CN109662576B - Refrigerating module and water dispenser - Google Patents

Abstract

The invention discloses a refrigeration module and a water dispenser, wherein the refrigeration module is used for the water dispenser, and comprises: a refrigeration shell provided with a refrigeration cavity for installing a refrigeration device; a sewage drainage flow path is arranged on the side wall and/or the bottom wall of the refrigeration cavity; the sewage draining flow path is communicated with the sewage draining outlet of the refrigerating device, so that sewage in the refrigerating device is discharged through the sewage draining flow path. The technical scheme of the invention enables the structure of the refrigeration module to be more compact.

Description

Refrigerating module and water dispenser

Technical Field

The invention relates to the technical field of water dispensers, in particular to a refrigeration module and a water dispenser.

Background

Along with the development of economy and the improvement of living standard, the requirements of people on the water dispenser are higher and higher. In the existing water dispenser, waterways among a water diversion part, a heating part or a refrigerating part in the water dispenser are all composed of scattered water pipes, and the pipelines are arranged in a shell of the water dispenser in a staggered and complicated manner. The structure of the water dispenser is redundant, and all the water pipes are mutually influenced, so that the water dispenser is not beneficial to work.

Disclosure of Invention

The invention mainly aims to provide a refrigerating module which aims at improving the compactness of the structure of a water dispenser and improving the working stability of the water dispenser.

In order to achieve the above object, the present invention provides a refrigeration module for a water dispenser, the refrigeration module comprising:

a refrigeration shell provided with a refrigeration cavity for installing a refrigeration device; a sewage drainage flow path is arranged on the side wall and/or the bottom wall of the refrigeration cavity;

the sewage draining flow path is communicated with the sewage draining outlet of the refrigerating device, so that sewage in the refrigerating device is discharged through the sewage draining flow path.

Preferably, the blowdown flow path is formed by combining blowdown hole paths, and the blowdown hole paths are formed in the side wall and/or the bottom wall of the refrigeration shell;

the water inlet of the blowdown hole is communicated with the blowdown outlet of the heating device and/or communicated with the blowdown outlet of the refrigerating device so that water is discharged through the blowdown hole.

Preferably, the blow-down hole path is formed by core pulling or hole opening on the refrigeration shell.

Preferably, the blowdown path comprises a cold water blowdown path;

the cold water drain hole path comprises a transverse section extending along the radial direction of the refrigeration shell and/or a vertical section extending along the height direction of the refrigeration shell.

Preferably, one end of the vertical section is communicated with a drain outlet of the refrigerating device, and the other end of the vertical section is communicated with one end of the transverse section;

The transverse section is arranged at the bottom of the refrigeration shell, the other end of the transverse section extends to a cold water drain outlet, and the cold water drain outlet is arranged on the outer surface of the refrigeration shell.

Preferably, the blowdown path comprises a hot water blowdown path;

the hot water drain hole path includes a radial section extending in a radial direction of the refrigeration housing, and an axial section extending in a height direction of the refrigeration housing.

Preferably, the axial section is arranged in the side wall of the refrigeration shell, one end of the axial section is communicated with a drain outlet of the heating device, and the other end of the axial section is communicated with one end of the radial section;

the radial section set up in the bottom of refrigeration casing, the other end of radial section extends to the hot water drain, the hot water drain is established the surface of refrigeration casing.

Preferably, the blowdown hole path comprises a cold water blowdown hole path and a hot water blowdown hole path;

the cold water pollution discharge hole path comprises a transverse section arranged along the radial direction of the refrigeration shell;

the hot water pollution discharge hole path comprises a radial section arranged along the radial direction of the refrigeration shell;

the transverse section and the radial section are located within the same layer of the refrigeration shell.

Preferably, the drain flow path includes:

the sewage draining tank circuit is arranged on the shell;

the sewage disposal pipeline is arranged along the sewage disposal tank way and is arranged in the sewage disposal tank way, and a water inlet of the sewage disposal pipeline is communicated with a sewage outlet of a heating device of the water dispenser and/or communicated with a sewage outlet of the refrigerating device so that water is discharged through the sewage disposal hole way.

Preferably, the blowdown tank circuit comprises a cold water blowdown tank circuit and/or a hot water blowdown tank circuit;

the cold water drain tank circuit comprises a transverse section extending along the radial direction of the refrigeration shell and a vertical section extending along the height direction of the refrigeration shell; one end of the vertical section is communicated with a sewage outlet of the refrigerating device, and the other end of the vertical section is communicated with one end of the transverse section; the transverse section is arranged at the bottom of the refrigeration shell, the other end of the transverse section extends to a cold water drain outlet, and the cold water drain outlet is arranged on the outer surface of the refrigeration shell; and/or the number of the groups of groups,

the hot water blowdown tank circuit comprises a radial section extending along the radial direction of the refrigeration shell and an axial section extending along the height direction of the refrigeration shell; the axial section is arranged in the side wall of the refrigeration shell, one end of the axial section is communicated with a drain outlet of the heating device, and the other end of the axial section is communicated with one end of the radial section; the radial section set up in the bottom of refrigeration casing, the other end of radial section extends to hot water dirt discharging mouth, hot water dirt discharging mouth sets up the surface of refrigeration casing.

Preferably, the transverse section and the radial section are located in the same layer of the refrigeration shell.

Preferably, the refrigeration shell is in a cylindrical shape, and the blowdown flow path is arranged in the refrigeration shell.

The invention further provides a water dispenser, which comprises a refrigeration module, wherein the refrigeration module comprises:

a refrigeration shell provided with a refrigeration cavity for installing a refrigeration device; a sewage drainage flow path is arranged on the side wall and/or the bottom wall of the refrigeration cavity;

the sewage draining flow path is communicated with the sewage draining outlet of the refrigerating device, so that sewage in the refrigerating device is discharged through the sewage draining flow path.

In the technical scheme of the invention, as the sewage drainage flow paths are arranged on the side wall and/or the bottom wall of the refrigerating cavity, the position relationship and the connection relationship between the pipeline structures on the refrigerating module are very clear, so that the hot water sewage drainage flow paths and the cold water sewage drainage flow paths of the sewage drainage flow paths are not crossed, and the mutual influence among pipelines is avoided, thereby effectively improving the use stability of the refrigerating module and effectively improving the use stability of the water dispenser; by arranging the sewage drainage flow path on the shell, the structure of the refrigeration module is more compact, and the stability of the refrigeration module is improved; the refrigerating module is independently arranged, so that the refrigerating module can be adapted to various water treatment modules, such as a heating module, a water diversion module and the like, and the use flexibility of the refrigerating module is greatly improved; meanwhile, a user can assemble the water dispenser according to own requirements, so that the practical requirements for the water dispenser are better met.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained from the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of an embodiment of a water dispenser according to the present invention;

FIG. 2 is a schematic diagram of a water diversion module of a water dispenser according to an embodiment of the present invention;

FIG. 3 is a schematic view of the structure of FIG. 2 at another angle;

FIG. 4 is a schematic top view of FIG. 2;

FIG. 5 is a schematic view of the internal structure of the bottom view of FIG. 2;

FIG. 6 is a schematic view of another embodiment of a water diversion module of a water dispenser according to the present invention;

FIG. 7 is a schematic view of a heating module of a water dispenser according to an embodiment of the invention;

FIG. 8 is a schematic view of the structure of FIG. 7 at another angle;

FIG. 9 is a schematic view of the internal structure of the bottom view of FIG. 7;

FIG. 10 is a schematic view of a heating module of a water dispenser according to an embodiment of the invention;

FIG. 11 is a schematic view of the internal structure of the bottom view of FIG. 10;

FIG. 12 is a schematic view of a heating module of a water dispenser according to an embodiment of the invention;

FIG. 13 is a schematic view of another embodiment of a water dispenser according to the present invention.

Reference numerals illustrate:

the achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It should be noted that all directional indications (such as up, down, left, right, front, and rear … …) in the embodiments of the present invention are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indication is changed accordingly.

Furthermore, the description of "first," "second," etc. in this disclosure is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present invention.

The invention mainly provides a water dispenser which is used for heating, refrigerating or other treatments of water. The water dispenser may include one or more of the water diversion module 100, the heating module 200, and the cooling module 300, i.e., the water dispenser may heat and/or cool water. The water dispenser has a water diversion function, a water outlet function, a heating function, a refrigerating function, a cleaning and pollution discharging function, a transition water function (when the water dispenser simultaneously comprises the water diversion module 100, the heating module 200 and the refrigerating module 300, when water needs to flow from the water diversion module 100 to enter into another module after flowing through one module, a water passing flow path can be arranged on the flowing module, for example, water in the water diversion module 100 needs to flow into the refrigerating module 300 for refrigerating after flowing through the water passing flow path on the heating module 200, and water after refrigerating module 300 needs to flow into the water diversion module 100 for water outlet and the like) and the like, and the functions can be configured on one or more of the water diversion module 100, the heating module 200 or the refrigerating module 300 according to actual needs. For a simple example, the water diversion function is implemented by the water diversion module 100, the heating function is implemented by the heating module 200, the refrigerating function is implemented by the refrigerating module 300, and the water discharge function and the cleaning and pollution discharge function can be set on the water diversion module 100, the heating module 200 or the refrigerating module 300 according to different situations. That is, various functions may be combined with various modules according to actual needs to achieve many different executable implementations. Avoiding leaving behind during the writing process, a unified description is made herein that all features of the present embodiments that may be used in other embodiments may be combined into other embodiments.

One of the important inventions of the present application is that the pipelines of the large functions (water diversion function, water outlet function, heating function, refrigerating function, cleaning and pollution discharge function, and transition water function) or the pipelines connected between the functions are attached and fixed to the shells of the water diversion module 100, the heating module 200, or the energy production module, so that the pipelines and the shells of the modules are tightly fixed together, that is, the pipelines are integrated on the structures of the modules, so that the space is fully saved, the structures of the modules are compact, the pipelines are orderly arranged, and the operation of the modules is prevented from being influenced by the redundancy of the pipelines, and the operation of the modules is stable;

a further important invention point of the present application is that on one or more side walls of the water diversion housing 110 of the water diversion module 100, the heating housing 210 of the heating module 200 and the cooling housing 310 of the cooling module 300, a wire slot is formed through which a wire passes, and the wire slot may be formed inside the housing, or may be formed on an outer side wall of the water diversion housing 110, the heating housing 210 and/or the cooling housing 310; the wiring grooves are integrated on the shell, particularly on the outer side wall of the shell, so that the arrangement of the wires is very clear and regular, the wires are installed, dismounted and replaced very quickly and conveniently, the arrangement of the wires on the shell or the water dispenser is irregular and regular through the regular arrangement of the wires, the phenomenon of safety accidents caused by disorder of the wires is avoided, and meanwhile, the wires are not threatened by water any more due to the fact that the wiring grooves and the flow paths are mutually independent; through the arrangement of the wire slots, the structure of each module is more compact, the structure of each module is more orderly, and the utilization rate of the space structure is further improved;

A further important invention point of the present application is that the water dispenser is modularized according to its functions (the water diversion module 100, the heating module 200 and the refrigerating module 300), so that each functional module can exist alone and realize its functions, and importantly, the water dispenser can be arbitrarily combined with other functional modules, for example, the water diversion module 100 can be independently combined with the heating module 200 or can be independently combined with the refrigerating module 300, so that the flexibility of the combination of the water dispenser can be greatly increased, the user can perform any combination according to his own needs, and the satisfaction degree of the individual needs of the user is greatly improved; meanwhile, due to modularization, when a certain module of the water dispenser has a problem, the whole water dispenser is not required to be maintained or replaced, and only the specific functional module is required to be maintained or replaced, so that the maintenance, the maintenance and the replacement of the water dispenser are more convenient and quick, the waste of the complete functional part of the water dispenser is avoided, and the resources are fully and reasonably utilized.

The specific structure of the water heater will be mainly described below.

Referring to fig. 1 to 13, the modules and functions that the water dispenser may include have been clearly described above, and detailed descriptions will be made with respect to the water diversion module 100, the heating module 200, and the cooling module 300, respectively, and then the connection relationship and the positional relationship between the water diversion module 100 and the heating module 200, between the water diversion module 100 and the cooling module 300, and between the heating module 200 and the cooling module 300, respectively, will be described.

The water diversion module 100. The water diversion module 100 comprises a water diversion shell 110, wherein the water diversion shell 110 is provided with a water diversion cavity 120, and the bottom of the water diversion cavity 120 is provided with a water inlet 121 of the whole water path system of the water dispenser. The shape of the water diversion housing 110 may be a variety of, for example, a column, and the cross-sectional shape thereof may be a triangle, a polygon, a circle, an ellipse, etc., and is not particularly limited herein, for example, a circle is provided, and of course, the circle may have a concave or convex shape due to actual demands. The water diversion shell 110 is provided with a water diversion cavity 120, and a water inlet hole 121 is formed in the bottom of the water diversion cavity 120; a water diversion flow path 130 is arranged on the side wall and/or the bottom of the water diversion cavity 120, and the water diversion flow path 130 is communicated with the water inlet hole 121. The water diversion path 130 is formed by combining water diversion hole paths 140, the water diversion hole paths 140 are formed inside the water diversion housing 110, and water inlets of the water diversion hole paths 140 are communicated with the water inlet holes 121, so that water flowing in from the water inlet holes 121 is diverted along the water diversion hole paths 140.

The water diversion module 100 has a water diversion flow path 130, the water diversion flow path 130 being provided on the water diversion housing 110 or on a side wall and/or a bottom wall of the water diversion cavity 120. Taking the water diversion flow path 130 as an example of being arranged at the bottom of the water diversion cavity 120, by arranging the water diversion flow path 130 at the bottom of the water diversion cavity 120, the water level in the water diversion flow path 130 is lower than the water level in the water diversion cavity 120, so that the water in the water diversion flow path 130 can flow under the action of water potential difference, and the fluidity of the water is increased. The water diversion flow path 130 includes one or more of a hot water inflow path for supplying water to the heating module 200, a cold water inflow path for supplying water to the cooling module 300, and a normal temperature water inflow path for directly discharging the normal temperature water. The water inlets of the hot water inlet flow path, the cold water inlet flow path and the normal temperature water flow path are all communicated with the water inlet hole 121.

The water diversion flow path 130 is provided independently of the presence of the heating module 200 and the cooling module 300, but the water diversion flow path 130 is necessarily provided when the heating module 200 and the cooling module 300 are present. Taking a hot water inlet flow path as an example, when the water dispenser does not include the heating module 200, the water diversion flow path 130 may include a hot water inlet flow path to improve the adaptability of the water diversion module 100, i.e., the water diversion module 100 may be suitable for multiple water dispensers; when the water dispenser includes the heating module 200, the water diversion flow path 130 should include a hot water inflow flow path to supply water to the heating module 200.

There are many ways in which the water diversion flow path 130 is disposed on the water diversion housing 110 in a fitting manner, or disposed on the side wall and/or the bottom of the water diversion cavity 120, and two ways are described below by way of example.

First, the water diversion flow path 130 is directly opened in the water diversion housing 110, and the water diversion flow path 130 and the water diversion housing 110 can be structured to the maximum extent by forming a hole path on the body of the water diversion housing 110 through core pulling, drilling and the like. It is noted that the hole route is a flow path formed by holes, that is, water flows in the holes to reach a predetermined position.

In order to distinguish the paths of the other modules, the path corresponding to the diversion path 130 is a diversion path 140, and the diversion path 140 includes a hot water inlet path 142 and a cold water inlet path 141 which are independent from each other, and the normal temperature water outlet path 183 may be a part of the diversion path 140 or a part of the outlet path 180. The cold water inlet path 141, the hot water inlet path 142 and the normal temperature outlet path 180 extend from the water inlet 121 in different directions. To ensure that the holes do not interfere with each other while also reserving sufficient space for the underlying heating and/or cooling holes 240, 340.

A hot water inlet path 142 extending from the water inlet hole 121 to the heating module 200 to transport water from the water inlet hole 121 to the heating module 200. The hot water inlet path 142 includes a radial section extending in a radial direction of the water diversion housing 110 and/or an axial section extending in a height direction of the water diversion housing 110 so that the hot water inlet path 142 can be extended to any desired position of the water diversion housing 110. It should be noted that the number of the radial segments and the axial segments of the hot water inlet channel 142 may be set according to actual requirements, so as to meet the requirement of channel extension. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

The water inlet 121 is disposed at an intermediate position of the bottom of the water diversion cavity 120, one end of the radial section is communicated with the water inlet 121, the other end extends to the edge of the water diversion housing 110 in the radial direction, one end of the axial section is communicated with one end of the radial section away from the water inlet 121, and the other end extends to the bottom of the water diversion housing 110 in the height direction of the water diversion housing 110 to be communicated with the heating flow path 230 of the hot water module.

A cold water inlet path 141 extending from the water inlet 121 to the refrigeration module 300 to transport water from the water inlet 121 to the refrigeration module 300. The cold water inlet passage 141 includes a lateral section extending in a radial direction of the water diversion housing 110 and/or a vertical section extending in a height direction of the water diversion housing 110, so that the cold water inlet passage 141 can be extended to any desired position of the water diversion housing 110. It should be noted that, the number of the horizontal sections and the vertical sections of the cold water inlet channel 141 may be set according to actual requirements, so as to meet the requirement of extending the channel. There are many arrangements of the transverse sections and the vertical sections, and the following will illustrate the arrangements of the transverse sections and the vertical sections by way of example:

the water inlet 121 is disposed at a middle position of the bottom of the water diversion cavity 120, one end of the lateral section is communicated with the water inlet 121, the other end extends to the edge of the water diversion housing 110 in the radial direction, one end of the vertical section is communicated with one end of the lateral section away from the water inlet 121, and the other end extends to the bottom of the water diversion housing 110 in the height direction of the water diversion housing 110 to be communicated with the refrigerating flow path 330 of the cold water module or the cold water passing flow path.

In some embodiments, to further increase the space utilization, the structure of the water diversion housing 110 is made more compact, and the radial section of the hot water inlet passage 142 and the lateral section of the cold water inlet passage 141 are located at the same layer of the water diversion housing 110. Of course, in some embodiments, the ambient outlet passage 180 is also located at the same level of the water diversion housing 110 as the radial section of the hot water inlet passage 142.

Second, the water diversion flow path 130 is opened in the water diversion housing 110, and the water diversion channel 150 is formed in the water diversion housing 110, and the forming mode may be injection molding or subsequent processing, so long as the channel can be formed on the body of the water diversion housing 110. The water diversion flow path 130 further comprises a water diversion pipeline 155, the water diversion pipeline 155 is arranged along the water diversion channel 150 and is installed in the water diversion channel 150, and a water inlet of the water diversion pipeline 155 is communicated with the water inlet hole 121, so that water flowing in from the water inlet hole 121 is diverted along the water diversion pipeline 155. The water diversion pipeline 155 is composed of a water pipe, and can be a hose or a hard water pipe. Allowing water to pass through the water diversion pipe to maximize the relationship between the water diversion line 155 and the water diversion housing 110. It should be noted that the water diversion channel 150 is a flow path formed by extending grooves, that is, the flow direction of water is consistent with the flow direction of the water diversion channel 150 so as to reach a preset position. The water diversion flow path 130 includes: a water diversion channel 150, wherein the water diversion channel 150 is arranged on the shell; the water diversion pipeline 155 is arranged along the water diversion channel 150 and is installed in the water diversion channel 150, and a water inlet of the water diversion pipeline 155 is communicated with the water inlet hole 121 so that water flowing in from the water inlet hole 121 is diverted along the water diversion pipeline 155.

In order to distinguish the tank circuits of other modules, the tank circuit corresponding to the water diversion flow path 130 is a water diversion tank circuit 150, and the water diversion tank circuit 150 comprises a hot water inlet tank circuit 152 and a cold water inlet tank circuit 151 which are independent, and the normal-temperature water outlet tank circuit can be used as a part of the water diversion tank circuit 150 or a part of the water outlet tank circuit. Wherein the cold water inlet channel 151, the hot water inlet channel 152 and the normal temperature water outlet channel extend from the water inlet hole 121 in different directions. To ensure that the channels do not interfere with each other while also reserving sufficient space for the underlying heating and/or cooling channels.

The hot water inlet channel 152 extends from the water inlet hole 121 to the heating module 200 to guide the water diversion channel 155 to the heating module 200. The hot water inlet channel 152 includes a radial section extending in a radial direction of the water diversion housing 110 and/or an axial section extending in a height direction of the water diversion housing 110 so that the hot water inlet channel 152 can be extended to any desired position of the water diversion housing 110. It should be noted that the number of radial segments and axial segments of the hot water inlet channel 152 may be set according to actual requirements to meet the requirements of channel extension. There are many arrangements of the radial segments and the axial segments, and the following examples are given to illustrate the arrangements of the radial segments and the axial segments:

The water inlet 121 is disposed at an intermediate position of the bottom of the water diversion cavity 120, one end of the radial segment is disposed corresponding to the water inlet 121, the other end extends to the edge of the water diversion housing 110 along the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water inlet 121, and the other end extends to the bottom of the water diversion housing 110 along the height direction of the water diversion housing 110 to correspond to the heating flow path 230 of the hot water module.

The cold water inlet tank 151 extends from the water inlet hole 121 to the refrigeration module 300 to guide the water diversion line 155 to the refrigeration module 300. The cold water inlet channel 151 includes a lateral section extending in a radial direction of the cutwater housing 110 and/or a vertical section extending in a height direction of the cutwater housing 110 so that the cold water inlet channel 151 may extend to any desired location of the cutwater housing 110. It should be noted that the number of the transverse sections and the vertical sections of the cold water inlet tank 151 may be set according to actual requirements to meet the requirement of tank extension. There are many arrangements of the transverse section and the vertical section, and the following will illustrate the arrangements of the transverse section and the vertical section by taking an example:

one end of the horizontal section is arranged corresponding to the water inlet 121, the other end of the horizontal section extends to the edge of the water diversion shell 110 along the radial direction, one end of the vertical section is communicated with one end of the horizontal section away from the water inlet 121, and the other end of the vertical section extends to the bottom of the water diversion shell 110 along the height direction of the water diversion shell 110 so as to be arranged corresponding to the refrigeration flow path 330 of the cold water module or the cold water flow path.

In some embodiments, to further increase the space utilization, the structure of the water diversion housing 110 is made more compact, with the radial section of the hot water inlet channel 152 and the lateral section of the cold water inlet channel 151 being located at the same level of the water diversion housing 110. Of course, in some embodiments, the normal temperature water outlet channel is also located in the same layer of the water diversion housing 110 as the radial section of the hot water inlet channel 152.

The water dispenser has a water outlet flow path 170 to discharge hot water of the heating module 200, cold water of the cooling module 300, and normal temperature water out of the water dispenser. The water outlet flow path 170 may be provided in a variety of locations, such as the water diversion module 100, the heating module 200, or the cooling module 300, for example, on the water diversion module 100.

The water diversion module 100 has a water outlet flow path 170, the water outlet flow path 170 being provided on the water diversion housing 110 or on a side wall and/or a bottom wall of the water diversion cavity 120. Taking the example that the water outlet flow path 170 is arranged at the bottom of the water distribution cavity 120, by arranging the water outlet flow path 170 at the bottom of the water distribution cavity 120, the water level in the water outlet flow path 170 is lower than the water level in the water distribution cavity 120, so that the water in the water outlet flow path 170 can flow under the action of water potential difference, and the fluidity of the water is increased. The water outlet flow path 170 includes one or more of a hot water outlet flow path 170 for discharging hot water out of the water heater, a cold water outlet flow path 170 for discharging cold water out of the water dispenser, and a normal temperature water flow path for directly discharging cold water. The water inlet of the hot water outlet flow path 170, the cold water outlet flow path 170 and the normal temperature water outlet flow path 170 are all communicated with the water inlet hole 121.

The water dispenser comprises a water treatment module, the water treatment module is positioned below the water diversion module 100, and the water diversion module 100 comprises: a water diversion shell 110, wherein the water diversion shell 110 is provided with a water diversion cavity 120, a water inlet hole 121 is formed in the bottom of the water diversion cavity 120, and a normal temperature water outlet 113 and/or a treated water outlet are formed in the outer side wall of the water diversion shell 110; a water outlet flow path 170 is disposed at the lower part of the water diversion housing 110, the water outlet flow path 170 communicates with the water treatment module and the treated water outlet, and/or the water outlet flow path 170 communicates with the water inlet hole 121 and the normal temperature water outlet 113. The water outlet flow path 170 is formed by combining water outlet hole paths 180, the water outlet hole paths 180 are formed inside the water distribution housing 110, and water inlets of the water outlet hole paths 180 are communicated with the water inlet holes 121 and/or the water treatment modules, so that water flowing in from the water inlet holes 121 and/or the water treatment modules flows out from the treated water outlet and/or the normal temperature water outlet 113 through the water outlet hole paths 180. The water treatment module includes a heating module 200, the heating module 200 having a heating flow path 230; the treated water outlet comprises a hot water outlet 112; the water outlet hole 180 includes a hot water outlet hole 182, and the hot water outlet hole 182 communicates with the heating flow path 230 and the hot water outlet 112. The water treatment module includes a refrigeration module 300, the refrigeration module 300 having a refrigeration flow path 330; the treated water outlet comprises a cold water outlet 111; the water outlet hole 180 includes a cold water outlet hole 181, and the cold water outlet hole 181 communicates with the refrigeration flow path 330 and the cold water outlet 111.

The water outlet flow path 170 is provided independently of the presence of the heating module 200 and the cooling module 300, but the water outlet flow path 170 is necessarily provided when the heating module 200 and the cooling module 300 are present. Taking the hot water outlet flow path 170 as an example, when the water dispenser does not include the heating module 200, the outlet flow path 170 may include the hot water outlet flow path 170 to improve the adaptability of the water diversion module 100, i.e., the water diversion module 100 may be suitable for multiple water dispensers; when the water dispenser includes the heating module 200, the water outlet flow path 170 should include a hot water outlet flow path 170 to discharge hot water heated by the heating module 200 out of the water dispenser.

The outlet flow path 170 is attached to the water diversion housing 110, and is disposed on the side wall and/or the bottom of the water diversion cavity 120 in a plurality of ways, and two ways are described below by way of example.

First, the water outlet flow path 170 is directly opened in the water diversion housing 110, and the water outlet flow path 170 and the water diversion housing 110 can be structured to the maximum extent by forming a hole in the body of the water diversion housing 110 through a core pulling or drilling method. It is noted that the hole route is a flow path formed by holes, that is, water flows in the holes to reach a predetermined position.

In order to distinguish the hole paths of the other modules, the hole path corresponding to the water outlet flow path 170 is a water outlet hole path 180, and the water outlet hole path 180 includes a hot water outlet hole path 182 and a cold water outlet hole path 181 which are independent from each other, and the normal temperature water outlet hole path 183 may be a part of the water outlet hole path 180 or a part of the water diversion hole path 140. Wherein the cold water outlet path 181, the hot water outlet path 182 and the normal temperature outlet path 180 extend from the water inlet 121 in different directions. To ensure that the holes do not interfere with each other while also reserving sufficient space for the underlying heating and/or cooling holes 240, 340.

A hot water outlet path 182 extending from the heating module 200 to the hot water outlet 112 to transport hot water from the heating module 200 to the hot water outlet 112, the hot water outlet 112 being opened on an outer sidewall of the water diversion housing 110. The hot water outlet 182 includes a radial section extending in a radial direction of the water diversion housing 110 and/or an axial section extending in a height direction of the water diversion housing 110, so that the hot water outlet 182 can be extended to any desired position of the water diversion housing 110. It should be noted that the number of the radial segments and the axial segments of the hot water outlet hole 182 may be set according to actual requirements to meet the requirement of hole extension. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

The hot water outlet path 182 includes a radial section and an axial section, the axial section extends from bottom to top, the lower end of the axial section is disposed corresponding to the water outlet of the heating module 200, one end of the radial section is communicated with the axial section, and the other section is communicated with the hot water outlet 112. One end of the radial section is communicated with the hot water outlet 112, the other end extends to the edge of the water diversion housing 110 in the radial direction, one end of the axial section is communicated with one end of the radial section away from the water inlet 121, and the other end extends to the bottom of the water diversion housing 110 in the height direction of the water diversion housing 110 to be communicated with the heating flow path 230 of the hot water module.

A cold water outlet path 181 extending from the refrigeration module 300 to the cold water outlet 111 to transport water from the refrigeration module 300 to the cold water outlet 111, the cold water outlet 111 being opened on an outer sidewall of the water diversion housing 110. The cold water outlet 181 comprises a transverse section extending in a radial direction of the water diversion housing 110 and/or a vertical section extending in a height direction of the water diversion housing 110, so that the cold water outlet 181 can extend to any desired position of the water diversion housing 110. It should be noted that, the number of the horizontal sections and the vertical sections of the cold water outlet hole 181 can be set according to actual requirements, so as to meet the requirement of hole extension. There are many arrangements of the transverse sections and the vertical sections, and the following will illustrate the arrangements of the transverse sections and the vertical sections by taking an example:

One end of the horizontal section communicates with the cold water outlet 111, the other end extends to the edge of the water diversion housing 110 in the radial direction, one end of the vertical section communicates with one end of the horizontal section away from the water inlet 121, and the other end extends to the bottom of the water diversion housing 110 in the height direction of the water diversion housing 110 to communicate with the refrigeration flow path 330 of the cold water module or with the cold water passing flow path. In this embodiment, the transverse segment includes a first transverse sub-segment and a second transverse sub-segment, which are both disposed along the radial direction of the water diversion housing 110, and are communicated near one end of the middle part, however, the feature can be applied to other embodiments

In some embodiments, to further increase the space utilization, the structure of the water diversion housing 110 is made more compact, and the radial section of the hot water outlet 182 and the lateral section of the cold water outlet 181 are located on the same layer of the water diversion housing 110. Of course, in some embodiments, the ambient outlet passage 180 is also located at the same level of the water separation housing 110 as the radial section of the hot water outlet passage 182. It should be noted that one or more of the radial section of the hot water outlet 182, the lateral section of the cold water outlet 181, the normal temperature outlet 180, the radial section of the hot water inlet 141 and the lateral section of the cold water inlet 141 are located on the same layer of the water diversion housing 110. It should be noted that, the radial section of the hot water outlet hole 182, the transverse section of the cold water outlet hole 181, and the normal temperature outlet hole 180 have the same extending direction, so as to facilitate processing.

Second, the water outlet flow path 170 is formed in the water diversion housing 110, and the water outlet flow path is formed in the water diversion housing 110 by injection molding or by subsequent processing, so long as the flow path can be formed in the body of the water diversion housing 110. The water outlet flow path 170 further includes a water outlet pipe, which is disposed along the water outlet flow path and is installed in the water outlet flow path, and a water inlet of the water outlet pipe is communicated with the water inlet hole 121, so that water entering from the heating module 200 or the cooling module 300 flows out of the water dispenser along the water outlet flow path. The water outlet pipe is composed of a water pipe, and can be a hose or a hard water pipe. So that water passes through the outlet pipe to maximally regulate the relationship between the outlet pipe and the water diversion housing 110. It should be noted that the water outlet channel is a flow path formed by extending grooves, that is, the flow direction of water is consistent with the flow direction of the water outlet channel so as to reach a preset position.

In order to distinguish between the channels of other modules, the channel corresponding to the water outlet channel 170 is a water outlet channel, which includes a hot water inlet channel 152 and a cold water outlet channel that are independent of each other, and the normal temperature water outlet channel may be a part of the water outlet channel or a part of the water diversion channel 150. Wherein the cold water outlet channel, the hot water outlet channel and the normal temperature outlet channel extend from the water inlet hole 121 in different directions. To ensure that the channels do not interfere with each other while also reserving sufficient space for the underlying heating and/or cooling channels.

A hot water outlet channel extending from the heating module 200 to the hot water outlet 112 to direct the outlet channel from the heating module 200 to the hot water outlet 112. The hot water outlet channel comprises a radial section extending in the radial direction of the water diversion housing 110 and/or an axial section extending in the height direction of the water diversion housing 110, so that the hot water outlet channel can be extended to any desired position of the water diversion housing 110. It is worth noting that the number of radial segments and axial segments of the hot water outlet tank circuit can be set according to actual requirements so as to meet the requirements of tank circuit extension. There are many arrangements of the radial segments and the axial segments, and the following examples are given to illustrate the arrangements of the radial segments and the axial segments:

one end of the radial section is arranged corresponding to the hot water outlet 112, the other end extends to the edge of the water diversion housing 110 along the radial direction, one end of the axial section is communicated with one end of the radial section away from the water inlet 121, and the other end extends to the bottom of the water diversion housing 110 along the height direction of the water diversion housing 110 so as to correspond to the heating flow path 230 of the hot water module.

A cold water outlet channel extending from the refrigeration module 300 to the cold water outlet 111 to direct the outlet channel from the refrigeration module 300 to the cold water outlet 111. The cold water outlet channel comprises a transverse section extending in the radial direction of the water diversion housing 110 and/or a vertical section extending in the height direction of the water diversion housing 110, so that the cold water outlet channel can extend to any desired position of the water diversion housing 110. It is worth to say that the number of the transverse sections and the vertical sections of the cold water outlet tank circuit can be set according to actual requirements so as to meet the requirements of tank circuit extension. There are many arrangements of the transverse sections and the vertical sections, and the following will illustrate the arrangements of the transverse sections and the vertical sections by way of example:

One end of the horizontal section is arranged corresponding to the cold water outlet 111, the other end of the horizontal section extends to the edge of the water diversion shell 110 along the radial direction, one end of the vertical section is communicated with one end of the horizontal section away from the cold water outlet 111, and the other end of the vertical section extends to the bottom of the water diversion shell 110 along the height direction of the water diversion shell 110 so as to be arranged corresponding to a refrigeration flow path 330 of the cold water module or a cold water passing flow path. In this embodiment, the transverse segment includes a first transverse sub-segment and a second transverse sub-segment, which are both disposed along the radial direction of the water diversion housing 110, and are communicated near one end of the middle portion, and of course, this feature can be applied to other embodiments.

In some embodiments, to further increase the space utilization, the structure of the water diversion housing 110 is made more compact, with the radial section of the hot water outlet tank and the lateral section of the cold water outlet tank being located at the same level of the water diversion housing 110. Of course, in some embodiments, the normal temperature water outlet tank is also located at the same level of the water diversion housing 110 as the radial section of the hot water outlet tank.

In this embodiment, the water diversion flow path 130 is disposed on the side wall and/or the bottom wall of the water diversion cavity 120, so that the positional relationship and the connection relationship between the pipeline structures on the water diversion module 100 are very clear, and there is no intersection between the hot water inlet flow path and the cold water inlet flow path of the water diversion flow path 130, so that the mutual influence between the pipelines is avoided, thus effectively improving the use stability of the water diversion module 100 and effectively improving the use stability of the water dispenser; by arranging the water diversion flow path 130 on the housing, the structure of the water diversion module 100 is more compact, and the stability of the water diversion module 100 is improved;

Because the water outlet flow path 170 is arranged on the side wall and/or the bottom wall of the water distribution cavity 120, the position relationship and the connection relationship between the pipeline structures on the water distribution module 100 are very clear, so that the hot water outlet flow path 170 and the cold water outlet flow path 170 of the water outlet flow path 170 are not crossed, the mutual influence among the pipelines is avoided, the use stability of the water distribution module 100 is effectively improved, and the use stability of the water dispenser is effectively improved; by disposing the water outlet flow path 170 on the housing, the structure of the water diversion module 100 is more compact, so that the stability of the water diversion module 100 is improved;

by arranging the water diversion module 100 independently, the water diversion module 100 can be adapted to various water treatment modules, such as a heating module 200, a refrigerating module 300 and the like, so that the flexibility of using the water diversion module 100 is greatly improved; meanwhile, a user can assemble the water dispenser according to own requirements, so that the actual requirements for the water dispenser are met more busy.

The heating module 200, the heating module 200 includes a heating housing 210, the heating housing 210 has a heating cavity 220, and a heating device 260 is disposed in the heating cavity 220. The shape of the heating housing 210 may be a variety of, for example, a column shape, and the cross-sectional shape thereof may be a triangle, a polygon, a circle, an ellipse, etc., and is not particularly limited herein, for example, a circle is provided, and of course, the circle may have a concave or convex shape due to practical requirements. The heating means 260 may take many forms, such as a hot tank or the like.

The heating module 200 has a heating flow path 230, and the heating flow path 230 is provided on the heating housing 210, or on a side wall and/or a bottom wall of the heating chamber 220. The heating module 200 is exemplified as being disposed under the water diversion module 100, and by disposing the heating flow path 230 under the water diversion flow path 130, the water level in the heating flow path 230 is lower than the water level in the water diversion flow path 130, so that the water in the heating flow path 230 can flow under the action of the water potential difference to increase the fluidity of the water. The heating flow path 230 includes a heating water inlet flow path for feeding water in the hot water inlet flow path to the heating device 260, and a hot water outlet flow path 170 for guiding hot water of the heating device 260 out of the heating module 200 may be implemented by communicating with the hot water outlet flow path 170. The water inlets of the heating water inlet flow path and the heating water outlet flow path 170 are communicated with the water diversion flow path 130.

The heating module 200 includes: a heating housing 210, the heating housing 210 having a heating cavity 220 for mounting a heating device 260; a heating flow path 230 is provided on a side wall or a bottom wall of the heating chamber 220; the heating flow path 230 communicates with a water source and a water inlet of the heating device 260, and/or communicates with a water outlet of the heating device 260 and a hot water outlet 112 of the water dispenser. The heating flow path 230 is formed by combining heating hole paths 240, and the heating hole paths 240 are formed in a side wall or a bottom wall of the heating housing 210; the water inlet of the heating orifice 240 communicates with a water source to allow water to flow into the heating device 260 along the water inlet portion of the heating orifice 240 and/or to flow to the hot water outlet 112 along the water outlet portion of the heating orifice 240. The heating hole 240 includes a heating water inlet 121; the heating water inlet 121 may include a radial section extending in a radial direction of the heating housing 210 and/or an axial section extending in a height direction of the heating housing 210. The axial section is disposed in the sidewall of the heating housing 210, and one end of the axial section is communicated with a water source, and the other end of the axial section is communicated with one end of the radial section; the radial segment is disposed at the bottom of the heating housing 210, and the other end of the radial segment extends to the bottom of the heating cavity 220 to be communicated with the water inlet of the heating device 260.

There are many ways in which the heating flow path 230 is disposed on the heating housing 210, or disposed on the side wall and/or the bottom of the heating chamber 220, and two ways are described below by way of example.

First, the heating flow path 230 is directly opened in the heating housing 210, and the heating flow path 230 and the heating housing 210 can be structured by a core pulling method, a drilling method, or the like, so long as the hole path can be formed in the body of the heating housing 210, and water can pass through the hole path, thereby maximally structuring the relationship between the heating flow path 230 and the heating housing 210. It should be noted that the hole path is a flow path formed by holes, that is, water flows in the holes to reach a predetermined position.

In order to distinguish the hole paths of the other modules, the hole path corresponding to the heating flow path 230 is a heating hole path 240, and the heating hole path 240 includes a heating water inlet hole 121 path and a heating water outlet hole path 242 which are independent from each other.

The heating water inlet 121 extends from the water diversion flow path 130 (specifically, the hot water inlet 142) to the heating module 200 to transport water from the water diversion flow path 130 to the heating module 200. The heating water inlet 121 path includes a radial section extending in a radial direction of the heating housing 210 and/or an axial section extending in a height direction of the heating housing 210, so that the heating water inlet 121 path may extend to any desired position of the heating housing 210. It should be noted that the number of the radial segments and the axial segments of the path of the heating water inlet 121 may be set according to actual requirements, so as to meet the requirement of extending the path. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

The water inlet of the heating device 260 is disposed at the bottom of the heating chamber 220, one end of the radial segment is communicated with the water inlet of the heating device 260, the other end extends to the edge of the heating housing 210 in the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water inlet 121, and the other end extends to the top of the heating housing 210 in the height direction of the heating housing 210 to communicate with the water diversion flow path 130 of the water diversion module 100.

The water outlet path 242 is heated to extend from the heating module 200 to a position corresponding to the water outlet path 170 to transport the hot water from the water inlet heating device 260 to the water outlet path 170. The heating water outlet path 242 includes a lateral section extending in a radial direction of the heating housing 210 and/or a vertical section extending in a height direction of the heating housing 210, so that the heating water outlet path 242 may extend to any desired position of the heating housing 210. It should be noted that the number of the radial segments and the axial segments of the heating water outlet path 242 may be set according to actual requirements, so as to meet the requirement of path extension. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

The water outlet of the heating device 260 is disposed at the bottom or on the side wall of the heating chamber 220, one end of the radial segment is communicated with the water outlet of the heating device 260, the other end extends to the edge of the heating housing 210 along the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water outlet, and the other end extends to the top of the heating housing 210 along the height direction of the heating housing 210 so as to be communicated with the water outlet flow path 170.

In some embodiments, to further improve the space utilization, the structure of the heating housing 210 is made more compact, and the radial section of the heating water inlet 121 and the radial section of the heating water outlet 242 are located on the same layer of the heating housing 210.

It should be noted that, the heating housing 210 has a heating cavity 220, the top of the heating cavity 220 is provided with an opening, the heating device 260 is disposed in the heating cavity 220, and the water inlet and/or the water outlet of the heating device 260 is disposed at the top of the heating device 260; the heating flow path 230 includes a hot water inlet pipe communicating with the water inlet of the heating device 260 and the water diversion flow path 130, and/or a hot water outlet pipe 270 communicating with the water outlet of the heating device 260 and the water outlet flow path 170. That is, when the water inlet 121 or the water outlet of the heating device 260 is provided at the top of the heating device 260, the water diversion flow path 130 and the water outlet flow path 170 are directly connected by the hot water inlet pipe or the hot water outlet pipe 270.

Second, the heating flow path 230 is opened in the heating housing 210, and the heating channel is formed in the heating housing 210, and the forming method may be injection molding or subsequent processing, so long as the channel can be formed in the body of the heating housing 210. The heating flow path 230 further includes a heating pipe, which is disposed along the heating tank and installed in the heating tank, and the heating pipe is composed of a water pipe, which may be a hose or a hard water pipe. So that water passes through the water diversion pipe to maximize the relationship between the heating pipe and the heating housing 210. It should be noted that the heating channel is a flow path formed by extending grooves, that is, the flowing direction of water is consistent with the extending direction of the heating channel so as to reach a preset position.

In order to distinguish between the channels of other modules, the channels corresponding to the heating flow path 230 are heating channels, which include the hot water inlet channel 152 and the heating outlet channel, which are independent of each other. Wherein the heating water outlet channel and the heating water inlet channel extend from the heating device 260 in different directions.

The water inlet channels are heated and extend from the water diversion flow path 130 (specifically, the hot water inlet channel 142 or channel) to the heating module 200 to transport water from the water diversion flow path 130 to the heating module 200. The heating water inlet channel comprises a radial section extending in a radial direction of said heating housing 210 and/or an axial section extending in a height direction of said heating housing 210, such that the heating water inlet channel can extend to any desired position of the heating housing 210. It is worth noting that the number of radial and axial sections of the heating inlet channel can be set according to actual requirements to meet the requirements of channel extension. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

The water inlet of the heating device 260 is disposed at the bottom of the heating chamber 220, one end of the radial segment is communicated with the water inlet of the heating device 260, the other end extends to the edge of the heating housing 210 in the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water inlet 121, and the other end extends to the top of the heating housing 210 in the height direction of the heating housing 210 to communicate with the water diversion flow path 130 of the water diversion module 100.

The water outlet channel is heated and extends from the heating module 200 to a position corresponding to the water outlet flow path 170 to transport hot water from the water inlet heating device 260 to the water outlet flow path 170. The heating water outlet channel comprises a transverse section extending in a radial direction of the heating housing 210 and/or a vertical section extending in a height direction of the heating housing 210, so that the heating water outlet channel can extend to any desired position of the heating housing 210. It is worth noting that the number of the transverse sections and the vertical sections of the heating water outlet tank circuit can be set according to actual requirements so as to meet the requirements of tank circuit extension. There are many ways to arrange the transverse segments and the vertical segments, and the following will illustrate the arrangement of the transverse segments and the vertical segments by taking an example:

the water outlet of the heating device 260 is disposed at the bottom or on the side wall of the heating chamber 220, one end of the radial segment is communicated with the water outlet of the heating device 260, the other end extends to the edge of the heating housing 210 along the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water outlet, and the other end extends to the top of the heating housing 210 along the height direction of the heating housing 210 so as to be communicated with the water outlet flow path 170.

In some embodiments, to further increase space utilization, the heating housing 210 is made more compact, with the radial sections of the heating inlet and outlet channels being located in the same layer of the heating housing 210.

When the water dispenser comprises the water diversion module 100, the heating module 200 and the refrigerating module 300, and the water diversion module 100, the heating module 200 and the refrigerating module 300 are sequentially arranged from top to bottom, a cold water passing flow path is arranged on the heating module 200; when the water diversion module 100, the refrigeration module 300 and the heating module 200 are sequentially arranged from top to bottom, the refrigeration module 300 is provided with a hot water passing flow path. Next, the heating module 200 is provided with a cold water flow path as an example.

The heating module 200 has a cold water flow path provided on the heating housing 210 or on a side wall and/or a bottom wall of the heating chamber 220. The cold water flow path is used for transporting normal-temperature water in the water diversion module 100 to the refrigeration module 300 and then transporting cold water in the refrigeration module 300 to the module with the cold water outlet 111. The heating module 200 is exemplified as being disposed below the water diversion module 100, and by disposing the cold water passing flow path below the water diversion flow path 130, the water level in the cold water passing flow path is lower than the water level in the water diversion flow path 130, so that the water in the cold water passing flow path can flow under the action of the water potential difference to increase the fluidity of the water. The cold water passing flow path includes a cold water inlet flow path that delivers water in the cold water inlet flow path into the refrigeration flow path 330 of the refrigeration module 300, and a cold water outlet flow path that directs cold water in the refrigeration flow path 330 into the water outlet flow path 170.

There are many ways in which the cold water flow path is provided on the heating housing 210 in a fitting manner, or provided on the side wall and/or the bottom of the heating chamber 220, and two ways are described below by way of example.

First, the cold water flow path is directly opened in the heating housing 210, and the cold water flow path and the heating housing 210 can be regulated to the maximum extent by forming a hole path on the body of the heating housing 210 through core pulling, drilling and the like. It should be noted that the hole path is a flow path formed by holes, that is, water flows in the holes to reach a predetermined position.

The cold water passing flow path is formed by combining cold water passing flow paths, and the cold water passing flow paths are formed in the side wall and/or the bottom wall of the heating shell 210; the water inlet of the cold water passing hole communicates with a water source to allow water to flow into the refrigeration module 300 through the water inlet portion of the cold water passing hole and/or to the cold water outlet 111 through the water outlet portion of the cold water passing hole.

In order to distinguish the hole paths of other modules, the hole paths corresponding to the cold water flow paths are cold water flow hole paths, and the cold water flow hole paths comprise a cold water inlet flow hole path 251 and a cold water outlet flow hole path 252 which are independent.

Into the cold water tap 251, extends from the tap 130 (in particular, may be the cold water tap 141) to the refrigeration module 300 to transport water from the tap 130 to the refrigeration module 300. The inlet water passage 251 includes a radial section extending in a radial direction of the heating housing 210 and/or an axial section extending in a height direction of the heating housing 210, so that the inlet water passage 251 can extend to any desired position of the heating housing 210. It should be noted that, the number of the radial segments and the axial segments of the inlet water flow channel 251 can be set according to actual requirements, so as to meet the requirement of channel extension. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

one end of the radial segment is communicated with the water inlet of the refrigeration module 300, the other end extends to the edge of the heating housing 210 in the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water inlet 121, and the other end extends to the top of the heating housing 210 in the height direction of the heating housing 210 to be communicated with the water diversion flow path 130 of the water diversion module 100.

The outlet cold water flow path 252 extends from a position corresponding to the outlet of the refrigeration module 300 to a position corresponding to the outlet water flow path 170 to transport cold water from the refrigeration module 300 to the outlet water flow path 170.

The outlet water passage 252 includes a transverse section extending in a radial direction of the heating housing 210 and/or a vertical section extending in a height direction of the heating housing 210, such that the outlet water passage 252 may extend to any desired location of the heating housing 210. It should be noted that the number of the radial segments and the axial segments of the outlet water passage 252 can be set according to actual requirements to meet the requirement of the passage extension. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

the water outlet (refrigerating water outlet 322) of the refrigerating device 370 is provided at the bottom or side wall of the refrigerating chamber 320, one end of the radial section is communicated with the water outlet of the refrigerating module 300, the other end extends to the edge of the heating housing 210 in the radial direction, one end of the axial section is communicated with one end of the radial section away from the water outlet, and the other end extends to the top of the heating housing 210 in the height direction of the heating housing 210 to communicate with the water outlet flow path 170.

In some embodiments, to further increase the space utilization, the heating housing 210 is made more compact, and the radial section of the inlet water flow path 251 and the radial section of the outlet water flow path 252 are located on the same layer of the heating housing 210.

It should be noted that, the refrigeration housing 310 has a refrigeration cavity 320, the top of the refrigeration cavity 320 is open, the refrigeration device 370 is disposed in the refrigeration cavity 320, and the water inlet (refrigeration water inlet 321) and/or the water outlet (refrigeration water outlet 322) of the refrigeration device 370 are disposed at the top of the refrigeration device 370; at this time, the inlet water channel 251 and the outlet water channel 252 are extended to the bottom of the heating housing 210, and correspond to the upper side of the refrigerating chamber 320, so as to directly correspond to the water inlet and the water outlet of the refrigerating device 370.

Second, the cold water flow path is opened in the heating housing 210, and the water flow path is formed in the heating housing 210, and the forming manner may be injection molding or subsequent processing, so long as the path can be formed in the body of the heating housing 210. The cold water flow path also comprises a cold water flow pipeline which is arranged along the water flow channel and is arranged in the water flow channel, and the cold water flow pipeline consists of a water pipe, and can be a hose or a hard water pipe. Such that water passes through the water diversion pipe to maximize the relationship between the chilled water passing line and the heating housing 210. It should be noted that the water channel is a flow path formed by extending grooves, that is, the flowing direction of water is consistent with the extending direction of the water channel so as to reach a preset position.

In order to distinguish the tank circuits of other modules, the tank circuit corresponding to the cold water flow path is a water flow tank circuit, and the water flow tank circuit comprises a cold water inlet tank circuit and a cold water outlet tank circuit which are mutually independent. The cold water passing water flow path includes: the cold water passing channel is arranged on the shell; the cold water passing pipeline is arranged along the cold water passing channel and is arranged in the cold water passing channel, and a water inlet of the cold water passing pipeline is communicated with a water source so that water flows into the refrigeration module 300 through a water inlet part of the cold water passing pipeline and/or flows to the cold water outlet 111 through a water outlet part of the cold water passing pipeline. The cold water passing channel comprises a cold water inlet channel and/or a cold water outlet channel; the inlet water channel includes a radial section extending in a radial direction of the heating housing 210, and an axial section extending in a height direction of the heating housing 210; the axial section is disposed on a side wall of the heating housing 210, and one end of the axial section is communicated with one end of the radial section; the radial section is disposed at the bottom of the heating housing 210, and the other end of the radial section extends above the cooling cavity 320 of the cooling module 300, so as to be disposed corresponding to the water inlet of the cooling module 300; and/or the outlet water channel comprises a transverse section extending along the radial direction of the heating housing 210, and a vertical section extending along the height direction of the heating housing 210; the vertical section is disposed on a side wall of the heating housing 210, and one end of the vertical section is communicated with one end of the horizontal section; the transverse section is disposed at the bottom of the heating housing 210, and the other end of the transverse section extends above the cooling cavity 320 of the cooling module 300, so as to be disposed corresponding to the water outlet of the cooling module 300.

Into the cold water flowpath, extending from the water diversion flowpath 130 (specifically the cold water inlet flowpath 141 or tank) to the refrigeration module 300 to transport water from the water diversion flowpath 130 to the refrigeration module 300. The inlet water passage includes a radial section extending in a radial direction of the heating housing 210 and/or an axial section extending in a height direction of the heating housing 210, so that the inlet water passage may extend to any desired location of the heating housing 210. It is worth noting that the number of radial segments and axial segments of the incoming cold water flow channel can be set according to actual requirements to meet the requirements of channel extension. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

one end of the radial segment is disposed corresponding to the water inlet of the refrigeration module 300, the other end extends to the edge of the heating housing 210 in the radial direction, one end of the axial segment communicates with one end of the radial segment away from the water inlet 121, and the other end extends to the top of the heating housing 210 in the height direction of the heating housing 210 to be disposed corresponding to the water diversion flow path 130 of the water diversion module 100.

And a cold water discharge water channel extending from a position corresponding to a water outlet of the refrigeration module 300 to a position corresponding to the water discharge flow path 170 to transport cold water from the refrigeration module 300 to the water discharge flow path 170.

The outlet cold water channel comprises a transverse section extending in a radial direction of the heating housing 210 and/or a vertical section extending in a height direction of the heating housing 210, so that the outlet cold water channel can extend to any desired position of the heating housing 210. It is worth noting that the number of the transverse sections and the vertical sections of the cold water outlet water channel can be set according to actual requirements so as to meet the requirements of channel extension. There are many arrangements of the transverse sections and the vertical sections, and the following will illustrate the arrangements of the transverse sections and the vertical sections by way of example:

the water outlet of the refrigerating device 370 is disposed at the bottom or on the sidewall of the refrigerating chamber 320, one end of the radial segment is communicated with the water outlet of the refrigerating module 300, the other end extends to the edge of the heating housing 210 in the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water outlet, and the other end extends to the top of the heating housing 210 in the height direction of the heating housing 210 to communicate with the water outlet flow path 170.

In some embodiments, to further increase space utilization, the heating housing 210 is made more compact, with the radial sections of the incoming and outgoing cold water channels being located in the same layer of the heating housing 210.

The refrigeration module 300, the refrigeration module 300 includes a refrigeration housing 310, the refrigeration housing 310 has a refrigeration cavity 320, and a refrigeration device 370 is disposed in the refrigeration cavity 320. The shape of the refrigeration housing 310 may be a variety of, for example, a column, and the cross-sectional shape thereof may be a triangle, a polygon, a circle, an ellipse, etc., which is not particularly limited herein, and for example, a circle is provided, and of course, the circle may have a concave or convex shape due to practical requirements. The form of the refrigeration device 370 may be numerous, such as an electronic curling, etc.

The refrigeration module 300 has a refrigeration flow path 330, the refrigeration flow path 330 being provided on the refrigeration housing 310 or on a side wall and/or a bottom wall of the refrigeration cavity 320. The refrigeration module 300 is exemplified as being disposed under the diversion module 100 or the refrigeration module 300, and by disposing the refrigeration flow path 330 under the diversion flow path 130, the water level in the refrigeration flow path 330 is lower than the water level in the diversion flow path 130, so that the water in the refrigeration flow path 330 can flow under the action of the water potential difference to increase the fluidity of the water. The cooling flow path 330 includes a cooling water inlet flow path for feeding water in the hot water inlet flow path to the cooling device 370, and can be implemented by communicating with the hot water outlet flow path 170 by guiding hot water of the cooling device 370 out of the hot water outlet flow path 170 of the cooling module 300. The water inlets of the refrigeration water inlet flow path and the refrigeration water outlet flow path 170 are communicated with the water diversion flow path 130.

There are many ways in which the refrigeration path 330 may be disposed in a conforming manner on the refrigeration housing 310, or on the side wall and/or bottom of the refrigeration cavity 320, two of which are described below by way of example.

First, the refrigerating flow path 330 is directly opened in the refrigerating housing 310, and the relationship between the refrigerating flow path 330 and the refrigerating housing 310 can be maximized by forming a hole in the body of the refrigerating housing 310 through core pulling, drilling, or the like. It should be noted that the hole path is a flow path formed by holes, that is, water flows in the holes to reach a predetermined position.

In order to distinguish the paths of the other modules, the paths corresponding to the cooling flow path 330 are cooling paths 340, and the cooling paths 340 include a cooling water inlet path 341 and a cooling water outlet path 342, which are independent of each other.

The cooling water inlet path 341 extends from the water diversion path 130 (specifically, the hot water inlet path 142) or the heating path 230 to the cooling module 300 to transport water from the water diversion path 130 to the cooling module 300. The refrigeration intake path 341 includes a radial section extending in a radial direction of the refrigeration housing 310 and/or an axial section extending in a height direction of the refrigeration housing 310, so that the refrigeration intake path 341 may extend to any desired position of the refrigeration housing 310. It should be noted that, the number of the radial segments and the axial segments of the refrigeration water inlet hole 341 may be set according to actual requirements, so as to meet the requirement of hole extension. There are many arrangements of the radial segments and the axial segments, and the following will illustrate the arrangements of the radial segments and the axial segments by way of example:

The water inlet of the refrigerating device 370 is disposed at the bottom of the refrigerating chamber 320, one end of the radial segment is communicated with the water inlet of the refrigerating device 370, the other end extends to the edge of the refrigerating housing 310 in the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water inlet 121, and the other end extends to the top of the refrigerating housing 310 in the height direction of the refrigerating housing 310 to communicate with the water diversion flow path 130 of the water diversion module 100.

The cooling water outlet hole 342 extends from the cooling module 300 to a position corresponding to the water outlet flow path 170 to transport hot water from the cooling device 370 to the water outlet flow path 170. The refrigeration water outlet 342 includes a transverse section extending in a radial direction of the refrigeration housing 310 and/or a vertical section extending in a height direction of the refrigeration housing 310, such that the refrigeration water outlet 342 can extend to any desired location of the refrigeration housing 310. It should be noted that the number of the radial segments and the axial segments of the cooling water outlet path 342 can be set according to actual requirements to meet the requirement of path extension. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

The water outlet of the refrigerating device 370 is disposed at the bottom or on the side wall of the refrigerating chamber 320, one end of the radial segment is communicated with the water outlet of the refrigerating device 370, the other end extends to the edge of the refrigerating housing 310 in the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water outlet, and the other end extends to the top of the refrigerating housing 310 in the height direction of the refrigerating housing 310 to communicate with the water outlet flow path 170.

In some embodiments, to further increase the space utilization, the structure of the refrigeration housing 310 is made more compact, and the radial section of the refrigeration water inlet hole 341 and the radial section of the refrigeration water outlet hole 342 are located on the same layer of the refrigeration housing 310.

It should be noted that, the refrigeration housing 310 has a refrigeration cavity 320, the top of the refrigeration cavity 320 is provided with an opening, the refrigeration device 370 is disposed in the refrigeration cavity 320, and the water inlet and/or the water outlet of the refrigeration device 370 is disposed at the top of the refrigeration device 370; the refrigeration flow path 330 includes a cold water inlet pipe 285 communicating with the water inlet of the refrigeration device 370 and the water diversion flow path 130, and/or a cold water outlet pipe 290 communicating with the water outlet of the refrigeration device 370 and the water outlet flow path 170. That is, when the water inlet 121 or the water outlet of the refrigerating device 370 is disposed at the top of the refrigerating device 370, only the cold water inlet pipe 285 or the cold water outlet pipe 290 is needed to directly communicate the refrigerating device 370 with the water diversion flow path 130 or directly communicate the refrigerating device 370 with the water outlet flow path 170.

Second, the cooling flow path 330 is opened in the cooling case 310, and a cooling channel is formed in the cooling case 310, and the forming method may be injection molding or subsequent processing, so long as the channel can be formed in the body of the cooling case 310. The refrigeration flow path 330 further includes a refrigeration pipeline, which is disposed along the refrigeration tank and is installed in the refrigeration tank, and the refrigeration pipeline is composed of a water pipe, which may be a hose or a hard water pipe. Such that water passes through the shunt tubes to maximize the relationship between the refrigerant lines and the refrigerant shell 310. It should be noted that the refrigerating tank circuit is a flow path formed by extending grooves, that is, the flowing direction of water is consistent with the extending direction of the refrigerating tank circuit so as to reach a preset position.

In order to distinguish between the channels of other modules, the channel corresponding to the refrigeration flow path 330 is a refrigeration channel, which includes a hot water inlet channel 152 and a refrigeration outlet channel that are independent of each other. Wherein the refrigerated water outlet and inlet channels extend in different directions from the refrigeration unit 370.

A refrigeration intake channel extends from the water diversion flow path 130 (specifically, the hot water intake channel 142 or channel) to the refrigeration module 300 to transport water from the water diversion flow path 130 to the refrigeration module 300. The refrigeration water inlet channel comprises a radial section extending along the radial direction of the refrigeration shell 310 and/or an axial section extending along the height direction of the refrigeration shell 310, so that the refrigeration water inlet channel can be extended to any position required by the refrigeration shell 310. It is worth noting that the number of radial segments and axial segments of the refrigeration water inlet channel can be set according to actual requirements to meet the requirements of channel extension. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

The water inlet of the refrigerating device 370 is disposed at the bottom of the refrigerating chamber 320, one end of the radial segment is communicated with the water inlet of the refrigerating device 370, the other end extends to the edge of the refrigerating housing 310 in the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water inlet 121, and the other end extends to the top of the refrigerating housing 310 in the height direction of the refrigerating housing 310 to communicate with the water diversion flow path 130 of the water diversion module 100.

A refrigerated water outlet channel extends from the refrigeration module 300 to a location corresponding to the water outlet flow path 170 to transport hot water from the water chiller 370 to the water outlet flow path 170. The refrigeration outlet channel comprises a transverse section extending in a radial direction of said refrigeration housing 310 and/or a vertical section extending in a height direction of said refrigeration housing 310, such that the refrigeration outlet channel can extend to any desired location of the refrigeration housing 310. It is worth noting that the number of the transverse sections and the vertical sections of the refrigeration water outlet tank circuit can be set according to actual requirements so as to meet the requirements of tank circuit extension. There are many ways to arrange the transverse segments and the vertical segments, and the following will illustrate the arrangement of the transverse segments and the vertical segments by taking an example:

the water outlet of the refrigerating device 370 is disposed at the bottom or on the side wall of the refrigerating chamber 320, one end of the radial segment is communicated with the water outlet of the refrigerating device 370, the other end extends to the edge of the refrigerating housing 310 in the radial direction, one end of the axial segment is communicated with one end of the radial segment away from the water outlet, and the other end extends to the top of the refrigerating housing 310 in the height direction of the refrigerating housing 310 to communicate with the water outlet flow path 170.

In some embodiments, to further increase the space utilization, the refrigeration housing 310 is made more compact, with the radial section of the refrigeration inlet channel and the radial section of the refrigeration outlet channel being located on the same layer of the refrigeration housing 310.

The water dispenser further includes a drain flow path that may be provided on the water diversion module 100, the heating module 200, or the cooling module 300, and will be described below by taking the case of being provided on the cooling module 300 as an example.

The refrigeration module 300 has a blowdown flow path disposed on the refrigeration housing 310 or on a side wall and/or bottom wall of the refrigeration cavity 320. The refrigeration module 300 is exemplified as being disposed under the water diversion module 100 or the heating module, and by disposing the drain flow path under the water diversion flow path 130, the water level in the drain flow path is lower than the water level in the water diversion flow path 130, so that the water in the drain flow path can flow under the action of the water potential difference to increase the fluidity of the water. The drain flow paths include a hot water drain flow path that discharges water in the heating flow path 230, and a cold water drain flow path that discharges water in the cooling flow path 330.

There are many ways in which the blowdown flow path may be snugly disposed on the refrigeration housing 310, or on the side walls and/or bottom of the refrigeration cavity 320, two of which are described below by way of example.

First, the drain flow path is directly opened in the refrigeration shell 310, and the drain flow path and the refrigeration shell 310 can be structured to be the most regular by forming a hole path on the refrigeration shell 310 by means of core pulling, drilling and the like, so that water passes through the hole path. It should be noted that the hole path is a flow path formed by holes, that is, water flows in the holes to reach a predetermined position.

In order to distinguish the hole paths of the other modules, the hole path corresponding to the drain flow path is a drain hole path 360, and the drain hole path 360 includes a hot water drain hole path 361 and a cold water drain hole path 362 which are independent of each other.

A hot water drain hole 361 extends from the heating flow path 230 (which may be specifically the heating water inlet 121) to the hot water drain 312 to drain the sewage from the heating module 200. Wherein the heating device drain 280 communicates with the hot water drain hole 361.

The hot water drain hole 361 includes a radial section extending in a radial direction of the refrigeration housing 310 and/or an axial section extending in a height direction of the refrigeration housing 310, so that the hot water drain hole 361 can be extended to any desired position of the refrigeration housing 310. It should be noted that, the number of the radial segments and the axial segments of the hot water drain hole 361 can be set according to actual requirements, so as to meet the requirement of hole extension. There are many arrangements of the radial segments and the axial segments, and the following illustrates an arrangement of the radial segments and the axial segments by way of example:

The axial section is disposed in the side wall of the refrigeration shell 310, one end of the axial section is communicated with the drain outlet of the heating device 260, and the other end of the axial section is communicated with one end of the radial section; the radial section is disposed at the bottom of the refrigeration shell 310, the other end of the radial section extends to the hot water drain 312, and the hot water drain 312 is disposed on the outer surface of the refrigeration shell 310.

A cold water drain hole path 362 extending from the refrigeration module 300 to the cold water drain 311 to drain the sewage in the cold tank from the refrigeration module 300. Wherein the refrigeration unit drain 371 communicates with the cold water drain hole 362.

The cold water drain hole 362 includes a lateral section extending in a radial direction of the refrigeration housing 310 and/or a vertical section extending in a height direction of the refrigeration housing 310, such that the cold water drain hole 362 can extend to any desired location of the refrigeration housing 310. It should be noted that the number of the horizontal sections and the vertical sections of the cold water drain hole 362 may be set according to actual requirements, so as to meet the requirement of hole extension. There are many arrangements of the transverse sections and the vertical sections, and the following will illustrate the arrangements of the transverse sections and the vertical sections by way of example:

One end of the vertical section is communicated with a sewage outlet of the refrigerating device 370, and the other end of the vertical section is communicated with one end of the horizontal section; the transverse section is arranged at the bottom of the refrigeration shell 310, the other end of the transverse section extends to a cold water drain outlet 311, and the cold water drain outlet 311 is arranged on the outer surface of the refrigeration shell 310.

In some embodiments, to further increase the space utilization, the refrigeration housing 310 is made more compact, with the radial section of the hot water drain hole 361 and the lateral section of the cold water drain hole 362 being located on the same layer of the refrigeration housing 310.

Second, the drain flow path is opened in the refrigeration case 310, and the drain channel is formed in the refrigeration case 310, and the forming manner may be injection molding, or the subsequent processing may be opened, so long as the channel can be formed in the body of the refrigeration case 310. The sewage disposal flow path also comprises a sewage disposal pipeline which is arranged along the sewage disposal groove path and is arranged in the sewage disposal groove path, and the sewage disposal pipeline consists of a water pipe, and can be a hose or a hard water pipe. Such that water passes through the water distribution pipe to maximize the relationship between the blowdown line and the refrigeration shell 310. It should be noted that the drain tank is a flow path formed by extending the grooves, that is, the flowing direction of water is consistent with the extending direction of the drain tank so as to reach a preset position.

The sewage draining tank circuit comprises a hot water sewage draining tank circuit and a cold water sewage draining tank circuit. Wherein, the extending direction of the hot water drain groove is consistent with the extending direction of the hot water drain hole 361. The hot water drain tank circuit differs from the hot water drain hole circuit 361 in that the hot water drain tank circuit is used for carrying a drain pipe, and the hot water drain hole circuit 361 is used for directly transporting water. Similarly, the direction of extension of the cold water drain tank is the same as the direction of extension of the cold water drain hole 362. The cold water drain channel differs from the cold water drain hole 362 in that the cold water drain channel is used to carry a drain pipe, and the cold water drain hole 362 is used to transport water directly.

Several common water dispenser splice states are described below, including a water diversion module 100 and a heating module 200.

According to the above embodiment, the water diversion channel 130, the heating channel 230 and the water outlet channel 170 may be formed with holes, or may be formed by a combination of a tank and a water pipe, and since the extending direction and the positional relationship of the tank are equivalent to those of the holes, the connection relationship between the water diversion channel 130, the heating channel 230 and the water outlet channel 170 when the water dispenser includes the water diversion module 100 and the heating module 200 will be described by taking the holes as an example.

The water diversion hole 140 includes a hot water inlet hole 142 and a cold water inlet hole 141, the water outlet hole 180 includes a hot water outlet hole 182, a cold water outlet hole 181, and a normal temperature water outlet hole 183, and the heating hole 240 includes a heating water inlet hole 121 and a heating water outlet hole 242.

The hot water enters the hot water inlet hole path 142 from the water inlet hole 121, enters the heating water inlet hole 121 path after passing through the hot water inlet hole path 142, and enters the heating device 260 after passing through the heating water inlet hole 121 path; after being heated by the heating device 260, the hot water flows out of the heating housing 210 from the heating water outlet path 242, enters the hot water outlet path 182, and then flows out from the hot water outlet 112;

the normal temperature water enters the normal temperature water outlet hole path 183 from the water inlet hole 121, and flows out from the normal temperature water outlet 113 after passing through the normal temperature water outlet hole path 183.

Of course, in some embodiments, when the water inlet (heating water inlet 221) and/or the water outlet (heating water outlet 222) of the heating device 260 are disposed at the top of the heating device 260, the heating water inlet 121 and/or the heating water outlet 242 may be replaced by a heating water inlet pipe and/or a heating water outlet pipe, i.e. the heating water inlet pipe communicates with the water inlet of the heating device 260 and the hot water inlet 142, and the heating water outlet pipe communicates with the water outlet of the heating device 260 and the hot water outlet 182.

The water dispenser includes a water diversion module 100 and a refrigeration module 300.

According to the above embodiment, the water diversion channel 130, the refrigeration channel 330 and the water outlet channel 170 may be formed with holes, or may be formed by a combination of a tank and a water pipe, and since the extending direction and the position of the tank are equivalent to those of the holes, the connection relationship between the water diversion channel 130, the refrigeration channel 330 and the water outlet channel 170 when the water dispenser includes the water diversion module 100 and the refrigeration module 300 will be described by taking the holes as an example.

The water diversion hole 140 includes a hot water inlet hole 142 and a cold water inlet hole 141, the water outlet hole 180 includes a hot water outlet hole 182, a cold water outlet hole 181, and a normal temperature water outlet hole 183, and the refrigerating hole 340 includes a refrigerating water inlet hole 341 and a refrigerating water outlet hole 342.

The cold water enters the cold water inlet hole path 141 from the water inlet hole 121, enters the refrigerating water inlet hole path 341 after passing through the cold water inlet hole path 141, and enters the refrigerating device 370 after passing through the refrigerating water inlet hole path 341; after being refrigerated by the refrigeration device 370, the cold water flows out of the refrigeration shell 310 from the refrigeration water outlet hole 342, enters the cold water outlet hole 181, and then flows out of the cold water outlet 111;

the normal temperature water enters the normal temperature water outlet hole path 183 from the water inlet hole 121, and flows out from the normal temperature water outlet 113 after passing through the normal temperature water outlet hole path 183.

Of course, in some embodiments, when the water inlet and/or the water outlet of the refrigeration device 370 is disposed at the top of the refrigeration device 370, the refrigeration water inlet hole 121 and/or the refrigeration water outlet hole 180 may be replaced by a refrigeration water inlet pipe and/or a refrigeration water outlet pipe, i.e. the refrigeration water inlet pipe communicates with the water inlet of the refrigeration device 370 and the hot water inlet hole 121, and the refrigeration water outlet pipe communicates with the water outlet of the refrigeration device 370 and the hot water outlet hole 180.

The water dispenser includes a water diversion module 100, a heating module 200, and a cooling module 300.

According to the above embodiment, the water diversion channel 130, the refrigeration channel 330 and the water outlet channel 170 may be formed with holes, or may be formed by a combination of a tank and a water pipe, and since the extending direction and the position of the tank are equivalent to those of the holes, the connection relationship between the water diversion channel 130, the refrigeration channel 330 and the water outlet channel 170 when the water dispenser includes the water diversion module 100 and the refrigeration module 300 will be described by taking the holes as an example.

The water diversion hole path 140 comprises a hot water inlet hole 121 path and a cold water inlet hole 121 path, the water outlet hole path 180 comprises a hot water outlet hole path 180, a cold water outlet hole path 180 and a normal temperature water outlet hole path 180, the refrigeration hole path 340 comprises a refrigeration water inlet hole 121 path and a refrigeration water outlet hole path 180, and the water passing hole path comprises a cold water passing hole path or a hot water passing hole path 350. At this time, it is determined whether to use the cold water flow path or the hot water flow path 350 according to the positional relationship between the heating module 200 and the cooling module 300, and when the heating module 200 is above the cooling module 300, the cold water flow path needs to be provided on the heating module 200; when the refrigeration module 300 is above the heating module 200, a hot water passing hole 350 needs to be provided on the refrigeration module 300. The following description will be made by taking an example in which the heating module 200 is provided on the cooling module 300.

The hot water enters the hot water inlet 121 from the water inlet 121, passes through the hot water inlet 121, enters the heating water inlet 121, passes through the heating water inlet 121, and enters the heating device 260; after being heated by the heating device 260, the warm water flows out of the heating shell 210 from the heating water outlet hole 180, enters the warm water outlet hole 180, and then flows out from the warm water outlet 112;

the cold water enters the cold water inlet hole 121 from the water inlet hole 121, enters the cold water inlet water outlet hole 251 after passing through the cold water inlet hole 121, enters the refrigerating water inlet hole 121, and enters the refrigerating device 370 after passing through the refrigerating water inlet hole 121; after being refrigerated by the refrigeration device 370, the cold water flows out of the refrigeration shell 310 from the refrigeration water outlet channel 180, flows into the cold water outlet channel 252, then flows into the cold water outlet channel 180, and then flows out of the cold water outlet 111;

the normal temperature water enters the normal temperature water outlet path 180 from the water inlet hole 121, and flows out from the normal temperature water outlet 113 after flowing out from the normal temperature water outlet path 180.

Regarding the drain hole 360, it may be provided on the water diversion module 100, the heating module 200, or the cooling module 300, for example, on the cooling module 300. The blowdown hole path 360 includes a hot water blowdown hole path 360 and a cold water blowdown hole path 360. The hot water drain hole 360 communicates with a water inlet provided at the bottom of the heating device 260 to drain the sewage out of the heating device 260 in a drain mode; the cold water drain hole 360 communicates with a drain at the bottom of the refrigerating apparatus 370 to drain the sewage out of the refrigerating apparatus 370 in a drain mode.

In addition, in order to further improve the compactness of the structure of the water dispenser, in order to further reasonably utilize the space of each module, a wire slot is formed in the water diversion housing 110, the heating housing 210 and the refrigerating housing 310 so as to mount the wires of the water dispenser in the wire slot, thereby ensuring that the wire arrangement of the water dispenser is neat and regular and avoiding faults caused by messy wires.

A water treatment module for a water dispenser having an electrical panel, a power interface, and wires connecting the electrical panel and the power interface, the water treatment module comprising: a housing, wherein a wire channel 160 is arranged on the outer side wall of the housing for the wires to be installed therein; the water treatment module is a water diversion module 100, a heating module 200 or a refrigerating module 300. The wire channels 160 have a vertical section extending in the direction of the height of the housing and a circumferential section extending circumferentially of the housing. The housing has a bore extending therein for guiding the flow of water within the housing. The hole path for water delivery and the wire channel 160 are independent of each other so that they do not affect each other, and the stability of the operation of both is increased. By integrating the wire channels 160 on the housing, the structure of the housing is more compact, improving the space utilization of the housing.

In the water dispenser, for convenience of user control water dispenser, control panel, display panel and the automatically controlled board of water dispenser all are located the front side of water dispenser, and the power source of water dispenser power supply, for pleasing to the eye and convenient connection power, then set up the rear side at the water dispenser. For connecting the electric control board and the power interface, the wire channel 160 includes a first vertical section, a circumferential section, and a second vertical section, where the first vertical section corresponds to the electric control board, the second vertical section corresponds to the power interface, and the circumferential section connects the first vertical section and the second vertical section.

Since the water dispenser has several forms of combining the water diversion module 100, the heating module 200 and the cooling module 300, the positions of the first vertical section, the second vertical section and the circumferential section may have various forms, which will be described below as examples.

The water dispenser includes: the water diversion module 100, wherein the water diversion module 100 comprises a water diversion shell 110, and a water diversion slot 161 is formed in the outer side wall of the water diversion shell 110; the heating module 200 and/or the refrigerating module 300, wherein the heating module 200 comprises a heating shell 210, and a heating wire slot 162 is formed in the outer side wall of the heating shell 210; the refrigeration module 300 includes a refrigeration housing 310, and a refrigeration wire slot 163 is formed in an outer side wall of the refrigeration housing 310; an electric control board for controlling the operation of the water dispenser, the electric control board being disposed at the front side of the water diversion housing 110, the heating housing 210 or the cooling housing 310; a power interface for accessing an external power, the power interface being disposed at the rear side of the water diversion housing 110, the heating housing 210 or the cooling housing 310; the wires between the circuit board and the power interface are secured by one or more of a water dividing wire chase 161, a heating wire chase 162, and a cooling wire chase 163.

When the water dispenser includes the water diversion module 100 and the heating module 200:

the heating housing 210 is disposed below the water diversion housing 110 and is detachably connected to the water diversion housing 110; the electric control board is arranged at the front side of the water diversion shell 110, and the power interface is arranged at the rear side of the heating shell 210; the water diversion trench 161 includes a first vertical section extending in the height direction of the water diversion housing 110, and/or a first circumferential section extending in the circumferential direction of the water diversion housing 110; the heating wire chase 162 includes a second vertical section disposed along the height of the heating housing 210, and/or a second circumferential section extending circumferentially along the heating housing 210; the lead sequentially passes through the first vertical section, the first circumferential section and/or the second circumferential section, and the second vertical section is connected with the power interface.

When the water dispenser includes the cutwater module 100 and the refrigeration module 300:

the refrigeration shell 310 is disposed below the water diversion shell 110 and is detachably connected with the water diversion shell 110; the electric control board is arranged at the front side of the water diversion shell 110, and the power interface is arranged at the rear side of the refrigeration shell 310; the water diversion trench 161 includes a first vertical section extending in the height direction of the water diversion housing 110, and/or a first circumferential section extending in the circumferential direction of the water diversion housing 110; the refrigeration wire slot 163 includes a second vertical section disposed along the height direction of the refrigeration housing 310, and/or a second circumferential section extending circumferentially along the refrigeration housing 310; the lead sequentially passes through the first vertical section, the first circumferential section and/or the second circumferential section, and the second vertical section is connected with the power interface.

When the water dispenser includes the water diversion module 100, the heating module 200, and the cooling module 300:

the heating housing 210 is disposed below the water diversion housing 110 and is detachably connected to the water diversion housing 110; the refrigeration housing 310 is disposed below the heating housing 210 and is detachably connected to the heating housing 210; the electric control board is arranged at the front side of the water diversion shell 110, and the power interface is arranged at the rear side of the refrigeration shell 310; the water diversion trench 161 includes a first vertical section extending in the height direction of the water diversion housing 110, and/or a first circumferential section extending in the circumferential direction of the water diversion housing 110; the heating wire chase 162 includes a third vertical section disposed along the height direction of the heating housing 210 and/or a second circumferential section disposed circumferentially along the heating housing 210; the refrigeration wire slot 163 includes a second vertical section disposed along the height direction of the refrigeration housing 310; the wire passes through the first vertical section, the first circumferential section and/or the second circumferential Xiang Duan, the third vertical section and the second vertical section in sequence and is connected with the power interface.

In order to make the arrangement of the wire channels 160 and wires more compact and regular, the first vertical section is located directly under the electric control board, and the second vertical section is located directly over the power interface. Through setting up first vertical section under the automatically controlled board for in the first vertical section was located along sharp card to the wire of circuit board, avoid the wire to buckle in the interface department, thereby be favorable to improving the connection stability of the wire of being connected with the automatically controlled board.

Through setting up the vertical section of second directly over power source for in the vertical section of second is located to the wire of being connected with power source near power source straight line card, avoids the wire to buckle in interface department, thereby is favorable to improving the connection stability with power source connection's wire.

In order to further improve the safety of the wires, one or more of a hot water outlet 112, a cold water outlet 111 and a normal temperature water outlet 113 are arranged on the water diversion shell 110; the electric control plate is arranged above the hot water outlet 112, the cold water outlet 111 or the normal temperature outlet 113. Through setting up the automatically controlled board in the top of delivery port, avoid water droplet to the automatically controlled board to eliminate the potential safety hazard.

The foregoing description is only of the preferred embodiments of the present invention and is not intended to limit the scope of the invention, and all equivalent structural changes made by the present description and drawings or direct/indirect application in other related technical fields are included in the scope of the present invention under the inventive concept of the present invention.

Claims (12)

1. A refrigeration module for a water dispenser, the refrigeration module comprising:

a refrigeration shell provided with a refrigeration cavity for installing a refrigeration device; a sewage drainage flow path is arranged on the side wall and the bottom wall of the refrigeration cavity;

The sewage drainage flow path is communicated with a sewage drainage outlet of the refrigerating device so that sewage in the refrigerating device is discharged through the sewage drainage flow path;

the refrigerating module is provided with a refrigerating flow path, and the refrigerating flow path is arranged on the refrigerating shell in a fitting way; the refrigerating flow path comprises a refrigerating water inlet flow path and a refrigerating water outlet flow path, the refrigerating water inlet flow path conveys water to the refrigerating device, and the refrigerating water outlet flow path guides cold water of the refrigerating device out of the refrigerating module;

the blowdown flow path is formed by combining blowdown hole paths, and the blowdown hole paths are formed in the side wall and the bottom wall of the refrigeration shell;

the water inlet of the blowdown hole is communicated with the blowdown outlet of the heating device and/or communicated with the blowdown outlet of the refrigerating device so that water is discharged through the blowdown hole.

2. The refrigeration module of claim 1, wherein the blow-down vent is formed by a loose core or an open bore in the refrigeration housing.

3. A refrigeration module as claimed in claim 1 or claim 2 wherein said blowdown port comprises a cold water blowdown port;

the cold water drain hole path comprises a transverse section extending along the radial direction of the refrigeration shell and/or a vertical section extending along the height direction of the refrigeration shell.

4. A refrigeration module according to claim 3 wherein one end of the vertical section communicates with a drain of the refrigeration device and the other end communicates with one end of the transverse section;

the transverse section is arranged at the bottom of the refrigeration shell, the other end of the transverse section extends to a cold water drain outlet, and the cold water drain outlet is arranged on the outer surface of the refrigeration shell.

5. A refrigeration module as claimed in claim 1 or claim 2 wherein said trapway comprises a hot water trapway;

the hot water drain hole path includes a radial section extending in a radial direction of the refrigeration housing, and an axial section extending in a height direction of the refrigeration housing.

6. The refrigeration module of claim 5, wherein said axial section is disposed within a side wall of said refrigeration housing and has one end in communication with a drain of a heating device and another end in communication with one end of said radial section;

the radial section set up in the bottom of refrigeration casing, the other end of radial section extends to hot water drain, hot water drain sets up the surface of refrigeration casing.

7. A refrigeration module as claimed in claim 1 or claim 2 wherein the blowdown port comprises a cold water blowdown port and a hot water blowdown port;

The cold water pollution discharge hole path comprises a transverse section arranged along the radial direction of the refrigeration shell;

the hot water pollution discharge hole path comprises a radial section arranged along the radial direction of the refrigeration shell;

the transverse section and the radial section are located within the same layer of the refrigeration shell.

8. The refrigeration module of claim 1, wherein the blowdown flow path comprises:

the sewage draining tank circuit is arranged on the shell;

the sewage disposal pipeline is arranged along the sewage disposal tank way and is arranged in the sewage disposal tank way, and a water inlet of the sewage disposal pipeline is communicated with a sewage outlet of a heating device of the water dispenser and/or communicated with a sewage outlet of the refrigerating device so that water is discharged through the sewage disposal hole way.

9. The refrigeration module of claim 8, wherein the blowdown tank circuit comprises a cold water blowdown tank circuit and/or a hot water blowdown tank circuit;

the cold water drain tank circuit comprises a transverse section extending along the radial direction of the refrigeration shell and a vertical section extending along the height direction of the refrigeration shell; one end of the vertical section is communicated with a sewage outlet of the refrigerating device, and the other end of the vertical section is communicated with one end of the transverse section; the transverse section is arranged at the bottom of the refrigeration shell, the other end of the transverse section extends to a cold water drain outlet, and the cold water drain outlet is arranged on the outer surface of the refrigeration shell; and/or the number of the groups of groups,

The hot water blowdown tank circuit comprises a radial section extending along the radial direction of the refrigeration shell and an axial section extending along the height direction of the refrigeration shell; the axial section is arranged in the side wall of the refrigeration shell, one end of the axial section is communicated with a drain outlet of the heating device, and the other end of the axial section is communicated with one end of the radial section; the radial section set up in the bottom of refrigeration casing, the other end of radial section extends to hot water drain, hot water drain sets up the surface of refrigeration casing.

10. The refrigeration module of claim 9, wherein the transverse section and the radial section are located in the same layer of the refrigeration housing.

11. The refrigeration module according to claim 1, wherein the refrigeration housing is provided in a cylindrical shape, and the drain flow path is provided inside the refrigeration housing.

12. A water dispenser comprising a refrigeration module as claimed in any one of claims 1 to 11.