WO2022057441A1

WO2022057441A1 - Water purifier control method, control device, electronic apparatus, readable storage medium, and water purifier

Info

Publication number: WO2022057441A1
Application number: PCT/CN2021/108141
Authority: WO
Inventors: 周勇; 吴卫平; 郑跃东
Original assignee: 佛山市顺德区美的饮水机制造有限公司; 美的集团股份有限公司
Priority date: 2020-09-18
Filing date: 2021-07-23
Publication date: 2022-03-24

Abstract

The present invention relates to the field of household appliances, and provides a water purifier control method, a control device, an electronic apparatus, and a readable storage medium. The water purifier control method comprises: acquiring a temperature of a heating system of a water purifier; determining current states of an exhaust valve and the heating system of the water purifier; determining an operation mode of the water purifier; and controlling the exhaust valve and the heating system on the basis of the temperature of the heating system, the current states of the exhaust valve and the heating system, and the operation mode of the water purifier. The water purifier control method further comprises: determining that the water purifier is powered on for the first time, and controlling the water purifier to enter a first-time flushing mode, wherein in the first-time flushing mode, a water drive system is turned on, a first branch loop of the water purifier is disconnected, the heating system of the water purifier is turned off, a waste water valve of the water purifier is opened, and the exhaust valve of the water purifier is closed. The water purifier control method of the embodiment of the present invention comprehensively considers factors including current operation states of the heating system and the exhaust valve, the temperature of the heating system, and the operation mode of the water purifier, and in particular, the current operation states of the heating system and the exhaust valve, such that the supply amount of hot water is ensured while guaranteeing safety.

Description

Water purifier control method, control device, electronic device, readable storage medium, and water purifier

CROSS-REFERENCE TO RELATED APPLICATIONS

This application requires the application number 202010990285.3 filed on September 18, 2020, and the invention title is "Control Method, Control Device, Electronic Device and Readable Storage Medium for Water Purifier" and the application filed on September 18, 2020 The priority of the Chinese patent application No. 202010990283.4 and the invention title is "Control Method, Control Device, Electronic Device and Readable Storage Medium of Water Purifier", which is fully incorporated into this application by reference.

technical field

The present invention relates to the technical field of household appliances, and in particular, to a control method, a control device, an electronic device, a readable storage medium and a water purifier for a water purifier.

Background technique

With the improvement of living standards, people have higher requirements for water quality, and the popularity of water purifiers is also increasing. The raw water (tap water or well water, etc.) input to the water purifier may contain more impurities, such as organic matter or inorganic salt. During use, the water purifier can filter out the impurities in the introduced raw water and output pure water.

In terms of heating drinking water, most of the existing solutions in the market use other heating devices such as kettles and pipeline machines for heating and drinking, which will increase the number of kitchen appliances and occupy kitchen space. The design integrated with the water purification function has entered people's field of vision. For an integrated water purifier, there are many working modes, and correspondingly, the temperature control of the heating system is also more complicated. For an integrated water purifier, there are many working modes, and correspondingly, the temperature control of the heating system is also more complicated.

In an ideal state, users get filtered pure water when using the water purifier, but in actual use, the quality of the first glass of water in the water purifier during use is average.

SUMMARY OF THE INVENTION

The present invention aims to solve at least one of the technical problems existing in the prior art. Therefore, the present invention proposes a control method for a water purifier, which can prevent the pipeline from being blocked when a new machine is in use.

The invention provides a control device of a water purifier.

The present invention provides an electronic device.

The present invention proposes a non-transitory computer-readable storage medium.

The present invention also provides a water purifier.

The method for controlling a water purifier according to an embodiment of the present invention includes: collecting the temperature of the heating system of the water purifier; determining the exhaust valve of the water purifier and the current state of the heating system; determining the water purifier The working mode of the heating system; based on the temperature of the heating system, the current state of the exhaust valve and the heating system, and the working mode of the water purifier, the exhaust valve and the heating system are controlled; wherein, the The water purifier includes a filtering system, a water driving system and the heating system, the water inlet of the heating system is connected to the water purification outlet of the filtering system, and the water driving system is used to drive water from the filtering system. The raw water inlet flows to the purified water outlet, and the exhaust valve is connected between the exhaust outlet of the heating system and the waste water outlet of the water purifier.

The control method of the water purifier according to the embodiment of the present invention comprehensively considers factors such as the current working state of the heating system and the exhaust valve, the temperature of the heating system and the working mode of the water purifier, especially considering the factors of the heating system and the exhaust valve. The current working state can ensure the supply of hot water while ensuring safety.

A control device for a water purifier according to an embodiment of the second aspect of the present invention includes: a temperature collection module for collecting the temperature of the heating system of the water purifier; a state determination module for determining the exhaust valve of the water purifier and the current state of the heating system; a mode determination module for determining the working mode of the water purifier; a control module for based on the temperature of the heating system, the exhaust valve and the current state of the heating system state and the working mode of the water purifier, control the exhaust valve and the heating system; wherein, the water purifier includes a filtering system, a water driving system and the heating system, and the water inlet of the heating system connected with the water purification outlet of the filtration system, the water driving system is used for driving water to flow from the raw water inlet of the filtration system to the purified water outlet, and the exhaust valve is connected to the exhaust port of the heating system between the waste water outlet of the water purifier.

The method for controlling a water purifier according to the embodiment of the third aspect of the present invention includes: determining that the water purifier is powered on for the first time, and controlling the water purifier to enter a first flushing mode, and in the first flushing mode, the water drive system is turned on, The first branch of the water purifier is disconnected, the heating system of the water purifier is closed, the waste water valve of the water purifier is opened, and the exhaust valve of the water purifier is closed; wherein, the purified water The device includes a filtering system, the water driving system and the heating system, the first branch is connected between the water purification outlet of the filtering system and the first water supply port of the water purifier, the heating system Installed on the first branch, the water drive system is used to drive water to flow from the raw water inlet of the filtration system to the purified water outlet, and the waste water valve is connected to the waste water outlet of the filtration system and the purifier. The exhaust valve is connected between the exhaust port of the heating system and the waste water outlet.

According to the control method of the water purifier according to the embodiment of the present invention, by flushing the filtering system separately and discharging the flushing water from the waste water outlet, impurities in the filtering system can be prevented from entering the heating system or subsequent pipelines during initial use.

The control device for a water purifier according to an embodiment of the fourth aspect of the present invention includes: a processing module for determining that the water purifier is powered on for the first time, and controlling the water purifier to enter the first flushing mode, and in the first flushing mode, The water drive system is turned on, the first branch of the water purifier is disconnected, the heating system of the water purifier is turned off, the waste water valve of the water purifier is turned on, and the exhaust valve of the water purifier is turned off; wherein , the water purifier includes a filtering system, the water driving system and the heating system, and the first branch is connected between the water purification outlet of the filtering system and the first water supply port of the water purifier , the heating system is installed in the first branch, the water driving system is used to drive water to flow from the raw water inlet of the filtration system to the purified water outlet, and the waste water valve is connected to the waste water of the filtration system The exhaust valve is connected between the exhaust port of the heating system and the waste water outlet.

An electronic device according to an embodiment of the fifth aspect of the present invention includes a memory, a processor, and a computer program stored in the memory and executable on the processor, and the processor executes the program to implement any one of the above The steps of the control method of the water purifier.

The non-transitory computer-readable storage medium according to the embodiment of the sixth aspect of the present invention stores a computer program thereon, and when the computer program is executed by a processor, implements the steps of any one of the above water purifier control methods.

A water purifier according to an embodiment of the seventh aspect of the present invention includes: a filtration system, the filtration system has a raw water inlet and a purified water outlet; , the water outlet located on the upper part of the heating system is connected to the first water supply port of the water purifier, the exhaust port of the heating system is connected with an exhaust valve, and the heating system is provided with a temperature sensor; , the water drive system is connected to the filter system and is arranged upstream of the water purification outlet, the water drive system is used to drive water from the raw water inlet to the purified water outlet, and is used to drive water from The water outlet of the heating system is discharged; a controller, the controller is electrically connected with the temperature sensor, the exhaust valve and the heating system, and is set to be based on the signal of the temperature sensor, the exhaust gas The current state of the valve and the heating system and the working mode of the water purifier control the exhaust valve and the heating system.

Additional aspects and advantages of the present invention will be set forth, in part, from the following description, and in part will be apparent from the following description, or may be learned by practice of the invention.

Description of drawings

In order to explain the embodiments of the present invention or the technical solutions in the prior art more clearly, the following briefly introduces the accompanying drawings that need to be used in the description of the embodiments or the prior art. Obviously, the accompanying drawings in the following description are only These are some embodiments of the present invention. For those of ordinary skill in the art, other drawings can also be obtained according to these drawings without creative efforts.

1 is a schematic diagram of a water circuit of a water purifier provided by an embodiment of the present invention;

2 is a schematic structural diagram of a water purifier provided in an embodiment of the present invention when placed vertically;

3 is a schematic structural diagram of a water purifier provided in an embodiment of the present invention when placed horizontally;

4 is an exploded view of a water purifier provided by an embodiment of the present invention;

5 is a schematic diagram of the internal structure of a water purifier provided by an embodiment of the present invention;

6 is an exploded view of a filter module and a heating module of a water purifier according to an embodiment of the present invention;

Fig. 7 is the partial enlarged view of E place in Fig. 6;

8 is an exploded view of a filter module of a water purifier provided by an embodiment of the present invention;

Fig. 9 is a partial enlarged view at F in Fig. 8;

10 is a schematic structural diagram of a filtering water circuit board of a water purifier according to an embodiment of the present invention;

11 is an exploded view of a heating module of a water purifier according to an embodiment of the present invention;

Fig. 12 is a partial enlarged view of G in Fig. 11;

13 is a schematic structural diagram of a heating system of a water purifier according to an embodiment of the present invention;

14 is an exploded view of a heating system of a water purifier provided by an embodiment of the present invention;

15 is a schematic structural diagram of a heating system of a water purifier provided in an embodiment of the present invention when placed vertically;

16 is a schematic structural diagram of a heating system of a water purifier provided in an embodiment of the present invention when placed horizontally;

17 is a schematic structural diagram of a water outlet waterway plate of a water purifier according to an embodiment of the present invention;

18 is a schematic structural diagram of the water purifier provided by the embodiment of the present invention after the valve is installed on the outlet waterway plate of the water purifier;

19 is a schematic structural diagram from another perspective after the valve is installed on the outlet waterway plate of the water purifier provided by the embodiment of the present invention;

20 is a schematic structural diagram from another perspective after the valve is installed on the outlet waterway plate of the water purifier provided by the embodiment of the present invention;

21 is a schematic diagram of the control logic of the heating system and the exhaust valve when the water purifier provided by the embodiment of the present invention is not producing water;

22 is a schematic diagram of the control logic of the heating system and the exhaust valve when the water purifier provided by the embodiment of the present invention is producing water;

23 is a schematic flowchart of a control method for a water purifier provided by an embodiment of the present invention;

24 is a schematic structural diagram of a control device for a water purifier provided by an embodiment of the present invention;

25 is a schematic flowchart of a control method for a water purifier provided by another embodiment of the present invention;

26 is a schematic structural diagram of a control device for a water purifier provided by another embodiment of the present invention;

FIG. 27 is a schematic structural diagram of an electronic device according to an embodiment of the present invention.

Reference number:

Filtration system 100, raw water inlet 101, water pump inlet 102, water pump outlet 103, waste water outlet 104, water purification outlet 105, filter water circuit board 110, pipe body 111, support 112, connecting arm 113, first port 121a, first port 121a, first port 121a The second port 122a, the third port 123a, the fourth port 124a, the fifth port 125a, the sixth port 121b, the seventh port 122b, the eighth port 122c, the ninth port 123b, the tenth port 124b, the eleventh port 124c, The twelfth mouth 125b;

Heating system 200, tank body 210, bottom surface 211, first side surface 212, tank body 213, upper end cover 214, lower end cover 215, water inlet 221, water outlet 222, exhaust port 223, terminal avoidance hole 224, temperature sensor Installation hole 225, water inlet pipe 226, water outlet pipe 227, exhaust pipe 228, tank assembly bracket 229, heating pipe 230, wiring terminal 231, thermostat fixing bracket 250;

The first bracket 310, the connecting arm mounting hole 311, the first flange 312, the tube body avoidance hole 313, and the positioning column 314;

The second bracket 320, the first connection structure 321, the second flange 322, the installation cavity 323, the sleeve 324, the first board 325, the second board 326, and the wiring groove 327;

The protective cover 400, the cover plate 410, the second connection structure 411, the notch 412, the water blocking plate 420, the main body section 421, the avoidance section 422, the water blocking rib 423, the wire opening 424, the guide rib 425;

Water pump 510, first branch 520, second branch 530, return pipe 540, safety branch 550, water purification check valve 561, water purification control valve 562, return water check valve 563, return water control valve 564, Exhaust check valve 565, exhaust valve 566, waste water valve 567, water pump inlet valve 568, water leakage protection valve 569;

Raw water inlet 601, waste water outlet 602;

Case 701, front case 702, upper cover 703, top cover 704, base 705, decorative plate 706, power adapter 707, display 708, electric control box 709, power board 710, TDS detection probe 711, pressure rod 712;

faucet 800;

Outlet waterway plate 900, base plate 910, mounting structure 911, first water pipe 921, first inlet 921a, first outlet 921b, first port 921c, second port 921d, second water pipe 922, second inlet 922a, second outlet 922b, the third water pipe 923, the third inlet 923a, the third outlet 923b, the fourth water pipe 924, the fourth inlet 924a, the fourth outlet 924b, the fifth water pipe 935, the fifth inlet 935a, the fifth outlet 935b, the fifth interface 935c, sixth water pipe 936, sixth inlet 936a, sixth outlet 936b, seventh water pipe 947, seventh inlet 947a, seventh outlet 947b, eighth water pipe 958, eighth inlet 958a, eighth outlet 958b;

The first direction A, the second direction B, and the third direction C.

detailed description

The embodiments of the present invention will be described in further detail below with reference to the accompanying drawings and examples. The following examples are intended to illustrate the present invention, but not to limit the scope of the present invention.

In the description of the embodiments of the present invention, it should be noted that the terms "center", "portrait", "horizontal", "top", "bottom", "front", "rear", "left", "right" , "vertical", "horizontal", "top", "bottom", "inside", "outside", etc. indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, only for the convenience of describing this Inventive embodiments and simplified descriptions are not intended to indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operate in a particular orientation, and therefore should not be construed as limiting the embodiments of the present invention. Furthermore, the terms "first", "second", and "third" are used for descriptive purposes only and should not be construed to indicate or imply relative importance.

In the description of the embodiments of the present invention, it should be noted that, unless otherwise expressly specified and limited, the terms "connected" and "connected" should be understood in a broad sense, for example, it may be a fixed connection or a detachable connection, Or integral connection; it can be mechanical connection or electrical connection; it can be directly connected or indirectly connected through an intermediate medium. Those of ordinary skill in the art can understand the specific meanings of the above terms in the embodiments of the present invention in specific situations.

In the embodiments of the present invention, unless otherwise expressly specified and limited, the first feature "above" or "under" the second feature may be in direct contact with the first and second features, or the first and second features pass through the middle indirect contact with the media. Also, the first feature being "above", "over" and "above" the second feature may mean that the first feature is directly above or obliquely above the second feature, or simply means that the first feature is level higher than the second feature. The first feature being "below", "below" and "below" the second feature may mean that the first feature is directly below or obliquely below the second feature, or simply means that the first feature has a lower level than the second feature.

In the description of this specification, description with reference to the terms "one embodiment," "some embodiments," "example," "specific example," or "some examples", etc., mean specific features described in connection with the embodiment or example , structures, materials, or features are included in at least one example or example of embodiments of the present invention. In this specification, schematic representations of the above terms are not necessarily directed to the same embodiment or example. Furthermore, the particular features, structures, materials or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, those skilled in the art may combine and combine the different embodiments or examples described in this specification, as well as the features of the different embodiments or examples, without conflicting each other.

The water purifier according to the embodiment of the present invention will be described below with reference to FIGS. 1 to 22 . The water purifier disclosed in the embodiment of the present invention may be a household water purifier, for example, an under-kitchen water purifier.

As shown in FIGS. 1-6 , the water purifier according to the first embodiment of the present invention includes: a filtering system 100 , a heating system 200 and a water pump 510 .

The filtration system 100 has a raw water inlet 101 and a purified water outlet 105, and the raw water inlet 101 can be directly or indirectly connected to a raw water pipe, for example, the raw water pipe can be a tap water pipe. The raw water to be filtered flows into the filtration system 100 from the raw water inlet 101, and then flows out pure water from the purified water outlet 105 after being filtered.

The heating system 200 has a water inlet 221 and a water outlet 222. The water inlet 221 of the heating system 200 is connected to the water purification outlet 105 of the filtration system 100, and the water outlet 222 of the heating system 200 is connected to the first water supply outlet of the water purifier. The heating system 200 is used to heat the water flowing through the heating system 200 .

The water pump 510 is connected to the filtering system 100, and the water pump 510 is arranged upstream of the water purification outlet 105 of the filtering system 100. 510 is used to drive water out of the water outlet 222 of the heating system 200 .

In other words, in one of the working modes of the water purifier, the raw water flows into the filtration system 100 from the raw water inlet 101 of the filtration system 100 , and under the driving of the water pump 510 , it is filtered and then flows out pure water from the water purification outlet 105 of the filtration system 100 . Water, the pure water flowing out from the water purification outlet 105 of the filtration system 100 flows into the heating system 200 from the water inlet 221 of the heating system 200. After being heated, driven by the water pump 510, the pure water flows into the pure water from the water outlet 222 of the heating system 200. The first water supply port of the appliance, so as to supply hot water.

As shown in FIG. 1 , the lower portion of the heating system 200 is provided with a water inlet 221 , and the upper portion of the heating system 200 is provided with a water outlet 222 . In other words, the filtered pure water flows into the heating system 200 from the lower part of the heating system 200 to be heated.

It can be understood that, after the pure water entering the heating system 200 is heated, the density of the hot water is relatively small and floats up, and the density of the cold water is relatively large and sinks.

In addition to driving the raw water to flow from the raw water inlet 601 to the purified water outlet 105 for filtering, the water pump 510 can also drive hot water to be discharged from the water outlet 222 of the heating system 200 .

In other words, the water pump 510 is both the driving pump of the filtering system 100 and the driving pump of the heating system 200. The hot water in the embodiment of the present invention is not extracted from the heating system 200 by designing an independent water pump, but is shared with the filtering system 100. The water pump 510 forms a water pressure difference between the water inlet 221 and the water outlet 222 of the heating system 200, and pushes the upper hot water to the first water supply port of the water purifier through the water pressure difference, so that the introduction of external air can be avoided. The waterway of the water purifier prevents secondary pollution.

As shown in FIG. 1 , the return pipe 540 is connected between the clean water outlet 105 and the inlet of the water pump 510 . When the water purifier is just turned on, when the water pump 510 is working, the pure water from the water purification outlet 105 can be sucked into the water pump 510 again through the return pipe 540. The purified water can re-enter the filtration system 100 for at least one stage of filtration.

In other words, when the return pipe 540 is connected, the first cup of water with insufficient quality can be prevented from flowing out, and the quality of the water introduced into the filtration system 100 is enhanced, so that the purified water of the water purification outlet 105 of the filtration system 100 has a higher quality. Especially for the first glass of water, by arranging the water return pipe 540, the quality of the first glass of water can be greatly improved.

The water purifier according to the embodiment of the present invention integrates the functions of water purification and heating. The water inlet 221 is arranged at the lower part of the heating system 200 and the water outlet 222 is arranged at the upper part of the heating system 200, and the push-type water outlet method of the water pump 510 is combined. , which can prevent the outside air from being introduced into the waterway of the water purifier and prevent secondary pollution. By setting the water return pipe 540 , the quality of the first glass of water can be greatly improved.

In some embodiments, as shown in FIG. 1 , the return water pipe 540 is provided with a return water control valve 564, and the return water control valve 564 is used to control the conduction state of the return water pipe 540. The water control valve 564 can be electrically connected to the controller of the water purifier, and the water purifier is set to open the return water control valve 564 for a preset time every time the water purifier is turned on, and the preset time can be 5s-25s, such as 10s.

In some embodiments, as shown in FIG. 1 , the return pipe 540 is provided with a return check valve 563 and a return control valve 564 . The return water control valve 564 is used to control the conduction state of the return water pipe 540, the return water control valve 564 can be a solenoid valve, and the return water one-way valve 563 can prevent the water that has not been completely filtered from directly flowing into the purified water outlet 105 through the return water pipe 540. Or the first water supply port.

The water purifier has a fresh water return mode. In the fresh water return mode, the water pump 510 and the return water control valve 564 are turned on. The water purifier is set to start the backflow fresh water mode every time the water purifier is powered on, and lasts for a preset time, and the preset time can be 5s-25s, such as 10s.

In some embodiments, as shown in FIG. 1 , the heating system 200 has an exhaust port 223 , and the water purifier further includes: a safety branch 550 . The safety branch 550 is connected between the exhaust port 223 of the heating system 200 and the water purifier. between the waste water outlet 602.

The safety branch circuit 550 is used to release the pressure through the exhaust port 223 and the safety branch circuit 550 when the pressure in the heating system 200 is too high, and the steam or water discharged during the pressure release can be discharged through the waste water outlet 602 of the water purifier.

As shown in FIG. 1 , the safety branch 550 may be provided with an exhaust one-way valve 565 and an exhaust valve 566 , and the exhaust one-way valve 565 conducts unidirectionally from the exhaust port 223 of the heating system 200 to the waste water outlet 602 . The exhaust valve 566 is used to control the conduction state of the safety branch 550, the exhaust valve 566 can be a solenoid valve, and the exhaust valve 566 can be electrically connected with the controller of the water purifier, or the exhaust valve 566 can be a pressure valve , the exhaust one-way valve 565 can prevent waste water from flowing back into the heating system 200 .

When hot water needs to be used, the exhaust valve 566 is closed, and the heating system 200 is in a closed state at this time, and the hot water can be pushed out from the water outlet 222 from bottom to top by the water pressure of the water pump 510 .

When it is necessary to discharge pressure or discharge old water, the discharge valve 566 is opened, and the water pressure of the water pump 510 can push the hot water out of the water outlet from the bottom to the top.

As shown in FIGS. 1-6 , the water purifier according to the second embodiment of the present invention includes: a filtering system 100 , a heating system 200 and a water pump 510 .

The filtration system 100 has a raw water inlet 101 and a purified water outlet 105, and the raw water inlet 101 can be directly or indirectly connected to a raw water pipe, for example, the raw water pipe can be a tap water pipe. The raw water to be filtered flows into the filtration system 100 from the raw water inlet 101 , and then flows out pure water from the purified water outlet 105 after being filtered.

The heating system 200 has a water inlet 221, a water outlet 222 and an exhaust outlet 223. The water inlet 221 of the heating system 200 is connected to the water purification outlet 105 of the filtration system 100, and the water outlet 222 of the heating system 200 is connected to the first water supply of the water purifier. mouth connected.

An exhaust valve 566 is connected to the exhaust port 223 of the heating system 200 .

When hot water needs to be used, the exhaust valve 566 is closed, and the heating system 200 is in a closed state at this time, and the hot water can be pushed out from the water outlet 222 from bottom to top by the water pressure of the water pump 510 . The exhaust valve 566 can prevent outside air from entering the heating system 200 and causing secondary pollution.

The air outlet 223 of the heating system 200 is positioned higher than the water outlet 222 of the heating system 200 .

In this way, the pressure at the air outlet 223 is lower than the pressure at the water outlet 222, which can prevent the air discharge valve 566 from being opened by mistake, and the steam accumulates on the top of the heating system 200, and the water outlet 222 is set at a position lower than the air outlet 223, It can prevent the steam from being discharged from the water outlet 222 and splashing the user, and setting the exhaust port 223 at the top is convenient for exhausting.

The water purifier according to the embodiment of the present invention integrates the functions of water purification and heating. The exhaust port 223 of the drain valve can form a closed heating system 200, and combined with the push-type water outlet method of the water pump 510, it can prevent the outside air from being introduced into the waterway of the water purifier and prevent secondary pollution.

In some embodiments, as shown in FIG. 1 , the water purifier of the embodiment of the present invention may include an exhaust one-way valve 565 that passes from the exhaust port 223 of the heating system 200 to the waste water of the water purifier. The outlet 602 conducts in one direction, and the exhaust one-way valve 565 can prevent waste water from being poured into the heating system 200 .

The exhaust check valve 565 may be disposed between the exhaust valve 566 and the exhaust port 223 , or the exhaust valve 566 may be disposed between the exhaust check valve 565 and the exhaust port 223 .

In some embodiments, as shown in FIG. 1 , the water purifier may further include: a water return pipe 540 connected between the water purification outlet 105 and the inlet of the water pump 510 .

When the water purifier is just turned on, when the water pump 510 is working, the pure water from the water purification outlet 105 can be sucked into the water pump 510 again through the return pipe 540. The purified water can re-enter the filtration system 100 for at least one stage of filtration.

In some embodiments, as shown in FIG. 1 , the return pipe 540 is connected to a position close to the second water supply port of the water purifier. For example, in the outlet water circuit board 900 shown in FIG. 17 , the second interface 921d of the first water pipe 921 is disposed at a position close to the first outlet 921b of the first water pipe 921 . In this way, in the fresh water return mode, the pure water remaining in the pipeline can be pumped to the inlet of the water pump 510 as much as possible.

As shown in FIGS. 1-12 , the water purifier according to the third embodiment of the present invention includes: a first support 310 , a filtering system 100 , a second support 320 and a heating system 200 .

The filter system 100 is mounted on the first bracket 310 , the first bracket 310 defines an installation space for installing the filter system 100 , and the first bracket 310 provides a support frame of the filter system 100 .

The heating system 200 is mounted on the second bracket 320 , the second bracket 320 defines an installation space for installing the heating system 200 , and the second bracket 320 provides a support frame of the heating system 200 .

The heating system 200 has a water inlet 221 and a water outlet 222. The water inlet 221 of the heating system 200 is connected to the water purification outlet 105 of the filtration system 100, and the water outlet 222 of the heating system 200 is connected to the first water supply outlet of the water purifier.

The second bracket 320 is detachably connected with the first bracket 310 . For example, the second bracket 320 and the first bracket 310 may be connected through a screw connection, or through a snap connection structure, or through a magnetic attraction structure.

In this way, the structure design of the water purifier is simple, and multiple different types of water purifiers can share the first bracket 310 and the filtering system 100. For example, for different types of water purifiers, only the second bracket 320 and the corresponding The first support 310, the filter system 100 and the second support 320 can even be shared by multiple different types of water purifiers. For example, for different types of water purifiers, only the corresponding heating system 200 can be redesigned.

In the related art, when designing a multifunctional water purifier, it is necessary to redesign the overall bracket for each type of multifunctional water purifier. Rearranging the structure and designing the brackets respectively makes the development cycle of the two product lines long and the cost of mold investment high.

Due to the water purifier of the embodiment of the present invention, separate supports are designed for the filter system 100 and the heating system 200, so that when facing different types of water purifiers, the design related to the filter system 100 can be retained to the greatest extent, and the realization of common use of modules.

According to the water purifier of the embodiment of the present invention, by separately designing detachable and connected brackets for the filtering system 100 and the heating system 200, the development cost and the development cycle can be shortened.

In some embodiments, as shown in FIGS. 6 , 7 , 8 and 11 , one of the second bracket 320 and the first bracket 310 is provided with a sleeve 324 , and the second bracket 320 and the first bracket 310 are provided with a sleeve 324 . The other is provided with a positioning post 314 which extends into the sleeve 324 .

The axial direction of the sleeve 324 and the positioning column 314 is the direction A in the figure. When the first bracket 310 and the second bracket 320 are aligned, the sleeve 324 is facing the positioning column 314, and the positioning column 314 is inserted into the sleeve 324. The positioning and assembling of the first bracket 310 and the second bracket 320 can be realized.

The sleeves 324 and the positioning posts 314 are in one-to-one correspondence, and the multiple sleeves 324 and the multiple positioning posts 314 are distributed at the top corners and the middle area of the second bracket 320 and the first bracket 310 . For example, in the embodiments shown in FIGS. 6 , 7 , 8 and 11 , the five positioning posts 314 are distributed at the four apex corners of the first bracket 310 and the middle edge of the direction B, and the five sleeves 324 are distributed in the The four top corners of the second bracket 320 and the middle edge of the direction B. In this way, the positioning of the first bracket 310 and the second bracket 320 is accurate in various places, and relative deviation is unlikely to occur.

The first bracket 310 and the second bracket 320 can be connected through a threaded connection, and the positioning post 314 can have an inner thread hole. The fixed connection between the first bracket 310 and the second bracket 320 can be realized.

As shown in FIGS. 1-6 , the water purifier according to the fourth embodiment of the present invention includes: a filtering system 100 , a heating system 200 , a water pump 510 and a casing.

The water pump 510 is connected to the filtration system 100, and the water pump 510 is arranged upstream of the water purification outlet 105 of the filtration system 100. 510 is used to drive water out of the water outlet 222 of the heating system 200 .

As shown in FIG. 1 , in some embodiments, the lower portion of the heating system 200 is provided with a water inlet 221 , and the upper portion of the heating system 200 is provided with a water outlet 222 . In other words, the filtered pure water flows into the heating system 200 from the lower part of the heating system 200 to be heated.

As shown in FIG. 2 and FIG. 3 , the filter system 100 , the water pump 510 and the heating system 200 are disposed in a housing, and the housing defines an accommodation space for installing the filter system 100 , the water pump 510 and the heating system 200 .

As shown in FIG. 2 and FIG. 3 , the casing can be in the shape of a cuboid, and the length direction of the casing can be the first direction, namely the direction A in the figure; the height direction of the casing can be the second direction, namely the direction B in the figure; The width direction of can be the third direction, namely the direction C in the figure. The first direction, the second direction and the third direction are perpendicular to each other.

As shown in Figures 4-6, the filter system 100, the water pump 510 and the heating system 200 are arranged side by side along the first direction of the housing, and the length direction of the filter system 100, the water pump 510 and the heating system 200 is along the second direction of the housing.

In this way, the arrangement of the filtering system 100, the water pump 510 and the heating system 200 is compact and the space utilization rate is high, so that the water purifier occupies a small space and is convenient to be arranged in a small space, such as a cabinet.

The water purifier according to the embodiment of the present invention integrates the functions of water purification and heating, and the push-type water outlet method of the water pump 510 can prevent the outside air from being introduced into the waterway of the water purifier and prevent secondary pollution. The parallel arrangement of 510 and the heating system 200 has compact arrangement and high space utilization.

In some embodiments, as shown in FIGS. 5 and 6 , the water pump 510 is provided between the filtration system 100 and the heating system 200 .

It can be understood that, in this embodiment, for the higher-priced water pump 510, the filtering system 100 and the heating system 200 can both protect the water pump 510, and the water pump 510 is located between the filtering system 100 and the heating system 200, Equivalent to being located in the middle area of the entire water purifier, the noise of the working of the water pump 510 can be effectively isolated by utilizing the blocking effect of other peripheral structures.

In some embodiments, as shown in FIG. 6 and FIG. 8 , the water purifier further includes: a filter water circuit board 110 , each of the water ports of the filter system 100 and the water pump 510 is connected to the filter water circuit board 110 , and the water pump 510 passes through the filter water circuit board 110 . The filter system 100 is connected, and the filter system 100 is connected to the heating system 200 and the external water circuit through the filter water circuit board 110 . In this way, there is no need to set too many pipelines on the filter system 100 side, which facilitates pipeline arrangement.

The filtering water circuit board 110 is located between the filtering system 100 and the heating system 200 . In this way, the filtering system 100 and the heating system 200 can be fully utilized to protect the filtering water circuit board 110 and prevent water leakage caused by the impact damage of the filtering water circuit board 110 .

In some embodiments, as shown in FIGS. 6 and 8 , the filtering water circuit board 110 and the water pump 510 are arranged side by side along the second direction, and the filtering water circuit board 110 is installed at one end of the water pump 510 in the length direction. The filtering water circuit board 110 and the water pump 510 are arranged along the direction B. In this way, the space between the filtering system 100 and the heating system 200 is fully utilized, and the structure of the entire water purifier is compact.

In some embodiments, as shown in FIG. 8 , each nozzle of the filtration system 100 is arranged side by side along the third direction of the housing, and each nozzle of the filtration system 100 is arranged opposite to the filter water channel plate 110 along the second direction. In this way, during assembly, each nozzle of the filtration system 100 is docked with the filtration water circuit board 110 along the second direction, so as to realize the assembly of the filtration system 100 and the filtration water circuit board 110, and the assembly is simple and not easy to make mistakes.

In some embodiments, as shown in FIG. 2 , one end of the housing in the second direction is provided with an opening, the opening is disposed opposite to the filter system 100 , and the opening is used for disassembling the filter system 100 . During actual use, the filter element of the filter system 100 can be removed from the opening by disassembling the pressing rod 712, so as to facilitate the replacement of the filter element.

In some embodiments, as shown in FIG. 6 and FIG. 11 , the water purifier may further include: an outlet water circuit board 900 , each nozzle of the heating system 200 is connected to the water outlet water circuit board 900 , and the outlet water circuit board 900 is connected to the heating system 200 along the The second direction is relatively set.

In this way, during assembly, the arrangement of pipelines can be reduced, and space can be saved by arranging the outlet water circuit board 900 and the heating system 200 opposite to each other along the second direction.

As shown in FIGS. 1-6 , the water purifier according to the fifth embodiment of the present invention includes: a filter module and a heating module.

The filter module has a raw water inlet 101 and a purified water outlet 105, and the raw water inlet 101 can be directly or indirectly connected to a raw water pipe, for example, the raw water pipe can be a tap water pipe. The raw water to be filtered flows into the filtration system 100 from the raw water inlet 101 , and then flows out pure water from the purified water outlet 105 after being filtered.

As shown in FIG. 11 , the heating module includes: a second bracket 320 , a heating system 200 and a protective cover 400 .

The second bracket 320 defines an installation cavity 323 with an open end, and the heating system 200 is installed in the installation cavity 323. For example, the installation cavity 323 can be a rectangular parallelepiped, and one side of the installation cavity 323 is open, so that the heating system 200 can be easily installed into the installation cavity 323. Cavity 323 is installed.

The connection terminal 231 of the heating system 200 faces the open end, the protective cover 400 is connected to the second bracket 320, the protective cover 400 covers the open end, and the protective cover 400 can be made of flame retardant material, such as nylon + glass fiber or 5VA grade ABS ( Acrylonitrile (A), butadiene (B), styrene (S) terpolymer of three monomers) and the like.

It should be noted that the heating system 200 is of an electric heating type, and the terminal 231 of the heating system 200 is the heat risk accumulation area of the heating system 200. By designing the heating module of the above structure, when the heating system 200 catches fire, it is possible to prevent the heating system 200 from catching fire. The fire spreads outward, which improves product reliability and reduces the risk of fire.

As shown in FIGS. 11 and 12 , the protective cover 400 includes a cover plate 410 and a water blocking plate 420 . The water blocking plate 420 protrudes toward the installation cavity 323 , the water blocking plate 420 extends into the installation cavity 323 , and the water blocking plate 420 is used to prevent External water flows into the installation cavity 323 . For example, when the pipeline bursts, the water blocking plate 420 can prevent water from directly flowing into the installation cavity 323 and prevent the connection terminals 231 of the heating system 200 from being short-circuited.

The second bracket 320 is provided with a first connection structure 321 , the cover plate 410 is provided with a second connection structure 411 , the second connection structure 411 is connected with the first connection structure 321 so that the cover plate 410 covers the open end, and the second connection structure 411 It is arranged on the outer side of the water blocking plate 420 .

Since the connection structure is arranged outside the water blocking plate 420 , water can be prevented from infiltrating into the installation cavity 323 from the connection structure.

According to the heating module of the embodiment of the present invention, by arranging the protective cover 400 on the side of the terminal 231 of the heating system 200, when the heating system 200 catches fire, the fire can be prevented from spreading outward. A connection structure is provided on the outside of 420, which can prevent water from infiltrating into the installation cavity 323 from the connection, and the product has high reliability and is not easy to catch fire.

The second bracket 320 is connected to the filter module, the heating system 200 has a water inlet 221 and a water outlet 222, the water inlet 221 of the heating system 200 is connected to the water purification outlet 105 of the filter module, and the water outlet 222 of the heating system 200 is connected to the purified water connected to the first water supply port of the device. The heating system 200 is used to heat the water flowing through the heating system 200 .

The water purifier according to the embodiment of the present invention integrates water purification and heating functions, and is provided with structures such as a protective cover 400 and a water blocking plate 420, which can effectively reduce the short-circuit risk of the water purifier and improve thermal protection performance.

In some embodiments, as shown in FIG. 9 , the filter module may include a first bracket 310 and a filter system 100 , the filter system 100 is mounted on the first bracket 310 , and the filter system 100 has a raw water inlet 101 and a purified water outlet 105 . The inlet 101 can be directly or indirectly connected to a raw water pipe, for example, the raw water pipe can be a tap water pipe. The raw water to be filtered flows into the filtration system 100 from the raw water inlet 101 , and then flows out pure water from the purified water outlet 105 after being filtered.

The second bracket 320 is detachably connected with the first bracket 310 .

That is to say, in the water purifier of the embodiment of the present invention, separate supports are designed for the filter system 100 and the heating system 200, so that when faced with water purifiers of different heating models, the relevant information of the filter system 100 can be retained to the greatest extent. It can reduce the development cost and shorten the development cycle by realizing the sharing of modules.

The following continues to describe the heating module of the embodiment of the present invention.

In some embodiments, as shown in FIG. 11 , the open end of the second bracket 320 is provided with a protruding first plate 325 and a second plate 326 , the water blocking plate 420 is located on the inner side of the first plate 325 , and the second plate 326 is located on the outer side of the first board 325 , and a wiring groove 327 is defined between the first board 325 and the second board 326 , and the cover plate 410 covers the wiring groove 327 .

It can be understood that the first plate 325 is used to cooperate with the water blocking plate 420, the second plate 326 is located outside the first plate 325, and the second plate 326 is spaced apart from the first plate 325, so that the second plate 326 and the A wiring groove 327 is formed between a plate 325 , and the cables drawn from the heating system 200 can be arranged along the wiring groove 327 after being drawn out of the installation cavity 323 , and the cover plate 410 extends outward relative to the water blocking plate 420 for a section. Covering the wiring slot 327 makes the structure of the heating module neater.

In some embodiments, as shown in FIG. 12 , the outer side of the water blocking plate 420 is provided with a protruding guide rib 425 , and the guide rib 425 extends in a direction away from the cover plate 410 and gradually decreases in height.

The height of the guide rib 425 gradually decreases from the direction close to the cover plate 410 to the direction away from the cover plate 410 , so that when the protective cover 400 is installed on the second bracket 320 , the guide rib 425 is gradually squeezed, so that the protective cover 400 is connected to the second bracket 320 . The bracket 320 forms an interference fit structure, and the gradient height of the guide ribs 425 facilitates assembly.

The water retaining plate 420 can be a quadrilateral enclosed structure (each side can be designed with a gap or cut off according to needs), each side can be provided with guide ribs 425, and some sides can be provided with multiple guide ribs 425.

In some embodiments, as shown in FIG. 12 , at least one section of the water blocking plate 420 includes a main body section 421 and an avoidance section 422 , the avoidance section 422 is recessed toward the middle of the protective cover 400 relative to the main body section 421 , and the main body section 421 and the avoidance section 422 are connected through a connecting plate, and the second connecting structure 411 is disposed opposite to the avoidance section 422 .

It should be noted that the provision of the avoidance section 422 recessed toward the middle can form a groove on the outer circumferential side of the water baffle 420 , and the groove can be used to accommodate the second connection structure 411 , so that the accommodating cavity of the second bracket 320 In the case of a certain volume, the protective cover 400 can be made as small as possible because the installation space of the second connection structure 411 outside the water blocking plate 420 is not considered, and the structure of the entire heating module is more compact.

In some embodiments, as shown in FIG. 12 , the outer surface of the main body section 421 is provided with a protruding water retaining rib 423 . The water retaining ribs 423 are used to further prevent water from flowing into the installation cavity 323 from the main body section 421 .

As shown in FIG. 12 , the main body section 421 is provided with a wire passage opening 424, and a part of the water retaining rib 423 extends along the edge of the wire passage opening 424. The wire passage opening 424 may be disposed at one end of the main body section 421 away from the cover plate 410, and is in the form of a notch. The cable opening 424 is used to lead out the cables of the heating system 200 .

In some embodiments, as shown in FIG. 12 , a protruding guide rib 425 is provided on the outer side of the main body section 421 . The guide rib 425 extends in a direction away from the cover plate 410 and gradually decreases in height. The two ends are respectively connected with two spaced apart guide ribs 425 .

The height of the guide ribs 425 gradually decreases from the direction close to the cover plate 410 to the direction away from the cover plate 410 , so that when the protective cover 400 is installed on the second bracket 320 , the guide ribs 425 are gradually compressed, so that the protective cover 400 and the second bracket 320 forms an interference fit structure, and the gradient height of the guide ribs 425 facilitates assembly.

In some embodiments, as shown in FIG. 12 , the second connection structure 411 is a buckle. Correspondingly, the first connection structure 321 includes a bayonet, and the buckle can extend into the bayonet to form a buckle.

As shown in FIG. 12 , a gap 412 is provided between the second connection structure 411 and the connection plate, and a reinforcing rib is provided on the side of the second connection structure 411 away from the connection plate. In this way, the second connection structure 411 has good elasticity and sufficient strength, and is not easily broken.

Of course, the first connection structure 321 and the second connection structure 411 may be screw connections, which will not be repeated here.

In some embodiments, the five walls of the installation cavity 323 surround the heating system 200, which can play a certain role of heat preservation. The second bracket 320 can be made of a fireproof and thermal insulation material, such as nylon+glass fiber or 5VA grade ABS (a terpolymer of three monomers of acrylonitrile (A), butadiene (B), and styrene (S). )Wait.

As shown in FIG. 1 , FIG. 13 to FIG. 16 , the water purifier according to the sixth embodiment of the present invention includes: a filtering system 100 and a heating system 200 .

The heating system 200 of the embodiment of the present invention will be described below with reference to FIGS. 13-16 .

As shown in FIG. 14 , the heating system 200 according to the embodiment of the present invention includes: a tank body 210 and a heating tube 230 .

The heating pipe 230 is installed in the tank body 210 , and the heating pipe 230 can be of an electric heating type. When the heating pipe 230 is energized, the water in the tank body 210 can be heated.

As shown in FIG. 15 , when the heating system 200 is placed vertically, the bottom surface 211 of the can body 210 faces downward. As shown in FIG. 16 , when the heating system 200 is placed horizontally, the first side surface 212 of the can body 210 faces downward.

The tank 210 has a water inlet 221 and a water outlet 222, the distance from the water outlet 222 to the bottom surface 211 is greater than the distance from the water inlet 221 to the bottom surface 211, and the distance from the water outlet 222 to the first side 212 is greater than the distance from the water inlet 221 to the first side 212. distance. The first side surface 212 is adjacent to the bottom surface 211 .

In this way, when placed vertically, the water outlet 222 is located above the water inlet 221 , and when placed horizontally, the water outlet 222 is still located above the water inlet 221 .

It can be understood that, after the water entering the heating system 200 is heated, the density of the hot water is relatively small and floats up, and the density of the cold water is relatively large and sinks.

In other words, the heating system 200 of the embodiment of the present invention can ensure that the temperature of the outlet water is sufficiently high whether it is placed vertically or horizontally. In this way, the heating system 200 can select an appropriate placement direction according to a specific installation environment, and has a wider application range.

According to the heating system 200 according to the embodiment of the present invention, by designing the distance between the water inlet and outlet to the bottom surface 211 and the first side surface 212, the heating system 200 can ensure the water outlet temperature regardless of whether it is placed vertically or horizontally, and has a wider application range .

FIG. 2 is a schematic structural diagram of a water purifier according to an embodiment of the present invention when placed vertically, and FIG. 3 is a schematic structural diagram of a water purifier according to an embodiment of the present invention when placed horizontally. The water purifier adopts the heating system of the above-mentioned embodiment. 200, the installation direction can be selected according to the actual installation environment, especially when the water purifier is installed in the narrow space under the cabinet, the adaptability is stronger.

The water purifier according to the embodiment of the present invention integrates the functions of water purification and heating, and can be installed vertically or horizontally according to the actual installation environment, without affecting the water outlet temperature.

In some embodiments, as shown in FIG. 1 , the water purifier may further include a water pump 510 , the water pump 510 is connected to the filtration system 100 , and the water pump 510 is arranged upstream of the water purification outlet 105 of the filtration system 100 , and the water pump 510 is used for driving The water flows from the raw water inlet 101 of the filtration system 100 to the purified water outlet 105 of the filtration system 100 , and the water pump 510 is used to drive the water to be discharged from the water outlet 222 of the heating system 200 .

The following continues to describe the heating system 200 of the embodiment of the present invention.

In some embodiments, as shown in FIG. 14 , the water inlet 221 and the water outlet 222 may be respectively arranged at diagonal positions on the front surface of the heating system, and the front surface is adjacent to the first side surface 212 and the bottom surface 211 . In this way, the water inlet 221 is close to the bottom surface 211, and the water outlet 222 is close to the top surface. After the water flows into the tank body 210 from the water inlet 221, it can be fully heated, and the temperature of the water flowing out from the water outlet 222 is high enough to be not easily affected by the water flow of the water inlet 221. .

Of course, the water inlet 221 and the water outlet 222 can also be arranged at other positions, for example, the water inlet 221 can be arranged at the lower left corner of the front surface, and the water outlet 222 can be arranged at one of the top corners of the top surface, which is close to the front surface. top right corner.

In some embodiments, as shown in FIGS. 13-16 , the heating system 200 includes a water inlet pipe 226 and a water outlet pipe 227 , the water inlet pipe 226 is inserted into the water inlet 221 , and a part of the water inlet pipe 226 protrudes outside the tank body 210 , To facilitate connection with other pipelines, the water outlet pipe 227 is inserted into the water outlet 222, and a part of the water outlet pipe 227 protrudes outside the tank body 210 to facilitate connection with other pipelines.

In some embodiments, as shown in FIG. 14 , the tank body 210 has an exhaust port 223 , and the distance from the exhaust port 223 to the bottom surface 211 is greater than the distance from the water inlet port 221 to the bottom surface 211 ; The distance is greater than the distance from the water inlet 221 to the first side surface 212 .

In other words, when placed vertically, the position of the exhaust port 223 is higher than the water inlet 221 to facilitate the discharge of water vapor above, and when placed horizontally, the position of the exhaust port 223 is higher than the position of the water inlet 221 to facilitate the discharge of water vapor above.

In this way, the heating system 200 does not affect the exhaust gas in both vertical and horizontal placement.

In some embodiments, as shown in FIG. 14 , the distance from the air outlet 223 to the bottom surface 211 is greater than the distance from the water outlet 222 to the bottom surface 211 , and the distance from the air outlet 223 to the first side surface 212 is greater than the distance from the water outlet 222 to the first side surface. 212 distance.

In this way, the pressure at the air outlet 223 is lower than the pressure at the water outlet 222, which can prevent the air discharge valve 566 at the air outlet 223 from opening by mistake, and the steam accumulates on the top of the heating system 200, and the water outlet 222 is set lower than The position of the exhaust port 223 can prevent the steam from being discharged from the water outlet 222 and splashing the user. Setting the exhaust port 223 at the top is convenient for exhausting.

In some embodiments, as shown in FIG. 14 , the water inlet 221 , the water outlet 222 and the air outlet 223 are provided on the same side of the tank body 210 . In this way, it is convenient to connect with other pipelines, and there is no need to leave installation space for other pipelines or valves on the non-open surface of the second bracket 320, and the assembly is more convenient.

In some embodiments, as shown in FIG. 14 , the water inlet 221 and the water outlet 222 may be respectively arranged at diagonal positions on the front surface of the heating system, the front surface is adjacent to the first side surface 212 and the bottom surface 211 , and the exhaust port 223 It is arranged adjacent to the water outlet 222, and is set closer to the upper right corner. In this way, the water inlet 221 is close to the bottom surface 211, and the water outlet 222 is close to the top surface. After the water flows into the tank body 210 from the water inlet 221, it can be fully heated, and the temperature of the water flowing out from the water outlet 222 is high enough to be not easily affected by the water flow of the water inlet 221. , the steam at the top of the tank body 210 can be smoothly discharged from the exhaust port 223 .

Of course, the water inlet 221, the water outlet 222 and the air outlet 223 can also be arranged in other positions, for example, the water inlet 221 can be arranged in the lower left corner of the front surface, and the water outlet 222 and the air outlet 223 can be arranged in one of the top surfaces The top corner is close to the upper right corner of the front surface, and the distance from the air outlet 223 to the top corner is smaller than the distance from the water outlet 222 to the top corner.

In some embodiments, as shown in FIGS. 13-16 , the heating system 200 includes an exhaust pipe 228, the exhaust pipe 228 is inserted into the exhaust port 223, and a part of the exhaust pipe 228 protrudes outside the tank body 210, It is convenient to connect with other pipelines.

In some embodiments, as shown in FIG. 14 , the can body 210 includes: a can body 213 , an upper end cap 214 and a lower end cap 215 , both ends of the can body 213 are open, and the upper end cap 214 is installed on the upper end of the can body 213 and is closed On the upper end of the can body 213 , the lower end cover 215 is installed on the lower end of the can body 213 and closes the lower end of the can body 213 . The connection between the upper end cover 214 and the tank body 213 is provided with a sealing structure, and the connection between the lower end cover 215 and the tank body 213 is provided with a sealing structure.

The water inlet 221 and the water outlet 222 are diagonally arranged on the tank body 213, and an air outlet 223 is also provided near the water outlet 222. The distance from the nearest vertex of the air outlet 223 is smaller than the distance from the water outlet 222 to the vertex. .

In some embodiments, as shown in FIG. 14 , the water inlet 221 and the water outlet 222 are provided on the same side of the tank body 213 . This makes it easy to connect to other pipelines.

In some embodiments, as shown in FIG. 13 to FIG. 16 , the can body 213 is provided with a terminal avoidance hole 224 , the terminal 231 of the heating tube 230 extends out of the can body 210 from the terminal avoidance hole 224 , and the terminal avoidance hole 224 , The water inlet 221 and the water outlet 222 are arranged on the same side of the tank body 213 . In other words, after the tank body 210 is installed on the second bracket 320 , only the open end of the second bracket 320 needs to be wired and connected, and the assembly is convenient.

There may be two connection terminals 231 of the heating tube 230 , the tank body 213 is provided with two connection terminal avoidance holes 224 , and the two connection terminals 231 correspond to the two connection terminal avoidance holes 224 one-to-one.

In some embodiments, as shown in FIGS. 13-16 , the can body 213 can be connected to a can body assembling bracket 229 , and the can body assembling bracket 229 is used to fix the can body 210 to the second bracket 320 on the can body assembling bracket 229 A mounting hole may be provided, through which the threaded connector passes and is threadedly connected with the second bracket 320 .

In some embodiments, as shown in FIGS. 13-16 , the tank body 210 is provided with a temperature sensor installation hole 225 , the temperature sensor installation hole 225 is used for installing a temperature controller, and the temperature sensor installation hole 225 is located on the bottom surface 211 . The ratio of the distance to the height of the tank 210 when the heating system 200 is placed vertically is a1, and the ratio of the distance from the temperature sensor mounting hole 225 to the first level to the height of the tank 210 when the heating system 200 is placed horizontally is a2, which satisfies : 0.5≤a1≤0.8, 0.5≤a2≤0.8. For example, a1=0.6, a2=0.6.

In this way, no matter whether the heating system 200 is placed vertically or horizontally, the temperature controller is basically located in the middle of the tank body 210, and the temperature measurement is more accurate.

As shown in FIGS. 13-16 , the tank body 210 may be installed with a thermostat fixing bracket 250, and the thermostat fixing bracket 250 is used for installing the thermostat.

In some embodiments, as shown in FIGS. 13-16 , the temperature sensor mounting hole 225 , the water inlet 221 and the water outlet 222 are provided on the same side of the tank body 210 .

In other words, after the tank body 210 is installed on the second bracket 320 , only the open end of the second bracket 320 needs to be wired and connected, and the assembly is convenient.

In some embodiments, as shown in FIGS. 13-16 , the water inlet 221 , the water outlet 222 , the exhaust port 223 , the terminal escape hole 224 and the temperature sensor installation hole 225 are all provided on the same side of the tank body 210 . In this way, after the tank body 210 is installed on the second bracket 320, only wiring and piping need to be performed at the open end of the second bracket 320, and the assembly is convenient.

As shown in FIGS. 1-6 , the water purifier according to the seventh embodiment of the present invention includes: a filtering system 100 , a heating system 200 and a water outlet water circuit board 900 .

The filtration system 100 is connected to the heating system 200 through the outlet water circuit board 900 , and the filtering system 100 and the heating system 200 are connected to external pipelines through the outlet water circuit board 900 .

The filtration system 100 has a raw water inlet 101 and a purified water outlet 105. The raw water inlet 101 is indirectly connected to a raw water pipe through the outlet water circuit board 900, for example, the raw water pipe may be a tap water pipe. The raw water to be filtered flows into the filtration system 100 from the raw water inlet 101 , and then flows out pure water from the purified water outlet 105 after being filtered.

The heating system 200 is used to heat the water flowing through the heating system 200. The heating system 200 has a water inlet 221 and a water outlet 222. The water inlet 221 of the heating system 200 is connected to the water purification outlet 105 of the filtration system 100 through the water outlet waterway plate 900, and the heating The water outlet 222 of the system 200 is connected to the first water supply outlet of the water purifier through the water outlet water circuit board 900 . The water purification outlet 105 of the filtration system 100 is connected to the second water supply port of the water purifier through the outlet water channel plate 900 . It can be understood that the first water supply port is used for supplying hot water, and the second water supply port is used for supplying normal temperature water.

The water outlet waterway plate 900 according to the embodiment of the present invention will be described below with reference to FIGS. 17-20 .

As shown in FIGS. 17-20 , the water outlet water circuit board 900 according to the embodiment of the present invention includes: a base plate 910 and a plurality of water pipes.

The base plate 910 can be a flat plate or a concave-convex plate, and the water pipes are installed on the base plate 910. In other words, the base plate 910 is a carrier of a plurality of water pipes. The base plate 910 can also be provided with a connection structure for connecting the water outlet water circuit plate 900 with the second bracket 320. The connection structure may be a snap connection structure or a screw connection structure.

Each water pipe has at least two water ports that communicate with each other. For example, two water ports can be formed at two ends of the water pipe, or one water port can be formed at one end of the water pipe, and another water port is opened on the peripheral wall of the water pipe; at least one water pipe has at least three water ports that communicate with each other. For example, two water ports can be formed at both ends of the water pipe, and one or more water ports can be opened on the peripheral wall of the water pipe.

The water pipe with two nozzles is mainly used to realize the connection of two pipelines, and the water pipe with three or more nozzles is mainly used to realize the multi-way connection of branch pipelines.

A water pipe with at least three water ports communicating with each other and another water pipe define a mounting location for mounting the valve. In other words, the inlet and outlet of the valve are respectively connected with the water inlets of the two water pipes, so that the installation position formed on the outlet water channel plate 900 can also realize the installation of the valve.

It can be understood that the plurality of water pipes of the water outlet water circuit board 900 are formed as a whole by the base plate 910. By installing the base plate 910 in the water purifier, such as the second bracket 320, each water pipe can be fixed, and the valve can be fixed. It is installed on the water outlet waterway board 900, and the interface is connected to the nozzle of the water outlet waterway board 900, so that the arrangement of pipelines can be omitted.

According to the water outlet water circuit board 900 of the embodiment of the present invention, the water pipes with multiple water ports are integrated into a whole through the base plate 910, so that the overall assembly and installation of the multiple pipes can be realized, and the installation of valves and the connection of water paths are more neat and tidy. concise.

The water purifier according to the embodiment of the present invention integrates water purification and heating functions. By arranging the water outlet water circuit board 900 of the above-mentioned structure in the water purifier, the pipelines in the water purifier can be reduced, the difficulty of assembly can be reduced, and the Wrong installation, improve assembly efficiency.

In some embodiments, as shown in FIG. 8 and FIG. 10 , the water purifier may further include: a filtering water circuit board 110 , and the filtering system 100 is connected to the outlet water circuit board 900 through the filtering water circuit board 110 .

In this way, the pipelines between the filtering system 100 and the heating system 200 and the outside can be greatly reduced, the difficulty of assembly is reduced, the wrong assembly is prevented, and the assembly efficiency is improved.

In some embodiments, as shown in FIGS. 1-8 , the water purifier may further include: a water pump 510 , the water pump 510 is connected to the filtration system 100 , and the water pump 510 is arranged upstream of the water purification outlet 105 of the filtration system 100 , and the water pump The water pump 510 is used to drive water to flow from the raw water inlet 101 of the filtration system 100 to the purified water outlet 105 of the filtration system 100 , and the water pump 510 is used to drive water to be discharged from the water outlet 222 of the heating system 200 .

It can be understood that, after the pure water entering the heating system 200 is heated, the density of the hot water is relatively small and floats, and the density of the cold water is relatively high and sinks.

The water purifier according to the embodiment of the present invention integrates the functions of water purification and heating. The water inlet 221 is arranged at the lower part of the heating system 200 and the water outlet 222 is arranged at the upper part of the heating system 200. Combined with the push-type water outlet method of the water pump 510 , which can prevent the outside air from being introduced into the waterway of the water purifier and prevent secondary pollution.

In some embodiments, the filtering system 100 is connected to the water pump 510 and the outlet water circuit board 900 through the filtering water circuit board 110 . For the specific structure of the filtering water channel board 110, please refer to FIG. 10 and the description of other embodiments.

In some embodiments, as shown in FIG. 17 , the base plate 910 is provided with a mounting structure 911 for fixing the valve at the mounting position. In other words, there are installation structures 911 near the two nozzles for connecting the valves. After the inlet and outlet of the valves are respectively connected to the two nozzles, the valves can be fixed by the installation structures 911 . The mounting structure 911 may be a connecting post with threaded holes.

In some embodiments, as shown in FIGS. 17 and 19 , the plurality of water pipes of the water outlet waterway plate 900 include: a first water pipe 921 , a second water pipe 922 , a third water pipe 923 and a fourth water pipe 924 .

The first water pipe 921 has a first inlet 921a, a first outlet 921b, a first port 921c and a second port 921d, and the first inlet 921a, the first outlet 921b, the first port 921c and the second port 921d communicate with each other.

The second water pipe 922 has a second inlet 922a and a second outlet 922b, and the second inlet 922a and the second outlet 922b communicate with each other.

The first port 921c and the second inlet 922a define a mounting position for mounting the valve.

The third water pipe 923 has a third inlet 923a and a third outlet 923b, and the third inlet 923a and the third outlet 923b communicate with each other. The second outlet 922b and the third inlet 923a define a mounting location for mounting the valve.

The fourth water pipe 924 has a fourth inlet 924a and a fourth outlet 924b, and the fourth inlet 924a and the fourth outlet 924b communicate with each other. The second port 921d and the fourth inlet 924a define a mounting location for mounting the valve.

When the outlet water circuit board 900 is installed in the water purifier, the first inlet 921a can communicate with the water purification outlet 105 of the filtration system 100. In the embodiment where the water purifier includes the filtration water circuit board 110, the first inlet 921a can be connected with the filter system 100. The twelfth port 125b of the waterway board 110 is connected; the first outlet 921b can be connected to the second water supply port of the water purifier; as shown in FIG. 18 and FIG. 19 , the first port 921c is connected to the inlet of the water purification check valve 561 , the second inlet 922a is connected to the outlet of the water purification check valve 561; as shown in FIG. 18, the second outlet 922b and the third inlet 923a are respectively connected to the inlet and outlet of the water purification control valve 562; the third outlet 923b is connected to the heating system As shown in FIG. 18 , the second port 921d and the fourth inlet 924a are respectively connected with the inlet and outlet of the backwater control valve 564 ;

In this way, in the water purifier, the pipeline connections and valve installations on the first branch 520, the second branch 530 and the return pipe 540 are extremely simple, and it is not easy to assemble errors. Simplify the water arrangement of the water purifier.

In some embodiments, as shown in FIG. 17 , the first port 921c and the second inlet 922a are arranged side by side and open in the same direction, which facilitates the installation of the water purification check valve 561 .

In some embodiments, as shown in FIG. 17 , the second outlet 922b and the third inlet 923a are arranged side by side and open in the same direction, which facilitates the installation of the clean water control valve 562 .

The second port 921d and the fourth inlet 924a are arranged side by side and open in the same direction. This facilitates the installation of the return water check valve 563 .

In the actual process, as shown in FIG. 17 , the first interface 921c and the second inlet 922a are open to the first edge of the substrate 910, the third outlet 923b is open to the second edge of the substrate 910, and the fourth outlet 924b is open to the substrate The third edge of 910 is open; the first inlet 921a, the second interface 921d, the second outlet 922b, the third inlet 923a and the fourth inlet 924a are located on one side of the substrate 910; the third outlet 923b is located on the other side of the substrate 910.

In this way, the valves are basically installed on one side of the base plate 910, the nozzles for connecting with the external pipeline of the water purifier are concentrated, and the nozzles for connecting with the heating system 200 of the water purifier are concentrated; The water ports connected to the filter water board 110 of the filter are relatively concentrated.

In some embodiments, as shown in FIG. 17 , the first water pipe 921 , the second water pipe 922 and the fourth water pipe 924 are arranged in parallel and side by side; the first outlet 921b and the first interface 921c are located at two ends of the first water pipe 921 An inlet 921a and a second port 921d are drawn out from the peripheral wall of the first water pipe 921, the second port 921d is located close to the first outlet 921b; the second inlet 922a is located at one end of the second water pipe 922, and the second outlet 922b is The third inlet 923a is drawn from the peripheral wall of the third water pipe 923, and the third outlet 923b is located at one end of the third water pipe 923; the fourth outlet 924b is located at one end of the fourth water pipe 924, and the fourth inlet 924a is located from the fourth The peripheral wall of the water pipe 924 is drawn out. In this way, the outlet water channel plate 900 has a simple structure and is easy to process when the above-mentioned water channel communication relationship is realized.

In some embodiments, as shown in FIGS. 17-20 , the plurality of water pipes of the water outlet waterway plate 900 include: a fifth water pipe 935 and a sixth water pipe 936 .

The fifth water pipe 935 has a fifth inlet 935a, a fifth outlet 935b and a fifth port 935c, and the fifth inlet 935a, the fifth outlet 935b and the fifth port 935c communicate with each other.

The sixth water pipe 936 has a sixth inlet 936a and a sixth outlet 936b, the sixth inlet 936a and the sixth outlet 936b communicate with each other, and the fifth port 935c and the sixth inlet 936a define an installation position for installing the valve.

When the outlet water circuit board 900 is installed in the water purifier, the fifth inlet 935a can communicate with the waste water port 104 of the filtration system 100. In the embodiment where the water purifier includes the filtration water circuit board 110, the fifth inlet 935a can communicate with the filtration water circuit The tenth port 124b of the plate 110 is connected; the fifth port 935c and the sixth inlet 936a are respectively connected to the inlet and outlet of the exhaust valve 566; the sixth outlet 936b is connected to the exhaust port 223 of the heating system 200, and the fifth outlet 935b is connected to the purified water The waste water outlet 602 of the device is connected.

In other words, the waste water discharged from the waste water port 104 of the filtration system 100 flows into the effluent waterway plate 900 through the fifth inlet 935a, and then flows from the fifth outlet 935b to the waste water outlet 602 of the water purifier for discharge; the waste water discharged from the exhaust port 223 of the heating system 200 The steam or water may flow to the waste water outlet 602 of the water purifier through the sixth outlet 936b, the exhaust valve 566, and the fifth outlet 935b.

In this way, in the water purifier, the pipeline connection and valve installation of the waste water pipeline and the safety branch 550 are extremely simple, and it is not easy to assemble errors. .

In some embodiments, as shown in FIG. 17 , the fifth port 935c and the sixth inlet 936a are arranged side by side and open in the same direction, which facilitates the installation of the exhaust valve 566 .

In some embodiments, as shown in FIG. 17 , the fifth inlet 935a opens toward the first edge of the substrate 910 ; the sixth outlet 936b opens toward the second edge of the substrate 910 ; the fifth outlet 935b opens toward the third edge of the substrate 910 The fifth interface 935c and the sixth inlet 936a are located on one side of the substrate 910; the sixth outlet 936b is located on the other side of the substrate 910.

In some embodiments, as shown in FIG. 17 , the fifth inlet 935a and the fifth outlet 935b are located at two ends of the fifth water pipe 935, respectively, the fifth interface 935c is drawn out from the peripheral wall of the fifth water pipe 935; the sixth outlet 936b is located at the first At one end of the four water pipes 924 , the sixth inlet is drawn out from the peripheral wall of the sixth water pipe 936 .

In this way, the outlet water channel plate 900 has a simple structure and is easy to process when the above-mentioned water channel communication relationship is realized.

In some embodiments, as shown in FIGS. 17 to 20 , the plurality of water pipes of the water outlet water channel plate 900 include: a seventh water pipe 947 . The seventh water pipe 947 has a seventh inlet 947a and a seventh outlet 947b, and the seventh inlet 947a and the seventh outlet 947b communicate with each other.

When the outlet water circuit board 900 is installed in the water purifier, the seventh inlet 947a can be connected to the first water supply port of the water purifier, and the seventh outlet 947b can be connected to the water outlet 222 of the heating system 200 .

In this way, in the water purifier, the piping for outgoing hot water is also integrated in the outflow waterway plate 900, which is not easy to assemble incorrectly.

In some embodiments, as shown in FIGS. 17-20 , the plurality of water pipes of the water outlet waterway plate 900 include: an eighth water pipe 958 . The eighth water pipe 958 has an eighth inlet 958a and an eighth outlet 958b, and the eighth inlet 958a and the eighth outlet 958b communicate with each other.

When the outlet water circuit board 900 is installed in the water purifier, the eighth inlet 958a can be connected to the raw water inlet 101 of the filtering system 100. In the embodiment where the water purifier includes the filtering water circuit board 110, the eighth inlet 958a can be connected to the filtering water circuit The sixth port 121b of the plate 110 is connected; the eighth outlet 958b can be connected to a water pipe.

In this way, in the water purifier, the pipeline to which the raw water is connected is also integrated in the outlet water circuit board 900, which is not easy to assemble incorrectly.

In various embodiments of the present invention, as shown in FIG. 1 , the filtration system 100 may include an exhaust one-way valve 565 , which is directed from the exhaust port 223 of the heating system 200 to the waste water outlet 602 of the water purifier. Passing through, the vent check valve 565 prevents waste water from backing up into the heating system 200 .

In various embodiments of the present invention, as shown in FIG. 1 , the water purifier may further include: a water return pipe 540 connected between the water purification outlet 105 and the inlet of the water pump 510 .

In some embodiments, as shown in FIG. 1 , the return water pipe 540 is provided with a return water control valve 564, and the return water control valve 564 is used to control the conduction state of the return water pipe 540. The water control valve 564 can be electrically connected with the controller of the water purifier, and the water purifier is set to open the return water control valve 564 for a preset time every time the water purifier is turned on, and the preset time can be 5s-25s, Such as 10s.

In some embodiments, as shown in FIG. 1 , the return pipe 540 is provided with a return check valve 563 and a return control valve 564, and the return check valve 563 conducts unidirectionally from the clean water outlet 105 to the inlet of the water pump 510. The return water control valve 564 is used to control the conduction state of the return water pipe 540, the return water control valve 564 can be a solenoid valve, and the return water one-way valve 563 can prevent the water that has not been completely filtered from directly flowing into the purified water outlet 105 through the return water pipe 540. Or the first water supply port.

The water purifier has a fresh water return mode. In the fresh water return mode, the water pump 510 and the return water control valve 564 are turned on. The water purifier is set to start the backflow fresh water mode every time the water purifier is powered on, and lasts for a preset time, and the preset time may be 5s-25s, such as 10s.

In various embodiments of the present invention, the filter system 100 may include a plurality of filter elements, and the multiple filter elements may be independently arranged or integrated into a composite filter element.

In some embodiments, the filtration system 100 includes a first filter element and a second filter element, the water inlet end of the first filter element is connected to the raw water inlet 101, the water outlet end of the first filter element is connected to the inlet of the water pump 510, and the outlet of the water pump 510 is connected to the raw water inlet 101. The water inlet end of the second filter element is connected, and the water outlet end of the second filter element is connected with the purified water outlet 105 .

The first filter element is used to realize the preliminary filtration of raw water, which can filter out large particles such as sediment, rust, insect eggs, and red worms in the raw water. The raw water can be tap water, well water, etc., and the first filter element can be PP cotton filter element (Polypropylene meltblown filter element), carbon rod filter element, composite filter element, etc.

The second filter element has a reverse osmosis membrane. The reverse osmosis membrane can be an artificial semi-permeable membrane. The membrane pore size of the reverse osmosis membrane is very small, which can effectively remove impurities such as dissolved salts, colloids, microorganisms, and organic matter in the water.

In some embodiments, the filtration system 100 includes a first filter element, a second filter element and a third filter element, the water inlet end of the first filter element is connected to the raw water inlet 101 , the water outlet end of the first filter element is connected to the inlet of the water pump 510 , and the water pump 510 The outlet of the second filter element is connected to the water inlet end of the second filter element, the water outlet end of the second filter element is connected to the water inlet end of the third filter element, and the water outlet end of the third filter element is connected to the clean water outlet 105 .

The third filter element is used to absorb odor and residual chlorine, and can be used to improve the taste of pure water, and the third filter element can be an activated carbon filter element.

The water purifiers of various embodiments of the present invention can provide various kinds of water or beverages, for example, can provide normal temperature purified water and heated purified water.

In some embodiments, as shown in FIG. 1 , the water purifier further includes: a first branch 520 and a second branch 530 .

Wherein, the first branch 520 is connected between the water purification outlet 105 of the filtration system 100 and the first water supply port of the water purifier, and the heating system 200 is arranged on the first branch 520, the water inlet 221 and the outlet of the heating system 200 The water inlets 222 are all connected to the first branch circuit 520 , and the water inlet 221 and the water outlet 222 of the heating system 200 can be connected to the first branch circuit 520 in series. The second branch 530 is connected between the water purification outlet 105 and the second water supply port of the water purifier.

In this embodiment, the first water supply port provides hot water through the first branch 520 , and the second water supply port provides normal temperature pure water through the second branch 530 .

The first water supply port and the second water supply port can both be connected to the faucet 800. When the faucet 800 connected to the first water supply port or the second water supply port is opened, the corresponding branch can be opened.

In some embodiments, as shown in FIG. 1 , the return pipe 540 is connected to the clean water outlet 105 through the second branch 530 , and the connection between the return pipe 540 and the second branch 530 is located near the second water supply outlet. For example, in the outlet water circuit board 900 shown in FIG. 17 , the second interface 921d of the first water pipe 921 is disposed at a position close to the first outlet 921b of the first water pipe 921 . In this way, in the fresh water return mode, the pure water remaining in the pipeline can be pumped to the inlet of the water pump 510 as much as possible.

In some embodiments, as shown in FIG. 1 , the first branch 520 is provided with a water purification control valve 562 , and the water purification control valve 562 is used to control the conduction state of the first branch 520 . The water purification control valve 562 may be The solenoid valve, the water purification control valve 562 can be electrically connected with the controller of the water purifier.

In some embodiments, as shown in FIG. 1 , the first branch circuit 520 is provided with a water purification check valve 561 and a water purification control valve 562, and the water purification control valve 562 is used to control the conduction state of the first branch circuit 520, The water purification control valve 562 can be a solenoid valve, and the water purification control valve 562 can be electrically connected with the controller of the water purifier.

In some embodiments, as shown in FIG. 1 , the water purifier further includes an exhaust valve 566 and a waste valve 567 .

The exhaust valve 566 is connected between the exhaust port 223 of the heating system 200 and the waste water outlet 602 of the water purifier. The exhaust valve 566 is used to control the conduction state between the exhaust port 223 and the waste water outlet 602. The exhaust valve 566 may be a solenoid valve, and the exhaust valve 566 may be electrically connected to the controller of the water purifier, or the exhaust valve 566 may be a pressure valve. When the exhaust valve 566 is open, depressurization or drainage of the heating system 200 may be achieved through the exhaust port 223 .

The waste water valve 567 is connected between the waste water port 104 of the filtration system 100 and the waste water outlet 602 of the water purifier. The waste water valve 567 is used to control the conduction state between the waste water port 104 and the waste water outlet 602 . The waste water valve 567 may be a solenoid valve, and the waste water valve 567 may be electrically connected with the controller of the water purifier.

In various embodiments of the present invention, as shown in FIG. 4 , FIG. 6 and FIG. 11 , the water purifier may further include: a water outlet water circuit board 900 , and each water outlet of the heating system 200 is connected to the water outlet water circuit board 900 , and the water outlet water circuit board 900 Installed on the second bracket 320 . In this way, the pipeline arrangement in the water purifier can be reduced, the difficulty of assembly is reduced, the wrong assembly is prevented, and the assembly efficiency is improved.

As shown in FIG. 4 , FIG. 6 and FIG. 11 , the filtering water channel plate 110 is located at one end of the second bracket 320 in the longitudinal direction. The outlet water channel plate 900 and the second bracket 320 are arranged along the direction B. As shown in FIG. In this way, the space below the second bracket 320 is fully utilized, and the entire water purifier has a compact structure.

In various embodiments of the present invention, as shown in FIG. 4 , FIG. 5 , FIG. 6 and FIG. 8 , the water purifier may further include: a water pump 510 , the water pump 510 is connected to the filtration system 100 , and the water pump 510 is used to drive water from the filtration system The raw water inlet 101 of the 100 flows to the purified water outlet 105 , and the water pump 510 is used to drive the water to be discharged from the water outlet 222 of the heating system 200 .

As shown in FIGS. 4-6 , the water pump 510 is mounted on the first bracket 310 , and the water pump 510 is located between the first bracket 310 and the second bracket 320 .

It can be understood that, in this embodiment, there is no need to design an independent support for the water pump 510 , the arrangement of the water purifier can be simplified, and the structure is more compact. The water pump 510 is installed between the first bracket 310 and the second bracket 320, so that the two brackets can better protect the higher-priced water pump 510, and the water pump 510 is located between the filter system 100 and the heating system 200 (heating system). 200), which is equivalent to being located in the middle area of the entire water purifier, and the noise of the working of the water pump 510 can be effectively isolated by the blocking effect of other peripheral structures.

In various embodiments of the present invention, as shown in FIGS. 6 , 8 and 11 , both the second bracket 320 and the first bracket 310 are provided with flanges protruding toward each other, and the flanges are used to define the middle installation cavity 323 .

In other words, the first bracket 310 is provided with the first flange 312 protruding toward the second bracket 320 , the second bracket 320 is provided with the second flange 322 protruding toward the first bracket 310 , the first flange 312 and the second flange 322 are provided The flange 322 is used to define the middle installation cavity 323 together with the first bracket 310 and the second bracket 320 , and the water pump 510 is installed in the middle installation cavity 323 .

In this way, the six sides of the water pump 510 are provided with protective structures, which can better protect the water pump 510 .

In various embodiments of the present invention, as shown in FIG. 5 and FIG. 6 , the filter system 100 , the water pump 510 and the heating system 200 are arranged side by side along the docking direction of the first support 310 and the second support 320 , and the filter system 100 , the water pump 510 parallel to the length of the heating system 200 .

The direction A is the butting direction of the first support 310 and the second support 320 , the direction B is the length direction of the filter system 100 , the water pump 510 and the heating system 200 , and the direction A is perpendicular to the direction B.

With the above layout, the entire water purifier has a compact structure and takes up little space, which is convenient for under-kitchen layout, and the longitudinal directions of the filtering system 100, the water pump 510 and the heating system 200 are parallel to facilitate the independent disassembly of each component in this direction.

In various embodiments of the present invention, as shown in FIG. 8 and FIG. 10 , the water purifier of the embodiment of the present invention may further include: a filter water circuit board 110 , and each nozzle of the filter system 100 and the water pump 510 is connected to the filter water circuit board 110 , the filtering water channel board 110 is installed on the first bracket 310 .

In other words, each water outlet of the filter system 100 and the water pump 510 is connected to other pipelines through the filter water circuit board 110, which can simplify the pipeline arrangement in the whole water purifier, and the pipelines in the water purifier are few, which is convenient for pipe layout.

In various embodiments of the present invention, as shown in FIG. 1, the filtration system 100 includes: a raw water inlet 101, a water pump inlet 102, a water pump outlet 103, a waste water outlet 104 and a clean water outlet 105. One end of the water pump inlet 102 is connected to the first The water outlet of a filter element is connected, the other end of the water inlet 102 of the water pump is connected to the inlet of the water pump 510 , and the outlet of the water pump 510 is connected to the water outlet 103 of the water pump.

As shown in FIG. 10 , the filtering water circuit board 110 includes a plurality of pipe bodies 111, and the pipe body 111 has a plurality of water ports, and these water ports include: a first port 121a, a second port 122a, a third port 123a, a fourth port 124a, The fifth port 125a, the sixth port 121b, the seventh port 122b, the eighth port 122c, the ninth port 123b, the tenth port 124b, the eleventh port 124c and the twelfth port 125b.

The first port 121a is connected to the raw water inlet 101 of the filter system 100, the second port 122a is connected to the water pump inlet 102 of the filter system 100, the third port 123a is connected to the water pump outlet 103 of the filter system 100, and the fourth port 124a is connected to the filter system 100. The waste water port 104 of the system 100 is connected, and the fifth port 125a is connected to the clean water outlet 105 of the filtration system 100 .

The sixth port 121b communicates with the first port 121a, the seventh port 122b, the eighth port 122c and the second port 122a communicate with each other, the ninth port 123b communicates with the third port 123a, and the tenth port 124b and the eleventh port 124c communicate with each other. The fourth port 124a communicates with each other, and the twelfth port 125b communicates with the fifth port 125a.

The sixth port 121b is used to introduce raw water. Specifically, the sixth port 121b can be connected to the eighth inlet 958a of the outlet waterway plate 900 , the seventh port 122b is used to install the water pump inlet valve 568 , and the eighth port 122c is connected to the water pump 510 . The inlet is connected, the ninth port 123b is connected with the outlet of the water pump 510, the tenth port 124b is used for connecting with the waste water outlet 602, the eleventh port 124c is used for installing the waste water valve 567, and the twelfth port 125b is used for connecting with the hot water system. The water inlet 221 or the second water supply port of the water purifier is connected. Specifically, the twelfth port 125b may be connected to the first inlet 921a of the water outlet waterway board 900 .

In some specific embodiments, as shown in FIG. 10 , five pipes 111 are arranged side by side, and one end of the five pipes 111 respectively forms a first port 121a, a second port 122a, and a third port 123a arranged side by side. , the fourth port 124a and the fifth port 125a, the raw water inlet 101, the water pump inlet 102, the water pump outlet 103, the waste water outlet 104 and the purified water outlet 105 are also arranged side by side in the filtration system 100, such as shown in FIG. 8 and FIG. 10. In the embodiment, the third port 123a, the first port 121a, the fifth port 125a, the second port 122a and the fourth port 124a are arranged side by side in sequence. Correspondingly, the water pump inlet 102, the raw water inlet 101, the purified water outlet 105, The water inlets 102 of the water pumps are arranged side by side in sequence.

In various embodiments of the present invention, as shown in FIG. 6 and FIG. 8 , the filtering water circuit board 110 is located between the first bracket 310 and the second bracket 320 . In this way, the first bracket 310 and the second bracket 320 can be fully utilized to protect the filter water channel board 110 and prevent the filter water channel board 110 from being damaged by impact.

In some embodiments, as shown in FIGS. 6 and 8 , the filtering water circuit board 110 is installed at one end of the water pump 510 in the length direction. The filtering water circuit board 110 and the water pump 510 are arranged along the direction B. In this way, the space between the first bracket 310 and the second bracket 320 is fully utilized, and the structure of the entire water purifier is compact.

In some embodiments, as shown in FIG. 10 , the filter water circuit board 110 includes: a support 112 and a plurality of pipe bodies 111 installed on the support 112 , the support 112 is connected with the first bracket 310 , and each water outlet of the filtering system 100 And each nozzle of the water pump 510 is respectively connected to the pipe body 111 corresponding to the filtering water channel board 110 .

In the actual production process, the support 112 and the pipe body 111 can be integrally processed plastic parts. A hollow structure or a weight reduction hole can be designed on the support 112 to help reduce the weight of the whole machine.

In some embodiments, as shown in FIG. 10 , the support 112 includes connecting arms 113 , and the number of connecting arms 113 may be two. The two connecting arms 113 are respectively provided at both ends of the support 112 and extend upward. 111 is located between the two connecting arms 113 . As shown in FIG. 9 , the first bracket 310 is provided with connecting arm mounting holes 311 , and correspondingly, there are also two connecting arm mounting holes 311 . The first bracket 310 is further provided with a tube body avoidance hole 313 for avoiding the tube body 111 , and a plurality of tube body avoidance holes 313 can be connected to form a through body. In this way, the matching relationship between the tube body avoiding hole 313 and the tube body 111 and the matching relationship between the connecting arm mounting hole 311 and the connecting arm 113 can play the role of positioning the filtering water circuit board 110 .

As shown in FIG. 6 and FIG. 8 , the water purifier may further include: a pressing rod 712, the pressing rod 712 is used for pressing the filter system 100, one end of the pressing rod 712 is connected with the first bracket 310, and the connecting arm 113 is installed through the connecting arm The hole 311 is connected with the other end of the pressing rod 712 . In this way, when the filter element of the filter system 100 needs to be replaced, the filter element can be easily disassembled by disassembling the pressing rod 712 .

In various embodiments of the present invention, as shown in FIG. 4 , the casing may include: a casing 701 , a front casing 702 , an upper cover 703 , a top cover 704 and a base 705 . The front case 702 , the upper cover 703 , the top cover 704 , and the base 705 are all mounted on the casing 701 . The housing can be plastic or metal, or a metal coating on the plastic.

In various embodiments of the present invention, as shown in FIG. 4 , the water purifier may further include: a water leakage protection valve 569, a decorative board 706, a power adapter 707, a display 708, an electric control box 709, a power board 710, and a TDS (Total dissolved solids, total dissolved solids) detection probe 711.

In various embodiments of the present invention, the water purifier may further include: a controller (not shown in the figure), the controller and the heating system 200 , a water purification control valve 562 , an exhaust valve 566 , a waste water valve 567 and a water pump 510 electrical connection. The controller is used to control the opening and closing of the heating system 200 , the water purification control valve 562 , the exhaust valve 566 , the waste water valve 567 and the water pump 510 .

In some embodiments, the controller is configured to control the water purifier to enter the first flushing mode, the forced flushing mode and the old water draining mode in sequence when it is determined that the water purifier is powered on for the first time.

In the first flush mode, the water pump 510 is turned on, the clean water control valve 562 is turned off, the heating system 200 is turned off, the waste water valve 567 is turned on, and the exhaust valve 566 is turned off. In this mode, the raw water flows in from the raw water inlet 101 under the driving action of the water pump 510, and then is discharged from the waste water outlet 104 to prevent impurities in the filtering system 100 from entering the heating system 200 during initial use.

In the embodiment shown in FIG. 1, referring to Table 1, in the first flush mode, the water pump 510 is turned on, the water pump inlet valve 568 is turned on, the clean water control valve 562 is turned off, the heating system 200 is turned off, the waste water valve 567 is turned on, and the exhaust gas is discharged. Valve 566 is closed.

In the forced flush mode, the second water supply port (normal temperature water port of the faucet 800 ) is opened, the water pump 510 is turned on, the water purification control valve 562 is turned off, the heating system 200 is turned off, the waste water valve 567 is closed, and the exhaust valve 566 is closed. In this mode, the raw water flows in from the raw water inlet 101 under the driving action of the water pump 510, and then discharges from the second water supply port of the faucet 800, which can provide a large flow of flushing.

In the embodiment shown in FIG. 1, referring to Table 1, in the forced flush mode, the water pump 510 is turned on, the water pump inlet valve 568 is turned on, the clean water control valve 562 is turned off, the heating system 200 is turned off, the waste water valve 567 is turned off, and the exhaust gas is Valve 566 is closed.

In the old water discharge mode, the second water supply port is closed, the water pump 510 is opened, the water purification control valve 562 is opened, the heating system 200 is closed, the waste water valve 567 is closed, and the exhaust valve 566 is opened. In this mode, raw water flows in from the raw water inlet 101 under the driving action of the water pump 510 , then flushes the heating system 200 , and discharges the old water in the heating system 200 from the exhaust port 223 .

In the embodiment shown in FIG. 1, referring to Table 1, in the stale water mode, the water pump 510 is turned on, the water pump inlet valve 568 is turned on, the water purification control valve 562 is turned on, the heating system 200 is turned off, the waste water valve 567 is turned off, and the waste water valve 567 is turned off. Gas valve 566 opens.

In some embodiments, the preset duration of the first flushing mode is t1, the preset duration of the forced flushing mode is t2, and the preset duration of the stale water mode is t3, satisfying: 15s≤t1≤60s, 6min≤ t2≤15min, 2min≤t3≤5min. By limiting the duration of each mode to the above range, it is possible to reduce water consumption on the premise of ensuring cleanliness.

In a specific embodiment, when it is determined that the water purifier is powered on for the first time, all loads are turned off for 5s, and after entering the first flushing mode for 30s, the handle of the faucet 800 of the second water supply port is opened, and the forced flushing mode is entered for 10 minutes. The faucet 800 handle of the second water inlet, and then enter the draining water mode for 3 minutes.

In some embodiments, the controller is configured to control the water purifier to enter a flush mode when it is determined that the water purifier is not powered on for the first time.

Among them, as shown in Table 1, in the flushing mode, the water pump 510 is turned on, the water purification control valve 562 is turned off, and the waste water valve 567 is turned on. In this mode, the raw water flows in from the raw water inlet 101 under the driving action of the water pump 510, and then is discharged from the waste water outlet 104, so as to prevent the impurities deposited in the filtration system 100 from flowing downstream.

In the embodiment shown in FIG. 1, referring to Table 1, in the flush mode, the water pump 510 is on, the water pump inlet valve 568 is on, the clean water control valve 562 is off, the waste water valve 567 is on, the heating system 200 and the exhaust valve 566 are on. Turns on or off based on the temperature of the heating system 200 .

As shown in FIG. 21 , if the heating system 200 and the exhaust valve 566 are both closed, it is determined that the temperature of the heating system 200 is lower than the first target temperature, and both the heating system 200 and the exhaust valve 566 are switched to the open state. If both the heating system 200 and the exhaust valve 566 are in the open state, it is determined that the temperature of the heating system 200 is greater than or equal to the second target temperature, and both the heating system 200 and the exhaust valve 566 are switched to the closed state; wherein, the second target temperature is higher than or equal to the second target temperature The first target temperature.

In other words, whether to switch the working states of the heating system 200 and the exhaust valve 566 needs to be determined based on the current working states of the heating system 200 and the exhaust valve 566 and the temperature of the heating system 200 .

In some embodiments, the first target temperature is T1, and the second target temperature is T2, satisfying: 65°C≤T1≤75°C, and 90°C≤T2≤100°C. In other words, in the relatively low temperature range, the heating system 200 needs to be turned on to heat the pure water, and the exhaust valve 566 needs to be turned on to prevent the pressure in the heating system 200 from becoming too large; when it is heated to the relatively high temperature range, it can be turned off based on a higher threshold Heating system 200 and exhaust valve 566 .

In a specific embodiment, T1=70°C and T2=95°C.

In actual execution, if it is not powered on for the first time, all loads are turned off for 5s, and the flush mode is entered for 25s.

In some embodiments, the controller is configured to determine that the second water supply port of the water purifier is open after the flushing mode ends, and control the water purifier to enter the normal temperature water production mode. In the normal temperature water production mode, the water pump 510 is turned on, and the water purification control Valve 562 is open, waste valve 567 is closed, exhaust valve 566 is closed, and heating system 200 is controlled based on the temperature of heating system 200 received.

In the actual use process, when the handle of the faucet 800 corresponding to the second water supply port is opened, the water purifier can be activated, and the water purifier enters the flushing mode. Under the driving action of the water pump 510 , it flows in from the raw water inlet 101 , and then flows out from the second water supply port through the second branch 530 from the purified water outlet 105 .

In the embodiment shown in FIG. 1, referring to Table 1, in the normal temperature water production mode, the water pump 510 is turned on, the water pump inlet valve 568 is turned on, the water purification control valve 562 is turned off, the waste water valve 567 is turned off, and the exhaust valve 566 is turned off, The heating system 200 is controlled based on the received temperature of the heating system 200 .

Specifically, as shown in FIG. 22 , if the heating system 200 is in the off state, it is determined that the temperature of the heating system 200 is lower than the third target temperature, and the heating system 200 is controlled to switch to the on state; if the heating system 200 is in the on state, it is determined that the heating system 200 The temperature is greater than or equal to the fourth target temperature, and the heating system 200 is controlled to switch to the off state; wherein, the fourth target temperature is higher than the third target temperature.

In other words, whether to switch the working state of the heating system 200 needs to be determined based on the current working state of the heating system 200 and the temperature of the heating system 200 .

In some embodiments, the third target temperature is T3, and the fourth target temperature is T4, satisfying: 65°C≤T3≤75°C, 76°C≤T4≤85°C. In other words, in a relatively low temperature range, the heating system 200 needs to be turned on to heat the pure water; when it is heated to a relatively high temperature range, the heating system 200 can be turned off based on a higher threshold.

In a specific embodiment, T3=70°C and T4=80°C.

In some embodiments, the controller is configured to determine that the first water supply port of the water purifier is open after the flushing mode ends, and control the water purifier to enter the hot water production mode. In the hot water production mode, the water pump 510 is turned on, and the The water control valve 562 is open, the waste valve 567 is closed, the exhaust valve 566 is closed, and the heating system 200 is controlled based on the received temperature of the heating system 200

In the actual use process, when the handle of the faucet 800 corresponding to the first water supply port is opened, the water purifier can be activated, and the water purifier enters the flushing mode. Under the driving action of the water pump 510, the raw water flows in from the raw water inlet 101, and then flows into the heating system 200 from the purified water outlet 105.

In the embodiment shown in FIG. 1, referring to Table 1, in the hot water production mode, the water pump 510 is turned on, the water pump inlet valve 568 is turned on, the water purification control valve 562 is turned on, the waste water valve 567 is turned off, and the exhaust valve 566 is turned off , the heating system 200 is controlled based on the received temperature of the heating system 200 .

In a specific embodiment, T3=70°C and T4=80°C.

In some embodiments, after the flushing mode ends, it is determined that both the first water supply port and the second water supply port of the water purifier are open, and the water purifier is controlled to enter the warm water making mode. The water control valve 562 is open, the waste valve 567 is closed, and the exhaust valve 566 is closed, and the heating system 200 is controlled based on the temperature of the heating system 200 received.

In the actual use process, the handle of the faucet 800 corresponding to the first water supply port and the second water supply port is opened, the water purifier can be activated, the water purifier enters the flushing mode, and automatically enters the warm water production mode after the flushing mode ends. In this mode, the raw water flows from the raw water inlet 101 under the driving action of the water pump 510, and a part of the pure water flows into the heating system 200 from the water purification outlet 105. The water supply port flows out, and another part of pure water flows out from the second water supply port through the second branch 530 from the purified water outlet 105 .

In the embodiment shown in FIG. 1, referring to Table 1, in the warm water production mode, the water pump 510 is turned on, the water pump inlet valve 568 is turned on, the water purification control valve 562 is turned on, the waste water valve 567 is turned off, and the exhaust valve 566 is turned off, The heating system 200 is controlled based on the received temperature of the heating system 200 .

In a specific embodiment, T3=70°C and T4=80°C.

As shown in Table 1, the water purifier also has a standby state. In the standby state, the water pump 510 is closed, the water pump inlet valve 568 is closed, the water purification control valve 562 is closed, the waste water valve 567 is closed, the exhaust valve 566 and the heating system 200 are closed. Turns on or off based on the temperature of the heating system 200 .

Table 1

The invention also discloses a control method of a water purifier, wherein the water purifier can be the water purifier of any of the above embodiments, the water purifier has a first water supply port and a second water supply port, and the first water supply port It is used to provide hot water, and the second water supply port is used to provide normal temperature pure water.

The water purifier includes a filtration system 100, a water driving system and a heating system 200. The water inlet 221 of the heating system 200 is connected to the water purification outlet 105 of the filtration system 100. The water driving system is used to drive water to flow from the raw water inlet 101 of the filtration system 100 to the The purified water outlet 105 and the exhaust valve 566 are connected between the exhaust port 223 of the heating system 200 and the waste water outlet of the water purifier.

In embodiments where the water drive system includes water pump 510, water drive system on means water pump 510 is on; The water inlet valve 568 is opened.

As shown in FIG. 23 , the control method of the water purifier according to the embodiment of the present invention includes steps 10 to 40 .

Step 10: Collect the temperature of the heating system 200 of the water purifier.

The heating system 200 of the water purifier is used to heat the pure water inside. The heating system 200 can be equipped with a temperature sensor for collecting the water temperature of the heating system 200. In this step, it is preferable to collect the water temperature in the central area of the heating system 200 to reduce the cooling Temperature deviation due to hot water convection.

Step 20: Determine the current state of the exhaust valve 566 of the water purifier and the heating system 200.

The exhaust valve 566 of the water purifier is electrically connected to the control device of the water purifier, and the heating system 200 is also electrically connected to the control device of the water purifier, and the control device can record or monitor the current state of the exhaust valve 566 and the heating system 200, For example, whether the exhaust valve 566 is open or closed, and whether the heating system 200 is open or closed.

Step 30: Determine the working mode of the water purifier.

The working modes of the water purifier include water production mode and non-water production mode.

The water making mode means that at least one water supply port of the water purifier is open, for example, the first water supply port is open and the user is taking hot water, or the second water supply port is open and the user is taking pure water at room temperature. In this state, at least the filtration system 100 needs to produce water.

The non-production mode means that each water supply port of the water purifier is closed.

Step 40: Control the exhaust valve 566 and the heating system 200 based on the temperature of the heating system 200, the current state of the exhaust valve 566 and the heating system 200, and the working mode of the water purifier.

In other words, whether to switch the working states of the heating system 200 and the exhaust valve 566 needs to be determined based on the current working states of the heating system 200 and the exhaust valve 566, the temperature of the heating system 200 and the working mode of the water purifier.

It should be noted that, in the related art, the switching control of the working state of the heating system is usually only performed according to its temperature, or according to the temperature and the water level. In actual use, this control method may lead to insufficient hot water supply or defective equipment safety.

The control method of the water purifier according to the embodiment of the present invention comprehensively considers factors such as the current working state of the heating system 200 and the exhaust valve 566, the temperature of the heating system 200 and the working mode of the water purifier, especially considering the heating system 200 and the working mode of the water purifier. The current working state of the exhaust valve 566 can ensure the supply of hot water under the condition of ensuring safety.

In some embodiments, step 40, controlling the exhaust valve 566 and the heating system 200 based on the temperature of the heating system 200, the current state of the exhaust valve 566 and the heating system 200, and the operating mode of the water purifier, includes: If the heater is in non-water production mode, and both the heating system 200 and the exhaust valve 566 are closed, it is determined that the temperature of the heating system 200 is lower than the first target temperature T1, and both the heating system 200 and the exhaust valve 566 are controlled to be switched to the open state.

As shown in FIG. 21 , when the water purifier is not taking water, that is, in the standby state, if the temperature of the heating system 200 is lower than the first target temperature T1, it means that the water temperature in the heating system 200 is insufficient. By turning on the heating system 200 can pre-produce hot water, so that when the user needs to take hot water, there is instant hot water, and opening the exhaust valve 566 can prevent the air pressure in the heating system 200 from rising suddenly during the heating process, so that the safety of the water purifier is Sex is higher.

In some embodiments, step 40, controlling the exhaust valve 566 and the heating system 200 based on the temperature of the heating system 200, the current state of the exhaust valve 566 and the heating system 200, and the operating mode of the water purifier, includes: If the heater is in the non-water production mode, and both the heating system 200 and the exhaust valve 566 are in the open state, it is determined that the temperature of the heating system 200 is greater than or equal to the second target temperature T2, and both the heating system 200 and the exhaust valve 566 are controlled to be switched to the closed state. ; wherein, the second target temperature is higher than the first target temperature.

As shown in FIG. 21 , when the water purifier is not taking water, that is, in the standby state, if the temperature of the heating system 200 is greater than or equal to the second target temperature T2, it means that the water temperature in the heating system 200 is high enough to close The heating system 200 and vent valve 566 can prevent the water from drying out.

In some embodiments, the first target temperature is T1, and the second target temperature is T2, satisfying: 65°C≤T1≤75°C, 90°C≤T2≤100°C.

In other words, in the relatively low temperature range, the heating system 200 needs to be turned on to heat the pure water, and the exhaust valve 566 needs to be turned on to prevent the pressure in the heating system 200 from becoming too large; when it is to be heated to the relatively high temperature range, it can be based on a higher temperature threshold. The heating system 200 and exhaust valve 566 are closed.

In a specific embodiment, T1=70°C and T2=95°C.

In some embodiments, step 40, controlling the exhaust valve 566 and the heating system 200 based on the temperature of the heating system 200, the current state of the exhaust valve 566 and the heating system 200, and the operating mode of the water purifier, includes: determining the purified water The generator is in the water making mode, and the control exhaust valve 566 is closed.

In other words, regardless of whether the water purifier is producing pure water at room temperature or hot water, the exhaust valve 566 is controlled to be closed, and when the hot water is being produced, the exhaust valve 566 is closed, so that the heating system 200 forms a closed environment, so that the water pump 510 can The hot water is pushed out from the upper water outlet 222; when the water is refrigerated, waste water may be discharged from the waste water outlet 104 when the water purifier is working.

In some embodiments, step 40 controls the exhaust valve 566 and the heating system 200 based on the temperature of the heating system 200, the current state of the exhaust valve 566 and the heating system 200, and the operating mode of the water purifier, including: a water purifier In the water making mode, and the heating system 200 is in the off state, it is determined that the temperature of the heating system 200 is lower than the third target temperature T3, and the heating system 200 is controlled to switch to the on state.

As shown in FIG. 22 , the water purifier is in the water making mode. If the temperature of the heating system 200 is lower than the third target temperature T3, it means that the water temperature in the heating system 200 is insufficient, and the heating system 200 can be turned on to make hot water.

In some embodiments, step 40, controlling the exhaust valve 566 and the heating system 200 based on the temperature of the heating system 200, the current state of the exhaust valve 566 and the heating system 200, and the operating mode of the water purifier, further comprising: purifying the water If the water heater is in the water making mode and the heating system 200 is on, it is determined that the temperature of the heating system 200 is greater than or equal to the fourth target temperature T4, and the heating system 200 is controlled to switch to the off state; wherein the fourth target temperature is higher than the third target temperature .

As shown in FIG. 22, it can be understood that if the water purifier is producing hot water, it means that the user is taking hot water. If the user is taking hot water, the hot water is less, but the water temperature in the heating system 200 is still When the fourth target temperature T4 is reached, it indicates that a fault has occurred, and the heating system 200 is turned off at this time to prevent safety accidents.

If the water purifier is producing pure water at room temperature, since the exhaust valve 566 is closed, that is to say, the heating system 200 is in a completely closed state, setting a temperature threshold lower than the third target temperature can prevent excessive pressure caused by continuous heating. Big.

In a specific embodiment, T3=70°C and T4=80°C.

The following describes the control device of the water purifier provided by the embodiments of the present invention, and the control device of the water purifier described below and the control method of the water purifier described above can be referred to each other correspondingly.

As shown in FIG. 24 , the control device of the water purifier according to the embodiment of the present invention includes: a temperature acquisition module 11 , a state determination module 21 , a mode determination module 31 and a control module 41 .

The temperature collection module 11 is used to collect the temperature of the heating system 200 of the water purifier; the state determination module 21 is used to determine the current state of the exhaust valve 566 of the water purifier and the heating system 200; the mode determination module 31 is used to determine The working mode of the water purifier; the control module 41 is used to control the exhaust valve 566 and the heating system 200 based on the temperature of the heating system 200, the current state of the exhaust valve 566 and the heating system 200 and the working mode of the water purifier; wherein , the water purifier includes a filtration system 100, a water driving system and a heating system 200. The water inlet 221 of the heating system 200 is connected to the water purification outlet 105 of the filtration system 100, and the water driving system is used to drive water from the raw water inlet 101 of the filtration system 100. Flowing to the purified water outlet 105, the exhaust valve 566 is connected between the exhaust port 223 of the heating system 200 and the waste water outlet of the water purifier.

The control device of the water purifier according to the embodiment of the present invention can ensure the supply of hot water under the condition of ensuring safety.

As shown in FIG. 25 , the control method of the water purifier according to the embodiment of the present invention includes step 50: determining that the water purifier is powered on for the first time, and controlling the water purifier to enter the first flushing mode. The first branch 520 of the water purifier is disconnected, the heating system 200 of the water purifier is closed, the waste water valve 567 of the water purifier is opened, and the exhaust valve 566 of the water purifier is closed.

Wherein, as shown in FIG. 1 , the water purifier includes a filtering system 100, a water driving system and a heating system 200, and the first branch 520 is connected between the water purification outlet 105 of the filtering system 100 and the first water supply port of the water purifier , the heating system 200 is installed on the first branch 520, the water driving system is used to drive water to flow from the raw water inlet 101 of the filtration system 100 to the purified water outlet 105, and the waste water valve 567 is connected to the waste water outlet 104 of the filtration system 100 and the water purifier. Between the waste water outlet, the exhaust valve 566 is connected between the exhaust outlet 223 of the heating system 200 and the waste water outlet.

It should be noted that the first branch 520 of the water purifier is disconnected, indicating that the first branch 520 does not flow. For example, a water purification control valve 562 can be installed in the first branch 520, and the water purification control valve 562 can be installed in the heating Between the water inlet 221 of the system 200 and the water purification outlet 105 of the filtration system 100, or by designing a high-strength heating system 200, the water purification control valve 562 may not be provided, and by closing the air outlet 223 of the heating system 200. The exhaust valve 566 and the faucet corresponding to the water outlet 222 of the heating system 200 can also achieve the effect of disconnecting the first branch 520 .

It can be understood that in the first flush mode, the water pump 510 is turned on, the water purification control valve 562 is turned off, the heating system 200 is turned off, the waste water valve 567 is turned on, and the exhaust valve 566 is turned off. In this mode, raw water flows in from the raw water inlet 101 under the driving action of the water pump 510 , and is then discharged from the waste water outlet 104 .

For the water purifier shown in Figure 1, referring to Table 1, in the first flush mode, the water pump 510 is turned on, the water pump inlet valve 568 is turned on, the water purification control valve 562 is turned off, the heating system 200 is turned off, the waste water valve 567 is turned on, and the exhaust valve is turned on. 566 closes.

In actual implementation, the control device of the water purifier can determine whether the water purifier is powered on for the first time according to the power-on status of the water purifier, and if the water purifier is powered on for the first time, it means that the water purifier has been powered on for the first time. Brand new water purifier.

Since the brand-new water purifier has not been actually used, it is inevitable that there will be some impurities in the filter system 100 and the pipeline, such as powder in the filter element of the filter system 100. By designing the above control method, the filter system 100 can be prevented from The impurities enter the heating system 200 or subsequent pipelines during initial use.

The filter system 100 includes a first filter element, a second filter element and a third filter element that are connected in series in series, the second filter element includes a reverse osmosis membrane, and the third filter element is an activated carbon filter element. In the embodiment, the waste water port 104 of the filter system 100 is actually the first filter element. The waste water port 104 of the second filter element. By designing the above-mentioned control method, impurities in the filter system 100 can be prevented from entering the third filter element during initial use, thereby blocking the pores of the third filter element.

On the other hand, after the user has installed the new water purifier and powered it on for the first time, he can also check whether the new water purifier enters the first flushing mode by observing whether it enters the first flushing mode. Specifically, the user can check whether to enter the first flushing mode by looking at the drainage of the waste water pipe or through the display information on the display device of the water purifier.

According to the control method of the water purifier according to the embodiment of the present invention, by rinsing the filtration system 100 separately first, and discharging the rinse water from the waste water port 104, impurities in the filtration system 100 can be prevented from entering the heating system 200 or subsequent pipes during initial use. on the road.

In some embodiments, after the first flushing mode ends, it is determined that the second water supply port of the water purifier is open, and the water purifier is controlled to enter the forced flushing mode. In the forced flushing mode, the water drive system is turned on, the first branch 520 is disconnected, the heating system 200 is turned off, the waste water valve 567 is turned off, and the exhaust valve 566 is turned off;

After the first flushing mode ends, if the user opens the faucet corresponding to the second water supply port, the water purifier is controlled to enter the forced flushing mode.

For example, a faucet may include a mechanical valve core, and an electrical signal switch (such as a Hall switch) is provided at the mechanical valve core. When the faucet is opened, the control device of the water purifier can determine that the second water supply port of the water purifier is open. ; Or the faucet does not use a mechanical valve core, and a solenoid valve is added to the faucet end for corresponding electrical signal control.

In the forced flush mode, the second water supply port (normal temperature water port of the faucet) is opened, the water pump 510 is turned on, the water purification control valve 562 is disconnected, the heating system 200 is turned off, the waste water valve 567 is closed, and the exhaust valve 566 is closed. In this mode, the raw water flows in from the raw water inlet 101 under the driving action of the water pump 510, and then is discharged from the second water supply port of the faucet, which can provide a large flow of flushing.

In the forced flushing mode, the flushing water flows through the entire filtration system 100 and the second branch 530, and since the second water supply port is directly opened, a large flow can be provided for flushing the filtering system 100, preventing the small flow in the first flushing mode. Flow flush is not clean.

In addition, for the filter system 100 including the first filter element, the second filter element and the third filter element connected in series in series, the second filter element includes a reverse osmosis membrane, and the third filter element is an activated carbon filter element in the embodiment, in the forced flushing mode, the water does not After the heating system, the toner of the third filter element can be prevented from being flushed to the heating system.

In some embodiments, after the forced flushing mode ends, it is determined that the second water supply port is closed, and the water purifier is controlled to enter the old water discharge mode. In the old water discharge mode, the water drive system is turned on, the first branch 520 is connected, and the heating system is 200 is closed, waste valve 567 is closed, and exhaust valve 566 is opened.

It can be understood that, through the first flushing mode and the forced flushing mode, impurities and possible old water in the filter system 100 can be flushed away, while the old water draining mode is mainly for draining the old water in the heating system 200, especially For the heat tank type heating system 200, the capacity is relatively large, and impurities or stale water are easily deposited. By controlling the water purifier to enter the stale water discharge mode, the water exchange of the heat exchange system can be realized.

In some embodiments, the preset duration of the first flushing mode is t1, which satisfies: 15s≤t1≤60s. The preset duration of the forced flushing mode is t2, which satisfies: 6min≤t2≤15min. The preset duration of the old water mode is t3, which satisfies: 2min≤t3≤5min. By limiting the duration of each mode to the above range, it is possible to reduce water consumption on the premise of ensuring cleanliness.

In addition, by designing the water discharge mode, since the water inlet 221 is located at the lower part of the heating system 200 and the exhaust port 223 is located at the upper part of the heating system 200, it can also ensure that the water in the heating system 200 is replenished to prevent dry burning.

In a specific embodiment, when it is determined that the water purifier is powered on for the first time, all loads are turned off for 5s, and after entering the first flushing mode for 30s, turn on the faucet handle of the second water supply port, enter the forced flushing mode for 10min, and turn off the second The faucet handle of the water supply port, and then enter the water discharge mode for 3 minutes.

In some embodiments, it is determined that the water purifier is not powered on for the first time, and the water purifier is controlled to enter a flushing mode. In the flushing mode, the water drive system is turned on, the first branch 520 is disconnected, and the waste water valve 567 is turned on.

When the water purifier is not powered on for the first time, it means that the water purifier has entered the normal use stage. In the flushing mode, the water pump 510 is turned on, the water purification control valve 562 is turned off, and the waste water valve 567 is turned on. In this mode, the raw water flows in from the raw water inlet 101 under the driving action of the water pump 510, and then is discharged from the waste water outlet 104, so as to prevent the impurities deposited in the filtration system 100 from flowing downstream.

In some embodiments, it is determined that the water purifier is not powered on for the first time, and the time since the last water discharge reaches a preset value, and the water purifier is controlled to enter the flushing mode. In the flushing mode, the water drive system is turned on, and the first branch 520 is disconnected. open, the waste water valve 567 is opened.

When the time since the last water discharge reaches the preset value, it means that the water purifier has not been used for a period of time. At this time, by executing the flushing mode, the old water in the filtering system 100 can be discharged through the waste water port 104 .

In some embodiments, in the flush mode, the exhaust valve 566 and the heating system 200 are controlled based on the received temperature of the heating system 200 and the current state of the exhaust valve 566 and the heating system 200 .

In some embodiments, the exhaust valve 566 and the heating system 200 are controlled based on the received temperature of the heating system 200 and the current state of the exhaust valve 566 and the heating system 200 in the flush mode, including: in the flush mode, if heating Both the system 200 and the exhaust valve 566 are in a closed state, it is determined that the temperature of the heating system 200 is less than the first target temperature, and both the heating system 200 and the exhaust valve 566 are controlled to be switched to an open state.

In the flushing mode, if both the heating system 200 and the exhaust valve 566 are in the open state, it is determined that the temperature of the heating system 200 is greater than or equal to the second target temperature, and both the heating system 200 and the exhaust valve 566 are controlled to be switched to the closed state; The second target temperature is higher than the first target temperature.

In a specific embodiment, T1=70°C and T2=95°C.

In some embodiments, after the flushing mode ends, it is determined that the second water supply port of the water purifier is open, and the water purifier is controlled to enter the normal temperature water production mode. In the normal temperature water production mode, the water drive system is turned on, and the first branch 520 is disconnected. open, waste valve 567 is closed, exhaust valve 566 is closed, and the heating system 200 is controlled based on the temperature of the heating system 200 received.

In the actual use process, the faucet handle corresponding to the second water supply port is opened, the water purifier can be activated, the water purifier enters the flushing mode, and automatically enters the normal temperature water making mode after the flushing mode ends. Under the driving action of the water pump 510 , the raw water flows in from the raw water inlet 101 , and then flows out from the second water supply port through the second branch 530 from the purified water outlet 105 .

In a specific embodiment, T3=70°C and T4=80°C.

In some embodiments, after the flushing mode ends, it is determined that the first water supply port of the water purifier is open, and the water purifier is controlled to enter the hot water production mode. In the hot water production mode, the water drive system is turned on, and the first branch is 520 is connected, the waste valve 567 is closed, the exhaust valve 566 is closed, and the heating system 200 is controlled based on the temperature of the heating system 200 received.

In a specific embodiment, T3=70°C and T4=80°C.

In some embodiments, after the flushing mode ends, it is determined that both the first water supply port and the second water supply port of the water purifier are open, and the water purifier is controlled to enter the warm water making mode, in which the water drive system is turned on, The first branch 520 is connected, the waste valve 567 is closed, the exhaust valve 566 is closed, and the heating system 200 is controlled based on the temperature of the heating system 200 received.

In a specific embodiment, T3=70°C and T4=80°C.

In the above steps, controlling the heating system 200 based on the received temperature of the heating system 200 includes: if the heating system 200 is in the off state, determining that the temperature of the heating system 200 is lower than the third target temperature, and controlling the heating system 200 to switch to the on state; If the heating system 200 is in the on state, it is determined that the temperature of the heating system 200 is greater than or equal to the fourth target temperature, and the heating system 200 is controlled to switch to the off state; wherein the fourth target temperature is higher than the third target temperature.

As shown in FIG. 26 , a control device for a water purifier according to another embodiment of the present invention includes: a processing module 51, where the processing module 51 is used to determine that the water purifier is powered on for the first time, and to control the water purifier to enter the first flushing mode, In the first flush mode, the water drive system is turned on, the first branch 520 of the water purifier is disconnected, the heating system 200 of the water purifier is turned off, the waste water valve 567 of the water purifier is turned on, and the exhaust valve 566 of the water purifier is closed; The water purifier includes a filtration system 100, a water drive system and a heating system 200. The first branch 520 is connected between the water purification outlet 105 of the filtration system 100 and the first water supply outlet of the water purifier. The heating system 200 is installed in In the first branch 520, the water driving system is used to drive water to flow from the raw water inlet 101 of the filtration system 100 to the purified water outlet 105. The waste water valve 567 is connected between the waste water outlet 104 of the filtration system 100 and the waste water outlet of the water purifier, and discharges the waste water. The gas valve 566 is connected between the exhaust port 223 of the heating system 200 and the waste water outlet.

FIG. 27 illustrates a schematic diagram of the physical structure of an electronic device. As shown in FIG. 27 , the electronic device may include: a processor (processor) 61, a communication interface (Communications Interface) 62, a memory (memory) 63 and a communication bus 64, The processor 61 , the communication interface 62 and the memory 63 communicate with each other through the communication bus 64 . The processor 61 can call the logic instructions in the memory 63 to execute the control method of the water purifier, the method comprising: collecting the temperature of the heating system 200 of the water purifier; determining the exhaust valve 566 of the water purifier and the The current state of the heating system 200; determining the operating mode of the water purifier; based on the temperature of the heating system 200, the current state of the exhaust valve 566 and the heating system 200, and the operating mode of the water purifier , control the exhaust valve 566 and the heating system 200; wherein, the water purifier includes a filtering system 100, a water driving system and the heating system 200, and the water inlet 221 of the heating system 200 is connected to the filtering system 200. The water purification outlet 105 of the system 100 is connected, and the water driving system is used to drive water to flow from the raw water inlet 101 of the filtration system 100 to the purified water outlet 105 , and the exhaust valve 566 is connected to the heating system 200 . Between the exhaust port 223 and the waste water outlet of the water purifier. The method further includes: determining that the water purifier is powered on for the first time, and controlling the water purifier to enter the first flushing mode, in the first flushing mode, the water drive system is turned on, the first branch of the water purifier is disconnected, and the heating system of the water purifier is turned on. closed, the waste water valve of the water purifier is opened, and the exhaust valve of the water purifier is closed; wherein, the water purifier includes a filtering system, a water driving system and a heating system, and the first branch is connected to the water purification outlet of the filtering system and the purified water. Between the first water supply port of the filter, the heating system is installed in the first branch, the water drive system is used to drive water from the raw water inlet of the filter system to the purified water outlet, and the waste water valve is connected to the waste water port of the filter system and the water purifier. Between the waste water outlet, the exhaust valve is connected between the exhaust outlet of the heating system and the waste water outlet.

In addition, the above-mentioned logic instructions in the memory 63 can be implemented in the form of software functional units and can be stored in a computer-readable storage medium when sold or used as an independent product. Based on this understanding, the technical solution of the present invention can be embodied in the form of a software product in essence, or the part that contributes to the prior art or the part of the technical solution. The computer software product is stored in a storage medium, including Several instructions are used to cause a computer device (which may be a personal computer, a server, or a network device, etc.) to execute all or part of the steps of the methods of various embodiments of the present invention. The aforementioned storage medium includes: U disk, mobile hard disk, Read-Only Memory (ROM, Read-Only Memory), Random Access Memory (RAM, Random Access Memory), magnetic disk or optical disk and other media that can store program codes .

Further, an embodiment of the present invention discloses a computer program product. The computer program product includes a computer program stored on a non-transitory computer-readable storage medium. The computer program includes program instructions. When the program instructions are executed by a computer, the computer can execute the program instructions. The method for controlling a water purifier provided by the above method embodiments includes: collecting the temperature of the heating system 200 of the water purifier; determining the exhaust valve 566 of the water purifier and the current state of the heating system 200 ; determine the working mode of the water purifier; control the exhaust based on the temperature of the heating system 200, the current state of the exhaust valve 566 and the heating system 200 and the working mode of the water purifier Valve 566 and the heating system 200; wherein, the water purifier includes the filtration system 100, the water driving system and the heating system 200, the water inlet 221 of the heating system 200 and the water purification outlet of the filtration system 100 105, the water driving system is used to drive water to flow from the raw water inlet 101 of the filtration system 100 to the purified water outlet 105, and the exhaust valve 566 is connected to the exhaust port 223 of the heating system 200 and the between the waste water outlet of the water purifier.

On the other hand, an embodiment of the present invention further provides a non-transitory computer-readable storage medium on which a computer program is stored, and when the computer program is executed by a processor, is implemented to perform the control of the water purifier provided by the above embodiments The method includes: collecting the temperature of the heating system 200 of the water purifier; determining the exhaust valve 566 of the water purifier and the current state of the heating system 200; determining the working mode of the water purifier; The temperature of the heating system 200, the current state of the exhaust valve 566 and the heating system 200, and the working mode of the water purifier, the exhaust valve 566 and the heating system 200 are controlled; wherein, the The water purifier includes a filtration system 100, a water driving system and the heating system 200. The water inlet 221 of the heating system 200 is connected to the water purification outlet 105 of the filtration system 100. The water driving system is used to drive water from The raw water inlet 101 of the filtration system 100 flows to the purified water outlet 105, and the exhaust valve 566 is connected between the exhaust outlet 223 of the heating system 200 and the waste water outlet of the water purifier.

As shown in FIG. 1 , the present invention further discloses a water purifier, which includes: a filtering system 100 , a heating system 200 , a water driving system and a controller.

The filtration system 100 has a raw water inlet 101 and a purified water outlet 105; the water inlet 221 at the lower part of the heating system 200 is connected to the purified water outlet 105, and the water outlet 222 at the upper part of the heating system 200 is connected to the first water supply outlet of the water purifier , the exhaust port 223 of the heating system 200 is connected with an exhaust valve 566, and the heating system 200 is provided with a temperature sensor; the water driving system is connected to the filtering system 100 and is arranged upstream of the water purification outlet 105, and the water driving system is used to drive water from The raw water inlet 101 flows to the purified water outlet 105, and is used to drive water to be discharged from the water outlet 222 of the heating system 200; the controller is electrically connected to the temperature sensor, the exhaust valve 566 and the heating system 200, and is configured to be based on the signal of the temperature sensor, The current state of the exhaust valve 566 and the heating system 200 and the operating mode of the water purifier control the exhaust valve 566 and the heating system 200 .

In the water purifier of the embodiment of the present invention, by designing the above-mentioned controller, factors such as the current working state of the heating system 200 and the exhaust valve 566, the temperature of the heating system 200 and the working mode of the water purifier can be comprehensively considered. The current working state of the heating system 200 and the exhaust valve 566 can ensure the supply of hot water while ensuring safety.

In some embodiments, the controller is set so that the water purifier is in a non-producing mode, and the heating system 200 and the exhaust valve 566 are both closed, determine that the temperature of the heating system 200 is lower than the first target temperature, and control the heating system 200 and The exhaust valve 566 is switched to the open state; the water purifier is in the non-water production mode, and the heating system 200 and the exhaust valve 566 are both in the open state, it is determined that the temperature of the heating system 200 is greater than or equal to the second target temperature, and the heating system is controlled 200 and exhaust valve 566 are both switched to a closed state; wherein the second target temperature is higher than the first target temperature.

In some embodiments, the controller is configured to determine that the water purifier is in the water production mode, and control the exhaust valve 566 to close; when the water purifier is in the water production mode, the heating system 200 is in a closed state, and it is determined that the temperature of the heating system 200 is less than For the third target temperature, control the heating system 200 to switch to the ON state; when the water purifier is in the water making mode, the heating system 200 is in the ON state, determine that the temperature of the heating system 200 is greater than or equal to the fourth target temperature, and control the heating system 200 to switch to the off state; wherein the fourth target temperature is higher than the third target temperature.

The device embodiments described above are only illustrative, wherein the units described as separate components may or may not be physically separated, and the components shown as units may or may not be physical units, that is, they may be located in One place, or it can be distributed over multiple network elements. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution in this embodiment. Those of ordinary skill in the art can understand and implement it without creative effort.

From the description of the above embodiments, those skilled in the art can clearly understand that each embodiment can be implemented by means of software plus a necessary general hardware platform, and certainly can also be implemented by hardware. Based on this understanding, the above-mentioned technical solutions can be embodied in the form of software products in essence or the parts that make contributions to the prior art, and the computer software products can be stored in computer-readable storage media, such as ROM/RAM, magnetic A disc, an optical disc, etc., includes several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to perform the methods described in various embodiments or some parts of the embodiments.

Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of the present invention, but not to limit them; although the present invention has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art should understand that it can still be The technical solutions described in the foregoing embodiments are modified, or some technical features thereof are equivalently replaced; and these modifications or replacements do not make the essence of the corresponding technical solutions deviate from the spirit and scope of the technical solutions of the embodiments of the present invention.

The above embodiments are only used to illustrate the present invention, but not to limit the present invention. Although the present invention has been described in detail with reference to the embodiments, those of ordinary skill in the art should understand that various combinations, modifications or equivalent replacements to the technical solutions of the present invention do not depart from the spirit and scope of the technical solutions of the present invention, and should cover within the scope of the claims of the present invention.

Claims

A control method for a water purifier, comprising:

Collect the temperature of the heating system of the water purifier;

determining the current state of the water purifier's exhaust valve and the heating system;

determining the working mode of the water purifier;

controlling the exhaust valve and the heating system based on the temperature of the heating system, the current state of the exhaust valve and the heating system, and the operating mode of the water purifier;

Wherein, the water purifier includes a filtering system, a water driving system and the heating system, the water inlet of the heating system is connected with the water purification outlet of the filtering system, and the water driving system is used to drive water from the The raw water inlet of the filtration system flows to the purified water outlet, and the exhaust valve is connected between the exhaust outlet of the heating system and the waste water outlet of the water purifier.
The control method of a water purifier according to claim 1, wherein the temperature of the heating system, the current state of the exhaust valve and the heating system, and the working mode of the water purifier are based on , controlling the exhaust valve and the heating system, including:

The water purifier is in a non-water production mode, and both the heating system and the exhaust valve are in a closed state, determining that the temperature of the heating system is lower than a first target temperature, and controlling the heating system and the exhaust The valves are switched to the open state.
The method for controlling a water purifier according to claim 2, wherein the method is based on the temperature of the heating system, the current state of the exhaust valve and the heating system, and the working mode of the water purifier. , controlling the exhaust valve and the heating system, including:

The water purifier is in a non-producing mode, and both the heating system and the exhaust valve are in an open state, determining that the temperature of the heating system is greater than or equal to a second target temperature, and controlling the heating system and the The exhaust valves are switched to the closed state;

Wherein, the second target temperature is higher than the first target temperature.
The method for controlling a water purifier according to claim 3, wherein the first target temperature is T1, the second target temperature is T2, and satisfies: 65°C≤T1≤75°C, 90°C≤T2 ≤100℃.
The control method of a water purifier according to claim 1, wherein the temperature of the heating system, the current state of the exhaust valve and the heating system, and the working mode of the water purifier are based on , controlling the exhaust valve and the heating system, including:

Determine that the water purifier is in the water making mode, and control the exhaust valve to close;

The water purifier is in a water making mode and the heating system is in an off state, it is determined that the temperature of the heating system is lower than a third target temperature, and the heating system is controlled to switch to an on state.
The method for controlling a water purifier according to claim 5, wherein the method is based on the temperature of the heating system, the current state of the exhaust valve and the heating system, and the working mode of the water purifier. , controlling the exhaust valve and the heating system, further comprising:

The water purifier is in the water making mode, and the heating system is in an on state, determining that the temperature of the heating system is greater than or equal to a fourth target temperature, and controlling the heating system to switch to an off state;

Wherein, the fourth target temperature is higher than the third target temperature.
The method for controlling a water purifier according to claim 6, wherein the third target temperature is T3, the fourth target temperature is T4, and satisfies: 65°C≤T3≤75°C, 76°C≤T4 ≤85℃.
A control device for a water purifier, comprising:

The temperature acquisition module is used to collect the temperature of the heating system of the water purifier;

a state determination module, configured to determine the current state of the exhaust valve of the water purifier and the heating system;

a mode determination module for determining the working mode of the water purifier;

a control module for controlling the exhaust valve and the heating system based on the temperature of the heating system, the current state of the exhaust valve and the heating system, and the working mode of the water purifier;

Wherein, the water purifier includes a filtering system, a water driving system and the heating system, the water inlet of the heating system is connected with the water purification outlet of the filtering system, and the water driving system is used to drive water from the The raw water inlet of the filtration system flows to the purified water outlet, and the exhaust valve is connected between the exhaust outlet of the heating system and the waste water outlet of the water purifier.
A control method for a water purifier, comprising:

It is determined that the water purifier is powered on for the first time, and the water purifier is controlled to enter the first flush mode. In the first flush mode, the water drive system is turned on, the first branch of the water purifier is disconnected, and the water purifier is disconnected. The heating system of the water purifier is closed, the waste water valve of the water purifier is opened, and the exhaust valve of the water purifier is closed;

Wherein, the water purifier includes a filtering system, the water driving system and the heating system, and the first branch is connected between the water purification outlet of the filtering system and the first water supply port of the water purifier During the time, the heating system is installed on the first branch, the water driving system is used to drive water to flow from the raw water inlet of the filtration system to the purified water outlet, and the waste water valve is connected to the filtration system. Between the waste water outlet and the waste water outlet of the water purifier, the exhaust valve is connected between the exhaust outlet of the heating system and the waste water outlet.
The method for controlling a water purifier according to claim 9, wherein after the first flushing mode ends, it is determined that the second water supply port of the water purifier is open, and the water purifier is controlled to enter the forced flushing mode ,

In the forced flushing mode, the water drive system is turned on, the first branch is disconnected, the heating system is turned off, the waste water valve is turned off, and the exhaust valve is turned off;

Wherein, the second water supply port is communicated with the purified water outlet.
The control method of a water purifier according to claim 10, wherein after the forced flushing mode ends,

It is determined that the second water supply port is closed, and the water purifier is controlled to enter the old water discharge mode. In the old water discharge mode, the water drive system is turned on, the first branch is connected, and the heating system is turned off, The waste valve is closed and the exhaust valve is opened.
The control method of a water purifier according to claim 11, wherein the preset duration of the water discharge mode is t3, which satisfies: 2min≤t3≤5min.
The method for controlling a water purifier according to claim 10, wherein the preset duration of the forced flushing mode is t2, which satisfies: 6min≤t2≤15min.
The control method of a water purifier according to claim 8, wherein the preset duration of the first flushing mode is t1, which satisfies: 15s≤t1≤60s.
The control method of a water purifier according to any one of claims 8-14, wherein,

It is determined that the water purifier is not powered on for the first time, and the time since the last water outlet is greater than the preset value, and the water purifier is controlled to enter the flushing mode. In the flushing mode, the water drive system is turned on, and the first branch Disconnected, the waste water valve opens.
The method for controlling a water purifier according to claim 15, wherein in the flushing mode, the control is performed based on the received temperature of the heating system and the current state of the exhaust valve and the heating system. the exhaust valve and the heating system.
The control method of a water purifier according to claim 16, characterized in that, in the flushing mode, based on the received temperature of the heating system and the current state of the exhaust valve and the heating system , controlling the exhaust valve and the heating system, including:

In the flushing mode, if both the heating system and the exhaust valve are in a closed state, it is determined that the temperature of the heating system is lower than the first target temperature, and both the heating system and the exhaust valve are controlled to be switched to open condition;

In the flushing mode, if both the heating system and the exhaust valve are in an open state, it is determined that the temperature of the heating system is greater than or equal to the second target temperature, and both the heating system and the exhaust valve are controlled to be switched to the closed state;

Wherein, the second target temperature is higher than the first target temperature.
The method for controlling a water purifier according to claim 17, wherein the first target temperature is T1, the second target temperature is T2, and satisfies: 65°C≤T1≤75°C, 90°C≤T2 ≤100℃.
The control method of a water purifier according to claim 15, wherein,

After the flushing mode is over, it is determined that the second water supply port of the water purifier is open, and the water purifier is controlled to enter the normal temperature water making mode. In the normal temperature water making mode, the water drive system is turned on, and the The first branch is disconnected, the waste valve is closed, the exhaust valve is closed, and the heating system is controlled based on the received temperature of the heating system; or

After the flushing mode is over, it is determined that the first water supply port of the water purifier is open, and the water purifier is controlled to enter the hot water production mode. In the hot water production mode, the water drive system is turned on, The first branch is in communication, the waste water valve is closed, the exhaust valve is closed, and the heating system is controlled based on the received temperature of the heating system; or

After the flushing mode ends, it is determined that both the first water supply port and the second water supply port of the water purifier are open, and the water purifier is controlled to enter the warm water making mode. In the warm water making mode, the water The drive system is turned on, the first branch is connected, the waste water valve is closed, the exhaust valve is closed, and the heating system is controlled based on the received temperature of the heating system.
The method for controlling a water purifier according to claim 19, wherein the controlling the heating system based on the received temperature of the heating system comprises:

If the heating system is in an off state, determining that the temperature of the heating system is lower than a third target temperature, and controlling the heating system to switch to an on state;

If the heating system is in the on state, determine that the temperature of the heating system is greater than or equal to the fourth target temperature, and control the heating system to switch to the off state;

Wherein, the fourth target temperature is higher than the third target temperature.
The control method of a water purifier according to claim 20, wherein the third target temperature is T3, the fourth target temperature is T4, and satisfies: 65°C≤T3≤75°C, 76°C≤T4 ≤85℃.
A control device for a water purifier, comprising:

The processing module is used to determine that the water purifier is powered on for the first time, and to control the water purifier to enter the first flushing mode. In the first flushing mode, the water drive system is turned on, and the first branch of the water purifier is disconnected. The heating system of the water purifier is closed, the waste water valve of the water purifier is opened, and the exhaust valve of the water purifier is closed;

Wherein, the water purifier includes a filtering system, the water driving system and the heating system, and the first branch is connected between the water purification outlet of the filtering system and the first water supply port of the water purifier. During the time, the heating system is installed on the first branch, the water driving system is used to drive water to flow from the raw water inlet of the filtration system to the purified water outlet, and the waste water valve is connected to the filtration system. Between the waste water outlet and the waste water outlet of the water purifier, the exhaust valve is connected between the exhaust outlet of the heating system and the waste water outlet.
[Corrected 13.08.2021 in accordance with Rule 91]
An electronic device, comprising a memory, a processor, and a computer program stored in the memory and running on the processor, characterized in that, when the processor executes the program, the implementation of claims 1 to 7 or 8 to 21 The steps of any one of the control methods of the water purifier.
[Correction 13.08.2021 according to Rule 91] A non-transitory computer-readable storage medium on which a computer program is stored, characterized in that the computer program, when executed by a processor, implements claims 1 to 7 or 8 to 21 The steps of any one of the control methods of the water purifier.
[Correction 13.08.2021 according to Rule 91] A water purifier, characterized in that it includes:

a filtration system, the filtration system has a raw water inlet and a purified water outlet;

A heating system, the water inlet set at the lower part of the heating system is connected with the water purification outlet, the water outlet set at the upper part of the heating system is connected with the first water supply port of the water purifier, and the discharge port of the heating system The air port is connected with an exhaust valve, and the heating system is provided with a temperature sensor;

a water drive system connected to the filtration system and arranged upstream of the water purification outlet, the water drive system for driving water to flow from the raw water inlet to the purified water outlet, and for The driving water is discharged from the water outlet of the heating system;

a controller electrically connected to the temperature sensor, the exhaust valve and the heating system and configured to be based on the temperature sensor signal, the current state of the exhaust valve and the heating system and the working mode of the water purifier, controlling the exhaust valve and the heating system.
[Correction 13.08.2021 according to Rule 91] The water purifier of claim 25, wherein the controller is set so that the water purifier is in a non-producing mode, and the heating system and the drain The air valves are all in the closed state, it is determined that the temperature of the heating system is lower than the first target temperature, and both the heating system and the exhaust valve are controlled to be switched to the open state; the water purifier is in the non-producing mode, and all The heating system and the exhaust valve are both in an open state, it is determined that the temperature of the heating system is greater than or equal to a second target temperature, and both the heating system and the exhaust valve are controlled to be switched to a closed state; wherein, the The second target temperature is higher than the first target temperature.
[Correction 13.08.2021 according to Rule 91] The water purifier according to claim 25, wherein the controller is configured to determine that the water purifier is in the water making mode, and control the exhaust valve to close; When the water purifier is in the water making mode, the heating system is in a closed state, it is determined that the temperature of the heating system is lower than the third target temperature, and the heating system is controlled to switch to an on state; In the water mode, the heating system is in an on state, it is determined that the temperature of the heating system is greater than or equal to a fourth target temperature, and the heating system is controlled to switch to an off state; wherein the fourth target temperature is higher than the fourth target temperature. Three target temperatures.
[Correction according to Rule 91 13.08.2021] The water purifier according to any one of claims 25-27, further comprising:

and a water return pipe, which is connected between the clean water outlet and the inlet of the water drive system.
[Correction 13.08.2021 under Rule 91] The water purifier of claim 28, further comprising:

a first branch, the first branch is connected between the water purification outlet and the first water supply port of the water purifier, and the heating system is arranged on the first branch;

A second branch, the second branch is connected between the water purification outlet and the second water supply port of the water purifier.
[Correction 13.08.2021 according to Rule 91] The water purifier according to claim 29, wherein the water return pipe is connected to the water purification outlet through the second branch, and the return pipe is connected to the The connection of the second branch is located near the second water supply port.
[Correction 13.08.2021 according to Rule 91] The water purifier according to any one of claims 25-27, characterized in that, the air outlet is set higher than the water outlet of the heating system, and the The setting position of the water outlet of the heating system is higher than the water inlet of the heating system.