CN112244727A - Water tank and dish-washing machine - Google Patents

Abstract

The invention provides a water tank and a dish washing machine, comprising: a water tank chamber; the water course, water course one end intercommunication water tank water inlet, the water course includes drainage section and rectification section, forms the outlet on at least one of drainage section and rectification section. Inside the drainage section can go out water flow from the water inlet and introduce the water tank, the rectification section can guide the adjustment to the direction of rivers to output columnar rivers. When the water tank is internally provided with a structure containing salt such as a containing groove, the salt can be more fully contacted with water under the impact of the water column and is dissolved in the water. When water is injected into the water tank to impact salt to form salt solution or the salt solution is directly injected into the water tank through the water outlet, water in the water tank is electrolyzed in the water tank or is fed into the electrolysis assembly to form sterilized water. When the sterilizing water is used for sterilizing the tableware in the dish washer, the pipeline through which the sterilizing water flows is also sterilized and disinfected, so that bacteria cannot grow.

Description

Water tank and dish-washing machine

Technical Field

The invention relates to the technical field of cleaning equipment, in particular to a water tank and a dish-washing machine.

Background

With the improvement of living standard, the dish washing machine gradually enters into the ordinary family, and the living quality of people is improved.

Generally, the main core components of existing dishwashers generally include: the water pump comprises a liner assembly, a water cup assembly, a spray arm assembly, a filter assembly, a washing pump, a drainage pump, a pipeline and the like. The dish washing machines in the current market generally carry out main cleaning and tableware disinfection by high temperature (usually about 70 ℃), and some dish washing machines can be also provided with UVC ultraviolet lamp disinfection, silver ion bacteriostasis added in part materials, steam high-temperature disinfection, hot air drying and other modes.

Disclosure of Invention

The invention provides a water tank and a dish washing machine.

A water tank, comprising:

the water tank cavity comprises a water tank water inlet and a water tank water outlet which are communicated with the water tank cavity;

the water tank water inlet is communicated with one end of the water channel, the water channel comprises a drainage section and a rectification section, and a water outlet is formed in at least one of the drainage section and the rectification section.

The water outlet is arranged on the rectifying section.

The rectifying section is arc-shaped.

The side wall of the water outlet extends into the water tank cavity to form a channel structure.

The water tank further includes:

the water tank comprises a water tank cavity, a water outlet and a water storage tank, wherein the water tank cavity is arranged in the water tank cavity, and the water outlet faces to the opening end of the water tank cavity.

The water outlet is positioned above the containing groove.

And the bottom and/or the side wall of the containing groove is/are provided with an overflowing hole.

A dishwasher, comprising:

an inner container;

a housing;

the water tank of any one of the above schemes is arranged at the outer side of the inner container or at the outer side of the shell.

The technical scheme of the invention has the following advantages:

1. the present invention provides a water tank comprising: the water tank cavity comprises a water tank water inlet and a water tank water outlet which are communicated with the water tank cavity; the water tank water inlet is communicated with one end of the water channel, the water channel comprises a drainage section and a rectifying section, and at least one of the drainage section and the rectifying section is provided with a drainage port.

Inside the drainage section can go out water flow from the water inlet and introduce the water tank, the rectification section can guide the adjustment to the direction of rivers to output columnar rivers. When the water tank is internally provided with a structure for containing salt, such as a containing groove, the water column which is directionally impacted and formed by the water channel drainage section or the rectification section enables the salt to be more fully contacted with water under the impact of the water column and be dissolved in the water. When water is injected into the water tank to impact salt to form salt solution or the salt solution is directly injected into the water tank through the water outlet, the water in the water tank is electrolyzed in the water tank or is sent into the electrolysis assembly to form sterilized water. When the sterilizing water is used for sterilizing tableware in the dish washer, the pipeline through which the sterilizing water flows is also sterilized and disinfected. Therefore, even if residual disinfectant exists, bacteria cannot grow.

2. According to the water tank provided by the invention, the water outlet is formed in the rectifying section.

The whole shape of the rectifying section enables water to flow into the direction with lower gravitational potential energy from the direction with higher gravitational potential energy, on one hand, the water in the drainage section forms thrust on the water in the rectifying section, and on the other hand, the gravitational potential energy is converted into kinetic energy, so that the water flowing out of the rectifying section has stronger salt impact capability. When the salt has coagulated salt blocks, the salt can be more easily dispersed and dissolved in water to form a salt solution.

3. According to the water tank provided by the invention, the side wall of the water outlet extends into the cavity of the water tank to form a channel structure.

The water outlet forms a channel structure, so that the flowing directionality of water flow can be further enhanced on the basis of the rectifying effect of the rectifying section on the water flow.

4. The invention provides a water tank, which further comprises: the water tank comprises a water tank cavity, a water outlet and a water storage tank, wherein the water tank cavity is arranged in the water tank cavity, and the water outlet is arranged towards the opening end of the water tank cavity.

The storage tank can store salt, and when water introduced the water tank cavity indoor, the salt in the storage tank contacted with water, can dissolved the aquatic, formed the salt solution.

5. According to the water tank provided by the invention, the water outlet is positioned above the accommodating groove.

The water outlet is positioned above the containing groove and can output water columns towards the containing groove, so that the salt can be more fully contacted with water under the impact of the water columns and is dissolved in the water. Even if part of salt is condensed into salt blocks, the salt can be fully dispersed and dissolved under the impact of a water column.

6. According to the water tank provided by the invention, the bottom and/or the side wall of the accommodating groove is/are provided with the overflowing hole.

The discharge orifice can release the mixed liquid of salt solution, salt granule bottom the storage tank, alleviates the impact pressure of storage tank on the one hand, prevents that the volume that rivers overflow from being less than the volume that the water column strikes the input, when storage tank water accumulation is many, the salt piece directly overflows through the opening at storage tank top easily. Through the reposition of redundant personnel effect of discharge orifice, the salt piece is difficult for overflowing through the opening of storage tank.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a schematic view of the interior of a water tank provided by the present invention;

FIG. 2 is a schematic view of an installation position of the dispenser according to the present invention;

FIG. 3 is a schematic view of another installation position of the dispenser provided by the present invention;

FIG. 4 is a schematic view of the assembly of the water tank of the present invention on a dishwasher;

fig. 5 is a schematic view of a spout structure provided in the present invention.

Description of reference numerals:

a 1-containing groove; a 103-overflowing hole;

b 0-water tank; b 1-first ribs; b 2-second ribs; b 5-water channel; b 501-a water outlet; b 502-drainage segment; b 503-a rectifying section; b 6-overflow port; b 7-water tank inlet; b 8-water outlet of water tank; b 9-water tank body; b 901-water tank chamber; b 902-pot mouth; b 9021-inclined plane of kettle mouth; b 9022-a spout convex part; b 9023-a first spout reinforcing rib; b 9024-a second spout reinforcing rib; b 9025-pot mouth channel; b 9026-a kettle mouth diameter-variable part; b 903-functional region; b904 — first tank sidewall; b 905-a second water tank side wall; b 10-salt input port;

c 0-electrolytic component; d 42-discharge pipe; d 5-inner bag; i-a flow meter.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, the technical features involved in the different embodiments of the present invention described below may be combined with each other as long as there is no conflict between them.

Example 1

The present embodiment provides a dishwasher, as shown in fig. 1, including:

the water tank b0 is internally provided with a water tank chamber b901, the water tank chamber b901 is provided with a salt adding port b10, specifically, a salt adding port b10 is used for adding salt or brine into the water tank chamber b901, in one embodiment, the salt adding port b10 can be used for communicating the water tank chamber b901 with a brine generating device, and the brine generating device can add salt or brine into the water tank chamber b901 through the salt adding port b10, when the brine generating device delivers brine into the water tank chamber b901 through the salt adding port b10, the brine can be prepared inside the brine generating device, or a prepared brine can be directly put into the brine generating device.

Specifically, in this embodiment, an electrolysis assembly c0 is further disposed in the water tank b0, and is disposed inside the water tank chamber b901 and adapted to perform electrolysis operation on the brine generated by the brine generator.

In addition to the above embodiments, as a further limited embodiment, the dishwasher further includes an inner container d5, the water tank b0 is communicated with the inner container d5, and the water tank b0 can provide the cleaning solution to the inner container d 5. The inner container d5 is suitable for placing tableware to be cleaned, the inner container d5 is provided with an opening, a door body is arranged on the opening, and the inner container is sealed through the door body. In order to facilitate the placement of the tableware, a plurality of layers of bowl baskets distributed along the height direction can be arranged in the inner container d 5. As an alternative embodiment, the bowl basket can be detachably arranged in the liner d5 in various specifications, and can also be integrally formed in the liner d 5.

As for the water tank b0 itself, a water tank inlet b7 and a water tank outlet b8 are generally provided for convenience of water inlet and outlet, and in this embodiment, the water tank inlet b7, the water tank outlet b8, and the salt intake b10 form three openings in the water tank body b 9. As an alternative embodiment, the salt throwing port b10 may share the same opening on the water tank body b9 with the water tank inlet b7, at this time, water may be injected into the water tank chamber b901 through the water tank inlet b7, brine may be injected into the water tank chamber b901 through the water tank inlet b7, and salt may be replenished into the water tank chamber b901 through the water tank inlet b 7.

The positional relationship between the water tank b0 and the liner d5 is not limited, and as shown in fig. 1, the water tank can be directly arranged on the outer side of the liner, and in one embodiment, the water tank b0 is arranged on the side wall of the liner. In other embodiments, the water tank b0 may be arranged on the top wall of the inner container, and the water tank b0 may be arranged on the door body. In a preferred embodiment, the water tank is correspondingly arranged on the side wall of the inner container, namely, the water tank is arranged on the left side wall of the inner container as shown in fig. 1. Correspondingly, the water tank can also be arranged at the right side wall of the inner container. As another alternative, the water tank b0 can be arranged inside the inner container.

The shape of the water tank b0 is not particularly limited, and as a further limited embodiment on the basis of the above embodiment, as shown in fig. 1, the upper part of the water tank b0 is rectangular, and the position corresponding to the top of the water tank is circular arc. As an alternative embodiment, the tank b0 is rectangular, as shown in the perspective of fig. 1, i.e., looking up the tank from the left side of the inner container d 5. As another alternative, the tank b0 may also be circular, oval, diamond, or other irregular shape in the view of fig. 1. In other embodiments, the water tank b0 may be spherical.

Specifically, as shown in fig. 1, the width of the bottom of the water tank b0 is relatively small, on one hand, in order to facilitate the water outlet of the water tank, that is, the water in the water tank can flow downwards by means of the self-gravity, and the guide effect can be achieved when the width of the bottom of the water tank is reduced. On the other hand, the narrowing of the bottom can reserve a larger space on the side wall of the inner container, thereby facilitating the installation of other structures. For the water tank of the dishwasher, a water softening mechanism can be usually included, and the bottom of the water tank b0 is narrowed in the embodiment, so that more space is reserved for the installation of other components such as a water softener, a respirator, a flow meter i and the like to flow out. As an alternative embodiment, the width of the bottom of the water tank b0 is relatively increased, or the width of the water tank b0 is uniform in the height direction.

As shown in fig. 1, the water tank b0 has a certain thickness to form an inner water tank chamber b901, and the integral water tank b0 is arranged on the outer side wall of the liner in parallel. Referring to fig. 1, it can be seen that the thickness of the water tank b0 is uniform throughout the thickness direction of the water tank b0, and the thickness direction of the water tank b0 can be understood as the direction from the side of the water tank b0 close to the sidewall of the inner container to the side of the water tank d5 away from the sidewall of the inner container shown in fig. 1. As an alternative embodiment, the water tank b0 is not uniform in its thickness direction, and may be embodied in that one side of the water tank b0 close to the inner container d5 is parallel to the inner container d5, and the other side is inclined toward the inner container d5, so that the thickness of the space inside the water tank b0 is gradually changed in the height direction of the water tank b0, thereby forming the water tank chamber 901 with the changed thickness. The shape and thickness of the tank chamber b901 are changed, on one hand, for the installation of internal components, the functions of the internal components are exerted; on the other hand, the water tank b0 is installed and connected with other mechanisms of the dishwasher to form structural cooperation, thereby saving space and increasing the compactness of the internal structure.

Further, the water tank chamber b901 inside the water tank b0 is used for storing and preparing the cleaning liquid. The cleaning liquid used for the dish washer can be water, salt water, cleaning agent for removing dirt and oil, disinfectant water and the like, the cleaning liquid is usually transported to a use place through a pipeline structure, and different cleaning modes can correspond to different temperatures of the cleaning liquid. Therefore, if the cleaning liquid in the water tank b0 needs to be heated, the outer shell of the water tank b0 can be reserved with a groove structure and/or a protrusion structure, so that the pipeline structure can pass through the groove and/or the protrusion, and when the cleaning liquid in the water tank b0 is heated, the medium in the pipeline structure can be heated in an auxiliary mode to save energy.

In this embodiment, the tank b0 includes a tank body b9, and other components disposed within the tank body b 9. The tank body b9 can be understood as a case structure of the water tank b 0. As shown in fig. 1 and 5, the tank body b9 includes a first tank sidewall b904 and a second tank sidewall b 905. The first tank sidewall b904 is parallel to the sidewall of the inner container d5, the first tank sidewall b904 and the second tank sidewall b905 are respectively protruded with a matching spigot structure, as shown in fig. 5, the second tank sidewall b905 is fastened on the first tank sidewall b904 to form a relatively closed tank chamber b901 in the tank body b 9. As an alternative embodiment of the structure of the tank body b9, the tank body b9 may be combined of three or more components. As another alternative embodiment of the structure of the body b9, the outer case of the body b9 is integrally formed as a single body.

The cleaning liquid in the dishwasher of the embodiment comprises disinfectant, and the preparation principle of the disinfectant is as follows: cathode 2 Cl-2 e ═ Cl2

Anode 2H2O +2e- ═ H2+2OH-

And (3) total reaction: 2Cl- +2H2O ═ H2+ Cl2+2OH-

A disproportionation reaction will occur between chlorine and water: cl₂+H₂The generated HClO has certain oxidability, thereby realizing the killing effect on bacteria and viruses.

In the embodiment, the main component of the salt is NaCl, which is non-toxic and stable in property, is not easy to deteriorate, and is convenient for storage and electrolytic disinfection operation. Other chlorates, such as KCl, CaCl, etc., are not recommended because of their own potential for harm to the human body.

On the basis of the above embodiment, as a further limited embodiment, a brine generating device is provided inside the water tank b0, and the brine generating device can provide brine or raw materials for preparing brine to support the preparation and transportation of brine. At this time, the user may replenish the salt water or the salt water into the salt water generating apparatus through the salt feeding port b 10. On the basis that the salt input port b10 is communicated with the brine generating device, the brine generating device can be directly arranged on the salt input port b10, and can also be arranged at the downstream of the salt input port b10 so as to receive the salt or the brine input through the salt input port b 10. As an alternative embodiment, the brine generating means may also be provided outside the water tank, and the brine generating means may communicate with the water tank b0 through a pipe structure. As another alternative, the brine generating device is arranged on the outer wall of the water tank and is in matched communication with the inside of the water tank through a spigot or the like.

The specific structure of the brine generating device is not limited, and on the basis of the above-described embodiments, as a further limited embodiment, as shown in fig. 1, the brine generating device is a salt dispenser in this embodiment. The salt dispenser can dispense salt or brine into the water tank chamber b901 through the salt dispensing port b 10. In this embodiment, the specific structure of the salt dispenser is the containing groove a1, the containing groove a1 is disposed on the salt dispensing opening b10, the containing groove a1 can contain salt, and after the water tank is filled with water, the water contacts with the salt to dissolve the salt in the water tank cavity b901 to form salt water, so that the electrolytic component c0 can prepare sterilized water. As an alternative embodiment, the salt dispenser is a pipe structure, one end of which is communicated with the water tank b0, and the other end of which extends to the outside of the dishwasher, so that a user can conveniently dispense salt into the water tank b0 from the outside of the dishwasher.

The position of the accommodating groove a1 is not particularly limited, and the accommodating groove a1 is disposed on the first tank sidewall b904 as shown in fig. 1 as a further limited embodiment on the basis that the accommodating groove a1 is located inside the water tank b 0. As an alternative embodiment, the container a1 is provided on the second water tank sidewall b 905. As another alternative, the container a1 is provided on the other inner wall of the tank chamber b 901.

In order to facilitate the replenishment of salt into the container a1, as a further limited embodiment, as shown in fig. 1, the container a1 is detachably connected to the tank body b9, so that the user can detach and take out the container a1 from the tank b0 and replenish the salt into the container a1 from the outside of the dishwasher. Since the first tank sidewall b904 of the tank b0 is close to the outer wall of the inner container d5, an opening channel is formed on the tank sidewall and the inner container d5 to facilitate the container a1 to pass through, wherein the opening channel forms a salt feeding opening b10 on the first tank sidewall b 904. Sealing structures are arranged among the water tank, the inner container and the accommodating groove a1 to ensure that the accommodating groove a1 sequentially penetrates through the side wall of the inner container d5 and the first water tank side wall b904 from the inside of the inner container d5 to enter the water tank. When the brine generating device is used for supplying brine, the brine can be directly introduced into the water tank chamber b901 through the brine inlet b 10. As an alternative embodiment, the container a1 may also be provided on the second tank sidewall b 905. The corresponding dishwasher shell is provided with a channel or an opening structure for the containing groove a1 to facilitate the user to directly install the containing groove on the water tank body b9 from the outside of the dishwasher, thereby supplementing salt into the water tank chamber b 901. As another alternative, the container may be disposed on other sidewalls of the water tank chamber b 901.

In order to facilitate the dissolution efficiency of salt and water, the accommodating groove a1 can be rotatably clamped with the water tank body b9, after a user adds salt into the accommodating groove a1, the opening of the accommodating groove a1 is upwards inserted into the water tank chamber b901, and when the accommodating groove a1 is inserted into a rotating position, the rotating position is rotated and clamped. Referring to fig. 2 and 3, at this time, the opening direction of the container with the upward opening is inclined or the opening faces downward, so that the surface of the salt pile in the container is spread to a larger area, when the inclined angle is relatively large, a part of salt directly falls into the water tank chamber b901, and when the opening of the container a1 faces downward completely, a majority of salt falls into the water tank chamber b 901. When the water tank chamber b901 is filled with water through the water tank inlet b7, water gradually accumulates in the water tank, and the flowing water comes into contact with salt falling in the water tank chamber b901 to dissolve the salt.

The position where the container a1 is disposed is not particularly limited, and on the basis of the above-described embodiments, as a further limited embodiment, as shown in fig. 1, the container a1 is disposed at the upper half portion of the tank chamber b 901. As an alternative embodiment, the container a1 is disposed at the lower half of the water tank chamber b901, and the container a1 may be disposed near the inner wall of the water tank chamber b901, and further, the container a1 may share the same side wall structure with the water tank chamber b 901.

In this embodiment, the water tank inlet b7 is used for the water feeding function of the water tank b0, and the water tank outlet b8 is used for communicating the inner container d 5. The dishwasher of the embodiment further comprises a water cup, wherein the water cup is used for supplying water to the inner container d5, the water outlet b8 of the water tank is used for supplying water to the water cup, and the water outlet b8 of the water tank is communicated with the water cup through a pipeline structure. In order to meet the temperature requirements of various washing modes, a heating device may be provided in the water tank b0, the water cup, or the pipe structure between the water tank and the water cup.

The position where the tank outlet b8 is provided is not particularly limited, and on the basis of the above-described embodiment, as a further limited embodiment, as shown in fig. 1, the tank outlet b8 is provided at the bottom of the tank. In this embodiment, even if the pump body is not installed, after the valve is opened, the water in the tank chamber b901 can be automatically discharged by gravity through the discharge pipe d42 connected to the tank outlet b 8. As an alternative embodiment, the water tank outlet b8 is arranged at any position on the inner wall of the water tank chamber b901, and the water discharge can be realized by the water discharge pipe d42 matched with the pump body structure.

The position where the water tank inlet b7 is provided is not particularly limited, and on the basis of the above-described embodiment, as a further limited embodiment, as shown in fig. 1, a water tank inlet b7 is provided at the bottom of the water tank chamber b 901. Specifically, the water tank inlet b7 is disposed adjacent to the water tank outlet b 8. Because the water tank water inlet b7 and the water tank water outlet b8 both need to be connected with a pipeline structure for use, the water tank water inlet b7 and the water tank water outlet b8 which are adjacently arranged are convenient to uniformly reserve space and set a pipeline structure at the corresponding position of the dish-washing machine. As an alternative embodiment, the tank water inlet b7 is provided at any position on the inner wall of the tank chamber b 901.

On the basis of the above embodiment, as a further limited embodiment, as shown in fig. 1, since the water tank chamber b901 has the container a1 therein, the container a1 has the salt to be dissolved therein, and in order to improve the dissolving efficiency of the salt, the water channel b5 is provided in the water tank b 0. As shown in fig. 2 and 3, a drain opening b501 is formed in the waterway b5, and an opening of the drain opening b501 is disposed toward the opening of the accommodating groove a 1. As shown in fig. 1, when the water tank b0 is filled, water is introduced into the water passage b5 through the water inlet b7 and then discharged through the water outlet b501, and the water flows directly into the accommodating groove a 1. Therefore, in the process of supplying water, the accommodating groove a1 always flushes the accommodating groove a1 to enable salt to be always in full contact with flowing water, and the dissolving efficiency of the salt is improved. On the other hand, if some of the salt in the container a1 is coagulated into salt lumps, the salt can be broken by the direct impact of the water flow, thereby further accelerating the dissolution of the salt.

A plurality of water outlets b501 may be formed on the waterway b5 in the above embodiments. Drain port b501 may be opened, or a valve may be provided to switch between opening and closing of drain port b 501. The inner diameters of the plurality of water outlets b501 may be the same or different, and the water outlets with different inner diameters may form water flow columns with different strengths correspondingly for users to switch.

The shape of the drain opening b501 is not particularly limited, and in the present embodiment, as shown in fig. 2 and 3, the inner wall of the drain opening is straight to form a linear waterway. The friction force that receives when can reduce rivers and flow along the inner wall of outlet, rivers can continuously receive the promotion of follow-up rivers in the water course when flowing in outlet b501 to make water accelerate in outlet b501, improve the impact force of outlet water. As an alternative embodiment, the drainage port b501 is parabolic or circular arc-shaped, and the inner wall of the drainage port is smooth. As another alternative, drain opening b501 is a polygonal line.

The shape of the waterway b5 is not particularly limited, and in the present embodiment, as shown in fig. 1, the waterway b5 includes a flow-inducing section b502 and a flow-rectifying section b503, and at least one of the flow-inducing section b502 and the flow-rectifying section forms the water discharge opening b 501. The drainage section b502 can lead water flow into the water tank chamber b901 from the water inlet, and the rectifying section b503 can guide and adjust the direction of the water flow, so as to output columnar water flow. When the water tank b0 is internally provided with a structure containing salt such as a containing groove, the salt can be more fully contacted with water through the water column which is directionally impacted and formed by the water channel drainage section b502 or the rectifying section, and the salt is dissolved in the water. As an alternative embodiment, the water tank b0 does not have the storage tank a1, salt is directly sprinkled into the water tank chamber b901 through the salt input port b10, and is accumulated at the bottom of the water tank chamber b901, at this time, the water discharge port b501 sprays water toward the accumulated salt, so that the water is contacted with the salt for dissolution, and local water flow is vigorously made under the impact action, thereby accelerating the dissolution of the salt. When water is injected into the water tank b0 to impact salt to form salt solution or salt solution is directly injected through the water outlet b501, water in the water tank is electrolyzed in the water tank or is fed into the electrolysis assembly to form sterilized water. The sterilizing water is used for sterilizing tableware in the dish washer, and meanwhile, a pipeline through which the sterilizing water flows is also sterilized and disinfected. Therefore, even if the disinfectant participates in the disinfection solution, bacteria cannot grow.

In addition to the above embodiments, as a further limited embodiment, as shown in fig. 1, the water discharge port is provided on the rectifying section b 503. The integral shape of the rectifying section b503 enables water to flow from the direction with higher gravitational potential energy to the direction with lower gravitational potential energy, on one hand, the water in the flow guiding section forms thrust on the water in the rectifying section b503, on the other hand, the water with the gravitational potential energy is converted into kinetic energy, and therefore the water flowing out of the rectifying section b503 has stronger salt impact capability. When the salt has coagulated salt blocks, the salt can be more easily dispersed and dissolved in water to form a salt solution. As an alternative embodiment, the drain opening is provided on the flow guiding section b 502. As another alternative, a plurality of water discharge openings may be distributed on the flow guiding section b502 and the flow rectifying section b 503.

The positional relationship between the flow-guiding section b502 and the rectifying section b503 is not particularly limited, and on the basis of the above embodiment, as a further limited embodiment, as shown in fig. 1 to 3, the included angle between the flow-guiding section b502 and the rectifying section b503 is less than 180 °, and a functional area b903 is defined between the flow-guiding section b502 and the rectifying section b 503. As an alternative embodiment, the angle between the flow-directing segment b502 and said flow-straightening segment b503 is equal to 180 °, or greater than 180 °.

The shape of the rectifying section b503 is not particularly limited, and as a further limited embodiment, the rectifying section b503 is a circular arc as shown in fig. 1. As an alternative embodiment, as shown in fig. 2, the rectifying section b503 is a straight line or a zigzag line, and the zigzag shape may refer to "M" shape, "N" shape, "V" shape, and the like, which is not described in detail in this embodiment, and a person skilled in the art may change the shape of the rectifying section b503 on the basis of the above example to optimize the water path and improve the water injection efficiency and the salt dissolution efficiency. As another alternative, the rectifying section b503 is wavy.

Specifically, the functional area b903 is located at a position where the horizontal position of the inner space of the water tank chamber b901 is relatively high, and an overflow port b6 is arranged in the functional area b 903. When the water quantity inside the water tank is too much, the operation of leading out redundant water from the water tank can be carried out through the overflow port b6, the water quantity inside the water tank can be detected through setting the overflow port b6, and then the water tank water inlet b7 can be controlled to stop carrying out the water inlet operation. The functional area is relatively arranged on the top of the water tank chamber b901, so that on the premise that the water tank chamber b901 can meet the capacity of water, saline water and disinfectant, a part of space is reserved on the top of the water tank, and after the liquid level of the water, the saline water and the disinfectant reaches the set capacity, the liquid level is positioned below the functional area, so that the overflow port can fully play the roles of overflowing and exhausting. When the water tank is internally subjected to electrolytic reaction, inflammable gases such as hydrogen can be generated inside the water tank, and the hydrogen can be rapidly led out to the outside from the inside of the water tank through the overflow port b6, so that the safety of the water tank is ensured. For the dish washer, an air exhaust structure can be arranged inside the dish washer to be matched with the overflow port to complete the air exhaust function.

Further, in the present embodiment, as shown in fig. 2 and 3, the drain port b501 is arranged in parallel with the overflow port b6, the drain port b501 can function as a functional area b903 divided in the tank chamber b901, and the overflow port b6 is arranged adjacent to the side wall of the drain port b501 and in parallel with the drain port b501 so that the level of the overflow port is not lower than the height of the outlet of the drain port b501, thereby preventing the water discharged from the drain port b501 from overflowing through the overflow port b 6.

Since the dissolution of the salt takes some time, the portion of the salt carried out by the water flow from the holding tank is present as salt lumps. The rate of dissolution of the salt cake in the water is slower than that of the small particles of salt, resulting in the salt cake being easily deposited toward the bottom of the tank. Since the tank outlet b8 is located at the bottom of the tank chamber b901, salt cake can easily accumulate at the tank outlet b8, which can cause the tank outlet b8 to become blocked.

On the basis of the above embodiments, the water tank b0 is further provided with a rectifying structure, as shown in fig. 1 to fig. 3, the rectifying structure is provided on the inner wall of the water tank chamber b901, specifically, the first water tank sidewall b904 in this embodiment. The rectifying structure comprises at least one rib, the rib is positioned on a flow path of salt and positioned at the upstream of the water outlet of the water tank, and water flows detour at the rectifying structure and form at least one detour path. When the water tank puts salt into the water tank cavity b901 through the salt input port b10, the ribs of the rectifying structure form a path for salt and water to bypass, so that salt blocks can be intercepted on the path from the salt flow to the water outlet, and the salt blocks are impacted and dispersed or the time for the salt to reach the water outlet is prolonged. When the salt lumps are impacted and dispersed, the contact area of the salt lumps and the solution is increased, and the dissolution of the salt lumps is accelerated. When the time of the salt block reaching the water outlet is increased, the flowing time of the salt in the solution is increased, so that the salt block can be more fully dissolved before reaching the water outlet, and the problem that the water outlet is easily blocked by the salt block is further solved.

Specifically, as shown in fig. 1, the rectifying structure includes: and the first rib b1 is arranged close to the water outlet b8 of the water tank. The first ribs b1 are arranged close to the water outlet b8 of the water tank, and can intercept and break away salt blocks flowing to the water outlet at the water outlet and force the salt blocks to bypass for full dissolution.

The arrangement of the first ribs b1 is not particularly limited, and on the basis of the above-described embodiment, as a further limited embodiment, as shown in fig. 1, the first ribs b1 are arranged horizontally. As an alternative embodiment, the first ribs b1 are arranged obliquely.

In addition to the above-described embodiments, as a further limited embodiment, as shown in fig. 1, the rectifying structure further includes: and the second ribs b2 are arranged between the downstream of the salt feeding port b10 and the upstream of the first ribs b 1. The second ribs b2 can break away and intercept the salt block before the salt block reaches the first ribs b1, and the salt block can be more fully contacted and dissolved with the solution while bypassing the second ribs b2, so that the effects of blocking and breaking away the salt block and promoting dissolution of the rectifying structure are further increased.

The number of the second ribs b2 is not particularly limited, and as a further limiting embodiment, on the basis of the above embodiment, as shown in fig. 1, there are two second ribs b2, and there is a space between the two second ribs b2, and the space forms a deflection channel between the two second ribs b 2. The deflecting channel formed by the two second ribs b2 can guide the salt cake into the deflecting channel on one hand, and can be temporarily intercepted at the opening of the deflecting channel for the salt cake with larger size on the other hand. When the salt block is clamped at the opening of the baffling channel, along with the inflow of water or the outflow of a salt solution, the solution in the water tank cavity is still in a flowing state, and the salt block can be dissolved or broken up in an accelerating way under the impact of water flow.

The positional relationship of the second ribs b2 is not particularly limited, and on the basis of the above-described embodiment, as a further limited embodiment, at least one of the second ribs b2 is provided obliquely toward the salt addition port as shown in fig. 1. When throwing in salt through salt input mouth, because second muscle b2 sets up towards salt input mouth b10, the in-process that drops of salt in water tank cavity b901 can strike on second muscle b2, and the salt piece easily scatters and is difficult for forming the caking. When the salt solution is injected through the salt feeding port b10, the salt solution falls on the second ribs b2, the second ribs b2 have the functions of diversion and buffering, the salt solution is prevented from directly falling on the bottom of the water tank chamber b901, and impact sputtering is formed in the water tank due to large fall.

There is no particular limitation on the positional relationship between the second rib b2 and the first rib b1, and on the basis of the above embodiment, as a further limited embodiment, as shown in fig. 1, the second rib b2 at least partially covers the gap upstream between the first rib b1 and the inner wall of the tank chamber. At least part of the second ribs b2 are distributed above the first ribs b1, so that the falling of the salt blocks or the falling of the salt blocks along with the flowing of water flow can be hindered layer by layer, and the blocking and dissolution accelerating effects of the salt blocks by the rectifying assembly are further enhanced. On the other hand, the setting mode that hinders layer upon layer can constantly promote rivers flow direction and form the baffling to form local torrent in water inside, further promote the dissolution of salt piece.

The structure of the ribs in the rectifying structure, such as the first rib b1 and the second rib b2, is not particularly limited, and on the basis of the above embodiments, as a further limited embodiment, a plurality of protruding structures are provided on the ribs. The protruding structure can make the salt piece receive the pressure increase when bumping the arch in-process with the salt piece contact, promotes the broken decomposition of salt piece. Meanwhile, the bulges can intercept the salt blocks, so that the salt blocks are intercepted in the gaps among the bulges. As an alternative embodiment, the ribs are a bar array structure made up of a plurality of columnar cells. Gaps for intercepting the salt blocks are reserved between the adjacent columnar units. As another alternative, the ribs are of a mesh panel construction.

On the basis of the above embodiment, as a further limited embodiment, the first rib b1 and the second rib b2 may extend from the first tank sidewall b904 to the second tank sidewall b905, so that after the second tank sidewall b905 is installed in cooperation with the first tank sidewall b904, the first rib b1 and the second rib b2 support the first tank sidewall b904 and the second tank sidewall b905, thereby improving the strength of the tank body b 9.

In this embodiment, in order to achieve sufficient dissolution of the salt in the accommodating groove a1, a plurality of overflowing holes a103 are disposed at the bottom of the accommodating groove a 1. The overflowing hole is arranged at the bottom of the groove, so that the solution generated in the accommodating groove a1 can be ensured to completely flow out, and the situation that the subsequent disinfectant concentration does not reach the standard due to the residual bottom solution in the accommodating groove is prevented.

The number, arrangement and shape of the overflowing holes themselves are not limited to a large number, and other arrangements, such as an annular arrangement, a triangular arrangement, etc., may be adopted as the arrangement, and as a preferred embodiment, a plurality of the overflowing holes a103 are linearly arranged side by side at the bottom of the accommodating groove a 1. Meanwhile, in terms of shape, the overflowing hole itself may take a regular shape such as a rectangle, an ellipse, or the like, or may also take an irregular shape as long as the leakage effect can be achieved, and as a preferred embodiment, the overflowing hole itself takes a circular shape. Meanwhile, the aperture range of the circular hole is greater than or equal to 0.5mm and less than or equal to 5mm, and the salt particles are prevented from directly falling out of the containing groove through the overflowing hole by the size setting mode.

In a preferred embodiment, in the present embodiment, as shown in fig. 3, a projection of the drain opening 501 coincides with the overflowing hole a 103. Specifically, the drain port 501 is provided at a position directly above the overflowing hole. Through the arrangement mode, water flowing out of the water outlet b501 can be directly applied to the position of the overflowing hole a103, and the water has larger kinetic energy under the action of weight, so that saline water can be directly discharged from the overflowing hole a103 after salt is washed, and the preparation efficiency of the saline water can be improved.

In order to facilitate the drainage function of the water tank b0 and prevent the water outlet from being blocked, as shown in fig. 1 and 4, a spout portion b902 with a gradually narrowing width is provided at the bottom of the water tank.

The position of the spout portion b902 is not particularly limited, and as shown in fig. 4, in the present embodiment, the spout portion b902 is correspondingly disposed below the salt feeding port b10 and/or the salt dispenser, and when water, an electrolyte solution, or sterilized water is directly injected into the water tank chamber through the salt feeding port, the water flow does not directly impact the spout portion, but is buffered by the first ribs, thereby preventing the formation of foam during water injection. The first rib b1 may be provided near the opening of the kettle mouth or inside the kettle mouth. The first ribs can be multiple, and the multiple first ribs are distributed in the kettle mouth part and on the part, close to the opening of the kettle mouth part, in the water tank cavity b 901.

As a preferred embodiment, as shown in fig. 4, the spout portion b902 includes a spout inclined surface b9021, the spout inclined surface b9021 is disposed at an end of the spout portion b902 away from the tank outlet b8, and the width of the spout portion b902 gradually decreases along the extending direction of the spout inclined surface b 9021. The spout inclined plane b9021 is positioned at the opening end of the spout part, can play a role in guiding water or sterilized water on two sides of the opening area of the spout part b902 to flow into the spout part b 902.

As for the structure of the spout inclined surface b9021, in addition to the above-described embodiments, as a further limited embodiment, as shown in fig. 5, the spout inclined surface b9021 is provided with: the spout convex part b9022 is arranged on the spout inclined plane b9021, and the spout convex part b9022 is arranged in the spout part in a protruding mode. Because the spout inclined plane b9021 plays a guiding role, water or disinfectant firstly impacts the spout inclined plane b9021 and then flows along the inclined surface of the spout inclined plane b 9021. Therefore, the spout convex part b9022 can be fully impacted with water flow or sterilized water flowing along the spout inclined plane b9021, when undissolved salt blocks exist in the water or the sterilized water, the salt blocks are impacted on the spout convex part b9022 along with the water flow and are broken away to be fully dissolved, and the salt blocks of solution are prevented from entering the spout part b902 to block the water outlet b8 of the water tank. On the other hand, the part adjacent to the kettle mouth is a local structure where the water tank inlet b7 is located, and a flow meter i is arranged at the water tank inlet b7 to monitor the water inflow of the water tank cavity. The mounting structure of flowmeter can correspond the setting at the back of kettle mouth convex part if seting up structures such as cell body, and kettle mouth convex part b9022 position is thicker relatively, has better mechanical strength, can improve the installation reliability of other spare parts such as flowmeter. The inclined plane can provide an installation foundation for other parts of the whole machine besides guiding water flow, and the compactness of the whole mechanical structure is improved.

As for the specific structure of the spout inclined surface b9021, as a further limited embodiment in addition to the above-described embodiment, as shown in fig. 5, the spout portion b902 includes: kettle mouth strengthening rib structure, kettle mouth strengthening rib structure includes first kettle mouth strengthening rib b9023 and second kettle mouth strengthening rib b9024 at least, first kettle mouth strengthening rib with constitute kettle mouth passageway b9025 between the second kettle mouth strengthening rib. The kettle opening channel can further tighten the cross section area through which water or sterilized water flows, and the water or the sterilized water is rectified in advance before entering 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, so that the strength of the water tank cavity is improved.

In addition to the above embodiments, as a further limited embodiment, as shown in fig. 5, the first spout reinforcing rib b9023 is in a zigzag shape, and a triangular reinforcing structure is enclosed between the first spout reinforcing rib b9023 and the spout inclined surface, so that the mechanical strength of the spout inclined surface b9021 can be further improved. In a preferred embodiment of the present invention, as shown in fig. 5, a spout reducing portion b9026 is disposed at one end of the spout passage b9025 close to the tank water outlet b8, and a width of the spout passage b9025 gradually increases toward the tank water outlet b8 at the spout reducing portion b 9026.

It should be understood that the above-described embodiments are merely examples for clarity of description and are not intended to limit the scope of the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. This list is neither intended to be exhaustive nor exhaustive. And obvious variations or modifications therefrom are within the scope of the invention.

Claims (8)

1. A water tank, comprising:

a water tank chamber (b901) comprising a water tank inlet (b7) communicating with the water tank chamber;

the water channel (b5), one end of the water channel (b5) is communicated with the water tank inlet (b7), the water channel (b5) comprises a drainage section (b502) and a rectifying section (b503), and a drainage outlet (b501) is formed in at least one of the drainage section (b502) and the rectifying section (b 503).

2. The tank according to claim 1, characterized in that the drain opening (b501) is provided on the rectifying section (b 503).

3. The water tank according to claim 2, characterized in that the rectifying section (b503) is circular arc shaped.

4. A cistern as claimed in any one of claims 1 to 3, wherein the side wall of the outlet (b501) extends into the cistern chamber (b901) to form a channel formation.

5. The water tank of claim 4, further comprising:

a container (a1) disposed in the tank chamber (b901), the drain opening (b501) being disposed toward an open end of the container (a 1).

6. The water tank as claimed in claim 5, wherein the drain port (b501) is positioned above the container (a 1).

7. The water tank as claimed in claim 5 or 6, wherein an overflowing hole (a103) is provided on the bottom and/or the sidewall of the container (a 1).

8. A dishwasher, comprising:

an inner container;

a housing;

the water tank (b0) of any of claims 1-7, disposed outside the inner bladder or outside the outer casing.

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