CN211621770U

CN211621770U - Waterway system

Info

Publication number: CN211621770U
Application number: CN201922330438.7U
Authority: CN
Inventors: 杨华; 于洋; 张涛; 樊光民; 郭文琪
Original assignee: Shanghai Chunmi Electronics Technology Co Ltd
Current assignee: Chunmi Technology Shanghai Co Ltd
Priority date: 2019-12-23
Filing date: 2019-12-23
Publication date: 2020-10-02
Anticipated expiration: 2029-12-23

Abstract

The present disclosure relates to waterway systems. This waterway system includes: the water storage tank is provided with a plurality of water inlets and a plurality of water outlets, the water outlet end of each water inlet pipe is connected to the water inlet, different water inlet pipes are connected to different water inlets, and the water inlet end of each water inlet pipe is connected to different water sources; the water inlet end of each water outlet pipe is connected to the water outlet, and different water outlet pipes are connected to different water outlets; the water outlet end of each water inlet pipe is connected with the water inlet through a water inlet valve; the water inlet end of each water outlet pipe is connected with the water outlet through a water outlet valve; the controller is connected with each water inlet valve and each water outlet valve and is used for controlling the opening and closing states of each water inlet valve and each water outlet valve. Through setting up a plurality of inlet tubes and every advances water piping connection to different water sources, can provide different water sources or provide different water sources for the different functions of same water equipment for different water equipment to satisfy the demand of water equipment, effectively promoted user experience.

Description

Waterway system

Technical Field

The present disclosure relates to the field of household appliance technology, and in particular, to a waterway system.

Background

At present, in the waterway systems in the related art, the water inlets of the waterway systems are only connected with a single water source, such as: the municipal water supply source can only use municipal water when the water equipment uses water provided by the waterway system, so that different water equipment can use the same water source, and the requirements of the water equipment cannot be met.

SUMMERY OF THE UTILITY MODEL

To overcome the problems in the related art, embodiments of the present disclosure provide a waterway system. The technical scheme is as follows:

according to a first aspect of embodiments of the present disclosure, there is provided a waterway system, including:

the water storage tank is provided with a plurality of water inlets and a plurality of water outlets;

the water outlet end of each water inlet pipe is connected to the water inlet, different water inlet pipes are connected to different water inlets, and the water inlet end of each water inlet pipe is connected to different water sources;

the water inlet end of each water outlet pipe is connected to the water outlet, and different water outlet pipes are connected to different water outlets;

the water outlet end of each water inlet pipe is connected with the water inlet through the water inlet valve;

the water inlet end of each water outlet pipe is connected with the water outlet through the water outlet valve;

and the controller is connected with each water inlet valve and each water outlet valve and is used for controlling the opening and closing states of each water inlet valve and each water outlet valve.

The technical scheme provided by the embodiment of the disclosure can have the following beneficial effects: the waterway system in the embodiment of the present disclosure includes: the water storage tank is provided with a plurality of water inlets and a plurality of water outlets, the water outlet end of each water inlet pipe is connected to the water inlet, different water inlet pipes are connected to different water inlets, and the water inlet end of each water inlet pipe is connected to different water sources; the water inlet end of each water outlet pipe is connected to the water outlet, and different water outlet pipes are connected to different water outlets; the water outlet end of each water inlet pipe is connected with the water inlet through a water inlet valve; the water inlet end of each water outlet pipe is connected with the water outlet through a water outlet valve; the controller is connected with each water inlet valve and each water outlet valve and is used for controlling the opening and closing states of each water inlet valve and each water outlet valve. Through setting up a plurality of inlet tubes and every advances water piping connection to different water sources, can provide different water sources or provide different water sources for the different functions of same water equipment for different water equipment to satisfy the demand of water equipment, effectively promoted user experience.

In one embodiment, further comprising: a waste water drain pipe and a waste water drain valve;

the water storage tank is also provided with a waste water outlet;

the water inlet end of the waste water drainage pipe is connected with the waste water drainage port through the waste water drainage valve;

the controller is also connected with the wastewater drainage valve and used for controlling the opening and closing state of the wastewater drainage valve.

In one embodiment, a flow sensor is also arranged inside the water storage tank.

In one embodiment, a flow sensor is arranged at each water outlet.

In one embodiment, further comprising: a total dissolved solids TDS sensor;

the TDS sensor is located inside the storage tank.

In one embodiment, further comprising: a heating member and a first temperature sensor;

the heating part and the first temperature sensor are both positioned in the water storage tank;

the controller is also connected with the heating part and the first temperature sensor and is used for controlling the working state of the heating part.

In one embodiment, further comprising: a control panel, the control panel comprising:

a housing;

a selection component comprising: the rotary knob component, the water inlet selection component and the water outlet selection component are arranged on the rotary knob component;

the knob assembly includes: a knob; the water inlet selection assembly comprises: a water inlet selection button; the water outlet selection assembly comprises: a water outlet selection key;

the knob, the water inlet selection key and the water outlet selection key are all positioned on the shell;

the knob is used for adjusting the water outlet temperature and the water outlet quantity;

the water inlet selecting key is used for selecting a water inlet;

the water outlet selection key is used for selecting a water outlet;

the controller is electrically connected with the knob, the water inlet selection key and the water outlet selection key and is used for executing the function selected by the knob and controlling the opening and closing states of the selected water inlet and the selected water outlet.

In one embodiment, the water inlet selection assembly further comprises: the water inlet selection indicator lamp and the water inlet selection indicator lamp correspond to each other; the water outlet selection assembly further comprises: the water outlet selection indicator lamp and the identifier corresponding to the water outlet selection indicator lamp;

the water inlet selection indicator lamp is positioned in the shell and surrounds the water inlet selection key; the pressing times of different water inlet selecting keys correspond to different water inlet selecting indicator lamps;

the mark corresponding to the water inlet selection indicator lamp is positioned around the corresponding water inlet selection indicator lamp; the controller is also electrically connected with the water inlet selection indicator lamp; the water inlet selecting key is used for pressing the water inlet selecting key to a corresponding time;

the water outlet selection indicator lamp is positioned in the shell and surrounds the water inlet selection key; the pressing times of different water outlet selection keys correspond to different water outlet selection indicator lamps;

the mark corresponding to the water outlet selection indicator lamp is positioned around the corresponding water outlet selection indicator lamp; the controller is also electrically connected with the water outlet selection indicator lamp; and the water outlet selection indicator lamp is used for controlling the lighting of the water outlet selection indicator lamp corresponding to the pressing times of the water outlet selection key.

In one embodiment, further comprising: a touch control screen;

the touch control screen is connected with the controller and used for selecting the water outlet temperature, the water outlet quantity, the water inlet and the water outlet and displaying the current working state of the waterway system.

In one embodiment, further comprising: a faucet and a faucet flow meter;

and the water inlet of the water faucet is connected with the water outlet in the water storage tank through the water faucet flowmeter.

In one embodiment, the water storage tank comprises: cold water storage tank and hot water storage tank still include: a refrigeration module and a second temperature sensor;

a plurality of cold water inlet sub-ports and a plurality of cold water outlet sub-ports are formed in the cold water storage tank;

a plurality of hot water inlet sub-ports and a plurality of hot water outlet sub-ports are arranged in the hot water storage tank;

the water outlet end of each water inlet pipe is respectively connected to the hot water inlet sub-port and the cold water inlet sub-port, and different water inlet pipes are connected to different hot water inlet sub-ports and different cold water inlet sub-ports;

the water inlet end of each water outlet pipe is respectively connected to the hot water outlet sub-port and the cold water outlet sub-port, and different water outlet pipes are connected to different hot water outlet sub-ports and different cold water outlet sub-ports;

the heating part and the first temperature sensor are both positioned in the hot water storage tank;

the refrigeration module is connected with the cold water storage tank, and the second temperature sensor is positioned in the cold water storage tank;

the controller is also connected with the refrigeration module and used for controlling the working state of the refrigeration module.

In one embodiment, further comprising: a hot water inlet valve, a hot water outlet valve, a cold water inlet valve and a cold water outlet valve;

the water outlet end of the water inlet pipe of the hot water storage tank is connected with the hot water inlet sub-port through the hot water inlet valve, and the water inlet end of the water outlet pipe of the hot water storage tank is connected with the hot water outlet sub-port through the hot water outlet valve;

the water outlet end of the water inlet pipe of the cold water storage tank is connected with the cold water inlet sub-port through the cold water inlet valve, and the water inlet end of the water outlet pipe of the cold water storage tank is connected with the cold water outlet sub-port through the cold water outlet valve.

In one embodiment, the refrigeration module comprises: a semiconductor refrigeration device;

the cold end of the semiconductor refrigerating device is connected with the cold water storage tank;

the hot end of the semiconductor refrigerating device is connected with the hot water storage tank;

the controller is also connected with the semiconductor refrigerating device and used for controlling the working state of the semiconductor refrigerating device.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present disclosure and together with the description, serve to explain the principles of the disclosure.

Fig. 1 is a schematic structural diagram of a waterway system according to an exemplary embodiment.

Fig. 2 is a schematic structural diagram of a waterway system according to an exemplary embodiment.

Fig. 3 is a schematic structural diagram of a waterway system according to an exemplary embodiment.

Fig. 4 is a schematic structural diagram illustrating a control panel according to an exemplary embodiment.

Fig. 5 is a schematic structural diagram of a waterway system according to an exemplary embodiment.

Fig. 6 is a schematic structural diagram of a waterway system according to an exemplary embodiment.

Fig. 7 is a schematic diagram of a control system configuration of a waterway system according to an exemplary embodiment.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The implementations described in the exemplary embodiments below are not intended to represent all implementations consistent with the present disclosure. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present disclosure, as detailed in the appended claims.

Fig. 1 is a schematic structural diagram illustrating a waterway system according to an exemplary embodiment, and as shown in fig. 1, the waterway system includes:

a water storage tank 11, wherein a plurality of water inlets 111 and a plurality of water outlets 112 are arranged in the water storage tank 11;

a plurality of water inlet pipes 12, the water outlet end of each water inlet pipe 12 being connected to a water inlet 111, and different water inlet pipes 12 being connected to different water inlets 111, the water inlet end of each water inlet pipe 12 being connected to different water sources;

a plurality of water outlet pipes 13, the water inlet end of each water outlet pipe 13 is connected to the water outlet 112, and different water outlet pipes 13 are connected to different water outlets 112;

a plurality of water inlet valves 14, wherein the water outlet end of each water inlet pipe 12 is connected with the water inlet 111 through the water inlet valve 14;

a plurality of water outlet valves 15, wherein the water inlet end of each water outlet pipe 13 is connected with the water outlet 112 through the water outlet valve 15;

and a controller (not shown) connected to each inlet valve 14 and each outlet valve 15 for controlling the opening and closing state of each inlet valve 14 and each outlet valve 15.

The scheme in this disclosure can realize the centralized control of many waterways.

In the solution of the present disclosure, there are a plurality of inlet pipes 12, and the inlet end of each inlet pipe 12 can be connected to different water sources, for example: there are three inlet tubes 12, be first inlet tube 12, second inlet tube 12 and third inlet tube 12 respectively, and wherein, first inlet tube 12 can connect the pure water, second inlet tube 12 can connect the clean water after the filtration, third inlet tube 12 can connect ordinary water etc.. Through setting up a plurality of inlet tubes 12, can be connected to different water sources, can provide different water sources or provide different water sources for the different functions of same water equipment for different water equipment to satisfy the demand of water equipment, effectively promoted user experience. For example: when the water using device is a cooking appliance, the filtered clean water provided by the second water inlet pipe 12 can be used for heating rice and dishes, and the purified water provided by the first water inlet pipe 12 can be used for cooking porridge.

In the scheme of this disclosure, still be provided with a plurality of outlet pipes 13, different outlet pipes 13 can connect different water consumption equipment, just so can provide different water sources for different water consumption equipment, for example: the water outlet end of the water outlet pipe 13 can be connected with a water faucet, an electric cooker and other intelligent cooking appliances; different water outlet pipes 13 can also be connected with the same water using equipment, so that different water sources can be provided for different functions of the same water using equipment.

The outlet end of each inlet pipe 12 is connected to the inlet 111 through a water inlet valve 14, and the open/close state of each water inlet valve 14 is controlled by a controller, and the position of each water inlet valve 14 is not limited in this disclosure. Continuing with the above example, if the purified water provided by the first inlet pipe 12 is selected, the controller may control to close the inlet valves 14 corresponding to the second inlet pipe 12 and the third inlet pipe 12 and open the inlet valve 14 corresponding to the first inlet pipe 12, so that the purified water provided by the first inlet pipe 12 may be used from the water using equipment to which the outlet pipe 13 is connected.

The water inlet end of each water outlet pipe 13 is connected with the water outlet 112 through a water outlet valve 15, and the opening and closing state of each water outlet valve 15 is controlled by the controller. For example: the electric cooker is characterized in that the electric cooker is provided with three water outlet pipes 13, namely a first water outlet pipe 13 and a second water outlet pipe 13, wherein the first water outlet pipe 13 is connected with a water tap, the second water outlet pipe 13 is connected with the electric cooker, when water needs to be injected into the electric cooker, a controller can control to close a water outlet valve 15 corresponding to the first water outlet pipe 13 and open a water outlet valve 15 corresponding to the second water outlet pipe 13, and therefore water can be injected into the electric cooker.

For example, any inlet pipe 12 may be communicated with any outlet pipe 13, one inlet pipe 12 may be communicated with a plurality of outlet pipes 13 at the same time, if the water source factor is considered, a plurality of inlet pipes 12 may not be communicated with one outlet pipe 13 at the same time, because the water source is different, but if the water source factor is not considered, a plurality of inlet pipes 12 may be communicated with the same outlet pipe 13.

The intersection of inlet tube 12 and outlet pipe 13 can set up a storage water tank 11, set up a plurality of water inlets 111 and a plurality of delivery port 112 in storage water tank 11's casing, an inlet tube 12 is all connected to each water inlet 111, and different inlet tube 12 is connected to different water inlets 111, an outlet pipe 13 is all connected to each delivery port 112, and different outlet pipe 13 is connected to different delivery port 112, through setting up storage water tank 11, the water at water source can get into storage water tank 11 through inlet tube 12, then the water in the storage water tank 11 gets into water equipment through outlet pipe 13.

The inlet valve 14 and the outlet valve 15 include: an electronic valve.

In one embodiment, instead of the water storage tank 11, a multi-way valve (e.g., a four-way valve) may be provided, so that different water inlet pipes 12 may be connected to different water inlets 111 of the multi-way valve, and different water outlet pipes 13 may be connected to different water outlets 112 of the multi-way valve.

The waterway system in the embodiment of the present disclosure includes: the water storage tank is provided with a plurality of water inlets and a plurality of water outlets, the water outlet end of each water inlet pipe is connected to the water inlet, different water inlet pipes are connected to different water inlets, and the water inlet end of each water inlet pipe is connected to different water sources; the water inlet end of each water outlet pipe is connected to the water outlet, and different water outlet pipes are connected to different water outlets; the water outlet end of each water inlet pipe is connected with the water inlet through a water inlet valve; the water inlet end of each water outlet pipe is connected with the water outlet through a water outlet valve; the controller is connected with each water inlet valve and each water outlet valve and is used for controlling the opening and closing states of each water inlet valve and each water outlet valve. Through setting up a plurality of inlet tubes and every advances water piping connection to different water sources, can provide different water sources or provide different water sources for the different functions of same water equipment for different water equipment to satisfy the demand of water equipment, effectively promoted user experience.

In one embodiment, as shown in fig. 2, further comprising: a waste water drain pipe 16 and a waste water drain valve 17;

the water storage tank 11 is also provided with a waste water outlet 113;

the water inlet end of the waste water drainage pipe 16 is connected with a waste water outlet 113 through a waste water drainage valve 17;

the controller is also connected with the wastewater drainage valve 17 and is used for controlling the opening and closing state of the wastewater drainage valve 17.

Because different water inlet pipes 12 are connected to different water sources, when the water-saving water supply device is used, water in the water inlet pipe 12 enters the water storage tank 11, if the water-saving equipment does not use up water in the water storage tank 11, and the next water-saving equipment does not use the type of the residual water in the current water storage tank 11, at the moment, the controller can control the waste water drain valve 17 to be opened so as to discharge the water in the water storage tank 11 through the waste water drain pipe 16, and after the residual water in the water storage tank 11 is discharged, the controller controls the waste water drain valve 17 to be closed again and controls the corresponding water inlet valve 14 to be opened. Continuing with the above example, if the purified water supplied from the first water inlet pipe 12 is used last time, after the water consuming device is used, the controller controls the water inlet valve 14 and the water outlet valve 15 to be closed, but the purified water still exists in the water storage tank 11, and the current water consuming device needs to use the normal water supplied from the third water inlet pipe 12, at this time, the controller needs to control the waste water drain valve 17 to be opened, so that the purified water in the water storage tank 11 is discharged through the waste water drain pipe 16, and after the purified water is discharged, the controller controls the waste water drain valve 17 to be closed, and controls the water inlet valve 14 corresponding to the third water inlet pipe 12 to be opened, so that the normal water enters the water storage tank 11 through the third water inlet pipe 12 and is supplied to the water consuming device through the water.

Through setting up waste water drain pipe 16 and waste water drain valve 17, can be with the drainage of remaining water in the storage water tank 11 clean before the use, avoid injecting into the non-water need to the water equipment to user experience has effectively been promoted.

In one embodiment, as shown in FIG. 3, a flow sensor 21 is also disposed inside water storage tank 11.

A flow sensor 21 may also be provided in the storage tank 11. If only one outlet 112 is opened at a time, the flow sensor 21 in the water storage tank 11 can detect the water output, if a plurality of outlets 112 are opened at a time, the total flow is detected by the flow sensor 21, and the flow of each outlet 112 can be proportionally calculated according to the opening degree of each outlet valve 15.

In one embodiment, a flow sensor 21 is provided at each water outlet 112.

By arranging the flow sensors 21 at each water outlet 112, the flow of each water outlet 112 can be accurately known, so that accurate control is achieved.

In one embodiment, as shown in fig. 3, further comprising: a Total Dissolved Solids (TDS) sensor 22.

The TDS sensor 22 is located inside the storage tank 11.

TDS sensor 22 detects the quality of water in storage water tank 11, because storage water tank 11 still is connected with waste water drain pipe 16, when needs use the water purification, judges whether need open waste water outlet 113 earlier according to the TDS value, discharges unclean water earlier.

In one embodiment, as shown in fig. 3, further comprising: a heating member 23 and a first temperature sensor 24;

heating component 23 and first temperature sensor 24 are both located inside water storage tank 11;

the controller is further connected to the heating member 23 and the first temperature sensor 24 for controlling the operating state of the heating member 23.

Can satisfy the user through setting up heating part 23 and use hydrothermal demand to can control the temperature of hot water for the temperature that the user set up through setting up first temperature sensor 24, and can be used for controlling the heating power who adds the part through setting up the controller, effectively promoted user experience.

In one implementation, as shown in fig. 4, the method further includes: control panel 3, control panel 3 includes:

a housing 31;

a selection component 32 comprising: a knob component 321, a water inlet selecting component 322 and a water outlet selecting component 323;

the knob assembly 321 includes: a knob 3211; the water inlet selection assembly 322 includes: a water inlet pipe selection button 3221; the effluent selection module 323 comprises: an outlet pipe selection button 231;

the knob 3211, the water inlet pipe selection button 3221 and the water outlet pipe selection button 3231 are all located on the shell 31;

the knob 3211 is used for adjusting the water outlet temperature and the water outlet amount;

the inlet pipe selection button 3221 is used for selecting the inlet pipe 12;

the water outlet pipe selection button 3231 is used for selecting the water outlet pipe 13;

and the controller is electrically connected with the knob 3211, the water inlet pipe selection button 3221 and the water outlet pipe selection button 3231 and is used for executing the function selected by the knob 3211 and controlling the opening and closing states of the selected water inlet pipe 12 and the selected water outlet pipe 13.

The knob 3211 may be partially located outside the housing 31 and partially located inside the housing, as long as the knob 3211 has a sufficient exposed portion for a user to rotate, and the knob 3211 may be matched with a controller, thereby implementing function switching of the knob 3211 and function selection of the knob 3211.

When using the waterway system provided in the present disclosure, the user may select the inlet pipe 12 using the inlet pipe selection button 3221 and select the outlet pipe 13 using the outlet pipe selection button 3231, according to the inlet pipe 12 and the outlet pipe 13 selected from the inlet pipe 12 and the outlet pipe 13.

For example: if the inlet pipe 12 comprises: a first inlet pipe 12, a second inlet pipe 12 and a third inlet pipe 12; the water outlet pipe 13 includes: a first water outlet pipe 13, a second water outlet pipe 13 and a third water outlet pipe 13. When a user wants to use the path of the first inlet pipe 12 and the third outlet pipe 13, the first inlet pipe 12 is selected by the inlet pipe selection button 3221, and the third outlet pipe 13 is selected by the outlet pipe selection button 3231.

Wherein the purpose of having a plurality of inlet pipes 12 is to connect different water sources, such as: the first inlet tube 12 can be connected with a purified water source, the second inlet tube 12 can be connected with a filtered purified water source, and the third inlet tube 12 can be connected with a water source of common water. The purpose of having multiple outlet pipes 13 is to achieve different purposes, such as: the first outlet pipe 13 may be connected to a water tap, and the second outlet pipe 13 may be connected to a cooking appliance.

In practical scenarios, the user may need different outlet water temperatures, and/or different outlet water amounts, such as: in winter, the user wants the discharged water to be hot water, and in summer, the user wants the discharged water to be ice water. At this time, the user can select the proper outlet water temperature and/or the proper outlet water amount by only rotating the knob 3211 in the housing.

When the user uses foretell control panel 3, can directly adjust and use foretell control panel 3 to select out water temperature, water yield, inlet tube 12 and outlet pipe 13, after the selection finishes, can directly get the water in the outlet pipe 13 department that outlet pipe 13 corresponds, control panel 3 has just so realized the water intaking function, has made things convenient for user's operation, has effectively promoted user experience.

In one embodiment, the inlet water selection assembly 322 further comprises: the water inlet pipe selection indicator lamp and the corresponding mark of the water inlet pipe selection indicator lamp are arranged on the same side of the water inlet pipe; the effluent selection module 323 further comprises: the outlet pipe selection indicator lamp and the identifier corresponding to the outlet pipe selection indicator lamp are arranged on the water outlet pipe;

the water inlet pipe selection indicator lamp is positioned in the shell 31 and surrounds the water inlet pipe selection button 3221; wherein, the pressing times of different water inlet pipe selecting buttons 3221 correspond to different indicator lamps of the selected water inlet pipe 12;

the mark corresponding to the water inlet pipe selection indicator lamp is positioned around the corresponding water inlet pipe selection indicator lamp; the controller is also electrically connected with a water inlet pipe selection indicator lamp; the indicator light for controlling the water inlet pipe 12 corresponding to the pressing times of the water inlet pipe selection button 3221 is lighted;

the water outlet pipe selection indicator lamp is positioned inside the shell 31 and surrounds the water inlet pipe selection button 3221; the pressing times of different water outlet pipe selection keys 3231 correspond to different water outlet pipe 13 selection indicator lamps;

the identifier corresponding to the water outlet pipe selection indicator lamp is positioned around the corresponding water outlet pipe selection indicator lamp; the controller is also electrically connected with a water outlet pipe selection indicator lamp; and an indicator lamp for controlling the selective outlet pipe 13 corresponding to the pressing times of the outlet pipe selection key 3231 to be lightened.

Since there are a plurality of inlet pipes 12, in order to allow the user to clearly know which inlet pipe 12 is currently selected, an inlet pipe selection indicator lamp and a logo are provided around the inlet pipe selection button 3221, when the user presses the inlet pipe selection button 3221, the inlet pipe selection indicator lamp corresponding to the number of times of pressing of the inlet pipe selection button 3221 is turned on, and then the user can know which inlet pipe 12 is currently selected through the logo around the lighted inlet pipe selection indicator lamp.

Continuing with the above example, pressing the inlet tube selection button 3221 once corresponds to the selection of the first inlet tube 12, pressing the inlet tube selection button 3221 twice corresponds to the selection of the second inlet tube 12, and pressing the inlet tube selection button 3221 three times corresponds to the selection of the third inlet tube 12, when a user wants to select the first inlet tube 12, the user presses the inlet tube selection button 3221 times, and when the controller detects that the user presses the inlet tube selection button 3221 times, the controller controls the inlet tube selection indicator lamp corresponding to the first inlet tube 12 to be turned on, that is, the inlet tube selection indicator lamp identified as 1 to be turned on, so that the user can know that the currently selected inlet tube 12 is the first inlet tube 12 through the corresponding identification as 1 on the turned-on inlet tube selection indicator lamp.

Because there are multiple outlet pipes 13, in order to make the user know which outlet pipe 13 is currently selected, an outlet pipe selection indicator lamp and an identifier are arranged around the outlet pipe selection key 3231, when the user presses the outlet pipe selection key 3231, the outlet pipe selection indicator lamp corresponding to the pressing frequency of the outlet pipe selection key 3231 is turned on, and then the user can know which outlet pipe 13 is currently selected through the identifier around the turned-on outlet pipe selection indicator lamp.

Continuing with the above example, pressing the outlet pipe selection key 3231 once corresponds to the first outlet pipe 13, pressing the outlet pipe selection key 3231 twice corresponds to the second outlet pipe 13, and pressing the outlet pipe selection key 3231 three times corresponds to the third outlet pipe 13, when the user wants to select the first outlet pipe 13, the user presses the outlet pipe selection key 3231 1 time, and when the controller detects that the number of times the user presses the outlet pipe selection key 3231 is 1 time, the controller controls the outlet pipe selection indicator lamp corresponding to the first outlet pipe 13 to be turned on, that is, the outlet pipe selection indicator lamp identified as 1 to be turned on, so that the user can know that the currently selected outlet pipe 13 is the first outlet pipe 13 through the corresponding identifier as 1 on the turned-on outlet pipe selection indicator lamp.

In one embodiment, the knob assembly 321 further comprises: a display screen;

the display screen is positioned outside the knob 3211; the display screen is used for displaying at least one of the following information: a selected inlet pipe 12, a selected outlet pipe 13, a selected outlet water temperature and a selected outlet water quantity;

the controller is also electrically connected with the display screen; for controlling the information displayed by the display screen.

In this embodiment, the knob 3211 may be provided with the display screen, which is used to display at least one of the following information: a selected inlet pipe 12, a selected outlet pipe 13, a selected outlet water temperature and a selected outlet water quantity; therefore, the user can clearly and quickly know the currently selected function option through the display screen.

In one embodiment, the knob assembly 321 further comprises a plurality of tick marks;

a plurality of graduations are disposed on the housing 31 and surround the knob 3211, the graduations being used to identify a selected outlet temperature, and/or an outlet flow rate.

In order to make the user know the outlet water temperature and/or the outlet water amount after rotating the knob 3211, graduation lines may be arranged around the knob 3211, and each graduation line represents a different outlet water temperature value and/or outlet water amount value.

When the user selects the water outlet temperature and the water outlet quantity through the knob 3211, taking the adjustment of the water outlet quantity as an example for explanation, the user adjusts the numerical value of the water outlet quantity through the rotation of the knob 3211, and when the rotation speed of the knob 3211 rotated by the user is detected to be lower than a certain preset value, the calculation is performed according to 5ml by one scale; when the rotation speed of the knob 3211 rotated by the user is detected to be greater than the preset value, the calculation is performed by 50ml per scale.

In one embodiment, the knob assembly 321 further comprises: a pressing part;

the bottom of the knob 3211 is connected with the pressing part;

the controller is also electrically connected with the pressing part; the pressing portion is used for pressing the knob 3211 after the knob 3211 is used to select the water outlet temperature or the water outlet amount, so as to send a selection instruction to the controller, wherein the selection instruction indicates the selected water outlet temperature or the selected water outlet flow.

The knob 3211 itself can be pressed by providing a pressing portion at the bottom of the knob 3211 to serve as a push switch. Alternatively, the display screen itself in the middle of the knob 3211 may be pressed as a push switch. The function of the push switch is to indicate a determination that the user has selected a water temperature or water output via knob 3211 and then pushes the push switch to send a signal to the controller indicating that the current selection is in effect. Or the user does not need to manually select the hand temperature and the water output amount, the press switch is directly pressed, the controller outputs water according to the default water output temperature, and the press switch is pressed again, so that the water output is stopped.

The knob 3211 is provided with a push switch for serving as a transmission carrier of the selection determination signal, so that the controller can clearly know the outlet water temperature and the outlet water amount currently selected by the user, and selection errors caused by the user accidentally touching the knob 3211 are avoided.

In one embodiment, further comprising: a switch;

the switch is positioned outside the shell 31 and electrically connected with the knob 3211; for switching the selection function of the knob 3211.

In order to facilitate the user to switch the functions of the knob 3211, a switch is further disposed on the control panel 3, and the control knob 3211 selects the outlet water temperature or the outlet water amount according to the selection function of the switch.

Of course, in actual practice, the knob 3211 may be used as it is without a switching button, and here, the long push knob 3211 may be used as a function switching key.

In one embodiment, the effluent selection module 323 further comprises: a water outlet waterway selection button;

the water outlet waterway selection key is positioned outside the shell 31 and is connected with the controller; for selecting a destination waterway of the outlet pipe 13, and the controller is used for controlling the on-off state of the destination waterway.

Due to the multiple outlet pipes 13, different outlet pipes 13 may be connected to different devices, for example: first outlet pipe 13 can connect tap, and second outlet pipe 13 can connect cooking utensil, and the play water route this moment is: the first water outlet pipe 13 is connected with a water path of the water faucet, and the second water outlet pipe 13 is connected with a water path of the cooking utensil. If the user selects the cooking appliance and the cooking function of the cooking appliance, the destination water path is the water path from the second water outlet pipe 13 to the cooking appliance, and the switch of the water path is turned on.

In one embodiment, if the water storage tank 11 is further connected to a mineral release module, the controller may be further configured to control the mineral release module to be turned on to add minerals to the water. For example: when mineral water is selected for cooking, the controller controls the mineral releasing module to be turned on.

When the control panel 3 in the present disclosure is used for taking water, if quantitative water taking is needed, the knob 3211 can be rotated, the display screen is lighted, at this time, the display screen displays the water amount, when the knob 3211 stops at a certain scale mark, the value corresponding to the scale mark is used as the default flow rate of quantitative water taking, the knob 3211 is pressed, and water is taken out according to the water amount; if the water needs to be taken quantitatively at a fixed temperature, a selector switch is pressed to switch to a water outlet temperature setting interface, the knob 3211 is rotated to adjust the set water outlet temperature, when the water stops at a certain scale mark, the temperature corresponding to the moment scale mark is taken as the water outlet temperature, the controller calculates the heating power according to the set water outlet temperature and the current water temperature, and the knob 3211 is pressed to heat the outlet water according to the power. Meanwhile, the water outlet amount can be set firstly, and then the water outlet temperature is set, so that the quantitative and constant-temperature water outlet is realized. In the water outlet process, the knob 3211 is clicked to stop water outlet.

The control panel 3 in the present disclosure may be located at any position, for example: the control panel 3 can be located at the center control position of the kitchen, and the user controls which water inlet pipe 12 and water outlet pipe 13 are opened, the water outlet temperature, the water outlet amount and the like through the control panel 3.

In another implementation manner, the waterway system further includes: a touch control screen;

the touch control screen is connected with the controller and used for selecting the water outlet temperature, the water outlet quantity, the water inlet pipe 12 and the water outlet pipe 13 and displaying the working state of the current waterway system.

All the function keys in the control panel 3 in the present disclosure can also be realized by providing one touch screen in the control panel 3. But the touch screen is more convenient and more beautiful and the user experience is better than the knob 3211 and the keys. In practical application, any setting mode can be selected according to actual needs.

In one embodiment, the waterway system further comprises: a faucet and a faucet flow meter;

the water inlet of the faucet is connected to the water outlet 112 in the water storage tank 11 through a faucet flow meter.

The tap further comprises a tap flow meter located inside the outlet pipe 13 and connected to the controller for the controller to know the real time water output for display in the control panel 3.

In one embodiment, as shown in FIG. 5, storage tank 11 comprises: a cold water storage tank 114 and a hot water storage tank 115, further comprising: a refrigeration module 25 and a second temperature sensor 26;

a plurality of cold water inlet sub-ports and a plurality of cold water outlet sub-ports are arranged in the cold water storage tank 114;

a plurality of hot water inlet sub-ports and a plurality of hot water outlet sub-ports are arranged in the hot water storage tank 115;

the water outlet end of each water inlet pipe 12 is respectively connected to a hot water inlet sub-port and a cold water inlet sub-port, and different water inlet pipes 12 are connected to different hot water inlet sub-ports and different cold water inlet sub-ports;

the water inlet end of each water outlet pipe 13 is respectively connected to a hot water outlet sub-port and a cold water outlet sub-port, and different water outlet pipes 13 are connected to different hot water outlet sub-ports and different cold water outlet sub-ports;

the heating part 23 and the first temperature sensor 24 are both located in the hot water storage tank 115;

the refrigeration module 25 is connected with the cold water storage tank 114, and the second temperature sensor 26 is positioned in the cold water storage tank 114;

the controller is also connected to the refrigeration module 25 for controlling the operating state of the refrigeration module 25.

At this time, the water inlet in each of the above embodiments includes: a cold water inlet tap (i.e., a water inlet of a cold water storage tank) and a hot water inlet tap (i.e., a water inlet of a hot water storage tank); the water outlet in each of the above embodiments includes: a cold water outlet (i.e., the outlet of the cold water storage tank) and a hot water outlet (i.e., the outlet of the hot water storage tank).

Through setting up cold water storage tank 114 and hot water storage tank 115, can satisfy the demand of water equipment to hot water and cold water simultaneously, effectively promoted user experience.

In one embodiment, the fill valve 14 includes: a cold water inlet valve (i.e., a water inlet valve of a cold water storage tank) and a hot water inlet valve (i.e., a water inlet valve of a hot water storage tank); the outlet valve 15 includes: a cold water outlet valve (i.e., an outlet valve of the cold water storage tank) and a hot water outlet valve (i.e., an outlet valve of the hot water storage tank);

the water outlet end of a water inlet pipe 12 of the hot water storage tank is connected with a hot water inlet sub-port through a hot water inlet valve, and the water inlet end of a water outlet pipe 13 of the hot water storage tank is connected with a hot water outlet sub-port through a hot water outlet valve;

the water outlet end of a water inlet pipe 12 of the cold water storage tank is connected with a cold water inlet sub-port through a cold water inlet valve, and the water inlet end of a water outlet pipe 13 of the cold water storage tank is connected with a cold water outlet sub-port through a cold water outlet valve.

Temperature sensors are arranged in the cold water storage tank 114 and the hot water storage tank 115. The controller can calculate the ratio of the cold water and the hot water according to the outlet water temperature set in the control panel 3 by the user and the current water temperatures in the cold water storage tank 114 and the current hot water storage tank 115, determine the outlet water amount of the cold water and the hot water according to the ratio, and also determine the opening degree of the opened hot water outlet valve and the opened cold water outlet valve according to the ratio.

In one embodiment, the refrigeration module 25 includes: a semiconductor refrigeration device;

the cold end of the semiconductor refrigerating device is connected with a cold water storage tank 114;

the hot end of the semiconductor refrigerating device is connected with a hot water storage tank 115;

The cold end of the semiconductor refrigerating device is connected with a cold water storage tank 114 and is used for cooling water in the cold water storage tank 114; the hot end of the semiconductor refrigerating device is connected with a hot water storage tank 115 and is used for heating water in the hot water storage tank 115.

The semiconductor refrigerating device is a heat transfer device, when a thermocouple formed by connecting an N-type semiconductor material and a P-type semiconductor material has current flowing through the thermocouple pair, heat transfer can be generated between two ends, the heat can be transferred from one end to the other end, and temperature difference is generated to form a cold end and a hot end, so that in the related technology, the refrigerating function of the semiconductor refrigerating device can be adopted, and the fan and the radiating fins are adopted to mainly radiate heat of the hot end of the refrigerating fin. However, in an actual scene, the temperature difference between the cold end and the hot end of the semiconductor refrigeration piece can reach 40-65 degrees, in order to effectively utilize the semiconductor refrigeration device, the cold end and the hot end of the semiconductor refrigeration device can be both utilized, the cold end is adopted to cool water in the cold water storage tank 114, and the hot end is adopted to heat water in the hot water storage tank 115, so that the utilization rate of the semiconductor refrigeration device is improved, energy is effectively saved, and the heat generated in the semiconductor refrigeration device is prevented from being wasted.

By way of example, the semiconductor refrigeration device described above may include: semiconductor refrigeration piece.

In one embodiment, the refrigeration module 25 further comprises a compressor and a condenser;

a condenser is fixed on the outer side of the cold water storage tank 114;

the condenser is electrically connected with the compressor;

the controller is also connected with the compressor and used for controlling the working state of the compressor.

In order to rapidly cool the pure water in the cold water storage tank 114, auxiliary refrigeration equipment (a compressor and a condenser) may be added to the pure water, and two cooling modes, namely a semiconductor refrigeration device and the auxiliary refrigeration equipment, may be adopted simultaneously during refrigeration, so as to accelerate the cooling speed.

In one embodiment, the heating member 23 includes: heating a tube;

the heating pipe is positioned inside the hot water storage tank 115;

the controller is also connected with the heating pipe and used for controlling the working state of the heating pipe.

In order to heat the pure water in the hot water storage tank 115 quickly, an auxiliary heating device (heating pipe) may be added to the hot water storage tank 115, and two heating modes, i.e., a semiconductor refrigeration device and the auxiliary heating device, may be used simultaneously during heating, so as to accelerate the heating speed.

In one embodiment, the waterway system further comprises: a buzzer;

the controller is electrically connected with the buzzer.

When the first temperature sensor 24 detects that the temperature in the hot water storage tank 115 reaches the preset temperature, the controller controls the buzzer to operate to remind the user that the current water temperature meets the requirement, and can be used, and/or when the second temperature sensor 26 detects that the temperature in the cold water storage tank 114 reaches the preset temperature, the controller controls the buzzer to operate to remind the user that the current water temperature meets the requirement, and can be used.

It should be noted that, in the water path system, there may be an auxiliary cooling device and an auxiliary heating device, or there may be only one of the auxiliary cooling device and the auxiliary heating device.

Fig. 6 is a schematic structural diagram of a waterway system according to an exemplary embodiment, as shown in fig. 6, including:

the waterway system comprises: the water treatment device comprises a water storage tank 11, three water inlet pipes 12, a water outlet pipe 13, a water inlet valve 14, a water outlet valve 15, a wastewater drainage pipe 16, a wastewater drainage valve 17, a flow sensor 21, a heating component 23 and a water suction pump 27.

Wherein, the water outlet end of each water inlet pipe 12 is connected with the water inlet 111 of the water storage tank 11 through a water inlet valve 14; the heating component 23 is an instant heating pipe, the heating pipe is not located in the water storage tank 11 at this time, but is connected to the water inlet end of the water outlet pipe 13, the water inlet end of the water outlet pipe 13 is connected to the water outlet end of the instant heating pipe through the water outlet valve 15, in order to increase the pressure of water, the instant heating water tank further comprises a water suction pump 27, the water inlet end of the heat pipe is connected to the water outlet end of the water suction pump 27, and the water inlet end of the water suction pump 27 is connected to the water outlet 112 of the water storage; the inlet end of the waste drain pipe 16 is connected to a waste drain 113 of the storage tank 11 through a waste drain valve 17.

Fig. 7 is a schematic structural diagram illustrating a control system of the waterway system according to an exemplary embodiment, and as shown in fig. 7, the control system includes:

a Micro Control Unit (MCU) core Control Unit 41 (corresponding to the controller in the above embodiments), an Organic Light-Emitting semiconductor (OLED) display Unit 42, a wifi (Wireless Fidelity) module communication Unit 43, a buzzer 44, an inlet 1 solenoid valve Control Unit 45, an inlet 2 solenoid valve Control Unit 46, an outlet 1 solenoid valve Control Unit 47, an outlet 2 solenoid valve Control Unit 48, a heating Control Unit 49, a refrigeration Control Unit 50, a flow sensor 21, a TDS sensor 22, a temperature sensor 51, a key 52, and a knob 3211.

Wherein, the MCU core control unit 41 can be used to control the working status of each component, the OLED display unit 42 can be used to display the current state of the waterway system (for example, hot water temperature, cold water temperature, remaining filter usage time, etc.), the wifi module communication unit 43 is used to connect the waterway system with other mobile terminals, so that the user can remotely control the waterway system through the mobile terminal or check the current working status of the waterway system through the mobile terminal, the buzzer 44 sends a prompt tone when the water temperature in the waterway system reaches a preset temperature or a problem occurs during the operation of the waterway system, the inlet 1 solenoid valve control unit 45 is used to control the open/close status of the inlet valve 14 corresponding to the first inlet pipe 12, the inlet 2 solenoid valve control unit 46 is used to control the open/close status of the inlet valve 14 corresponding to the second inlet pipe 12, the outlet 1 solenoid valve control unit 47 is used to control the open/close status of the outlet valve 15 corresponding to the first outlet pipe 13, the outlet 2 solenoid valve control unit 48 is used for controlling the open-close state of the outlet valve 15 corresponding to the second outlet pipe 13, the heating control unit 49 is used for controlling the working state of the heating component 23, the refrigeration control unit 50 is used for controlling the working state of the refrigeration module 25, the flow sensor 2121 is used for measuring the water output of the water outlet 112, the TDS sensor 2222 is used for controlling the TDS sensor 22 to detect the water quality in the water storage tank 11, the temperature sensor 51 comprises a first temperature sensor 24 and a second temperature sensor 26, the first temperature sensor 24 is used for measuring the water temperature in the hot water storage tank 115, the second temperature sensor 26 is used for measuring the water temperature in the cold water storage tank 114, and the button 52 comprises: the water inlet 111 and the water outlet 112 are respectively used for selecting the water inlet 111 and the water outlet 112, and the knob 3211 is used for setting the water temperature in the waterway system.

The water path system is connected with a mobile terminal of a user through a wifi module communication unit 43 in the water purifier, so that the user can control and watch the working state of the water path system through the mobile terminal, then, the user selects the water temperatures in the cold water storage tank 114 and the hot water storage tank 115 through a knob 3211 in the control panel 3, the knob 3211 sends a control signal to the MCU core control unit 41, the user selects a key to select the water inlet 111 (for example, select the water inlet 1111) through the water inlet 111 in the control panel 3, the user selects a key to select the water outlet 112 (for example, select the water outlet 1122) through the water outlet 112 in the control panel 3, the MCU core control unit 41 controls the TDS sensor 2222 to measure the water quality in the water storage tank 11, when the water quality is not the water quality of the water source corresponding to the water inlet 1111, the MCU core control unit 41 controls the waste water drain valve 17 to open, so, then the wastewater drainage valve 17 is closed, the MCU core control unit 41 controls the water inlet 1 electromagnetic valve control unit 45 to control the water inlet valve 14 corresponding to the water inlet 1111 to be opened, controls the water outlet 2 electromagnetic valve control unit 48 to control the water outlet valve 15 corresponding to the water outlet 1122 to be opened, controls the heating control unit 49 and the refrigeration control unit to start working, controls the first temperature sensor 24 to measure the water temperature in the hot water storage tank 115 of the hot water storage tank 115, controls the second temperature sensor 26 to measure the water temperature in the cold water storage tank 114, sends the measurement result to the MCU core control unit 41, and controls the buzzer to give an alarm and controls the flow sensor 21 to measure the water outlet amount when the MCU core control unit 41 detects that the water temperatures in the cold water storage tank 114 and the hot water storage tank 115 meet the set water temperature of the user.

Although the above units are not individually shown in the embodiments corresponding to fig. 1 to 6, in practical applications, the above units are also implicitly included in the embodiments corresponding to fig. 1 to 6, and it cannot be assumed that the waterway system in the present disclosure does not include the units in the embodiments corresponding to fig. 1 to 6.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. This application is intended to cover any variations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

It will be understood that the present disclosure is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims

1. A waterway system, comprising:

2. The waterway system of claim 1, further comprising: a waste water drain pipe and a waste water drain valve;

the water storage tank is also provided with a waste water outlet;

3. The waterway system of claim 1, wherein a flow sensor is further disposed inside the storage tank.

4. The waterway system of claim 1, wherein a flow sensor is disposed at each of the water outlets.

5. The waterway system of claim 1, further comprising: a total dissolved solids TDS sensor;

the TDS sensor is located inside the storage tank.

6. The waterway system of claim 1, further comprising: a heating member and a first temperature sensor;

7. The waterway system of claim 6, further comprising: a control panel, the control panel comprising:

a housing;

the water inlet selecting key is used for selecting a water inlet;

the water outlet selection key is used for selecting a water outlet;

8. The waterway system of claim 7, wherein the intake selector assembly further comprises: the water inlet selection indicator lamp and the water inlet selection indicator lamp correspond to each other; the water outlet selection assembly further comprises: the water outlet selection indicator lamp and the identifier corresponding to the water outlet selection indicator lamp;

9. The waterway system of claim 6, further comprising: a touch control screen;

10. The waterway system of claim 1, further comprising: a faucet and a faucet flow meter;

11. The waterway system of claim 6, wherein the storage tank comprises: cold water storage tank and hot water storage tank still include: a refrigeration module and a second temperature sensor;

12. The waterway system of claim 11, further comprising: a hot water inlet valve, a hot water outlet valve, a cold water inlet valve and a cold water outlet valve;

13. The waterway system of claim 11, wherein the refrigeration module comprises: a semiconductor refrigeration device;