outlet end of the electrolysis chamber (74) are communicated with the anode chamber (7411), and the third water inlet end and the second water outlet end of the electrolysis chamber (74) are communicated with the cathode chamber (7412).

12. The integrated sink of claim 10, wherein: the cleaning machine (5) is arranged in the cabinet body (1), the cleaning machine (5) is provided with a water inlet end, and the water inlet end is communicated with the water outlet end of the soft water tank (72) through fluid.

13. The integrated sink of claim 12, wherein: the water outlet end of the soft water tank (72) is communicated with the second water inlet end and the third water inlet end of the electrolysis chamber (74) through a first soft water pipe (722), and is communicated with the water inlet end of the cleaning machine (5) through a second soft water pipe (723);

the first flexible water pipe (722) and the second flexible water pipe (723) are respectively provided with a valve, so that the integrated water tank has at least two states:

in the first state, the first soft water pipe (722) is communicated, and the second soft water pipe (723) is blocked;

in the second state, the second soft water pipe (723) is communicated, and the first soft water pipe (722) is blocked.

14. The integrated sink of claim 10, wherein: the salt tank (71) is communicated with the soft water tank (72) through a backflushing channel (720), and a valve for controlling the on-off of the backflushing channel (720) is arranged at the backflushing channel.

15. The integrated sink of claim 1, wherein: a water purifier (4) is arranged in the cabinet body (1), the water purifier (4) is provided with a water inlet end, a water purifying end and a waste water end, and the water inlet end of the water purifier (4) is in fluid communication with a tap water supply pipeline;

the electrolyzed water generating device (7) also comprises

The soft water tank (72) is used for softening a water body and is provided with a water inlet end for hard water to enter and a water outlet end for soft water to be discharged, and the water inlet end of the soft water tank (72) is communicated with the wastewater end of the water purifier (4) in a fluid mode so that the wastewater enters the soft water tank (72) to be softened and generate concentrated water;

a concentrate tank (73) for storing concentrate having a water inlet end and a water outlet end, the water inlet end of the concentrate tank (73) being in fluid communication with the water outlet end of the soft water tank (72); and

16. The integrated sink of claim 15, wherein: the electrolytic chamber (74) comprises

A case (741);

an anode (743) disposed in the anode chamber (7411); and

a cathode (744) disposed in the cathode chamber (7412);

17. The integrated sink of claim 15, wherein: the cleaning machine is characterized in that a cleaning machine (5) is arranged in the cabinet body (1), the cleaning machine (5) is provided with a water inlet end, the water inlet end of the soft water tank (72) is communicated with a tap water supply pipeline in a fluid mode, and the water outlet end of the soft water tank (72) is communicated with the water inlet end of the cleaning machine (5) in a fluid mode.

18. The integrated sink of claim 17, wherein: the water inlet end of the water purifier (4) is communicated with the tap water supply pipeline through a third tap water pipe (41), and the waste water end of the water purifier (4) is communicated with the water inlet end of the soft water tank (72) through a waste water pipe (43);

the water inlet end of the soft water tank (72) is communicated with the tap water supply pipeline through a second tap water pipe (721), the water outlet end of the soft water tank (72) is communicated with the water inlet end of the concentrated water tank (73) through a first soft water pipe (722), and the water outlet end of the soft water tank (72) is communicated with the water inlet end of the cleaning machine (5) through a second soft water pipe (723);

valves are arranged on the third tap water pipe (41), the second tap water pipe (721), the first soft water pipe (722) and the second soft water pipe (723), so that the integrated water tank has at least two states:

in the first state, the third tap water pipe (41) is communicated with the first soft water pipe (722), and the second tap water pipe (721) is blocked from the second soft water pipe (723);

in the second state, the second tap water pipe (721) and the second soft water pipe (723) are communicated, and the third tap water pipe (41) and the first soft water pipe (722) are blocked.

19. The integrated sink of claim 16, wherein: mesa (11) on install clean water tap (112), this clean water tap (112) have into water end and play water end, the end of intaking of clean water tap (112) passes through clean water pipe (42) intercommunication the clean water end of water purifier (4), the play water end orientation of clean water tap (112) the open-top of basin (2).

20. The integrated sink according to any one of claims 1 to 19, wherein: valves are arranged on the acidic water pipe (751) and the alkaline water pipe (761).

21. The integrated sink according to any one of claims 1 to 19, wherein: the circumferential wall of one side of the annular spray pipe (36) facing the inner cavity of the treatment barrel (32) is provided with at least two spray holes (361) which are arranged at intervals along the circumferential direction, and the spray holes (361) form the water outlet end of the annular spray pipe (36).

22. The integrated sink according to any one of claims 1 to 19, wherein: an accommodating groove (321) with an open top is formed in the processing barrel (32), and the garbage processor (3) further comprises a crushing device (33) for crushing the garbage in the accommodating groove (321).

23. The integrated sink of claim 22, wherein: the crushing device (33) comprises a cutter (331) which is rotatably connected to the bottom wall inside the processing barrel (32); and

the driving piece (332) is installed at the bottom of the processing barrel (32), the power output end of the driving piece sequentially penetrates through the processing barrel (32) and extends into the accommodating groove (321), and the power output end of the driving piece (332) is detachably connected with the cutter (331).