CN212315727U - Integrated waterway component and water purifier with same - Google Patents

Abstract

The utility model provides an integrated water route component and purifier that has it. The integrated waterway component is provided with a filter element mounting seat, a water inlet electromagnetic valve water inlet interface, a water inlet electromagnetic valve water outlet interface, a booster pump water inlet interface, a booster pump water outlet interface, a wastewater electromagnetic valve water inlet interface and a wastewater electromagnetic valve water outlet interface, the filter element mounting seat is used for communicating the composite filter element, and the filter element mounting seat is provided with a first water inlet interface, a first wastewater water outlet interface and a first pure water outlet interface and is used for communicating the composite reverse osmosis filter element in the composite filter element; the filter element mounting seat is also provided with a second water inlet connector and a second water outlet connector which are used for communicating the composite front filter element or rear filter element in the composite filter element. Like this, the combined filter core of compound reverse osmosis filter core can be connected to integrated water route component, greatly reduced the size of integrated water route component, the runner in the integrated water route component obtains shortening, and the circulation resistance of rivers reduces, and then makes the purifier energy consumption reduce, and the structure is exquisite small and exquisite more.

Description

Integrated waterway component and water purifier with same

Technical Field

The utility model relates to a technical field of aqueous cleaning specifically, relates to an integrated waterway component and purifier that has it.

Background

With the improvement of living standard, the water quality requirement of people on domestic water is higher and higher. There are various purifiers in the existing market, and the purifier is installed on the water supply runner, carries out filtration purification to the running water.

In order to improve the water quality, most of the water purifiers are formed by connecting multi-stage filter elements in series end to end and respectively filter different substances in raw water.

In order to connect multistage filter core, this integrated waterway component need be provided with a plurality of filter core mount pads, consequently leads to integrated waterway component's size great, and the water route is longer, and the circulation resistance of rivers is great, and then leads to the purifier energy consumption higher. In addition, the provision of multiple cartridge mounts on the integrated waterway member may also result in more complex water flow passages within the integrated waterway member. Most of existing integrated waterway components are integrally formed, and on the basis, the more complex the waterway channel in the integrated waterway component is, the more difficult the integrated waterway component is to be processed is, and the requirements on the design of the internal waterway channel are higher.

SUMMERY OF THE UTILITY MODEL

In order to at least partially solve the problems of the prior art, according to one aspect of the present invention, an integrated waterway member is provided. The integrated waterway component is provided with a filter element mounting seat, a water inlet electromagnetic valve water inlet interface, a water inlet electromagnetic valve water outlet interface, a booster pump water inlet interface, a booster pump water outlet interface, a wastewater electromagnetic valve water inlet interface and a wastewater electromagnetic valve water outlet interface, wherein the filter element mounting seat is used for mounting a composite filter element, and the filter element mounting seat is provided with a first water inlet interface, a first wastewater water outlet interface and a first pure water outlet interface and is used for communicating with a composite reverse osmosis filter element in the composite filter element; the filter element mounting seat is also provided with a second water inlet connector and a second water outlet connector which are used for communicating the composite front filter element or rear filter element in the composite filter element.

Through this kind of setting, compound reverse osmosis filter core can be connected to integrated waterway component. When realizing multi-stage filtration, greatly reduced the size of integrated water route component, the runner in the integrated water route component obtains shortening, and the circulation resistance of rivers reduces, and then makes the purifier energy consumption reduce, and the structure is exquisite small and exquisite more. In addition, only one filter element mounting seat needs to be arranged on the integrated waterway component, so that a water flow channel in the integrated waterway component is simpler. From this, even this integrated waterway component adopts integrated into one piece to make, also can reduce the design degree of difficulty of the rivers passageway in the integrated waterway component, and then greatly reduced its processing degree of difficulty.

Illustratively, the integrated waterway component is internally provided with a water inlet flow passage, a pure water flow passage and a waste water flow passage, wherein the water inlet flow passage is communicated to the second water inlet interface, the second water outlet interface is communicated to the water inlet interface of the water inlet electromagnetic valve, the water outlet interface of the water inlet electromagnetic valve is communicated to the water inlet interface of the booster pump, the water outlet interface of the booster pump is communicated to the first water inlet interface, the first waste water outlet interface is communicated to the water inlet interface of the waste water electromagnetic valve, the water outlet interface of the waste water electromagnetic valve is communicated to the waste water flow passage, and the first pure water outlet interface is communicated to the pure water flow passage. Therefore, a complete water flow passage is formed in the integrated waterway component, and the use requirement of the water purifier is met.

Illustratively, the first water inlet interface, the first wastewater outlet interface, the first pure water outlet interface, the second water inlet interface and the second water outlet interface extend along a vertical direction of the integrated waterway member. Through the arrangement, the composite filter element can be conveniently installed, and the installation difficulty is reduced.

Exemplarily, the water inlet channel, the pure water channel and the wastewater channel are located at a first transverse end of the integrated waterway member, the water inlet solenoid valve water inlet interface, the water inlet solenoid valve water outlet interface, the wastewater solenoid valve water inlet interface and the wastewater solenoid valve water outlet interface are located at a second transverse end of the integrated waterway member, and the first transverse end and the second transverse end are located at two sides of the filter element mounting seat along the transverse direction of the integrated waterway member. Through the arrangement, the water inlet of the integrated waterway component is located on the same side, so that the integrated waterway component is convenient to connect with an external pipeline, the water inlet electromagnetic valve and the wastewater electromagnetic valve can be located on the opposite side, and therefore the integrated waterway component is more reasonable in layout, convenient to process and minimum in size.

Illustratively, the water inlet flow passage, the pure water flow passage, and the waste water flow passage extend in a lateral direction of the integrated waterway member. Therefore, the water flow passage of the integrated waterway component is neat and orderly, and the integrated waterway component is convenient to process and manufacture and has the smallest size.

Illustratively, the water inlet channel is located between the pure water channel and the wastewater channel, and the water outlet interface of the wastewater solenoid valve is coaxially arranged with the wastewater channel. In this way, the layout of the waterway on the integrated waterway member can be simplified, and the resistance to the discharge of wastewater can be reduced.

Illustratively, the second water inlet interface and the first pure water outlet interface are sequentially arranged along the longitudinal direction of the integrated waterway member, the first wastewater outlet interface, the second water outlet interface and the first water inlet interface are sequentially arranged along the longitudinal direction, and along the transverse direction, the second water inlet interface is aligned with a gap between the first wastewater outlet interface and the second water outlet interface, and the first pure water outlet interface is aligned with a gap between the second water outlet interface and the first water inlet interface. Thus, the integrated waterway member can be suitable for connecting the composite filter element used by the integrated waterway member.

Exemplarily, the device further comprises a check valve, a water inlet pipe of the check valve is communicated to the first pure water outlet port, and a water outlet pipe of the check valve is communicated to the pure water flow channel. The check valve can prevent water outside the integrated waterway component from flowing back to the inside of the integrated waterway component, so that purified pure water is polluted.

Illustratively, the cartridge mount is disposed on a first surface of the integrated waterway member, and the check valve is disposed on a second surface opposite the first surface. Therefore, the size of the integrated waterway component can be reduced, and the integrated waterway component is more exquisite and small.

Illustratively, the booster pump water inlet interface and the booster pump water outlet interface are located on the same side of the filter element mounting seat along the longitudinal direction of the integrated waterway component. Like this, be convenient for connect the booster pump, make the water circulating path in the purifier neat orderly, the pipeline of connecting the booster pump is shortest, reduces the overall structure of purifier.

Exemplarily, the booster pump water inlet interface includes the booster pump inlet channel and is connected to the booster pump inlet channel of the outer end of booster pump inlet channel connects, the booster pump outlet interface includes the booster pump outlet conduit and is connected to the booster pump outlet conduit of the outer end of booster pump outlet conduit connects, the booster pump inlet channel with the booster pump outlet conduit follows the longitudinal extension of integrated waterway component. Therefore, the water flow passage of the integrated waterway component is simple in structure, orderly and orderly, and convenient to process and manufacture.

Illustratively, the water inlet solenoid valve water inlet interface and the water inlet solenoid valve water outlet interface extend along a transverse direction of the integrated waterway member, and/or the waste solenoid valve water inlet interface and the waste solenoid valve water outlet interface extend along a transverse direction of the integrated waterway member. Therefore, the water flow passage of the integrated waterway component is simple in structure, orderly and orderly, and convenient to process and manufacture.

Illustratively, the integrated waterway member includes a water inlet solenoid valve connected to the water inlet solenoid valve water inlet interface and the water inlet solenoid valve water outlet interface, and/or a wastewater solenoid valve connected to the wastewater solenoid valve water inlet interface and the wastewater solenoid valve water outlet interface. By this arrangement, the inflow and/or the waste water can be controlled.

According to another aspect of the present invention, there is provided a water purifier, comprising any one of the integrated waterway members described above.

A series of concepts in a simplified form are introduced in the disclosure, which will be described in further detail in the detailed description section. The summary of the invention is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

The advantages and features of the present invention are described in detail below with reference to the accompanying drawings.

Drawings

The following drawings of the present invention are used herein as part of the present invention for understanding the present invention. There are shown in the drawings, embodiments and descriptions thereof, which are used to explain the principles of the invention. In the drawings, there is shown in the drawings,

fig. 1 is a first angled perspective view of an integrated waterway member according to an exemplary embodiment of the present invention;

FIG. 2 is a second angled perspective view of the integrated waterway member shown in FIG. 1;

FIG. 3 is a third angled perspective view, partially in section, of the integrated waterway member shown in FIG. 1; and

fig. 4 is a schematic water path diagram of a water purifier according to an exemplary embodiment of the present invention.

Wherein the figures include the following reference numerals:

100. an integrated waterway member; 110. a first transverse end; 120. a second transverse end portion; 130. a first surface; 140. a second surface; 200. a filter element mounting seat; 210. a first water inlet interface; 220. a first wastewater outlet port; 230. a first pure water outlet port; 240. a second water inlet interface; 250. a second water outlet interface; 310. a water inlet electromagnetic valve; 311. a water inlet interface of the water inlet electromagnetic valve; 312. a water inlet electromagnetic valve water outlet interface; 320. a booster pump water inlet interface; 321. a water inlet pipeline of the booster pump; 322. a booster pump water inlet pipeline joint; 330. a water outlet interface of the booster pump; 331. a booster pump water outlet pipeline; 332. a booster pump water outlet pipeline joint; 340. a wastewater solenoid valve; 341. a wastewater electromagnetic valve water inlet interface; 342. a wastewater solenoid valve water outlet interface; 350. a check valve; 410. a water inlet flow channel; 420. a pure water flow passage; 430. a waste water flow channel.

Detailed Description

In the following description, numerous details are provided to provide a thorough understanding of the present invention. One skilled in the art, however, will understand that the following description illustrates only a preferred embodiment of the invention and that the invention may be practiced without one or more of these details. In addition, some technical features that are well known in the art are not described in detail in order to avoid obscuring the present invention.

The utility model provides an integrated waterway component 100. The integrated waterway component 100 is mainly used in a water purifier, is used for integrating waterways of all parts in the water purifier, forms water flow passage connection among all elements, and can also be used for fixing a filter element of the water purifier. An integrated waterway member 100 according to an embodiment of the present invention will be described in detail with reference to fig. 1-3.

Illustratively, as shown in fig. 1 and 3, integrated waterway member 100 may include a cartridge mount 200. In use, the water passing end of the composite filter element can be mounted to the filter element mounting base 200. The filter element mounting seat 200 enables the flow channel in the integrated waterway member 100 to be communicated with the corresponding flow channel in the composite filter element through the butt joint of the water inlet and outlet interfaces on the filter element and the water inlet and outlet interfaces on the composite filter element. To clearly illustrate the flow path of integrated waterway member 100, only the water inlet and outlet interfaces (described in detail below) of cartridge mount 200 are shown in fig. 1 and 3, and the portion of cartridge mount 200 for securing the composite cartridge is omitted.

The integrated waterway member 100 may further include a water inlet solenoid valve water inlet interface 311, a water inlet solenoid valve water outlet interface 312, a booster pump water inlet interface 320, a booster pump water outlet interface 330, a wastewater solenoid valve water inlet interface 341, and a wastewater solenoid valve water outlet interface 342, which may be located at any position on the integrated waterway member 100 as long as it can satisfy its normal operation. Preferably, cartridge mount 200 may be integrally formed with integrated waterway member 100.

The utility model discloses in, filter core mount pad 200 is used for communicating composite filter element. After the composite filter element is installed on the filter element installation seat 200, the water inlet and outlet interfaces on the composite filter element can be in butt joint with the water inlet and outlet interfaces on the filter element installation seat 200, so that water flows between the composite filter element and the filter element installation seat 200. The composite filter element can be a composite filter element of a reverse osmosis filter element and a front filter element, and can also be a composite filter element of a reverse osmosis filter element and a rear filter element. The cartridge mounting base 200 may have a first water inlet 210, a first waste water outlet 220, and a first pure water outlet 230, which may be used to communicate with a reverse osmosis cartridge combined in a composite cartridge. Cartridge mounting base 200 can also have a second inlet connection 240 and a second outlet connection 250 that can be used to communicate with a front cartridge or a rear cartridge that is combined in a composite cartridge. The front filter element can comprise a PP cotton filter element, a front activated carbon filter element and the like. The post-filter element may comprise a post-activated carbon filter element or the like.

The water inlet solenoid valve water inlet interface 311 and the water inlet solenoid valve water outlet interface 312 may be connected to the water inlet solenoid valve 310 to control water inlet. The water flow can enter the water inlet solenoid valve 310 through the water inlet interface 311 of the water inlet solenoid valve, and then flow out through the water outlet interface 312 of the water inlet solenoid valve after passing through the water inlet solenoid valve 310.

The booster pump water inlet interface 320 and the booster pump water outlet interface 330 may be connected to the booster pump. As is known in the art, reverse osmosis cartridges rely on pressure to drive a flow of water through a reverse osmosis layer to separate pure water from other substances in the water flow. The booster pump is used for increasing pressure for rivers to satisfy the work demand of reverse osmosis filter core. The water flow is connected to the booster pump through the booster pump water inlet interface 320, is pressurized by the booster pump, and then flows out through the booster pump water outlet interface 330.

As is known in the art, reverse osmosis cartridges produce a proportion of waste water at the same time as pure water is produced. Wastewater can enter the wastewater solenoid valve 340 through the first wastewater outlet port 220 and the wastewater solenoid valve inlet port 341 in sequence, and then flows out through the wastewater solenoid valve outlet port 342 after passing through the wastewater solenoid valve 340. Pure water may flow out through the first pure water outlet port 230.

In an embodiment where the second water inlet 240 and the second water outlet 250 may be connected to a pre-filter, the second water inlet 240 and the second water outlet 250 are located upstream of the first water inlet 210, the first wastewater outlet 220 and the first pure water outlet 230 on a water path, that is, water may sequentially enter the pre-filter through the second water inlet 240, and after being filtered by the pre-filter, sequentially enter the reverse osmosis filter through the second water outlet 250 and the first water inlet 210, and after being filtered by the reverse osmosis filter, wastewater may sequentially enter the wastewater solenoid valve 340 through the first wastewater outlet 220 and the wastewater solenoid valve inlet 341, and after passing through the wastewater solenoid valve 340, the wastewater may then flow out through the wastewater solenoid valve outlet 342. Pure water may flow out through the first pure water outlet port 230. The water inlet interface 311 and the water outlet interface 312 of the water inlet solenoid valve may be disposed at the upstream of the second water inlet interface 240, or may be disposed between the water outlet interface 312 of the water inlet solenoid valve and the first water inlet interface 210.

In the embodiment where the second water inlet 240 and the second water outlet 250 are connected to the rear filter element, the second water inlet 240 and the second water outlet 250 may be disposed at the downstream of the first water inlet 210, the first wastewater outlet 220 and the first pure water outlet 230, that is, the water flow may enter the reverse osmosis filter element through the first water inlet 210, after being filtered by the reverse osmosis filter element, the wastewater may sequentially enter the wastewater solenoid valve 340 through the first wastewater outlet 220 and the wastewater solenoid valve inlet 341, and after passing through the wastewater solenoid valve 340, the wastewater may flow out through the wastewater solenoid valve outlet 342. Pure water can enter the post-filter via the first pure water outlet 230 and the second water inlet 240 in sequence, and then flows out via the second water outlet 250 after passing through the post-filter. The water inlet interface 311 and the water outlet interface 312 of the water inlet solenoid valve may be disposed at the upstream of the first water inlet interface 210, or may be disposed between the first pure water outlet interface 230 and the second water inlet interface 240.

With this arrangement, the integrated waterway member 100 may be connected to the composite reverse osmosis cartridge. When realizing multi-stage filtration, greatly reduced integrated waterway component 100's size, the runner in integrated waterway component 100 obtains shortening, and the circulation resistance of rivers reduces, and then makes the purifier energy consumption reduce, and the structure is exquisite small and exquisite more. In addition, since only one cartridge mounting seat 200 is required to be disposed on the integrated waterway member 100, a water flow passage in the integrated waterway member 100 is simpler. From this, even this integrated waterway component adopts integrated into one piece to make, also can reduce the design degree of difficulty of the rivers passageway in the integrated waterway component, and then greatly reduced its processing degree of difficulty.

Preferably, as shown in fig. 4, the integrated waterway member 100 may have therein a water inlet flow passage 410, a pure water flow passage 420, and a waste water flow passage 430. The water inlet flow passage 410, the pure water flow passage 420, and the waste water flow passage 430 may be located at any position on the integrated waterway member 100, and they may extend in any direction as long as their normal operation is satisfied. The water inlet channel 410 may be connected to the second water inlet connector 240. The second water outlet interface 250 can be communicated to the water inlet interface 311 of the water inlet electromagnetic valve. The water inlet solenoid valve outlet port 312 may be connected to the booster pump inlet port 320. The booster pump water outlet port 330 may be communicated to the first water inlet port 210. The first waste water outlet port 220 may be connected to a waste water solenoid valve inlet port 341. The waste solenoid valve outlet port 342 may be connected to the waste channel 420. The first pure water outlet port 230 may be connected to the pure water flow passage 430. Thus, a complete water flow passage is formed in the integrated waterway member 100, and the use requirement of the water purifier is met.

Preferably, as shown in fig. 1 to 3, the first water inlet interface 210, the first wastewater outlet interface 220, the first pure water outlet interface 230, the second water inlet interface 240 and the second water outlet interface 250 may extend in a vertical direction (i.e., a direction indicated by an arrow a in the drawing) of the integrated waterway member 100. The vertical direction A can be consistent with the insertion direction of the composite filter element. Vertical a may be perpendicular to integrated waterway member 100. Integrated waterway member 100 may extend substantially along a horizontal plane perpendicular to vertical direction a. In the horizontal plane, a transverse direction B and a longitudinal direction C (i.e., directions indicated by arrows B and C in the drawings) are further defined for clarity of the following description. The transverse direction B is perpendicular to the longitudinal direction C, and both can be perpendicular to the vertical direction A. In general, the lateral direction B may be understood as a longitudinal direction of the integrated waterway member 100, and the longitudinal direction C may be understood as a width direction of the integrated waterway member 100. Through the arrangement, the composite filter element can be conveniently installed, and the installation difficulty is reduced.

Preferably, as shown in fig. 1-3, the inlet channel 410, the pure water channel 420, and the waste water channel 430 may be located at the first lateral end 110 of the integrated waterway member 100. The water inlet solenoid valve water inlet interface 311, the water inlet solenoid valve water outlet interface 312, the waste solenoid valve water inlet interface 341, and the waste solenoid valve water outlet interface 342 may be located at the second lateral end 120 of the integrated waterway member 100. First and second lateral ends 110 and 120 may be located on either side of cartridge mount 200 in a lateral direction of integrated waterway member 100 (i.e., the direction indicated by arrow B). Through the arrangement, the water inlets of the integrated waterway member 100 are positioned on the same side, so that the external pipeline connection is facilitated, and the water inlet electromagnetic valve 310 and the wastewater electromagnetic valve 340 can be positioned on the opposite side, so that the integrated waterway member 100 is more reasonable in layout, convenient to process and minimum in size.

Preferably, as shown in fig. 1 to 3, the inflow channel 410, the pure water channel 420, and the waste water channel 430 may extend in a lateral direction of the integrated waterway member 100. In this manner, the integrated waterway member 100 has a neat and orderly water flow path, is easy to manufacture, and has a minimum size.

Preferably, as shown in fig. 1 to 3, the water inlet channel 410 may be located between the pure water channel 420 and the wastewater channel 430, and the wastewater solenoid valve water outlet port 342 may be coaxially disposed with the wastewater channel 430. In this way, the waterway layout on the integrated waterway member 100 may be simplified, and the resistance to the discharge of wastewater may be reduced.

Preferably, as shown in fig. 1-3, the second water inlet connector 240 and the first pure water outlet connector 230 may be sequentially arranged along the longitudinal direction of the integrated waterway member 100 (i.e., the direction indicated by the arrow C in the drawings). The first wastewater outlet port 220, the second outlet port 250 and the first water inlet port 210 may be sequentially arranged along the longitudinal direction, and along the transverse direction of the integrated waterway member 100, the second water inlet port 240 aligns with a gap between the first wastewater outlet port 220 and the second outlet port 250, and the first pure water outlet port 230 aligns with a gap between the second outlet port 250 and the first water inlet port 210. As such, the integrated waterway member 100 may be adapted for use in connection with a composite filter cartridge in which it is used.

Illustratively, as shown in fig. 1-3, the integrated waterway member 100 may further include a check valve 350. The inlet pipe of the check valve 350 may be connected to the first pure water outlet port 230. An outlet pipe of the check valve 350 may be connected to the pure water passage 420. The check valve 350 may be used to allow water flow in a given direction without allowing reverse flow. The check valve 350 may be any type and style of check valve, and those skilled in the art may select any type of check valve that is or may come into existence in the future, as long as the above-described function is achieved, and thus will not be described in further detail.

Referring to fig. 4, the water flow may sequentially pass through the first pure water outlet port 230 and the water inlet pipe of the check valve 350, pass through the check valve 350, and then flow out through the water outlet pipe of the check valve 350 and the pure water flow passage 420. The integrated waterway member 100 is more suitable for a water purifier using a high-pressure switch disposed on a waterway behind a check valve. For a water purifier without a high-pressure switch, the check valve 350 may also prevent water outside the integrated waterway member 100 from flowing back into the integrated waterway member, thereby contaminating purified water.

Preferably, as shown in fig. 1-3, cartridge mount 200 may be disposed on a first surface 130 of integrated waterway member 100, and check valve 350 may be disposed on a second surface 140 opposite first surface 130. In this way, the size of the integrated waterway member 100 may be reduced, and the integrated waterway member 100 may be more compact.

Preferably, as shown in fig. 1 to 3, the booster pump water inlet port 320 and the booster pump water outlet port 330 may be located at the same side of the cartridge mounting seat 200 in the longitudinal direction of the integrated waterway member 100. Like this, be convenient for connect the booster pump, make the water circulating path in the purifier neat orderly, the pipeline of connecting the booster pump is shortest, reduces the overall structure of purifier.

1-3, the booster pump water inlet interface 320 may include a booster pump water inlet line 321 and a booster pump water inlet line junction 322. The booster pump water inlet pipeline joint 322 is connected at the outer end of the booster pump water inlet pipeline 321 so as to be connected with an external booster pump. The booster pump water outlet interface 330 may include a booster pump water outlet line 331 and a booster pump water outlet line fitting 332. The booster pump water outlet pipeline joint 332 is connected to the outer end of the booster pump water outlet pipeline 331 so as to be connected with an external booster pump. The booster pump water inlet line 321 and the booster pump water outlet line 331 may extend in a longitudinal direction of the integrated waterway member 100. Thus, the water flow path of the integrated waterway member 100 is simple and orderly in structure, and is convenient to process and manufacture.

Preferably, as shown in fig. 3, the inlet solenoid valve inlet interface 311 and the inlet solenoid valve outlet interface 312 may extend in a lateral direction of the integrated waterway member 100, and/or the waste solenoid valve inlet interface 341 and the waste solenoid valve outlet interface 342 may extend in a lateral direction of the integrated waterway member 100. Thus, the water flow path of the integrated waterway member 100 is simple and orderly in structure, and is convenient to process and manufacture.

For example, as shown in fig. 1-3, the integrated waterway member 100 may include a water inlet solenoid valve 310 connected to a water inlet solenoid valve water inlet interface 311 and a water inlet solenoid valve water outlet interface 312, and/or a waste water solenoid valve 340 connected to a waste water solenoid valve water inlet interface 341 and a waste water solenoid valve water outlet interface 342. Preferably, the inlet solenoid valve 310 and/or the waste solenoid valve 340 may be connected to the integrated waterway member 100 by a screw connection. By this arrangement, the inflow and/or the waste water can be controlled.

According to another aspect of the present invention, there is provided a water purifier, comprising any one of the integrated waterway members 100 described above. For the components included in the integrated waterway member 100, reference may be made to the above description, and for brevity, the description is omitted here.

In the description of the present invention, it is to be understood that the orientation or positional relationship indicated by the orientation words such as "front", "rear", "upper", "lower", "left", "right", "horizontal", "vertical", "horizontal" and "top", "bottom", etc. are usually based on the orientation or positional relationship shown in the drawings, and are only for convenience of description and simplification of description, and in the case of not making a contrary explanation, these orientation words do not indicate and imply that the device or element referred to must have a specific orientation or be constructed and operated in a specific orientation, and therefore, should not be interpreted as limiting the scope of the present invention; the terms "inner" and "outer" refer to the interior and exterior relative to the contours of the components themselves.

Spatially relative terms, such as "above … …," "above … …," "above … …," "above," and the like, may be used herein for ease of description to describe the spatial relationship of one or more components or features shown in the figures to other components or features. It is to be understood that the spatially relative terms are intended to encompass not only the orientation of the component as depicted in the figures, but also different orientations of the component in use or operation. For example, if an element in the drawings is turned over in its entirety, the articles "over" or "on" other elements or features will include the articles "under" or "beneath" the other elements or features. Thus, the exemplary term "above … …" can include both an orientation of "above … …" and "below … …". Further, these components or features may also be positioned at various other angles (e.g., rotated 90 degrees or other angles), all of which are intended to be encompassed herein.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments according to the present application. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, elements, components, and/or combinations thereof, unless the context clearly indicates otherwise.

It should be noted that the terms "first," "second," and the like in the description and claims of this application and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are capable of operation in sequences other than those illustrated or described herein.

The present invention has been described in terms of the above embodiments, but it is to be understood that the above embodiments are for purposes of illustration and description only and are not intended to limit the invention to the described embodiments. Furthermore, it will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that many more modifications and variations are possible in light of the teaching of the present invention and are within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (14)

1. The integrated waterway component is characterized in that the integrated waterway component is provided with a filter element mounting seat (200), a water inlet electromagnetic valve water inlet interface (311), a water inlet electromagnetic valve water outlet interface (312), a booster pump water inlet interface (320), a booster pump water outlet interface (330), a wastewater electromagnetic valve water inlet interface (341) and a wastewater electromagnetic valve water outlet interface (342), wherein the integrated waterway component is provided with a filter element mounting seat (200), a water inlet electromagnetic valve water inlet interface (311), a water inlet electromagnetic valve water outlet interface (312

The filter core mount pad is used for installing composite filter element, the filter core mount pad has first interface (210) of intaking, first waste water play water swivel (220) and first pure water play water swivel (230), is used for the intercommunication compound reverse osmosis filter core among the composite filter element, and the filter core mount pad still has second interface (240) of intaking and second play water swivel (250), is used for the intercommunication compound leading filter core or rearmounted filter core among the composite filter element.

2. The integrated waterway member of claim 1, wherein the integrated waterway member has a water inlet channel (410), a pure water channel (420) and a waste water channel (430), the water inlet channel is connected to the second water inlet port (240), the second water outlet port (250) is connected to the water inlet solenoid valve water inlet port (311), the water inlet solenoid valve water outlet port (312) is connected to the booster pump water inlet port (320), the booster pump water outlet port (330) is connected to the first water inlet port (210), the first waste water outlet port (220) is connected to the waste water solenoid valve water inlet port (341), the waste water solenoid valve water outlet port (342) is connected to the waste water channel, and the first pure water outlet port (230) is connected to the pure water channel.

3. The integrated waterway member of claim 2, wherein the first inlet (210), the first waste outlet (220), the first pure water outlet (230), the second inlet (240), and the second outlet (250) extend in a vertical direction of the integrated waterway member.

4. The integrated waterway member of claim 2, wherein the inlet channel (410), the pure water channel (420), and the waste water channel (430) are located at a first lateral end (110) of the integrated waterway member, the inlet solenoid valve inlet interface (311), the inlet solenoid valve outlet interface (312), the waste solenoid valve inlet interface (341), and the waste solenoid valve outlet interface (342) are located at a second lateral end (120) of the integrated waterway member, and the first and second lateral ends are located at both sides of the cartridge mounting seat (200) in a lateral direction of the integrated waterway member.

5. The integrated waterway member of claim 2, wherein the influent channel (410), the purified water channel (420), and the waste water channel (430) extend in a transverse direction of the integrated waterway member.

6. The integrated waterway assembly of claim 5, wherein the water inlet channel (410) is disposed between the pure water channel (420) and the wastewater channel (430), and the wastewater solenoid valve outlet port (342) is disposed coaxially with the wastewater channel.

7. The integrated waterway member of claim 5, wherein the second water inlet (240) and the first pure water outlet (230) are sequentially arranged along a longitudinal direction of the integrated waterway member, and the first waste water outlet (220), the second water outlet (250) and the first water inlet (210) are sequentially arranged along the longitudinal direction, and

along the transverse direction, the second water inlet interface is aligned with a gap between the first wastewater outlet interface and the second water outlet interface, and the first pure water outlet interface is aligned with a gap between the second water outlet interface and the first water inlet interface.

8. The integrated waterway member of claim 2, further comprising a check valve (350), a water inlet pipe of the check valve being connected to the first pure water outlet port (230), and a water outlet pipe of the check valve being connected to the pure water flow channel (420).

9. The integrated waterway member of claim 8, wherein the cartridge mount (200) is disposed at a first surface (130) of the integrated waterway member and the check valve (350) is disposed at a second surface (140) opposite the first surface.

10. The integrated waterway member of claim 1, wherein the booster pump water inlet (320) and the booster pump water outlet (330) are located on the same side of the cartridge mounting seat (200) along a longitudinal direction of the integrated waterway member.

11. The integrated waterway member of claim 1, wherein the booster pump water inlet interface (320) includes a booster pump water inlet line (321) and a booster pump water inlet line connector (322) connected to an outer end of the booster pump water inlet line, and the booster pump water outlet interface (330) includes a booster pump water outlet line (331) and a booster pump water outlet line connector (332) connected to an outer end of the booster pump water outlet line, the booster pump water inlet line and the booster pump water outlet line extending in a longitudinal direction of the integrated waterway member.

12. The integrated waterway member of claim 11, wherein the water inlet solenoid valve water inlet port (311) and the water inlet solenoid valve water outlet port (312) extend in a lateral direction of the integrated waterway member, and/or the waste solenoid valve water inlet port (341) and the waste solenoid valve water outlet port (342) extend in a lateral direction of the integrated waterway member.

13. The integrated waterway member of claim 1, comprising a water inlet solenoid valve (310) connected to the water inlet solenoid valve water inlet interface (311) and the water inlet solenoid valve water outlet interface (312), and/or a wastewater solenoid valve (340) connected to the wastewater solenoid valve water inlet interface (341) and the wastewater solenoid valve water outlet interface (342).

14. A water purification machine comprising an integrated waterway member of any one of claims 1-13.

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