WO2022083319A1 - Dishwasher - Google Patents

Abstract

Provided is a dishwasher. Saline water for electrolysis is generated by means of a saline water generator, the saline water can be electrolyzed itself in a chamber structure and form high-valence hypochlorite ions, and a box can be provided to achieve fixing of the chamber structure itself. Disinfectant with high oxidability enters an inner container (d5) from the chamber structure to clean tableware in the inner container (d5), a bowl basket and side walls thereof, etc. in the inner container (d5), and fruits, vegetables, etc. in the inner container (d5), so as to achieve all-around disinfection for the inner container (d5).

Description

a dishwasher

This disclosure claims the priority of a Chinese patent application with the application number 202011150216.8 and the invention titled “A Dishwasher” filed with the China Patent Office on October 23, 2020, the entire contents of which are incorporated in this disclosure by reference.

technical field

The present disclosure relates to the technical field of household appliances, in particular to a dishwasher.

Background technique

With the improvement of living standards, dishwashers have gradually entered our ordinary families, improving our quality of life.

Generally, the main core components of an existing dishwasher usually include: a liner assembly, a water cup assembly, a spray arm assembly, a filter assembly, a washing pump, a drain pump, and pipelines. At present, dishwashers on the market generally use high temperature (usually about 70 ° C) for main cleaning and tableware disinfection, and some are also equipped with UVC ultraviolet lamps for disinfection, adding silver ions to parts materials for bacteriostasis, steam high-temperature disinfection, hot air drying, etc.

SUMMARY OF THE INVENTION

The present disclosure provides a novel dishwasher.

A dishwasher comprising:

The chamber structure is provided with a water tank chamber, and the water tank chamber is provided with a salt water generating device;

an electrolysis assembly, which is arranged inside the water tank chamber and is suitable for electrolyzing the brine generated by the brine generating device;

A box body, the chamber structure acts on the box body, the box body includes an inner tank and a door body suitable for closing the inner tank, the inner tank is suitable for placing tableware to be cleaned, and the The chamber structure is adapted to act on at least one of the liner and the door;

Substances located in the chamber structure are adapted to flow out of the tank chamber and into the bladder.

In the dishwasher provided by the present disclosure, the chamber structure includes at least one of a respirator and a water tank.

In the dishwasher provided by the present disclosure, the cavity structure is provided on the inner container.

In the dishwasher provided by the present disclosure, the cavity structure is a water tank, and the water tank is detachably arranged on the inner tank.

In the dishwasher provided by the present disclosure, an overflow port is provided on the water tank, a through hole is provided on the inner tank at a position corresponding to the overflow port, and a space between the overflow port and the through hole is provided. An overflow exhaust structure is provided, and the overflow exhaust structure is suitable for restricting the unidirectional flow of substances in the water tank into the through hole from the overflow port.

In the dishwasher provided by the present disclosure, the overflow exhaust structure includes:

The water gas inlet is arranged through the first side of the overflow exhaust structure;

a water blocking end cover, which is arranged on the second side of the overflow and exhaust structure and is arranged along the extending direction of the water and gas inlet, and is suitable for blocking the extending direction of the water and gas inlet; and

The overflow exhaust port penetrates through the overflow exhaust structure in a direction parallel to the water blocking end cover, and is at least partially in conduction with the water gas inlet port.

In the dishwasher provided by the present disclosure, the overflow exhaust structure further includes: a backflow prevention rib disposed on the conducting path between the overflow port and the overflow exhaust port, and the backflow prevention rib is adapted to at least partially to block the overflow.

In the dishwasher provided by the present disclosure, the backflow prevention rib is disposed at the lower edge of the overflow port.

In the dishwasher provided by the present disclosure, the lowest point position of the backflow prevention rib in the up-down direction is higher than the lowest point position of the overflow exhaust port.

In the dishwasher provided by the present disclosure, the backflow prevention rib is arranged in parallel with the water blocking end cover.

In the dishwasher provided by the present disclosure, the overflow exhaust structure further includes: a flow guide rib at least partially disposed around the water gas inlet and adapted to support the water blocking end cover.

In the dishwasher provided by the present disclosure, the notch of the guide rib and the water blocking end cover are jointly enclosed to form the overflow exhaust port.

In the dishwasher provided by the present disclosure, the angle between the exhaust overflow direction of the overflow exhaust port and the horizontal plane is β1, where 0°≤β1≤180°.

The dishwasher provided by the present disclosure further includes: a spray arm, suitable for spraying water flow; the value range of the included angle β2 between the opening direction of the overflow exhaust port and the spraying direction of the spray arm is 90°≤β2≤ 180°.

In the dishwasher provided by the present disclosure, the overflow exhaust structure is further provided with a tooling rib, and the tooling rib is suitable for adjusting the orientation of the overflow exhaust port.

In the dishwasher provided by the present disclosure, an overflow port flange is provided around the periphery of the overflow port, and a screw portion is provided on the overflow exhaust structure corresponding to the overflow port flange; the An inner thread or an outer thread is arranged on the flange of the overflow port, and an outer thread or an inner thread is correspondingly arranged on the screwing part.

In the dishwasher provided by the present disclosure, an overflow port sealing ring is further arranged between the water tank and the inner tank, and the overflow port sealing ring is arranged around the overflow port.

In the dishwasher provided by the present disclosure, the salt water generating device comprises: a dispenser, which is detachably arranged on the water tank, and an accommodating groove is arranged in the dispenser.

In the dishwasher provided by the present disclosure, the water tank includes:

the side wall of the first water tank;

The side wall of the second water tank is arranged opposite to the side wall of the first water tank, the side wall of the second water tank is arranged adjacent to the inner wall of the inner tank, and the overflow exhaust structure corresponds to the second water tank side wall setting;

A salt injection port is provided on the side wall of the second water tank, a flange hole is provided on the inner wall of the inner tank at a position corresponding to the salt injection port, and the injection device is adapted to penetrate into the in the water tank.

In the dishwasher provided by the present disclosure, a salt spout flange is formed protruding from the edge of the salt injection opening in the direction extending into the inner tank, and the dispenser is detachably arranged on the salt spout flange.

In the dishwasher provided by the present disclosure, a knob catch is protruded from the inner wall of the salt spout flange, and the dispenser is detachably connected to the knob catch.

The dishwasher provided by the present disclosure further includes: a water channel, which is provided on the water tank, and is provided with a drain port, and the water passing through the water channel acts on the accommodating tank through the drain port.

The dishwasher provided by the present disclosure further comprises: a water tank inlet and a water tank outlet, which are respectively communicated with the water tank chamber, one end of the water channel is connected to the water tank water inlet, and the water channel includes a drainage section and a rectification section, The water outlet is formed on at least one of the diversion section and the rectification section.

In the dishwasher provided by the present disclosure, the drain port is provided on the rectifying section.

In the dishwasher provided by the present disclosure, the dispenser includes:

the accommodating groove;

The holding part is arranged on the first groove wall of the accommodating groove.

In the dishwasher provided by the present disclosure, a plurality of flow-through holes are provided at the bottom of the accommodating tank.

In the dishwasher provided by the present disclosure, a plurality of the flow-through holes are arranged in a side-by-side linear shape at the bottom of the accommodating groove and close to the second groove wall.

In the dishwasher provided by the present disclosure, the flow-through hole is configured as a circular hole, and the diameter of the circular hole ranges from 0.5 mm to 5 mm or more.

In the dishwasher provided by the present disclosure, the accommodating groove is further provided with a plurality of scales along the groove depth direction, and the scales are used to identify the real-time capacity of the accommodating groove.

In the dishwasher provided by the present disclosure, when the rotating clip is clipped to the positioning clip slot, the flow-through hole of the accommodating slot is disposed toward the drain port in the water tank.

In the dishwasher provided by the present disclosure, the projection of the drain port coincides with the flow hole.

The dishwasher provided by the present disclosure further includes a fixing seat, which is arranged on the salt mouth flange, and after the fixing seat is fixed in place, one end surface of the fixing seat abuts on the inner wall.

In the dishwasher provided by the present disclosure, the fixing seat is screwed on the salt mouth flange.

The dishwasher provided by the present disclosure further includes: a water cup, which is arranged in the inner tank; the water tank is provided with a water tank outlet, and the water outlet of the water tank is located on a plane higher than the upper surface of the water cup.

The dishwasher provided by the present disclosure further includes: a respirator, on which is provided a respirator water inlet pipe, the respirator water inlet pipe is connected to a water source through a water inlet solenoid valve; a water softener is connected to the respirator The water softener is provided with a water softener water outlet pipe; a three-way valve is connected with the water softener water outlet pipe, and the water outlet ends of the three-way valve are respectively communicated with the water tank and the water cup.

In the dishwasher provided by the present disclosure, a plurality of layers of bowl baskets arranged in the height direction are arranged in the inner vessel, and the bowl baskets are suitable for placing tableware; a baffle plate is arranged on the opening of the inner vessel, and the baffle plate is adapted to close the opening.

The technical solution of the present disclosure has the following advantages:

1. The dishwasher provided by the present disclosure, with a chamber structure, is provided with a water tank chamber, and a salt water generating device is provided on the water tank chamber; The salt water generated by the salt water generating device is electrolyzed; a box body, the chamber structure acts on the box body, the box body includes an inner tank and a door body suitable for sealing the inner tank, and the inner tank is in the inner tank. Suitable for placing tableware to be cleaned, the cavity structure is suitable for acting on at least one of the inner tank and the door body; the substance located in the cavity structure is suitable for flowing out from the water tank cavity and into the liner.

The brine for electrolysis is generated by the brine generator. The brine can electrolyze the brine itself in the chamber structure and form high-value hypochlorite ions. By setting the box, the chamber structure itself can be fixed. The disinfectant with high oxidizing property will enter into the inner tank from the chamber structure, and clean the tableware in the inner tank, the bowls and baskets in the inner tank, the side walls, etc., and the fruits and vegetables in the inner tank, so as to realize All-round disinfection of the inner tank.

2. In the dishwasher provided by the present disclosure, an overflow port is provided on the water tank, a through hole is provided on the inner tank at a position corresponding to the overflow port, and the overflow port is connected to the through hole. An overflow exhaust structure is arranged therebetween, and the overflow exhaust structure is adapted to restrict the material in the water tank from flowing into the through hole in one direction from the overflow port.

When there is too much water in the water tank, the excess water can be drawn out of the water tank through the overflow port. In addition, the highly oxidizing disinfectant produced in the water tank is clean water, while the water in the inner tank itself It is turbid water, which is mixed with a large amount of oil pollution. At this time, it is necessary to prevent the water in the inner tank from flowing backward into the water tank, causing pollution to the water in the water tank. One-way flow of clean water to the inner tank, and through the overflow exhaust structure, when the electrolysis reaction occurs inside the water tank, flammable gases such as hydrogen will be generated inside the water tank. By setting the overflow port, the hydrogen can be quickly discharged from the water tank. Lead out to the outside world to ensure the safety of the water tank itself.

3. In the dishwasher provided by the present disclosure, the overflow exhaust structure comprises: a water gas inlet, which is arranged through the first side of the overflow exhaust structure; a water blocking end cover is arranged on the overflow The second side of the exhaust structure is arranged along the extending direction of the water and gas inlet, and is suitable for shielding the extending direction of the water and gas inlet. By arranging the water blocking end cover, the unidirectional flow of the clean water in the water tank to the inner tank can be realized.

4. In the dishwasher provided by the present disclosure, the backflow prevention rib is arranged in the overflow port of the water tank, specifically arranged on the conduction path between the overflow port and the overflow exhaust port, and is preferably arranged in the overflow port. inside the flow port and at a position corresponding to the overflow exhaust port. Therefore, the liquid or gas from a specific angle of the second side of the overflow exhaust structure is not only blocked by the water blocking end cover, but also enters the overflow exhaust port when a small part of the liquid or gas is After that, it is blocked by the backflow prevention ribs again, so as to reduce the occurrence of the situation of entering the overflow exhaust structure due to sputtering.

The cooperation of the backflow prevention rib and the water blocking end cover makes the diversion channel inside the overflow exhaust structure form a meandering structure, which increases the specificity to the second side of the overflow exhaust structure. The shielding of the liquid or gas at the angle increases the difficulty of the liquid or gas from a specific angle of the second side of the overflow exhaust structure entering the overflow exhaust structure.

5. In the water tank provided by the embodiment of the present disclosure, the lowest point position of the backflow prevention rib in the up-down direction is higher than the lowest point position of the overflow exhaust port, so that after the overflowed water in the water tank enters the water vapor inlet port, It will be blocked by the anti-reflux ribs to avoid backflow; and after the external water enters from the overflow exhaust port, it will also be blocked by the anti-reflux ribs in the process of flowing to the water tank, thereby reducing the amount of external water entering the water tank. probability.

6. In the dishwasher provided by the present disclosure, the opening direction of the overflow exhaust port and the spraying direction of the spray arm are set at an angle, and the specific value range is 90°≤β2≤180°, that is, the The opening direction of the overflow exhaust port and the spraying direction of the spray arm are arranged in a substantially opposite direction, which can reduce the entry of the spray water flow of the spray arm into the overflow exhaust structure, thereby reducing the number of spray arms. A jet of water is injected into the water tank.

7. In the dishwasher provided by the present disclosure, the salt water generating device comprises: a dispenser, which is detachably arranged on the water tank, and a accommodating groove is arranged in the dispenser; a water channel is arranged on the water tank, A drain port is provided on it, and the water passing through the water channel acts on the accommodating tank through the drain port.

Through the combination between the dispenser and the water channel, the water outside the dishwasher can be introduced into the water tank, and at the same time, the operation of dissolving the salt in the dispenser inside the water tank can be realized, and the operation is simple and efficient. At the same time, the amount of salt placed in the accommodating tank can also be adjusted according to the type, quantity or degree of contamination of the tableware, thereby improving the applicable range of the entire device.

8. In the dishwasher provided by the present disclosure, the water tank includes a first water tank side wall; a second water tank side wall, which is disposed opposite to the first water tank side wall, and the second water tank side wall is connected to the inner wall. The inner tank wall is arranged adjacently; the side wall of the second water tank is provided with a salt injection port, and the part corresponding to the salt injection port is provided with a flange hole on the inner tank wall, and the injection device is suitable for passing through the inner tank wall. Flange holes penetrate deep into the tank.

Through the combination between the salt injection port and the flange hole, the connection between the water tank and the inner tank can be realized, and at the same time, it is helpful to realize the material exchange between the water tank and the inner tank.

9. In the dishwasher provided by the present disclosure, a salt spout flange is protruded and formed on the edge of the salt spout extending into the inner pot, and the dispenser is detachably arranged on the salt spout flange . A knob catch is protruded from the inner wall of the salt mouth flange, and the dispenser is detachably connected to the knob catch.

Through the above arrangement, the stable connection between the dispenser and the water tank can be achieved, the stability of the dispenser itself can be ensured during the preparation of salt water, and the stability during the preparation of the disinfectant can be achieved.

10. In the dishwasher provided by the present disclosure, when the rotating clip is clipped to the positioning clip slot, the flow-through hole of the accommodating slot is disposed toward the drain port in the water tank. The projection of the water outlet coincides with the flow hole.

Through the above setting method, the water flowing out from the drain can be directly applied to the position of the flow-through hole. At this time, the water has a large kinetic energy under the action of weight. Therefore, after flushing the salt, the salt water can be directly discharged from the flow-through hole. discharge, so that the production efficiency of the brine can be improved.

11. The dishwasher provided by the present disclosure, further comprising a fixing seat disposed on the salt mouth flange, and after the fixing seat is fixed in place, one end surface of the fixing seat abuts against the inner wall superior.

By arranging the fixing seat, after it cooperates with the flange of the salt mouth, a stable connection between the water tank and the inner tank can be realized, thereby improving the stability of the entire dishwasher itself.

12. The dishwasher provided by the present disclosure, further comprising: a water tank water inlet and a water tank water outlet, respectively communicating with the water tank chamber; one end of the water channel is connected to the water tank water inlet, and the water channel includes a drainage section and a rectifier The drainage port is formed on at least one of the diversion section and the rectification section.

The drainage section can guide the water flow from the water inlet to the inside of the water tank, and the rectification section can guide and adjust the direction of the water flow, thereby outputting a columnar water flow. When the water tank has a structure such as a solute tank for accommodating salt, the directional impact water column formed by the drainage section or the rectification section of the water channel makes the salt more fully contacted by the water column and dissolved in water. When the water is injected into the water tank to impact the salt to form a salt solution, or the salt solution is injected directly through the drain, the water in the water tank is electrolyzed in the water tank or into the electrolysis assembly to form a disinfectant. While the tableware in the dishwasher is disinfected with the disinfectant, the pipes through which the disinfectant flows are also sterilized. Therefore, even if there is a participating disinfectant, it will not breed bacteria.

13. The dishwasher provided by the present disclosure, wherein the drain port is provided on the rectifying section. The overall shape of the rectification section makes the water flow from the direction with higher gravitational potential energy to the direction with lower gravitational potential energy. On the one hand, the water in the drainage section forms a thrust on the water in the rectification section, and on the other hand, the gravitational potential energy is converted into kinetic energy, so that the water flows out from the rectification section. The water has a stronger ability to shock salt. When the salt has coagulated salt clumps in it, it can be more easily dissipated and dissolved into the water to form a salt solution.

14. The dishwasher provided by the present disclosure, further comprising: a respirator, on which is provided a respirator water inlet pipe, the respirator water inlet pipe is connected to a water source through a water inlet solenoid valve; a water softener, which is connected to the respirator. The water softener is provided with a water softener water outlet pipe; a three-way valve is connected with the water softener water outlet pipe, and the water outlet ends of the three-way valve are respectively communicated with the water tank and the water cup.

By setting the three-way valve, the water flowing out from the water softener can be introduced into the water tank for electrolysis water operation, or into the inner tank to rinse the tableware, so as to realize the cleaning and disinfection of the tableware in the inner tank.

15. The dishwasher provided by the present disclosure, wherein the cavity structure comprises at least one of a respirator and a water tank.

When the chamber structure itself adopts a respirator, the salt water generated by the salt water generating device enters the chamber structure, and the electrolysis component will perform electrolysis operation inside the respirator, thereby electrolyzing the salt water to form a disinfectant. An electrolytic component is arranged inside the traditional ventilator, and the prepared disinfectant can enter the interior of the dishwasher to achieve comprehensive disinfection and sterilization of the dishwasher.

Through the above arrangement, the preparation of the disinfectant itself can be realized by the respirator, thereby helping to reduce the structure involved in the whole machine and helping to improve the compactness of the whole machine.

Description of drawings

In order to more clearly illustrate the technical solutions in the specific embodiments of the present disclosure or related technologies, the following briefly introduces the accompanying drawings required in the description of the specific embodiments or related technologies. Obviously, the accompanying drawings in the following description are For some embodiments of the present disclosure, for those of ordinary skill in the art, other drawings can also be obtained from these drawings without creative efforts.

1 is a schematic structural diagram of the dispenser provided by the present disclosure;

2 is another schematic structural diagram of the dispenser provided by the present disclosure;

3 is a cross-sectional view of the dispenser provided by the present disclosure;

4 is a schematic diagram of the connection between the inner tank, the water tank and the fixing seat provided by the present disclosure;

5 is a schematic diagram of a fixing base provided by the present disclosure;

6 is an internal schematic diagram of a water tank provided by the present disclosure;

FIG. 7 is a schematic diagram of the position of the dispenser provided by the present disclosure when the assembly is not completed;

FIG. 8 is a schematic diagram of the position of the dispenser provided in the present disclosure when it is assembled;

9 is a schematic diagram of the assembly between the overflow exhaust structure and the inner tank provided by the present disclosure;

10 is a schematic diagram of the location of the overflow port provided by the present disclosure;

11 is a schematic assembly diagram of the overflow exhaust structure provided by the present disclosure;

12 is a cross-sectional view of an overflow exhaust structure provided by the present disclosure;

13 is a schematic assembly diagram of the overflow exhaust structure provided by the present disclosure;

14 is a schematic diagram of the assembly between the overflow exhaust structure, the water tank and the inner tank provided by the present disclosure;

15 is a schematic diagram of the overflow exhaust structure provided by the present disclosure when the assembly is completed;

Figure 16 is a cross-sectional view of an electrolysis device provided by the present disclosure;

Fig. 17 is a partial enlarged view of area A in Fig. 16;

Fig. 18 is a partial enlarged view of region B in Fig. 16;

19 is a schematic structural diagram of the protective cover provided by the present disclosure on the electrolysis device;

Figure 20 is a schematic diagram of the second structure of the protective cover provided by the present disclosure on the electrolysis device;

21 is a schematic diagram of the assembly of the water tank provided by the present disclosure on the dishwasher;

Figure 22 is a schematic diagram of the assembly between the water cup and the inner tank provided by the present disclosure;

23 is a cross-sectional view of a dishwasher provided by the present disclosure;

24 is a schematic diagram of the interior of the dishwasher provided by the present disclosure;

FIG. 25 is a schematic structural diagram of the spout provided by the present disclosure.

Description of reference numbers:

a1-accommodating groove; a101-first groove wall; a102-guide protrusion; a103-flow hole; a104-scale; a105-support foot; a106-second groove wall;

a2-holding part; a201-holding base body; a202-edge protection; a203-guide groove; a204-holding rib; a205-first sealing groove; a206-handle; - Positioning slot; a2073-travel guide slot;

a3 - the first seal;

a4-clamping structure; a401-dispenser buckle; a402-dispenser slot;

a5-rotating buckle;

a6-fixed seat; a601-tooling slot;

a7-Second sealing groove.

b0-water tank; b1-first rib; b2-second rib; b5-water channel; b501-drainage outlet; b502-drainage section; b503-rectification section; b6-overflow port; b61-overflow exhaust structure ; b611-overflow exhaust port; b612- diversion rib; b614- water retaining end cap; b615- tooling rib position; b616- water and gas inlet; b617- swivel part; Orifice flange; b64-overflow port sealing ring; b7-water tank inlet; b8-water tank outlet; b9-water tank body; b901-water tank chamber; b9023-the first spout reinforcing rib; b9024-the second spout spout reinforcing rib; b9025- spout channel; b9026- spout reducing part; b903-functional area; b904-first water tank side wall; b905-the side wall of the second water tank; b9051-protection groove, b9052-conduction opening, b10-salt injection port; b101-salt port flange; b102-sealing rib; b103-second seal.

c0-electrolytic assembly, c10-insulation separator, c11-first insulating frame, c111-give way through hole, c12-second insulating frame, c13-first insulating boss, c131-first insulating cavity, c14-th Two insulating bosses, c141-second insulating cavity, c15-third insulating boss, c151-first positioning hole, c16-fourth insulating boss, c161-second positioning hole, c17-hook, c171-handle Department, c172-Hook Department,

c2-electrolysis structure, c201-sheet body, c202-electrolysis through hole, c21-first electrode, c211-first opening, c22-second electrode, c221-second opening,

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

c4-wire, c41-mounting hole,

c5-third seal, c51-seal body, c52-conical seal,

c6-protective cover, c61-connection end, c62-free end,

c71-easy-folding body, c72-first through slot, c73-second through slot,

c811-first buckle body, c812-card slot, c813-first guide slope, c821-second buckle body, c822-give way slot, c823-second guide slope,

c91-sink, c92-stopper bump,

d1-spray arm, d5-inner tank, d51-inner tank wall, S1-water jet direction, S2-exhaust path, S3-overflow path, S4-exhaust overflow direction;

d4-water cup; d42-drain pipe; d43-drain valve; d44-three-way valve;

d5- inner tank; d51- inner tank wall; d52- flange hole; d53- third sealing groove;

e- respirator; e1- respirator water inlet pipe; e2- water inlet solenoid valve

f- water softener; f1- water softener outlet pipe.

g - cutlery; h - bowl basket; i - flow meter.

Detailed ways

The technical solutions of the present disclosure will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are a part of the embodiments of the present disclosure, but not all of the embodiments. Based on the embodiments in the present disclosure, all other embodiments obtained by those of ordinary skill in the art without creative efforts shall fall within the protection scope of the present disclosure.

In the description of the present disclosure, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. The indicated orientation or positional relationship is based on the orientation or positional relationship shown in the drawings, and is only for the convenience of describing the present disclosure and simplifying the description, rather than indicating or implying that the indicated device or element must have a specific orientation or a specific orientation. construction and operation, and therefore should not be construed as limiting the present disclosure. Furthermore, the terms "first", "second", and "third" are used for descriptive purposes only and should not be construed to indicate or imply relative importance.

In the description of the present disclosure, it should be noted that the terms "installed", "connected" and "connected" should be understood in a broad sense, unless otherwise expressly specified and limited, for example, it may be a fixed connection or a detachable connection Connection, or integral connection; can be mechanical connection, can also be electrical connection; can be directly connected, can also be indirectly connected through an intermediate medium, can be internal communication between two elements. For those of ordinary skill in the art, the specific meanings of the above terms in the present disclosure can be understood in specific situations.

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

Example

This embodiment provides a dishwasher, including:

The chamber structure is provided with a water tank chamber b901 inside, and a salt water generating device is arranged on the water tank chamber b901;

Specifically, the arrangement of the chamber structure itself is not limited too much, as long as it can accommodate the saline itself. As an optional implementation manner, in this embodiment, the chamber structure may be a water tank, or a structure such as a respirator;

A box body, the chamber structure acts on the box body, the box body includes an inner pot d5 and a door body suitable for closing the inner pot d5, and the inner pot d5 is suitable for placing tableware to be cleaned g, the chamber structure is suitable for acting on at least one of the inner bladder d5 and the door body;

Specifically, in some embodiments, the following combination scheme can be produced between the chamber structure and the box body: the water tank is arranged on the inner tank; the water tank is arranged on the door body; the respirator is arranged on the inner tank; the respirator is arranged on the inner tank on the door body. The above-mentioned various solutions can all realize the installation and fixation of the chamber structure itself.

In some implementations, in this embodiment, the chamber structure itself is a water tank, and the water tank itself is disposed on the side wall of the inner bladder. A water tank chamber b901 is provided inside the water tank b0, and a salt water generating device is provided on the water tank chamber b901. Specifically, the salt water generating device has salt water inside. The salt water can be prepared inside the salt water generating device, or it can be directly configured in advance The good salt solution is put into the salt water generating device. When using a pre-prepared salt solution, a corresponding injection port can be set on the water tank b0, and the prepared salt solution can be directly poured into it;

The electrolysis assembly c0, arranged inside the water tank chamber b901, is suitable for electrolyzing the salt water generated by the salt water generating device;

The inner pot d5, the water tank b0 is arranged on the inner pot d5, the inner pot d5 is suitable for placing tableware to be cleaned, the cleaning liquid for the tableware occurs in the inner pot d5, and the inner pot itself is provided with an opening , a door body is arranged on the opening, and the inner tank is closed by the door body; the inner tank d5 is provided with several layers of bowl baskets h arranged in the height direction, and the bowl baskets are suitable for placing tableware g.

The relative positional relationship between the water tank b0 and the inner tank is not limited too much. The water tank itself can be directly arranged on the outside of the inner tank. , can also be set on the door body. In some embodiments, the water tank itself is disposed on the side wall of the inner liner, as shown in FIG. 23 , the water tank is arranged on the left side wall of the inner liner. Correspondingly, the water tank can also be arranged on the right side wall of the inner tank.

The water tank b0 is provided with a salt injection port b10, the inner tank d5 is provided with a through hole at a position corresponding to the overflow port b6, and the substance located in the water tank b0 is suitable for passing through the overflow port. b6 and the through hole enter into the inner pot d5.

In this embodiment, the working principle of the dishwasher itself is as follows:

Cathode: 2Cl ^- -2e=Cl ₂

Anode: 2H ₂ O+2e ^- =H ₂ +2OH ^-

Overall reaction: 2Cl ⁻ +2H ₂ O=H ₂ +Cl ₂ +2OH ⁻

A disproportionation reaction will occur between chlorine gas and water: Cl ₂ +H ₂ O=HCl+HClO, the generated HClO itself has a certain oxidizing property, so as to achieve the killing effect on bacteria and viruses.

In the present embodiment, the salt used is NaCl, which is non-toxic and stable in nature, is not prone to deterioration, and is convenient for preservation and electrolytic disinfection operations. For other chlorates, such as KCl, CaCl ₂ , etc., because they will cause certain harm to the human body, it is not recommended to use them.

In some embodiments, the salt water is prepared inside the water tank b0 in this example. In order to realize the preparation operation of brine, the brine generator will adopt the following specific structure:

A dispenser, which is provided with a accommodating tank a1. Specifically, the accommodating tank itself is used to place sodium chloride. When the dishwasher needs to start the cleaning operation on tableware, fruits and vegetables, etc., it is placed in the accommodating tank. Add a predetermined amount of sodium chloride. There is no limitation on the specific delivery method of sodium chloride, it can be delivered manually, or automatic weighing equipment can be used for delivery, as long as a specified amount of sodium chloride can be delivered; The material is not limited too much, and it can be directly prepared from plastic material by injection molding.

In this embodiment, the installation method of the dispenser is not limited, and it can be integrally formed on the water tank. In this case, a channel for placing salt is provided between the dispenser and the water tank. In some embodiments, the dispenser itself is detachably arranged on the water tank, and is detachably arranged on the water tank b0;

The water channel b5 is provided with a water outlet b501, and the water passing through the water channel b5 acts on the accommodating groove a1 through the water outlet b501. Specifically, the water channel itself may have a specific structure, or a water spout or the like may be directly used. The water from the outside world can be introduced into the water tank through the drainage port set in the water channel, and further into the holding tank of the dispenser. The salt in the holding tank will dissolve after being washed, and then flow out from the holding tank a1. , thereby producing brine for electrolysis.

In this embodiment, in order to realize the putting operation of the dispenser, the following structure is adopted: the water tank b0 includes a first water tank side wall b904 and a second water tank side wall b905 arranged oppositely, wherein the second water tank The side wall b905 is arranged adjacent to the inner wall d51 of the inner tank; a salt injection port b10 is provided on the side wall 904 of the first water tank, and the part corresponding to the salt injection port b10 on the inner tank wall d51 A flange hole d52 is provided through which the dispenser is adapted to penetrate deep into the water tank b0 through the flange hole d52 and the salt dispensing port b10.

That is, when the dispenser needs to be put in, the dispenser needs to be put into the inner tank first, and then the dispenser passes through the flange hole and the salt dispensing port in sequence, and enters the inside of the water tank.

In some embodiments, in order to ensure the connection stability between the dispenser and the inner container, a salt mouth flange b101 is protruded and formed in the direction in which the edge of the salt injection opening b10 extends into the inner container d5. Removably provided on the salt mouth flange b101. When it is necessary to add salt in the dispenser or to clean the dispenser, the dispenser can be directly separated from the salt mouth flange b101.

Specifically, as shown in FIG. 4 , the salt mouth flange itself is arranged in a ring shape, and it penetrates into the inner tank for a certain distance. The above arrangement can form a platform for placing the dispenser, thereby improving the stability of the dispenser itself. The axis of the salt mouth flange itself and the inner wall or the side wall of the first water tank are arranged perpendicular to each other, so as to avoid the drop of the dispenser. The salt mouth flange itself is provided on the water tank by being integrally formed with the water tank.

In some embodiments, after the dispenser is placed in the salt mouth flange, other structures may be provided to prevent the dispenser from being released from the inner bladder or the like. In this embodiment, a knob catch a5 is protruded from the inner wall of the salt mouth flange b101, and the dispenser is detachably connected to the knob catch a5.

Specifically, the structure of the knob clip itself is not limited, and it can be arranged elastically or in a convex shape. When the elastic setting is adopted, when the dispenser enters the salt mouth flange, the knob buckle itself will be compressed, and when the dispenser is stabilized into the salt mouth flange, the rotary buckle will be reset, and the dispenser itself can be displayed at this time. exercise. In some embodiments, the knob catch itself adopts a convex arrangement, and when the dispenser rotates to a certain extent, it can act on the knob catch, so as to achieve stability between the two.

The dropper provided by this embodiment is introduced below:

In order to realize the operation of throwing salt, in this embodiment, the dispenser includes: the accommodating groove a1; The accommodating tank itself is used to store sodium chloride, and the handle is connected to the accommodating tank. When it is necessary to drive the accommodating tank to move, the user can directly act on the handle to realize the moving or rotating operation.

In this embodiment, the accommodating groove and the holding portion may be integrally formed, or a separate operation may be adopted. When integral molding is adopted, it can be directly prepared by injection molding. In some embodiments, the accommodating groove a1 is detachably provided on the holding portion a2.

Specifically, the specific disassembly method between the accommodating groove and the holding portion is not limited too much, and the method of interference fit or the method of screw connection can be adopted. In some embodiments, a clamping structure a4 is provided between the accommodating groove a1 and the holding portion a2.

At this time, the snap connection structure a4 includes a dispenser snap a401 and dispenser snap slot a402 that cooperate with each other; wherein a snap can be provided on the first slot wall, and a snap slot can be provided on the handle; A card slot is arranged on the wall of the slot, and a buckle is arranged on the handle portion. Or at the same time, the first groove wall and the holding portion are provided with mutually matching locking grooves and locking structures.

In this embodiment, as shown in FIG. 1 , the holding part a2 includes a holding base a201 and a protective edge a202 arranged along the inner edge of the holding base a201 in the circumferential direction, the dispenser buckle a401 and/or the The dispenser card slot a402 is provided on the edge guard a202.

A guide protrusion a102 is formed on the end surface of the first groove wall a101 facing the grip portion a2, and the grip portion a2 further includes a guide groove a203 arranged on the grip base a201 and matched with the guide protrusion a102 .

In some embodiments, the holding portion a2 further includes a holding rib a204 disposed between the holding base a201 and the guard a202, and a first A sealing groove a205, a first sealing member a3 is arranged in the first sealing groove a205. By setting the first sealing groove a205, the first sealing member a3 can be pressed against the salt mouth flange b101, so as to realize the sealing between the dispenser and the water tank, and prevent the water in the inner tank from entering the water tank through the dispenser. Contaminate the tank.

Specifically, the first sealing member a3 is configured as a sealing ring structure. Meanwhile, the first seal itself is made of a flexible material, such as rubber, so that it can deform after being compressed and further form a seal.

In this embodiment, as shown in FIG. 1 , a handle a206 is provided on the end surface of the holding base a201 away from the accommodating groove a1 . The structure of the handle itself is not limited too much, and the handle itself can be protruded on the handle base in a "one" shape, so as to facilitate the user to rotate the dispenser as a whole. As a modification, the handle itself may also be in the shape of a "cross", which is not limited in this embodiment.

In this example, the brine mixture prepared from the accommodating tank can flow out to the outside directly through the opening of the accommodating tank. In some embodiments, in order to fully dissolve the sodium chloride in the accommodating tank, the accommodating tank Several flow-through holes a103 are arranged at the bottom of the groove of a1. The flow hole is arranged at the bottom of the tank, which can ensure that the solution generated in the holding tank can flow out completely, and prevent the bottom liquid remaining in the holding tank, which will cause the subsequent concentration of the disinfectant to fail to meet the standard. At the same time, by setting the flow hole a103, which can delay the speed of the salt particles flowing out of the accommodating tank a1, thereby helping to dissolve the salt.

The number, arrangement and shape of the flow holes themselves are not limited too much. As far as the arrangement is concerned, other arrangements can be adopted, such as annular arrangement, triangular arrangement, etc. In some embodiments, several The flow-through holes a103 are arranged in a side-by-side straight line at the groove bottom a1 of the accommodating groove near the second groove wall a106 . At the same time, in terms of shape, the flow hole itself can adopt a regular shape, such as a rectangle, an ellipse, etc., or an irregular shape, as long as the leakage effect can be achieved. In some embodiments, the flow hole itself adopts a circular shape. shape. At the same time, the diameter of the circular hole is greater than or equal to 0.5mm and less than or equal to 5mm, and the above-mentioned size setting method prevents the salt particles from directly passing through the flow hole from the accommodating tank.

In order to achieve precise control of the amount of sodium chloride in the accommodating tank, a number of scales a104 are also provided on the accommodating tank a1 along its groove depth direction, and the scales a104 are used to identify the real-time status of the accommodating tank a1. capacity. For different tableware and different pollution conditions, the amount of salt that needs to participate in the chemical reaction will also be different. The design of the scale facilitates the user to control the amount of salt added, thereby realizing the accurate preparation of the concentration of the disinfectant.

In this embodiment, in order to prevent the accommodating tank from coming out from the flange of the salt mouth, the following arrangement can be adopted: a number of legs a105 are provided on the back of the bottom of the accommodating tank a1. The handle and the accommodating groove are designed as circular structures, which are prone to rolling when placed, causing the salt in them to spill. Therefore, a foot structure is designed to limit the rollover of the dispenser when it is placed. The feet themselves can enter into the water tank through the salt injection opening along the side wall of the second water tank, and since they have a certain length, they can limit the axial movement of the injection device along the salt injection opening.

In some embodiments, a rotation card slot a207 that is matched with the rotation snap is formed on the edge protection a202 of the handle portion a2.

Specifically, the rotating clip a207 includes: a guide slot a2071 that is introduced into the rotating clip a5; a positioning slot a2072 that locks the rotating clip a5; and is connected between the guide slot a2071 and the Between the positioning grooves a2072, a travel guide groove a2073 for the rotation stroke is provided.

In this embodiment, in order to improve the connection stability of the dispenser on the water tank, in the direction of the travel guide groove a2073 toward the positioning card groove a2072, the size of the notch is gradually reduced. Specifically, the size of the slot can be reduced linearly or non-linearly, as long as the reduction action can be achieved.

In this embodiment, in order to realize the action of reducing the size of the notch, the groove edge structures on both sides of the travel guide groove a2073 are configured as curved guide structures. Through the above arrangement, the dispenser is gradually clamped during the rotation process, so as to avoid shaking or coming out.

In this embodiment, the extension size of the positioning slot itself is also limited. When the rotating clip a5 is engaged with the positioning slot a2072, the flow-through hole a103 of the accommodating slot a1 faces toward The drain port b501 in the water tank b0 is provided.

As shown in FIG. 3 , through the above arrangement, the water flowing out of the water outlet can be fully acted on the inside of the accommodating tank, so that the sodium chloride in the accommodating tank can be quickly and fully dissolved. In this embodiment, the water outlet itself can be inclined appropriately, as long as it is ensured that the water flowing out of the water outlet finally flows at the position of the flow-through hole.

In some implementations, in this embodiment, as shown in FIG. 8 , the projection of the drain port 501 coincides with the flow hole a103 . Specifically, the water outlet is arranged at a position just above the flow hole. Through the above setting method, the water flowing out from the drain b501 can be directly applied to the position of the flow hole a103. At this time, the water has a large kinetic energy under the action of weight. Therefore, after rinsing the salt, the salt water can be directly passed through The flow hole a103 is discharged, so that the preparation efficiency of the brine can be improved.

In this embodiment, in order to realize the connection action of the water tank and the inner tank, a supporting seat may be separately provided under the water tank, so as to play a role of stabilizing the water tank. In some embodiments, the structure of the fixed seat is provided separately in this embodiment, and the following is a description of the specific structure of the fixed seat:

The fixing seat a6 itself is disposed on the salt mouth flange b101, and after the fixing seat a6 is fixed in place, one end surface of the fixing seat a6 abuts on the inner wall d51. By providing the fixing seat a6, after it cooperates with the salt mouth flange b101, a stable connection between the water tank and the inner tank can be realized, thereby improving the stability of the entire dishwasher itself.

The shape of the fixing seat itself is not limited, and it may be a circle or a rectangle. In some embodiments, the fixing seat itself is arranged in a circular shape, the center of which is arranged in a hollow shape, and the inner wall of the fixing seat is provided with a At the same time, correspondingly, a thread is provided on the outer wall of the salt mouth flange, and the connection action of the water tank and the inner tank is realized through the connection before the thread. When the fixing seat itself is tightened, the end of the fixing seat will abut against the side wall of the inner container. As a variant, it is also possible to tighten the fixing seat a6 on the salt inlet flange b101. Specifically, along the direction close to the salt injection port b10, the outer wall size of the salt inlet flange b101 gradually increases. During assembly, as the fixing seat goes deeper, the fixing seat is gradually tightened on the salt mouth flange b101.

In this embodiment, a second sealing groove a7 is formed between the end of the fixing seat a6 away from the inner wall d51 and the upper edge of the salt mouth flange b101, and the dispenser is provided with a first sealing member a3, the first sealing member a3 is clamped on the second sealing groove a7. By setting the second sealing groove a7, it can cooperate with the first sealing member on the dispenser, so that the water in the inner tank can be prevented from entering the water tank through the gap between the dispenser and the fixed seat, and the water in the water tank can be prevented from entering the water tank. create pollution.

Specifically, the second sealing groove itself is annularly arranged, and the first sealing member itself is arranged in the second sealing groove, wherein the first sealing member itself is made of a flexible material, such as rubber, and the radius of the first sealing member itself is smaller than that of the second sealing member itself. The radius of the seal groove, thereby stabilizing the first seal in the second seal groove.

In some embodiments, several tooling grooves a601 are provided on the end surface of the fixing seat a6 away from the inner wall d51 .

A plurality of tooling grooves are arranged at equal intervals from each other before, and the tooling grooves themselves are arranged in a concave shape, and the operator can put their hands into the tooling grooves to realize the rotation of the tooling grooves.

In this embodiment, in order to further realize the sealing cooperation between the water tank and the inner tank and prevent water from flowing out through the gap between the water tank and the inner tank, as shown in FIG. 4 , the side wall b904 of the first water tank faces the inner tank. A sealing rib b102 is protruded from one side of the bladder wall d51 , a third sealing groove d53 is correspondingly formed on the inner bladder wall d51 , and the sealing rib b102 is clamped on the third sealing groove d53 . Through the above arrangement, the sealing performance of the connection between the water tank and the inner tank can be improved. Avoid the water outside the water tank entering the inner tank, or the water in the inner tank flowing into the gap between the water tank and the inner tank, causing pollution to the outer wall of the dishwasher or the surrounding environment.

Specifically, the sealing rib itself may be arranged in a continuous shape, or may be arranged in a discontinuous shape. In some embodiments, the sealing rib itself is arranged in a continuous shape, and in this case, the sealing rib can be arranged in a circle or a rectangle. In some embodiments, the sealing rib itself adopts a circular arrangement. Correspondingly, the third sealing groove itself also adopts a circular sealing method.

In this embodiment, the sealing rib itself can be integrally formed on the side wall of the first water tank, or can be separately provided on the side wall of the first water tank. In some embodiments, the sealing rib b102 is configured as an annular protrusion The structure itself can be disposed on the side wall of the first water tank by means of integral injection molding.

In some embodiments, in order to enhance the sealing performance between the water tank and the inner tank, a second sealing member b103 is sandwiched between the outer peripheral surface of the salt mouth flange b101 and the flange hole d52 abutting. Specifically, the second sealing member b103 itself is set in the form of an annular rubber ring, and at this time, the second sealing member b103 will be directly made of rubber material.

In this embodiment, the setting position of the second sealing member b103 is not limited. It can be arranged close to the fixed seat, and can also be arranged offset from the fixed seat. In some embodiments, the lower edge of the fixing seat a6 abuts on the second sealing member b103, and the above arrangement can prevent the water in the inner bladder from passing through the gap between the fixing seat and the inner bladder wall into the area between the tank and the liner, causing water to flow out of the dishwasher. In some embodiments, a plurality of the second seals themselves may be provided, and the plurality of second seals are arranged concentrically with each other, and along the direction away from the flange of the salt mouth, the inner diameter of the second seals gradually increases, thereby forming multiple Hierarchical sealing structure. Specifically, the second sealing member b103 is configured as a sealing ring structure.

The above mainly describes how the inner tank and the water tank are connected and sealed. In some embodiments, in order to realize the conduction operation between the water tank and the water in the outside world, the following structure is adopted:

The water tank chamber b901 is provided with a water tank inlet b7 and a water tank outlet b8 respectively, and the water tank inlet communicates with the outside world. As shown in FIG. 6 , the water tank inlet b7 and the water tank outlet b8 are arranged at the lower position of the water tank, and a water pump and other structures are arranged in the water tank b0 to pressurize the water introduced through the water tank inlet b7 into the water tank. At the same time, when the electrolysis assembly c0 completes the electrolysis operation of the salt water, the disinfectant with high oxidizing property flows out through the water outlet b8 of the water tank and enters the inner tank, thereby realizing the disinfection operation of the substances in the inner tank d5. As an alternative embodiment, since the water outlet b8 of the water tank is disposed at the bottom of the water tank b0, when the disinfectant is discharged, the water outlet b8 of the water tank can be opened and automatically discharged by the gravity of the disinfectant.

In this embodiment, in order to realize the fully dissolving operation of the salt water flowing out from the dispenser, a rectifying structure is separately provided in the water tank, specifically:

The rectification structure is arranged on the side wall b901 of the first water tank, the rectification structure includes at least one rib, the rib is located on the flow path of the salt, and the rib is located above the water tank outlet b8, The water flow detours at the rectifying structure and forms at least one detour path. Through the above setting method, when the water entering through the water inlet b7 of the water tank and the sodium chloride inside the dispenser complete the dissolving action, the generated salt water will collide with the ribs, thereby fully dissolving the salt that is not completely dissolved. At the same time, the salt water flowing out of the dispenser will fall while dissolving.

In this embodiment, as shown in FIG. 6 , the rectifying structure includes: a first rib b1 , which is arranged close to the water outlet b8 of the water tank. The first rib is set close to the water outlet, which can intercept and disperse the salt blocks flowing to the water outlet at the water outlet and force the salt blocks to bypass and fully dissolve.

Specifically, the first rib itself can be arranged in an inclined shape, or can be arranged in a horizontal shape, as long as the brine flowing out of the dispenser can flow on it. The first rib itself can be directly disposed in the water tank chamber b901 by means of integral molding.

Specifically, the first rib itself is disposed at the lower part of the water tank chamber. As a preferred embodiment, the water tank chamber b901 is provided with a spout b902, the water tank outlet b8 is provided in the spout b902, and the first rib b1 is provided in the pot Inside the mouth b902, and between the first rib b1 and the side wall of the spout b902, there is at least a gap for the water supply to flow through. By setting the gap, the salt water generated after electrolysis can be introduced into the water tank outlet. into the mouth and further into the liner. As an alternative embodiment, the first rib b1 is provided above the open end of the spout b902.

The location of the spout b902 is not specifically limited. As shown in FIGS. 6 and 25 , in this embodiment, the spout b902 is correspondingly arranged below the salt injection port b10 and/or the salt injector. When water, electrolyte solution, or disinfectant is directly injected into the water tank chamber, the water flow will not directly impact the spout, but will be buffered by the first ribs to prevent foam from forming during water injection.

In some embodiments, as shown in FIG. 25 , the spout b902 includes a spout inclined surface b9021, and the spout inclined surface b9021 is provided at an end of the spout b902 away from the water outlet b8 of the water tank. The width of the spout b902 varies with the width of the spout b902. The extension direction of the spout slope b9021 gradually becomes smaller. The spout slope b9021 plays a guiding role and can guide the water or disinfectant on both sides of the opening area of the spout b902 to flow into the spout b902.

Regarding the structure of the spout b902, on the basis of the above-mentioned embodiments, in some embodiments, as shown in FIG. 25 , the spout b9021 is provided with: a spout b9022, which is provided on the spout On the inclined surface b9021, the protruding portion b9022 of the spout protrudes into the spout portion. Since the spout inclined surface b9021 plays a guiding role, the water or the disinfectant first strikes the spout inclined surface b9021, and then flows along the inclined surface of the spout inclined surface b9021. Therefore, the protruding part b9022 of the spout can fully collide with the water flow or the disinfectant flowing along the slope b9021 of the spout. When there is undissolved salt in the water or the disinfectant, the salt will hit the protruding part b9022 of the spout with the water flow. It is scattered and fully dissolved, preventing the salt block of the solution from entering the spout b902 and blocking the water outlet b8 of the water tank. On the other hand, the part adjacent to the spout is the local structure where the water inlet b7 of the water tank is located, and a flow meter i is set at the water inlet b7 of the water tank to monitor the water intake of the water tank chamber. The installation structure of the flowmeter, such as the opening of the groove body, can be correspondingly arranged on the back of the convex part of the pot mouth. The convex part of the pot mouth is relatively thick and has good mechanical strength, which can improve the installation of other components such as the flowmeter. reliability. In addition to guiding the water flow, the inclined plane can also provide the installation foundation for other components of the whole machine, which improves the compactness of the overall mechanical structure.

Regarding the specific structure of the spout slope b9021, on the basis of the above-mentioned embodiments, in some embodiments, as shown in FIG. 25 , the spout part b902 includes a spout reinforced rib structure, and the spout reinforced rib structure It includes at least a first spout reinforcing rib b9023 and a second spout reinforcing rib b9024, and a spout channel b9025 is formed between the first spout reinforcing rib and the second spout reinforcing rib. The spout channel can further tighten the cross-sectional area through which water or disinfectant flows, and rectify in advance before the water or disinfectant enters the water outlet b8 of the water tank. On the other hand, the spout reinforcing rib has a certain height, and the spout reinforcing rib can be supported between the first water tank side wall and the second water tank side wall of the water tank to improve the strength of the water tank chamber.

On the basis of the above-mentioned embodiments, in some embodiments, as shown in FIG. 25 , the first spout reinforcing rib is in the shape of a broken line, and the first spout reinforcing rib and the spout sloping surface surround The triangular reinforcement structure can further improve the mechanical strength of the inclined surface of the spout.

Specifically, as a preferred embodiment of the shape of the spout channel, as shown in FIG. 25 , the spout channel b9025 is provided with a spout reducing portion b9026 at one end close to the water outlet b8 of the water tank, and the spout channel b9025 The width of the spout gradually increases in the direction of the water tank outlet b8 at the spout reducing portion b9026.

In this embodiment, in order to further realize the dissolving operation of the salt itself, the rectifying structure further includes:

The second rib b2 is arranged between the downstream of the salt feeding port b10 and the upstream of the first rib b1, as shown in FIG. Above the first rib b1. As shown in FIG. 6 , by arranging multi-layered ribs along the height direction, the salt particles are constantly impacted with the ribs and further dissolved.

The number of the second ribs b2 is not limited too much. In some embodiments, there are two second ribs b2, and there is a distance between the two second ribs b2, and the distance is between the two second ribs b2. A baffle channel is formed between the second ribs b2. Specifically, the lower end of the second rib b2 located above is set at the upper position of the second rib b2 located above, so that the salt water left from the second rib above can be received, thereby realizing the connection between salt particles and water. full dissolution operation in between.

In this embodiment, at least one of the second ribs b2 is disposed obliquely toward the salt injection port b10. Through the above arrangement, the second rib itself can receive more salt water flowing out from the dispenser, so that the salt water can flow along the second rib, increase the dissolution time between the salt particles and the water, and prevent the salt water from falling directly. Drop to the bottom of the tank chamber.

In some embodiments, the second rib b2 at least partially covers the upstream of the gap between the first rib b1 and the inner wall of the water tank chamber b901 . The above arrangement can prevent the water left from the second rib from falling directly into the gap, resulting in a reduction in the time for the dissolving between the salt particles and the water, thereby affecting the normal dissolving operation of the salt water.

In this embodiment, in order to realize the dissolving operation of the salt in the dispenser, a variety of different methods can be adopted. As an embodiment, water can be injected from the bottom of the water tank and then gradually flow through the dispenser.

In some embodiments, a water channel is provided in the water tank, and the water channel itself plays the role of draining and flushing the salt in the dispenser. One end of the water channel b5 is connected to the water inlet b7 of the water tank, and the water channel b5 includes a drainage section. b502 and the rectification section b503, the drainage port b501 is formed on at least one of the drainage section b502 and the rectification section b503.

By setting the water channel, when the water enters the water tank b0, the water-to-salt dissolution operation can be realized, avoiding the need to wait for the water to rise to a certain height before dissolving the salt, which can effectively reduce the time required for the salt to dissolve.

Specifically, the water outlet b501 itself can be set on the drainage section b502 or on the rectification section b503, as long as the water flowing out through the water outlet b501 can act on the dispenser. In some implementations, in this embodiment, the water outlet b501 is provided on the rectifying section b503.

Specifically, the angle between the diversion section b502 and the rectification section b503 is less than 180°, and a functional area b903 is enclosed between the diversion section b502 and the rectification section b503 . Through the above setting method, the water drained through the water channel can directly act on the upper position of the dispenser, so that when the water flows out from the water outlet b501, a certain acceleration operation is performed under the action of gravity and a certain kinetic energy is generated, so that the water is A greater rate is applied to the dispenser, enabling the dissolving operation of the salt particles in the dispenser.

The shape of the rectification section b503 is not limited too much, and it can be arranged in a folded line or an "S" shape. In some embodiments, the rectification section b503 is in an arc shape. Specifically, the center of the rectification section is located inside the tank chamber b904.

In this embodiment, the functional area b903 refers to an area that can perform a drainage operation and an overflow exhaust operation at the same time. The overflow port b6 is provided in the functional area b903.

The overflow port itself can achieve the following functions: when there is too much water in the water tank, the excess water can be drawn out of the water tank through the overflow port, and at the same time, the amount of water inside the water tank can be detected by setting the overflow port, and then the water tank can be controlled. The water inlet stops the water feeding operation. In some embodiments, when the electrolysis reaction occurs inside the water tank, flammable gas such as hydrogen gas will be generated inside the water tank. By setting the overflow port, the hydrogen gas can be quickly led out from the inside of the water tank to the outside, so as to ensure the safety of the water tank itself.

In some embodiments, the highly oxidizing disinfectant produced in the water tank is clean water, while the water in the inner tank is turbid water, and the turbid water is mixed with a large amount of oil. The water flows in the reverse direction into the water tank, causing pollution to the water in the water tank. To this end, in this embodiment, an overflow port b6 is provided on the water tank, a through hole is provided on the inner tank at a position corresponding to the overflow port b6, and the overflow port is connected to the through hole. There is an overflow exhaust structure between them, and an overflow exhaust structure is arranged at the corresponding part of the inner tank and the overflow port b6, and the overflow exhaust structure is suitable for restricting the air flow in the water tank b0. The substance flows into the through hole from the overflow port b6 in one direction.

Specifically, the through hole itself may be integrally formed on the side wall of the inner bladder, or may be provided on the side wall of the inner bladder by post-processing, and the through hole itself is provided in a circular shape.

In this embodiment, the overflow exhaust structure itself may be a one-way valve, or a structure for realizing one-way movement of fluid. In some embodiments, the overflow exhaust structure includes:

The water gas inlet b616 is arranged through the first side of the overflow exhaust structure; specifically, the water gas inlet is arranged on the side of the overflow exhaust structure deep into the water tank;

The water blocking end cover b614 is arranged on the second side of the overflow exhaust structure, and is arranged along the extending direction of the water gas inlet b616, and is suitable for blocking the extending direction of the water gas inlet b616; Specifically, the water blocking end cover itself is arranged in the inner tank, a cavity is provided between the water blocking end cover and the water gas inlet, and

The overflow exhaust port b611 runs through the overflow exhaust structure in a direction parallel to the water blocking end cover b614, and is at least partially connected to the water vapor inlet b616. By arranging the overflow exhaust port, the gas or liquid acting on the water blocking end cover can be guided, so that the gas or liquid finally enters the inner tank at a certain angle.

In this embodiment, the liquid from the first side of the overflow exhaust structure is overflowing, and the liquid from the second side of the overflow exhaust structure is a spray type. After the water blocking end cover b614 blocks the extending direction of the water and gas inlet b616, an overflow exhaust port b611 is also opened on the second side of the overflow exhaust structure. The port b611 is at least partially connected to the water vapor inlet b611, and then the overflow exhaust structure is internally penetrated and conducted, so that the water vapor can enter the water vapor from the first side of the overflow exhaust structure. The liquid or gas in the port b611 is discharged from the overflow exhaust port b611 located on the second side of the overflow exhaust structure.

In the specific implementation process, the liquid or gas enters from the water gas inlet b616 on the first side of the overflow exhaust structure, passes through the internal channel of the overflow exhaust structure, and is subjected to the flow path of the liquid or gas. The water blocking end cover b614 located on the second side of the overflow exhaust structure blocks and changes direction, and finally the liquid or gas is discharged from the overflow exhaust port b611. The liquid or gas from the second side of the overflow exhaust structure must enter from the overflow exhaust port b611 if it wants to enter the overflow exhaust structure. The extension direction and the extension direction of the water gas inlet b616 are arranged at an angle, and in this embodiment, the two are arranged vertically, so that the liquid or gas from the second side of the overflow exhaust structure cannot pass from The direction parallel to the extending direction of the water gas inlet b616 enters the overflow exhaust structure, thereby shielding liquid or gas from a specific angle of the second side of the overflow exhaust structure.

In this embodiment, the overflow exhaust structure further includes: a backflow prevention rib b62, which is arranged on the conduction path between the overflow port b6 and the overflow exhaust port b611, and the backflow prevention rib b62 is suitable for at least Part of the overflow port b6 is blocked. Therefore, the liquid or gas from a specific angle of the second side of the overflow exhaust structure is not only blocked by the water blocking end cover, but also enters the overflow exhaust port when a small part of the liquid or gas is After that, it is blocked by the backflow prevention ribs again, so as to reduce the occurrence of the situation of entering the overflow exhaust structure due to sputtering.

Specifically, the backflow prevention rib b62 is disposed at the lower edge of the overflow port b6 , and the lowest point position of the backflow prevention rib b62 in the up-down direction is higher than the lowest point position of the overflow exhaust port b611 . In this embodiment, the backflow prevention ribs b62 are arranged in parallel with the water blocking end caps b614.

Specifically, at least one gap is formed on the path of the air guide rib b612 surrounding the water vapor inlet b616. At least one notch is formed on the path of the air guide rib b612 surrounding the water gas inlet b616, so that the connection with the water blocking end cover b614 can be disconnected at the notch of the guide rib b612, thereby It is convenient to form the water vapor inlet b616.

Specifically, the notch of the guide ribs b612 and the water blocking end cover b614 are jointly enclosed to form the overflow exhaust port b611 . As shown in FIG. 12 , in the exhaust path S2 and the overflow path S3 inside the overflow exhaust structure, both exhaust gas and overflow enter from the water gas inlet b616, and finally exhaust from the overflow Port b611 is discharged.

In this embodiment, a spray arm is provided in the inner tank, and the bowl basket and the tableware, fruits and vegetables placed on the bowl basket are rinsed through the spray arm. At the same time, the overflow exhaust structure itself is provided with a gap. Since the inner tank itself is in the water spray environment of the spray arm, it is very likely that the water in the spray arm will act on the overflow exhaust structure through the gap. In order to prevent the occurrence of the above situation, in this embodiment, the angle between the exhaust overflow direction S4 of the overflow exhaust port b611 and the horizontal plane is β1, where 0°≤β1≤180°. And preferably, 0°<β1<180°, so that the exhaust overflow direction S4 of the overflow exhaust port b611 is set downward as much as possible, which is convenient for overflow and reduces the entry of liquid on the second side. The optimum range is 120°<β1<150°.

Through the above arrangement, the water sprayed from the spray arm cannot directly enter the overflow exhaust structure through the gap, thereby preventing the water in the inner tank from polluting the overflow exhaust structure.

Specifically, the dishwasher also includes:

The spray arm d1 is suitable for spraying water;

The overflow exhaust structure is provided with an overflow exhaust port b611, and the value range of the included angle β2 between the opening direction of the overflow exhaust port b611 and the injection direction of the spray arm d1 is 90°≤β2≤ 180°.

In some embodiments, the spray arm d1 is at least partially disposed in the inner tank d5. In this embodiment, the spray arm d1 is located in the middle of the inner tank d5, and the water tank b0 is installed in the inner tank d5. On the side wall of the inner tank d5, so that the overflow exhaust structure is also located on the side wall of the water tank b0. The spray arm d1 sprays the water flow by rotating, and the spray direction S1 of the water flow is as shown in the figure. In this embodiment, the spray arm d1 rotates clockwise as an example, that is, the high-pressure water column sprayed by the spray arm d1 is flushed counterclockwise. When the opening direction of the overflow exhaust port b611 and the spraying direction of the spray arm d1 are arranged in substantially opposite directions, the water flow sprayed by the spray arm d1 can be reduced to enter the overflow exhaust structure. Further, the spraying of water flow by the spray arm d1 into the water tank b0 is reduced.

In the dishwasher provided by this embodiment, the opening direction of the overflow exhaust port b611 and the spraying direction of the spray arm d1 are set at an angle, and the specific value range is 90°≤β2≤180°, even if The opening direction of the overflow exhaust port b611 and the spraying direction of the spray arm d1 are arranged in substantially opposite directions, which can reduce the entry of the sprayed water flow from the spray arm d1 into the overflow exhaust structure, thereby reducing the The spray arm d1 sprays water into the water tank b0.

In this embodiment, in order to realize the quick loading and unloading operation of the overflow exhaust structure itself, a tooling rib position b615 is also provided on the overflow exhaust structure, and the tooling rib position b615 is suitable for adjusting the overflow exhaust port The orientation of b611. Specifically, the tooling ribs are radially arranged on the overflow exhaust structure, and the number of tooling ribs is not limited too much. In some embodiments, there are two tooling ribs themselves, the tooling ribs and the overflow The angle between the exhaust ports is 120°.

In this embodiment, the overflow port b6 is provided with an overflow port flange b63 around the periphery, and the overflow exhaust structure is provided with a screw portion b617 at a position corresponding to the overflow port flange b63; The overflow flange b63 is provided with an inner thread or an outer thread, and the screw portion b617 is correspondingly provided with an outer thread or an inner thread.

Through the cooperation between the overflow flange b63 and the screw part b617, the overflow exhaust structure can be installed on the water tank. Preferably, the overflow flange b63 is arranged on the outside of the water tank as a deformation , the overflow flange b63 may also be disposed on the inner side of the water tank or on both sides of the side wall b904 of the first water tank along the thickness direction. Correspondingly, the rotating portion b617 is located on the first side of the overflow exhaust structure, preferably at the outer circumferential position of the water vapor inlet b616, so that the water vapor inlet b616 can be directly joined with the overflow port b6.

In some embodiments, in order to avoid the outflow of water at the position of the overflow exhaust structure, as shown in FIG. 14 , an overflow sealing ring b64 is also provided between the water tank and the inner bladder d5, and the overflow A port sealing ring b64 is provided around the overflow port b6.

In the present embodiment, in order to realize the electrolysis operation of the sodium chloride solution, an electrolysis assembly is separately provided in the water tank. The specific structure is as follows, and the electrolysis assembly c0 includes:

installation structure;

The electrolytic structure includes at least two electrodes, and the at least two electrodes have at least one first electrode c21 and at least one second electrode c22, the first electrode and the second electrode are arranged at intervals on the mounting structure ;

At least two conductive structures, and at least two of the conductive structures have at least one first conductive structure c31 and at least one second conductive structure c32, the first conductive structure is electrically connected to the first electrode, the The second conductive structure is electrically connected to the second electrode. By electrically connecting the first conductive structure with the first electrode, electrically connecting the second conductive structure with the second electrode, and making the first electrode and the second electrode spaced apart on the mounting structure, it is possible to kill, remove and wash by means of electrolysis. bacteria in the dishwasher, so that the dishes can be stored in the dishwasher for a long time.

In this embodiment, in order to realize the installation operation of the electrolysis assembly, the installation structure of the electrolysis assembly and the electrolysis structure are provided in the water tank chamber, and the conductive structure part extends out of the water tank chamber b901.

In some embodiments, in order to realize a conductive operation, one end of the conductive structure away from the electrode is a terminal, and the terminal of each of the conductive structures is respectively connected with a wire c4; the installation structure includes an insulating baffle, The first electrode is located on the side of the insulating separator close to the terminal, and the second electrode is located on the side of the insulating separator away from the terminal.

In this embodiment, the installation structure further includes:

The first insulating frame c11 is located on the side of the first electrode facing away from the insulating separator, and the first insulating frame is provided with suitable for the first conductive structure and the second conductive structure to pass through respectively. passing through holes;

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

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

A second insulating boss c14, the second insulating boss is provided on the second insulating frame and/or the insulating spacer, and the second electrode is provided with a second insulating boss suitable for accommodating the second insulating boss The second opening of the platform, the second insulating boss is provided with a second insulating cavity, and the first conductive structure is accommodated in the second insulating cavity through the first electrode.

By arranging the first insulating boss and the second insulating boss, the corresponding electrodes are only in contact with the corresponding conductive structures, thereby ensuring the stability of current transfer.

Specifically, the first insulating boss and the insulating baffle are integrally formed, and the second insulating boss and the second insulating frame are integrally formed. As a variant, the first insulating boss and the second insulating boss can also be arranged in the form of washers.

In this embodiment, the installation structure further includes:

A third insulating boss c15 is provided on the second insulating frame and extends away from the electrode, and a third insulating boss c15 is provided on the third insulating boss for accommodating the second conductive structure. The first positioning hole; the fourth insulating boss c16, which is arranged on the second insulating frame and extends away from the electrode, and the fourth insulating boss is provided with the second insulating a second positioning hole communicating with the cavity; the side of the fourth insulating boss facing away from the electrode is flush with the side of the third insulating boss facing away from the electrode.

In this embodiment, the installation structure further includes at least one hook c17, and the hook includes: a handle c171, which is arranged on the second insulating frame and extends toward the first insulating frame; a hook c172 is arranged on one end of the handle away from the second insulating frame, and is in contact with the side of the first insulating frame facing away from the second insulating frame.

By arranging the hooks, the first insulating frame, the second insulating frame, the first electrode, the second electrode and the insulating separator between the first insulating frame and the second insulating frame can be clamped, so that a plurality of components can be formed. A complete structure, thus avoiding scattering.

In this embodiment, the electrode is an electrolytic sheet, and the electrolytic sheet includes a sheet-shaped body and a plurality of electrolytic through holes arranged on the sheet-shaped body. The contact area between them can increase the reaction rate. Specifically, the electrolytic through holes themselves are arranged in a circular manner. The disposition form of the plurality of electrolytic through holes is not limited, and may be disposed randomly. In some embodiments, the plurality of electrolytic through holes are evenly distributed on the sheet-like body.

In this embodiment, the first electrode and the second electrode are parallel to each other. An anodic reaction is provided on one of the first electrode and the second electrode, and a cathodic reaction is performed on the other.

In this embodiment, the conductive structure includes: a conductive body, which is electrically connected to the corresponding electrode; and a wire-fixing structure, which is provided at an end of the conductive body away from the electrode and is set as a fixed wire. By arranging the conductive body, electric energy is transmitted to the corresponding electrodes.

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

In this embodiment, the wire itself can be directly wound on the conductive body. In some embodiments, an installation hole is formed at one end of the wire, and the wire is sleeved on the conductive body through the installation hole. Specifically, the mounting hole itself is set with a round hole, and is set on the bolt itself, so as to perform a conductive operation.

The present embodiment also provides an electrolysis device, the electrolysis device comprising:

The water tank body is formed with a water tank chamber b901, and the side wall of the water tank body b9 away from the terminal c301 is the first water tank side wall b904, and the side wall close to the terminal c301 is the second water tank side wall b905;

In the above-mentioned electrolysis assembly, the installation structure of the electrolysis assembly c0 and the electrolysis structure c2 are provided in the water tank chamber b901, and the conductive structure part extends out of the water tank chamber b901;

At least two seals c5 are disposed between the second water tank side wall b905 and the installation structure, and are disposed corresponding to the conductive structure.

The sealing member c5 is a sealing ring, and includes a sheet-shaped sealing body c51, and a conical sealing portion c52 extending from the sealing body c51 toward the terminal c301; the sealing body c51 and the conical sealing portion c52 The sealing portion c52 is integrally formed, and the sealing ring is provided with a sealing hole sequentially passing through the conical sealing portion c52 and the sealing body c51, and the sealing hole is suitable for the conductive structure to pass through.

In some embodiments, in this embodiment, in order to realize the stable installation action of the entire electrolysis device, the following setting methods are adopted:

The water tank body includes a first water tank side wall and a second water tank side wall arranged oppositely, and the first water tank side wall and the second water tank side wall cooperate to enclose a accommodating cavity suitable for accommodating the electrolysis assembly c0, and the second shell A protective groove b9051 is provided on the side facing away from the first shell, and a conduction opening b9052 is provided on the second shell to communicate with the protective groove b9051 and the accommodating cavity;

The protective cover c6 is provided on the side wall of the first water tank and the side wall of the second water tank, and has a first state of covering the protective groove b9051 and a second state of opening the protective groove b9051. By arranging the protective cover, the conductive body located inside the protective groove can be shielded, so that external water can be prevented from directly entering the protective groove, resulting in a short circuit of the conductive body itself. At the same time, it can also prevent external dust from entering the protective groove and causing pollution to the conductive body.

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

Through the above operations, the space of the opening on the protective groove can be fully utilized. As a variant, in addition to the form of rotating the protective cover, the form of pulling the protective cover can also be used. At this time, a slideway can be set on the side wall of the first water tank or the side wall of the second water tank, and the protective cover can be embedded in the slide. Road. In some implementations, in this embodiment, the connecting end c61 is rotatably connected to the side wall of the second water tank through a frangible structure.

In this embodiment, the easy-folding structure includes an easy-folding body c71 and a first through groove c72, and the first through-groove c72 is disposed at a position opposite to the notch of the easy-folding body c71 and the protective groove b9051. side.

Specifically, the first through groove itself adopts a semi-circular groove arrangement, and as a variant, it can also be arranged in a triangular arrangement. In this way, it is only necessary to turn the protective cover over the side of the protective groove away from the connecting end with the first through groove as the axis, or to keep the protective cover in a natural state, so that the protective cover can be between the first state and the second state. The switch has the advantages of simple structure and easy implementation.

In this embodiment, the easy-folding structure further includes a second through groove c73 , and the second through groove c73 is provided on the side of the easy-folding body c71 and the notch of the protective groove b9051 facing the same.

By arranging the second through groove, the rotation convenience of the protective cover itself can be increased again, and the elastic force concentration at the position of the second through groove can be avoided when the protective cover is rotated, which causes the protective cover itself to have a driving force to open.

As an alternative embodiment, the easy-to-break structure can also be a structure made of a flexible material or an elastic material.

In this embodiment, the protective cover c6, the easy-folding structure and the second shell are integrally formed. As a variant, structures such as a protective cover can also be arranged on the second housing by splicing.

In this embodiment, in order to achieve the stability of the protective cover on the side wall of the second water tank, the free end c62 and the side wall of the second water tank are detachably connected through a snap structure.

Specifically, the buckle structure includes: a first buckle, including a first buckle body c811 disposed on the groove wall of the protection groove b9051, and a first buckle body c811 formed on the first buckle body c811 and the escape groove The card slot c812 between the groove bottoms of the c822; the side of the first buckle body c811 facing away from the card slot c812 is formed with a first guide slope c813; the second buckle includes the protective covers c6 respectively provided The second buckle body c821 and the let-away slot c822 on the upper part, the second buckle body c821 is provided with a second guide slope c823 that cooperates with the first guide slope c813, and the give-away groove c822 is suitable for the The second buckle body c821 accommodates the first buckle body c811 when the second buckle body c821 is stuck in the card slot c812; the second buckle body c821 is stuck against the first buckle body c821 when the protective cover c6 is in the first state into the card slot c812, and when the protective cover c6 is in the second state, the protective cover c6 comes out of the card slot c812.

In this way, the locking and unlocking of the protective cover in the first state can be achieved only by snapping the second buckle body into the card slot or out of the card slot, with simple structure, convenient operation and stable locking effect.

In this embodiment, at least one sinking slot c91 is provided at the bottom of the protection slot b9051, and the conducting opening b9052 communicates the sinking slot c91 and the accommodating cavity. By providing the groove, the tightening or loosening operation of the first nut and the second nut can be facilitated, thereby improving the convenience of operation.

In this embodiment, a wire blocking structure disposed in the protection groove b9051 is also included. By setting the wire blocking structure, the wires drawn from the electrolysis assembly can be guided and limited, so that the wiring in the protective groove is more tidy and standardized.

Specifically, the wire blocking structure is set as a convex block arranged on the protective groove, and its specific shape and size are not limited too much. It acts on the front position of the wire rotation path. When the wire is rotated by an external force to the blocking wire After the structure will stop and continue to rotate. In this embodiment, the blocking line protrusion c92 is disposed close to the sinking groove c91. As a modification, it can also be set properly away from the groove, as long as the blocking action on the wire can be achieved, which is not limited in this embodiment.

In this embodiment, it also includes:

The water cup d4 is arranged in the inner bladder d5;

The water tank b0 is provided with a water tank outlet b8, and the plane where the water tank outlet b8 is located is higher than the upper surface of the water cup d4.

The plane where the water outlet b8 of the water tank is located is higher than the upper surface of the water cup d4, so that there is a positional gap between the plane where the water outlet b8 of the water tank is located and the upper surface of the water cup d4, so that the disinfectant in the water tank b0 can flow into the water cup only under the action of gravity d4, and using the principle of the connector, it can ensure that all the disinfectant in the water tank b0 flows into the water cup d4, which is convenient to dilute the disinfectant in the water cup d4 according to the preset volume of water, avoiding the problem of inaccurate concentration of the active ingredients of the disinfectant. .

As shown in FIG. 22 , the height difference between the plane where the water outlet b8 of the water tank is located and the upper surface of the water cup d4 is H, where H>0 cm.

As a specific realization form, the volume of the water tank b0 is designed according to 1.1L, and the required water storage volume is 1L. After all the disinfectant in the water flow into the water cup d4, add 2L of pure water into the water cup d4, so that the water cup d4 has 3L of electrolytic disinfectant with a concentration of 250mg/L. All the disinfectant in b0 flows into the water cup d4 to ensure that the water tank b0 can obtain the disinfectant of accurate volume and accurate active ingredient concentration after adding the preset volume of pure water, thereby facilitating the disinfection of the items to be disinfected.

Specifically, a water discharge valve d43 is provided on the water discharge pipe d42. The water discharge valve d43 is suitable for controlling the on-off of the water discharge pipe d42, so that the water discharge pipe d42 is conducted as required. The drain valve d43 is normally closed. In the disinfection mode, the electrolysis device provided in the water tank b0 works to prepare the disinfectant of the required concentration. When the water discharge valve d43 is opened from the normally closed state, the disinfectant in the water tank flows into the water cup d4 under the action of gravity, and carries out Washing and disinfection work.

Specifically, the capacity of the water tank b0 is less than or equal to the capacity of the water cup d4. By designing the capacity of the water tank b0 to be less than or equal to the capacity of the water cup d4, the disinfectant in the water tank b0 will not overflow when all of the disinfectant flows into the water cup d4.

Specifically, the water tank is provided with a flow meter. The flow meter is arranged at the water inlet of the water tank, and the flow meter is arranged to measure the flow rate of the water flowing into the water tank.

Specifically, the dishwasher further includes: a water softener water outlet pipe f1, one end of the water softener water outlet pipe f1 is respectively connected with the water tank water inlet b7 of the water tank b0 and the water cup water inlet of the water cup d4 through a three-way valve d44. Connected.

Specifically, the other end of the water softener water outlet pipe f1 is adapted to be in conduction with the water outlet end of the water softener f.

The water softener f is suitable for softening the water introduced into the dishwasher, and communicates with the water tank b0 and the water cup d4 through the three-way valve d44, so that the water softened by the water softener f can be softened. Flow into the water tank b0 or the water cup d4 as required. The three-way valve d44 has a structure of one inlet and two outlets. When one of the two water outlets is opened, the other one is closed and not opened at the same time. In the washing mode, the three-way valve is connected with the water inlet of the water cup, so that the water flows to the water cup d4. In the disinfection mode, the three-way valve is connected to the water inlet b7 of the water tank, so that the water flows to the water tank b0.

Specifically, the water tank outlet b8 of the water tank b0 is set at the lowest point position of the bottom of the water tank b0. By arranging the water tank outlet b8 at the lowest position of the bottom of the water tank b0, the disinfectant in the water tank b0 can be completely discharged to avoid residues.

The dishwasher provided in this embodiment further includes: a respirator on which is provided a respirator water inlet pipe, the respirator water inlet pipe is connected to a water source through a water inlet solenoid valve; a water softener, which is connected to the respirator The water softener is provided with a water softener water outlet pipe; a three-way valve is connected with the water softener water outlet pipe, and the water outlet ends of the three-way valve are respectively communicated with the water tank and the water cup.

By setting the three-way valve, the water flowing out from the water softener can be introduced into the water tank for electrolysis water operation, or into the inner tank to rinse the tableware, so as to realize the cleaning and disinfection of the tableware in the inner tank.

The working process of the dishwasher provided by this embodiment is as follows: the respirator e itself is connected to an external water source through the respirator water inlet pipe e1, and the external water source can be a water tank or a tap water pipe, and the respirator water inlet pipe e1 is provided with a The water inlet solenoid valve e2 can control the water flow into the respirator e by controlling the on-off of the water inlet solenoid valve e2. After the water flow enters the inside of the respirator e, it will further flow into the water softener f. After the softening operation of the water softener, the water flow will flow into the water softener outlet pipe f1 and further into the three-way valve. From the water outlet, the water flow can enter the water cup d4 or the water tank, and the water entering the water cup d4 will clean the tableware in the inner tank. The water entering the water tank first flows into the water tank through the water tank inlet b7, then enters the water channel b5, and flows out through the water outlet b501 of the water channel b5. In a1, the solid sodium chloride located in the accommodating tank a1 is dissolved. After the mixture of sodium chloride and water flows out from the opening of the accommodating tank and the flow hole a103, it flows through the second rib b2 and the first Ribs b1, and then enter the inside of the mouth of the pot. With the continuous increase of the water volume, the water level of the water inside the water tank will gradually increase, and then the electrolysis component c0 will gradually disappear. When the current concentration in the solution inside the water tank exceeds a predetermined value After that, the electrolysis assembly c0 will start the electrolysis operation, and after the electrolysis, a highly oxidizing disinfectant will be formed. When the washing operation of the inner tank is performed by washing the dishes, the disinfectant is discharged into the water cup d4 through the water discharge pipe d42, so as to realize the disinfection operation of the tableware. At the same time, during the preparation process of the disinfectant, the gas generated inside the water tank and the disinfectant will flow out into the inner tank through the overflow port b6.

After completing the disinfection of the inner tank, you can stop pouring the disinfectant into the inner tank at this time, and then continue to pour clean water into the inner tank for rinsing, so as to transfer the residual disinfectant inside the dishwasher to the outside of the dishwasher. . At this time, the fan on the inner tank can be further activated to transfer the water vapor in the inner tank to the outside.

Obviously, the above-mentioned embodiments are only examples for clear description, and are not intended to limit the implementation manner. For those of ordinary skill in the art, changes or modifications in other different forms can also be made on the basis of the above description. There is no need and cannot be exhaustive of all implementations here. However, the obvious changes or changes derived from this are still within the protection scope of the present disclosure.

Claims (36)

1. A dishwasher comprising:

   A chamber structure, a water tank chamber (b901) is arranged inside, and a salt water generating device is arranged on the water tank chamber (b901);

   An electrolysis assembly (c0), arranged inside the water tank chamber (b901), is suitable for electrolyzing the salt water generated by the salt water generating device;

   A box body, the chamber structure acts on the box body, the box body includes an inner liner (d5) and a door body suitable for closing the inner liner (d5), and the inner liner (d5) is moderate in size For placing tableware to be cleaned, the cavity structure is suitable for acting on at least one of the inner container (d5) and the door body;

   Substances located in the chamber structure are adapted to flow out of the tank chamber (b901) and into the bladder.
2. The dishwasher of claim 1, wherein the chamber structure includes at least one of a respirator and a water tank (b0).
3. The dishwasher of claim 2, wherein the cavity structure is provided on the inner container.
4. The dishwasher according to claim 3, wherein the cavity structure is a water tank (b0), and the water tank (b0) is detachably arranged on the inner tank.
5. The dishwasher according to claim 4, wherein an overflow port (b6) is provided on the water tank (b0), and a part corresponding to the overflow port (b6) on the inner tank is provided with a through hole (b6). An overflow vent structure is provided between the overflow port and the through hole, and the overflow vent structure is suitable for restricting the substances in the water tank (b0) from passing from the overflow port (b6) Unidirectional flow into the through hole.
6. The dishwasher of claim 5, wherein the overflow exhaust structure comprises:

   a water gas inlet (b616), arranged through the first side of the overflow exhaust structure;

   A water blocking end cover (b614), arranged on the second side of the overflow and exhaust structure, and arranged along the extending direction of the water gas inlet (b616), is suitable for the water gas inlet (b616) occludes the direction of extension; and

   The overflow exhaust port (b611) penetrates the overflow exhaust structure in a direction parallel to the water blocking end cover (b614), and is at least partially connected to the water gas inlet port (b616).
7. The dishwasher according to claim 6, further comprising: a backflow prevention rib (b62) disposed on the conduction path between the overflow port (b6) and the overflow exhaust port (b611), The backflow prevention rib (b62) is adapted to at least partially block the overflow port (b6).
8. The dishwasher according to claim 7, wherein the backflow prevention rib (b62) is arranged at a lower edge position of the overflow port (b6).
9. The dishwasher according to claim 8, wherein the lowest point position of the backflow prevention rib (b62) in the up-down direction is higher than the lowest point position of the overflow exhaust port (b611).
10. The dishwasher according to claim 9, wherein the backflow prevention rib (b62) is arranged in parallel with the water blocking end cover (b614).
11. The dishwasher according to claim 5, further comprising: a flow guide rib (b612), at least partially disposed around the water vapor inlet (b616), and adapted to support the water blocking end cover (b614) ).
12. The dishwasher according to claim 11, wherein the notch of the baffle (b612) and the water blocking end cover (b614) are jointly enclosed to form the overflow vent (b611).
13. The dishwasher according to any one of claims 5-12, wherein the angle between the exhaust overflow direction of the overflow exhaust port (b611) and the horizontal plane is β1, wherein 0°≤β1≤180° .
14. The dishwasher of claim 13, further comprising:

    Spray arm (d1), suitable for spraying water;

    The value range of the included angle β2 between the opening direction of the overflow exhaust port (b611) and the spraying direction of the spray arm (d1) is 90°≤β2≤180°.
15. The dishwasher according to claim 14, wherein a tooling rib position (b615) is further provided on the overflow exhaust structure, and the tooling rib position (b615) is suitable for adjusting the overflow exhaust port (b615). b611) orientation.
16. The dishwasher according to claim 5, wherein an overflow flange (b63) is provided around the periphery of the overflow port (b6), and the overflow exhaust structure is protruded from the overflow port. The flange (b63) is provided with a screwing part (b617) at the corresponding position; the overflow flange (b63) is provided with an internal thread or an external thread, and the screwing part (b617) is correspondingly provided with an external thread or an internal thread thread.
17. The dishwasher according to claim 16, wherein an overflow sealing ring (b64) is further provided between the water tank and the inner tank (d5), and the overflow sealing ring (b64) surrounds the The overflow port (b6) is set.
18. The dishwasher of claim 4, wherein the salt water generating means comprises:

    A dispenser is detachably arranged on the water tank (b0), and an accommodating groove (a1) is arranged in the dispenser.
19. The dishwasher of claim 18, wherein the water tank (b0) comprises:

    the side wall of the first water tank (b904);

    The second water tank side wall (b905) is arranged opposite to the first water tank side wall (b904), and the second water tank side wall (b905) is arranged adjacent to the inner tank wall (d51) of the inner tank, so The overflow exhaust structure is arranged corresponding to the side wall of the second water tank (b905);

    A salt injection port (b10) is provided on the side wall of the second water tank (b905), and a flange hole (d52) is provided on the inner wall (d51) corresponding to the salt injection port (b10). , the dispenser is adapted to penetrate deep into the water tank (b0) through the flange hole (d52).
20. The dishwasher according to claim 19, wherein a salt mouth flange (b101) is protruded and formed in a direction in which the edge of the salt injection port (b10) protrudes into the inner pot (d5), and the doser Removably provided on the salt mouth flange (b101).
21. The dishwasher according to claim 20, wherein a knob catch (a5) is protruded from the inner wall of the salt mouth flange (b101), and the dispenser is detachably connected to the knob catch (a5).
22. The dishwasher according to any one of claims 19-21, further comprising: a water channel (b5), which is provided on the water tank (b0), and is provided with a drain port (b501), passing through the water channel (b5) The water of 100 ℃ acts into the accommodating tank (a1) through the water outlet (b501).
23. The dishwasher according to claim 18, further comprising: a water tank water inlet (b7) and a water tank water outlet (b8), respectively communicating with the water tank chamber (b901), and one end of the water channel (b5) The water inlet (b7) of the water tank is communicated, and the water channel (b5) includes a drainage section (b502) and a rectification section (b503), and at least one of the drainage section (b502) and the rectification section (b503) forms a Describe the drain (b501).
24. The dishwasher according to claim 23, wherein the drain port (b501) is provided on the rectifying section (b503).
25. The dishwasher of claim 24, wherein the dispenser comprises:

    the accommodating groove (a1);

    The holding part (a2) is provided on the first groove wall (a101) of the accommodating groove (a1).
26. The dishwasher according to claim 25, wherein a plurality of flow-through holes (a103) are provided at the bottom of the accommodating groove (a1).
27. The dishwasher according to claim 26, wherein a plurality of the flow-through holes (a103) are arranged in a side-by-side straight line at the bottom (a1) of the accommodating tank near the second tank wall (a106) .
28. The dishwasher according to claim 26 or 27, wherein the flow-through hole (a103) is configured as a circular hole, and the diameter of the circular hole ranges from 0.5 mm to 5 mm or more.
29. The dishwasher according to claim 25, wherein the accommodating groove (a1) is further provided with a plurality of scales (a104) along its groove depth direction, and the scales (a104) are used to identify the accommodating groove (a104). The real-time capacity of slot (a1).
30. The dishwasher according to claim 27, wherein, when the rotating clip (a5) is clipped to the positioning slot (a2072), the flow-through hole (a103) of the accommodating slot (a1) ) towards the drain (b501) in the tank (b0).
31. The dishwasher according to claim 30, wherein the projection of the drain port (501) coincides with the flow hole (a103).
32. The dishwasher according to claim 1, further comprising a fixing seat (a6) arranged on the salt mouth flange (b101), and after the fixing seat (a6) is fixed in place, the fixing seat (a6) is One end surface of the seat (a6) abuts on the inner wall (d51).
33. The dishwasher according to claim 32, wherein the fixing seat (a6) is screwed on the salt mouth flange (b101).
34. The dishwasher of claim 1, further comprising:

    A water cup (d4), arranged in the inner bladder (d5);

    The water tank (b0) is provided with a water tank outlet (b8), and the water tank outlet (b8) is located on a plane higher than the upper surface of the water cup (d4).
35. The dishwasher of claim 34, further comprising:

    a respirator, which is provided with a respirator water inlet pipe, and the respirator water inlet pipe is connected with a water source through a water inlet solenoid valve;

    a water softener, communicated with the respirator, and a water softener outlet pipe is arranged on the water softener;

    A three-way valve is connected with the water outlet pipe of the water softener, and the water outlet ends of the three-way valve are respectively communicated with the water tank and the water cup.
36. The dishwasher according to claim 1, wherein several layers of bowl baskets arranged in the height direction are arranged in the inner container (d5), and the bowl baskets are suitable for placing tableware; A baffle is arranged on the opening, and the baffle is suitable for closing the opening.

Images