RU2666875C9 - Water purifier - Google Patents

Abstract

FIELD: water treatment.SUBSTANCE: invention relates to the water treatment of, in particular to the water purifier. Water purifier comprises body and the tap connector, connected to the purifier body through the tubular assembly, wherein the purifier body has inlet and outlet openings. Tubular assembly comprises at least inlet tube and outlet tube. Tap connector has at least the first inlet, the first outlet, the second inlet and the second outlet. First inlet is connected to the first outlet. First outlet is connected to the tubular assembly inlet tube first end. Tubular assembly inlet tube second end is connected to the purifier inlet. Purifier outlet is connected to the tubular assembly outlet tube first end, the tubular assembly outlet tube second end is connected to the second inlet, and the second inlet is connected to the second outlet. Body comprises casing, comprising the lower shell, side walls and top cover, located on the lower shell and having m cascade flow chambers water flow manifold, each of which has one inlet interface and one outlet interface, where m≥2 and m is the integer. Filtering elements assembly contains n stages of the filtering elements. Each stage of the filtering elements has inlet and outlet. i-th stage filtering element inlet is connected to the j-th water-flow chamber outlet interface, the i-th stage filtering element outlet is connected to the j+1-th water-flow chamber inlet interface, where n≥1 and n is the integers, 1≤i≤n and i is the integers, 1≤j≤-m-1 and j is the integers. Tube interface assembly comprises at least the inlet tube and the outlet tube. Inlet tube first end is the purifier inlet, the inlet tube second end is connected to the first water flow chamber inlet interface, outlet tube first end is the purifier outlet, and the outlet tube second end is connected to the m-th water flow chamber outlet interface.EFFECT: enabling the plant installation process simplification and increase in the plant efficiency.14 cl, 21 dwg

Description

TECHNICAL FIELD

[0001] The present invention relates to water treatment, in particular, to a water purifier.

BACKGROUND INVENTIONS

[0002] A water purifier serving as a health product is welcomed by more and more customers.

[0003] Water purifiers available on the market are generally installed under the sink. As the name implies, a water purifier installed under the sink is usually installed in a cabinet under the kitchen sink, where its inlet is connected to the water inlet tube, and its water outlet tube is connected to the water outlet tap. The water purifier installed under the sink can dispense purified water by filtering tap water. In use, the user turns on the faucet in the sink and receives purified water, filtered by a purifier installed under the sink.

[0004] In the process of carrying out the invention, it was found that the above-described construction has at least the following disadvantages: a professional is required to install a water purifier installed under the sink in accordance with the design of the water intake tube, and the installation is inconvenient and has low efficiency.

SUMMARY OF INVENTION

[0005] To solve the above problems of an inconvenient and inefficient water purifier installation, the present invention also proposes a water purifier. The technical solution is presented below.

[0006] In accordance with one aspect of the embodiment, a water purifier is provided. The cleaner contains a housing and a connector for a tap connected to the housing of the water purifier through a tubular assembly;

[0007] the case of the water purifier has an inlet and an outlet;

[0008] the tubular assembly comprises at least an inlet tube and an outlet tube;

[0009] the tap connector has at least a first inlet, a first outlet, a second inlet, and a second outlet;

[0010] wherein the first inlet is connected to the first outlet, the first outlet is connected to the first end of the inlet tube of the tubular assembly, and the second end of the inlet tube of the tubular assembly is connected to the cleaner inlet; the outlet of the cleaner is connected to the first end of the outlet tube of the tubular assembly, the second end of the outlet tube of the tubular assembly is connected to the second inlet, and the second inlet is connected to the second outlet.

[0011] Alternatively, the connector for the valve further has a third outlet connected to the first inlet, the connector comprising an electrically controlled valve assembly;

[0012] The valve assembly has an inlet end, a first outlet end and a second outlet end, the inlet end is connected to the first inlet, the first outlet end is connected to the first outlet, and the second outlet end is connected to the third outlet;

[0013] When the specified valve assembly is in the first operating state, the channel between the inlet end and the first outlet end is open to connect these ends, and the channel between the inlet end and the second outlet end is closed;

[0014] When the specified valve assembly is in the second operating state, the channel between the inlet end and the second outlet end is open to connect these ends, and the channel between the inlet end and the first outlet end is closed.

[0015] Alternatively, said valve assembly is an electrically controlled valve with one inlet and two outlets; or

[0016] the specified valve site contains two electrically controlled valves, each of which has one inlet and one outlet and a three-way connecting element; or

[0017] said valve assembly comprises one electrically controlled valve with one inlet and one outlet, and a three-way connecting element.

[0018] Alternatively, the cleaner body includes:

[0019] a housing comprising a lower case, side walls, and an upper cover;

[0020] a flow collector located on the lower casing and having m cascade flow chambers, each flow chamber having one inlet interface and one outlet interface, with m≥2, where m is an integer;

[0021] the filter element assembly contains n-stage filter elements, each filter element stage having an inlet and an outlet, and the inlet of the filter element of the i-th stage is connected to the outlet interface of the j-th flow chamber, the outlet of the filter element i- stage n is connected to the inlet interface j + 1st flow chamber, where n≥1 and n is an integer, 1≤i≤n and i is an integer, 1≤j≤m-1 and j is an integer;

[0022] the tube interface unit comprises at least an inlet tube and an outlet tube, the first end of the inlet tube is the inlet of the purifier, the second end of the inlet tube is connected to the inlet interface of the first flow chamber, the first end of the outlet tube is the outlet of the purifier, the second end of the discharge tube connected to the outlet interface of the mth flow chamber.

[0023] Alternatively, the cleaner body further comprises:

[0024] a pump unit having an inlet and an outlet;

[0025] wherein the inlet of the pump is connected to the outlet interface of the kth flow chamber, the outlet of the pump is connected to the inlet interface k + of the 1st flow chamber, where 1≤k≤m≤ 1 and k is an integer.

[0026] Alternatively, each stage of the filter elements contains:

[0027] a base mounted on the drainage collector and having an inlet of the filter element and an outlet of the filter element;

[0028] the housing is connected with the possibility of detaching with the upper part of the base of the filter element, the filter element housing contains a filtering space, with both ends of the filtering space communicating with the first filtering channel and the second filtering channel respectively, and the filtering space is provided with filtering material; wherein, when the filter element is used, the first filter channel communicates with the inlet of the filter element, and the second filter channel communicates with the outlet of the filter element.

[0029] Alternatively, the base of the filter element contains:

[0030] a housing mounted on the water flow collector and having an inlet of the filter element and an outlet of the filter element;

[0031] a rotatable body that is rotatably connected with the upper part of the base body and comprising a rotatable plate having an inlet tube of the filter element and an outlet tube of the filter element;

[0032] wherein, when the filter element is used, the lower opening of the inlet tube of the filter element communicates with the inlet opening of the filter element, the inlet tube of the filter element is inserted into the first filter channel, the upper opening of the inlet tube of the filter element communicates with the first filter channel, and the lower opening of the outlet tube the filter element communicates with the outlet of the filter element, while the outlet tube of the filter element is inserted into the second filter al, and the upper opening of the outlet tube of the filter element communicates with the second channel filter;

[0033] when the filter element is in a disassembled state, the swiveling plate closes the inlet of the filter element and the outlet of the filter element.

[0034] Alternatively, the upper part of the base body has a groove, the rotatable plate is located at the bottom of the groove, the first threaded structure is located on the inner side wall of the groove, and the lower part of the filter element body has a protrusion, the second threaded structure is located on the outer side wall of the protrusion, and the first threaded structure is associated with the second threaded structure.

[0035] Alternatively, both the first filter channel and the second filter channel have a waterproof lip, an o-ring and a waterproof block;

[0036] the sealing ring is located near the base body, the waterproof unit is located above the sealing ring, and the waterproof protrusion is located above the waterproof unit;

[0037] When the filter element is used, the inlet tube of the filter element and the outlet tube of the filter element press the waterproof unit into contact with the waterproof ledge, so that the first filter channel communicates with the inlet of the filter element through the filter element inlet tube and the second filter channel communicates with the outlet the hole of the filter element through the outlet tube of the filter element;

[0038] when the filter element is in a disassembled state, the waterproof unit is lowered down to connect to the sealing ring, and closes the bottom openings of the first and second filter channels.

[0039] Alternatively, when at least one step of the filter elements comprises a filter element for protection against harmful substances, the cleaner body additionally has a water tank assembly, and the filter element for protection against harmful substances additionally has an outlet for the collected water;

[0040] wherein the water tank assembly has an inlet; the water flow collector additionally has a water collection chamber for the collected water, which contains an inlet interface for the collected water and an outlet interface for the collected water; the outlet for the collected water is connected to the inlet interface for the collected water, the inlet of the tank is connected to the outlet interface for the collected water.

[0041] Alternatively, the water tank assembly further has a tank outlet, the tube interface assembly further comprises an outlet tube for collected water, and the tubular unit further comprises an outlet tube for collected water, the connector for the tap further comprises a third inlet;

[0042] wherein the outlet of the reservoir is connected to the first end of the discharge pipe for collected water, the second end of the outlet pipe for collected water is connected to the first end of the outlet pipe of the tubular assembly for collected water, the second end of the outlet tube of the tubular assembly for collected water is connected to the third inlet .

[0043] Alternatively, the tank assembly further has at least one level switch.

[0044] Alternatively, each flow chamber further comprises at least one expansion portion;

[0045] The expansion part is located between the inlet interface and the outlet interface, and the cross-sectional area of the expansion part is larger than each of the cross-sectional areas of the inlet interface and the outlet interface.

[0046] Alternatively, the water purifier housing further comprises a mounting assembly for the filter element;

[0047] the side edge of the fastening assembly for the filter element is connected to the side wall via a hinge, the fastening assembly for the filter element having at least η fastening holes;

[0048] on the upper surface of each filter element has a protrusion that is inserted into the corresponding mounting hole.

[0049] Alternatively, the protrusion has a handle.

[0050] The technical solutions described herein may have the following primary technical results:

[0051] the cleaner case is connected to the tap connector through a tubular assembly, and the tap connector can be directly installed on the tap outlet, which solves the problem of inconvenient and inefficient installation of a known water purifier, achieves the effect of simplifying the installation procedure and improving installation efficiency.

[0052] It should be understood that the above general description and detailed description that follows, are merely illustrative and explanatory and do not limit the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[0053] The accompanying drawings are included in the present description and form part of it, and together with the description, serve to explain the principle of the present invention.

[0054] FIG. 1 is a schematic structural view showing a water purifier configured in accordance with an illustrative embodiment;

FIG. 2 is a schematic structural view showing another water purifier made in accordance with an illustrative embodiment;

FIG. 3 is a diagram showing a connector for a crane made in accordance with an illustrative embodiment;

FIG. 4 is a diagram showing another connector for a crane made in accordance with an illustrative embodiment;

FIG. 5 is a diagram showing another connector for a crane made in accordance with an illustrative embodiment;

FIG. 6 is a diagram showing another connector for a crane made in accordance with an illustrative embodiment;

FIG. 7 is a diagram showing another connector for a crane, made in accordance with an illustrative embodiment;

FIG. 8 is a disassembled view showing the water purifier housing in accordance with an illustrative embodiment;

FIG. 9 is a schematic diagram showing a flow collector made in accordance with an illustrative embodiment;

FIG. 10 is a sectional view showing a water flow collector configured in accordance with an illustrative embodiment;

FIG. 11 is a schematic view showing a filter element assembly, made in accordance with an illustrative embodiment;

FIG. 12 is a schematic view showing a tube interface assembly configured in accordance with an illustrative embodiment;

FIG. 13 is a schematic view showing a filter element configured in accordance with an illustrative embodiment;

FIG. 14 is a schematic sectional view showing a filtering element configured in accordance with an illustrative embodiment;

FIG. 15 is a schematic view showing the base of the filter element in accordance with an illustrative embodiment;

FIG. 16 is a schematic view illustrating a first state of a base of a filter element configured in accordance with an illustrative embodiment;

FIG. 17 is a schematic view illustrating a second state of a base of a filter element configured in accordance with an illustrative embodiment;

FIG. 18 is a schematic view illustrating the state of a filter element used in accordance with an exemplary embodiment;

FIG. 19 depicts a schematic view showing the filter element in a disassembled state, in accordance with an illustrative embodiment;

FIG. 20 is a schematic view showing a mounting assembly constructed in accordance with an illustrative embodiment; and

FIG. 21 is a schematic view showing the lid of the water tank according to an illustrative embodiment.

[0055] Embodiments of the present invention shown in the above drawings are described in more detail below. These accompanying drawings and the description are in no way intended to limit the scope of the present invention, but only to explain its concept to those skilled in the art with reference to specific embodiments.

DETAILED DESCRIPTION

[0056] Illustrative embodiments are described below, examples of which are illustrated in the accompanying drawings. The following description relates to the accompanying drawings, in which like reference numerals in different drawings designate the same or similar elements unless otherwise indicated. The implementations set forth in the following description of illustrative embodiments are not all implementations that are possible with the invention. Instead, they are merely examples of water purifiers that are consistent with certain aspects of the invention, as indicated in the accompanying claims.

[0057] FIG. 1 is a schematic structural view showing a water purifier made in accordance with an illustrative embodiment. The water purifier may comprise a housing 10 and a connector 30 for a water faucet connected to the housing 10 of the water purifier via a tubular assembly 20.

[0058] The cleaner body 10 has an inlet and an outlet of the water purifier.

[0059] The tubular assembly 20 comprises at least an intake tube and an exhaust tube.

[0060] The crane connector 30 has at least a first inlet 31, a first outlet 32, a second inlet 33, and a second outlet 34.

[0061] The first inlet 31 is connected to the first outlet 32, the first outlet 32 is connected to the first end of the inlet tube of the tubular assembly, and the second end of the outlet tube of the tubular assembly is connected to the inlet of the water purifier; the outlet of the water purifier is connected to the first end of the inlet tube of the tubular assembly, the second end of the outlet tube of the tubular assembly is connected to the second inlet 33, and the second inlet 33 is connected to the second outlet 34.

[0062] As described above, in the water purifier made in accordance with this embodiment, the housing 10 is connected to the connector 30 via the tubular assembly 20, while the connector 30 can be directly installed in the tap outlet, so a problem such as inconvenient and inefficient installation of water purifier, is solved, and thus some effects are achieved, such as simplifying installation procedures and improving installation efficiency.

[0063] FIG. 2 is a schematic view showing the construction of another water purifier configured in accordance with an illustrative embodiment. The water purifier may comprise a housing 10 and a connector 30 for a water faucet connected to the housing 10 of the water purifier via a tubular assembly 20.

[0064] The housing 10 has an inlet and an outlet of the water purifier.

[0065] The tubular assembly 20 comprises at least an inlet tube and an outlet tube.

[0066] The connector 30 has at least a first inlet 31, a first outlet 32, a second inlet 33, and a second outlet 34.

[0067] The first inlet 31 is connected to the first outlet 32, the first outlet 32 is connected to the first end of the inlet tube of the tubular assembly, and the second end of the outlet pipe of the tubular assembly is connected to the inlet of the water purifier; the outlet of the water purifier is connected to the first end of the inlet tube of the tubular assembly, the second end of the outlet tube of the tubular assembly is connected to the second inlet 33, and the second inlet 33 is connected to the second outlet 34.

[0068] The connector 30 can be directly installed in the outlet of the valve 40 as in the socket. Water from the outlet of the valve 40 passes successively through the first inlet 31, the first outlet 32, the inlet tube of the tubular assembly and the inlet of the purifier, and into the housing 10. The housing 10 is used to filter the incoming water and release the purified water that is discharged sequentially through the outlet the opening of the cleaner, the outlet tube of the tubular assembly, the second inlet 33 and the second outlet 34.

[0069] In an alternative embodiment of the invention shown in FIG. 3 shows a diagram of a connector for a crane. The connector 30 is additionally provided with a third outlet port 35 connected to the first inlet port 31, with an electrically controlled valve assembly 36 located in the connector 30.

[0070] The valve assembly 36 has an inlet end, a first outlet end and a second outlet end. The inlet end is connected to the first inlet 31, the first outlet end is connected to the first outlet 32, and the second outlet end is connected to the third outlet 35.

[0071] When the valve assembly 36 is in the first operating state, the channel provides communication between the inlet end and the first outlet end, while the channel between the inlet end and the second outlet end is closed. At this point, water from the outlet port 40 is filtered through the housing 10 for obtain purified water, and such purified water flows from the second outlet 34.

[0072] When the valve assembly 36 is in the second operating state, the passage provides communication between the inlet end and the second outlet end, while the passage between the inlet end and the first outlet end is closed. At this point, water from the outlet of the tap 40 flows out of the third outlet 35 directly through the housing 10.

[0073] As shown in FIG. 4, in a possible embodiment, the valve assembly 36 is an electrically controlled valve 361 with one inlet and two outlets. The inlet end 361a of the electrically controlled valve 361 is connected to the first inlet 31, the first outlet end 361b of the electrically controlled valve 361 is connected to the first outlet 32, and the second outlet end 361c of the electrically controlled valve 361 is connected to the third outlet 35. In the first operating condition communication through the channel between the inlet end 361a and the first outlet end 361b of the electrically controlled valve 361, and the channel between the inlet end 361a and the second outlet end 361c is closed. In the second operating state, the channel is provided between the inlet end 361a and the second outlet end 361c of the electrically controlled valve 361, and the channel between the inlet end 361a and the first outlet end 361b is closed.

[0074] As shown in FIG. 5, in another possible embodiment, the valve assembly 36 comprises two electrically controlled valves 362, 363, each of which has one inlet and one outlet, and a three-way connecting element 364. The first port 364a of the three-way connecting element 364 is connected to the first inlet 31 ; the second port 364b of the three-way connecting element 364 is connected to the inlet end of the first electrically controlled valve 362; the outlet end of the first electrically controlled valve 362 is connected to the first outlet 32; the third port 364s of the three-way connecting element 364 is connected to the inlet end of the second electrically controlled valve 363; the outlet end of the second electrically controlled valve 363 is connected to the third outlet 35. In the first operating state, the first electrically controlled valve 362 is turned on and the second electrically controlled valve 363 is turned off; in the second operating state, the first electrically controlled valve 362 is turned off, and the second electrically controlled valve 363 is turned on.

[0075] As shown in FIG. 6, in another possible embodiment, the valve assembly 36 comprises one electrically controlled valve 365 with one inlet and one outlet and a three-way connecting element 366. The first port 366a of the three-way connecting element 366 is connected to the first inlet 31; the second port 366b of the three-way connecting element 366 is connected to the first outlet 32; the third port 366 from the three-way connecting element 366 is connected to the inlet end of the electrically controlled valve 365; the outlet end of the second electrically controlled valve 365 is connected to the third outlet 35. In the first operating state, the electrically controlled valve 365 is turned off; in the second operating state, the electrically controlled valve 365 is turned on.

[0076] In various embodiments, as shown in FIG. 4, 5 and 6, an electrically controlled valve refers to a valve that controls, for example, a solenoid valve and an electric valve by electrically turning it on / off. The electrically controlled valve can be connected to the control circuit with a wire, and the control circuit controls the electrically controlled valve by on / off so that the valve assembly 36 switches between the first operating state and the second operating state. Alternatively, the connector 30 additionally has at least one operating button on its surface, wherein said at least one operating button is connected to the control circuit via a wire. The at least one operating button is used to control the operating state of the valve assembly 36. For example, the at least one operating button may include a tap water button and a purified water button, and the valve assembly 36 may, by default, be in a second operating state. When the user presses the purified water button, the control circuit receives the first operating instruction and sends the first control signal to the valve assembly 36 in accordance with the first operating instruction. The first control signal is used to control the valve assembly 36 to switch to the first operating state from the second operating state. When the user presses the tap water button, the control circuit receives the second operating instruction and sends the second control signal to the valve assembly 36 in accordance with the second operating instruction. The second control signal is used to control the valve assembly 36 to switch to the second operating state from the first operating state.

[0077] It should be noted that in the embodiment shown in FIG. 6, by designing the inside of the connector 30 in an appropriate manner, or by resisting the internal assemblies of the housing 10 to water, the tap water is discharged from the outlet of the valve 40 directly from the third outlet 35 when the electrically controlled valve 365 is turned on. For example, as shown in FIG. 6, when the channel between the first inlet 31 and the first outlet 32 is vertical, and the channel between the first inlet 31 and the third outlet 35 runs vertically downwards, tap water will be discharged directly from the third outlet 35, while the two outlet channels are in communication with each other. In addition, due to the resistance of the water to the filter element assembly in the housing 10, tap water from the tap 40 can automatically select a channel with less resistance, i.e. flow directly from the third outlet 35.

[0078] Further, as shown in FIG. 7, the second outlet 34 and the third outlet 35 can also be combined into a common outlet 37. In this case, a three-way connecting element 38 is further provided in the connector 30. The first port 38a of the three-way connecting element 38 is connected to the second inlet 33; the second port 38b of the three-way connecting element 38 is connected to a common outlet 37; the third port 38c of the three-way connecting element 38 is connected to the first inlet 31 through the valve assembly 36. By combining the second outlet 34 and the third outlet 35 into the common outlet 37, the user can get water without selecting an outlet, which facilitates the user's work and improves user practice.

[0079] In connection with FIG. 3, 4, 5, 6 or 7, when the valve assembly 36 is in different operating states, at least one open outlet channel always exists inside the connector 30 through the high-speed instantaneous characteristics of the valve assembly 36, which effectively eliminates the pressure problem on the connector 30, eliminates potential risks of leakage and destruction in the joint and improves safety of use.

[0080] In an alternative embodiment of the invention, as in FIG. 8 shows a constructive view in disassembled state of the cleaner body. The housing 10 of the purifier contains a casing, a water collector 12, a node 13 of filter elements and a node 14 of the tube interface, and

[0081] the housing includes a lower housing 111, side walls 112, and an upper cover 113.

[0082] The water collector 12 is located on the lower casing 111. As shown in FIG. 9 and 10, the flow collector 12 has m cascade flow chambers 121, each of which contains one inlet interface 121a and one outlet interface 121b, where m≥2 and m are integers. Each flow chamber 121 is located transversely in three-dimensional space. As shown, for example, in FIG. 9, the flow collector 12 is generally approximately square-shaped, and outside the flow header 12 has six interfaces, one or more of which can be selected and made as interface surface 122. Each interface surface 122 has one or more interfaces, i.e., intake interface 121a and / or exhaust interface 121b. Each interface communicates with the corresponding components, such as, in series, a filter element, a booster pump and a valve, etc. Of course, in other possible embodiments, the profile of the watercourse 12 may be selected by another polyhedron, and the number of interface surfaces 122 is not limited. Such an internal transverse structure of the flow collector 12 can be made by block injection molding or by three-dimensional printing, and a method of combining injection molding with machine processing can also be chosen.

[0083] The filter element assembly 13 comprises n-stage filter elements, the filter element at each stage having an inlet and an outlet, where n 1 1 and n is an integer. The level of the filter element and the type of filter element of the corresponding stage contained in the node 13 of the filter elements can be selected in accordance with the actual situation. Typically, the node 13 of the filter elements contains a front filter element, the main filter element and the control filter element. As shown, for example, in FIG. 11, the filter element assembly may contain four-stage filter elements, which are in sequence as a filter element 131a from a polypropylene yarn, a front activated filter element 131b from activated carbon, a filter element 131c for protection against harmful substances and a filtering element 131d after an activated carbon filter. A polypropylene yarn filter element 131a is used to remove debris, such as sludge, from tap water; activated carbon front filter element 131b is used to absorb and filter pollutants, odor and color from tap water; filter element 131c is used to filter any material that is harmful to the human body, such as heavy metal ions, bacteria, viruses, radioactive substances, dissolved salt and various pollutants; The filter element 131d after the activated carbon filter is used to further filter the water to improve the effect of water purification. In addition, the inlet of the filter of the i-th stage is connected to the outlet interface of the j-th flow chamber; The outlet of the filter of the i-th stage is connected to the inlet interface j + 1st flow chamber, where 1≤i≤n and i is an integer, 1≤j≤m-1 and j is an integer. Taking as an example the aforementioned 4-stage filtering elements, the inlet of the filter element of a polypropylene thread of the first stage is connected to the outlet interface of the first flow chamber, the outlet of the filter element of a polypropylene thread of the first stage is connected to the inlet interface of the second flow chamber; the inlet of the second-stage activated carbon filter element 131b is connected to the outlet interface of the second flow chamber, the exhaust port of the second-stage activated carbon filter element 131b is connected to the inlet interface of the third flow cell; the inlet of the third-stage filter element 131c is connected to the outlet of the third flow chamber; the outlet of the third-stage filter element 131c is connected to the inlet interface of the fourth flow chamber; the inlet of the filter element 131d after the activated carbon filter is connected to the outlet interface of the fourth flow chamber, and the outlet of the filter element 131d after the fourth stage activated carbon filter is connected to the inlet interface of the fifth flow chamber.

[0084] As shown in FIG. 12, the tube interface assembly 14 comprises at least an inlet tube 141 and an outlet tube 142. The first end of the inlet tube 141 is an inlet to the water purifier, and the second end of the inlet tube 141 is connected to the inlet interface of the first water course. The first end of the outlet tube 142 is the outlet of the water purifier, and the second end of the outlet tube 142 is connected to the outlet interface of the m-th flow chamber.

[0085] Alternatively, as shown in FIG. 8, the cleaner body 10 may further comprise a pump unit 15. The pump unit 15 has an inlet and an outlet. The inlet of the pump is connected to the outlet interface of the kth flow chamber, the outlet of the pump is connected to the inlet interface k + of the 1st flow chamber, where 1≤k≤m-1 and k is an integer. The pumping unit 15 may be a booster pump, which is used to increase the water pressure and supply pressurized water to the filter elements. Due to the location of the booster pump, the speed and flow of the supplied water is ensured. Typically, a booster pump is installed between the front filter element and the main filter element. For example, in the above-mentioned four-stage filter elements, a booster pump is installed between the filter element 131b with the second-stage activated carbon and the filter element 131c of the third stage. At this time, the inlet of the filter element of the polypropylene thread of the first stage is connected to the outlet interface of the first flow chamber, the outlet of the filter element of the polypropylene thread of the first stage is connected to the inlet interface of the second flow chamber; the inlet of the second-stage activated carbon filter element 131b is connected to the outlet port of the second flow chamber, and the exhaust port of the front filter element 132b with the second-stage activated carbon tube is connected to the inlet interface of the third flow cell; the inlet of the booster pump is connected to the outlet interface of the third flow chamber, and the outlet of the booster pump is connected to the inlet interface of the fourth flow chamber; the inlet of the third-stage prevention element 131c is connected to the fourth outlet of the fourth flow chamber, and the outlet of the third-stage element 131c is connected to the inlet interface of the fifth flow-through chamber; and the inlet of the filter element 131d after the fourth stage activated carbon filter is connected to the outlet interface of the fifth flow chamber, and the outlet of the filter element 131d after the fourth stage activated carbon filter is connected to the inlet interface of the sixth flow chamber.

[0086] In an alternative embodiment of the invention, as shown in FIG. 13 and 14, a schematic view of the filter element is depicted. The filter element of each stage of the node filter elements contains the base 132 and the housing 133.

[0087] The base 132 of the filter element is mounted on the water flow collector 12. The base 132 of the filter element can be mounted on the water drain 12 using fasteners such as a screw, a bolt, and the like. The base 132 of the filter element has an inlet 132a and an outlet 132b, both of which communicate with the outside in order to separately form the aisles for production and recovery.

[0088] The housing 133 of the filter element is detachably connected to the top of the base 132 of the filter element for ease of maintenance. The housing 133 has a space 133a, both ends of which communicate with the first filter channel 133b and the second filter channel 133c, respectively. The filter space 133a is provided with a filter material 133d for filtering water or another liquid through it. When the filter element is used, the first filter channel 133b communicates with the filter element inlet 132a, and the second filter channel 133c communicates with the filter element outlet 132b.

[0089] The filter element, as provided in this embodiment of the invention, can receive and discharge water from the base 132 of the filter element at the bottom. The housing 133 of the filter element is installed in the upper part of the base 132 of the filter element and, thus, an inverted vertical structure is formed. Such a design can not only allow not to install the tube, but also to make the whole design of the filter element more compact.

[0090] The construction of the base 132 of the filter element is shown in FIG. 15, and the base 132 of the filter element includes a housing 132c and a rotatable housing 132d.

[0091] The base body 132c is mounted on the water collection manifold to support the rotatable body 132d. The lower part of the base body 132c is a socket. The inlet 132a of the filter element and the outlet 132b of the filter element are located and exit from the socket and are connected to the corresponding interfaces of the water flow collector by means of connections. The upper part of the base body 132c has a groove structure. On the inner side wall of the groove 132c1, a first threaded structure is additionally provided, the first threaded structure may be an internal thread or an inclined structure similar to the internal thread. Accordingly, the lower part of the housing 133 of the filter element has protrusions. A second threaded structure is provided on the outer side wall of the protrusion 133e, which is associated with the first threaded structure.

[0092] The rotatable body 132d is rotatably connected to the upper part of the body 132 from the base. The rotatable body 132d comprises a rotatable plate 132d1, an inlet tube 132d2 of the filter element and an outlet tube 132d3 of the filter element. The filter element inlet tube 132d2 and filter element outlet tube 132d3 are mounted on a rotatable plate 132d1. The rotatable plate 132d1 is a sheet construction, the outer edge of which is fitted to the lower surface of the groove 132c1 of the base body 132c. The lower end surface of the rotatable plate 132d1 abuts against the lower surface of the groove 132c1, and a sealing structure 132d4 is installed between the lower end surface of the rotatable plate 132d1 and the lower surface of the groove 132c1 (as shown in Figures 18 and 19). The sealing construction 132d4 is usually a sealing ring or gasket. The upper part of the rotatable plate 132d1 is pressed against removable fasteners with such a suitable force that can not only rotate the rotatable plate 132d1 relative to the base body 132c in the plane, but can also provide a reliable seal between the lower end surface of the rotatable plate 132d1 and the lower surface of the groove 132c1. The rotatable plate 132d1 is connected to the inlet tube 132d2 of the filter element and the outlet tube 132d3 of the filter element. The lower openings of the inlet tube 132d2 of the filter element and the outlet tube 132d3 of the filter element correspond respectively to the inlet opening of the filter element 132a and the outlet 132b of the filter element.

[0093] As shown in FIG. 16 and 17, the rotatable plate 132d1 in different positions corresponds to different states, and in this embodiment two states are represented. When the filter element is used, the lower opening of the inlet tube 132d2 of the filter element communicates with the inlet hole 132a of the filter element, the inlet tube 132d of the filter element is inserted into the first filter channel 133b (see Fig. 18 and 19), and the upper hole of the inlet tube 132d of the filter element is reported with the first filter channel 133b. At the same time, the lower hole of the outlet tube 132d3 of the filter element communicates with the outlet hole 132b of the filter element, the outlet tube 132d3 of the filter element is inserted into the second filter channel 133c, and the upper opening of the outlet tube 132d3 filter element communicates with the second filter channel 133c. In this case, the inlet 132a of the filter element, the inlet tube 132d2 of the filter element and the first filter channel 133b are connected in series, with water or other liquid entering the filter space 133a. At the same time, the outlet element 132b of the filter element, the outlet tube 132d3 of the filter element and the second filter channel 133c are connected sequentially, and through them filtered water or other liquid flows out from the filter 133a, as shown in FIG. 16 and 18. In addition, when the filter element is in a disassembled state, the swiveling plate 132d1 closes the inlet opening 132a and the outlet opening 132b of the filtering element. When the filter element is in a disassembled state, the swiveling plate 132d1 is rotated, the filter element inlet tube 132d2 on the rotatable plate 132d1 no longer coincides with the filter element inlet 132a, and the filter element outlet 132d3 no longer coincides with the filter element outlet 132b, as shown in FIG. 17

[0094] As shown in FIG. 14, the lower part of the filtering space 133a communicates with the first filtering channel 133b, and the upper part of the filtering space 133a communicates with the second filtering channel 133c. In order to prevent air leakage and its presence in the upper part of the filtering space 133a during filtration, the second filtering channel 133c communicates with the guide tube 133f, which is located in the middle of the filtering space 133a and runs in the axial direction. The guide tube 133f has an upper opening that is located close to the upper part of the filtering space 133a, and a lower opening that communicates with the second filtering channel 133c. Water or other liquid that is filtered through the filter material 133d can flow into the guide tube 133f only through the upper gap in the filter space 133a, which causes such pressure that air cannot escape, but enters the guide tube 133f with water or other liquid and is discharged from the housing 133 of the filter element through the second filter channel 133c.

[0095] As shown in FIG. 18 and 19, in order to facilitate the filling and closing of the filter material and the installation of the guide tube 133f, the filter space 133a additionally has a bracket 133g. The main body of the bracket 133g is a panel, the outer periphery of which is fitted to the internal structure of the wall of the filtering space, and the middle part has a hollow shaft design with a stepped through hole. The lower part of the guide tube 133f is provided with a sleeve 133h and is inserted into the stepped through hole together with the sleeve 133h. The lower end of the guide tube 133f is adjacent to the stepped surface of the stepped through hole, and a sealing ring 133i1 is provided between the guide tube 133f and the stepped through hole to provide a seal. The lower part of the bracket 133g is mounted on the upper shoulder 133j of the second filter channel 133c, and the bracket 133g and the second filter channel 133c are sealed with a sealing ring 133i2. Here, the bracket panel 133g is provided with a gasket 133k for attaching the filter material 133d in the filter space 133a. This design is placed by covering the entire circle in order to achieve a coaxial 180-degree reliable connection, so that the entire assembly of filter elements becomes simpler and more convenient.

[0096] Alternatively, as shown in FIG. 18 and 19, and the first filter channel 133b, and the second filter channel 133c have a waterproof protrusion 1331, an o-ring 133m and a waterproof unit 133n. The sealing ring 133m is located close to the base body 132c, the waterproof unit 133n is located above the sealing ring 133m, and the waterproof protrusion 1331 is located above the waterproof unit 133n. When the filter element is used, as shown in FIG. 18, the filter element inlet tube 132d2 and the filter element outlet tube 132d3 press the waterproof unit 133n to the waterproof protrusion 1331 so that the first filter channel 133b communicates with the filter element inlet 132a through the filter element inlet 132d2 and communicates with the second filter channel 133c the outlet 132b of the filter element through the discharge tube 132d3 of the filter element. When the filter element is in a disassembled state, as shown in FIG. 19, the waterproof unit 133n is lowered to fit the sealing ring 133m, so that the lower through holes of the first filter channel 133b and the second filter channel 133c are closed. The fall of the waterproof unit 133n may be effected by its own weight or by a return spring (not shown), which is installed between the waterproof protrusion 1331 and the waterproof unit 133n.

[0097] As shown in FIG. 14-19, in the process of assembling the filter element for the first time, first the rotatable body 132d is installed in the base body 132c, and the entire filter element base 132 is installed in the drainage collector by means of a connector, at which time the rotatable plate 132d1 closes the filter element inlet 132a and outlet 132b of the filter element. Then, the lower protrusion 133e of the filter element body 133 is inserted respectively into the groove 132c1 of the body 132 from the base, and the filter element body 133 and the rotatable body 132d rotate together relative to the base body 132c with a structural interaction of two threads (or elements similar to threads). After rotating the filter element inlet tube 132d2 of the rotatable body 132d, communicates with the filter element inlet 132a, the filter element outlet tube 132d3 communicates with the filter element outlet 132b and the upper part of the filter element inlet tube 132d2 and pushes the waterproof unit 133n upward during the fall of the filter element housing 133, so that the upper opening of the filter element inlet tube 132d2 communicates with the first frame ltruyuschim channel 133b, and the upper opening of the discharge tube 132d3 filter element communicates with the second channel filter 133c. In this case, water or other liquid to be filtered can flow into or out of the filter space 133a inside the filter element body 133 through the above channels and can be treated with filter material 133d.

[0098] When the filter element body 133 is disassembled, the filter element body 133 is rotated, and the filter element body 133 and the rotatable body 132d rotate together relative to the body 132 from the base with a structural interaction of two threads (or elements similar to threads). After rotation, the rotatable plate 132d1 of the rotatable body 132d closes the filter element inlet 132a and the filter element outlet 132b, the upper parts of the filter element inlet tube 132d2 and the filter element outlet tube 132d3 freeing the waterproof unit 133n during lifting of the filter element body 133. The waterproof unit 133n is lowered by its own weight or return spring and approaches the sealing ring 133m to close the outer through holes of the first filter channel 133b and the second filter channel 133c, so that water or other liquid inside the filter element body 133 cannot exit.

[0099] In addition, when the filter element body 133 is installed again, it simply needs to be screwed into the base 132, which is stationary, and the connection process is carried out as described above.

[00100] In addition, the design of the filter element in this embodiment can also be applied to a non-inverted vertical filter element, while other filter elements are also possible (for example, a horizontal structure).

[00101] Next, as shown in FIG. 8, when at least one step of the filter elements comprises a filter element for protection against harmful substances (protective filter), the cleaner body 10 additionally has a water tank assembly 16, and the protective filter element additionally has an outlet for collected water. The water tank assembly 16 has an inlet to the tank. The water collector has a water collection chamber for collected water. The flow chamber for collected water contains an inlet interface for collected water and an outlet interface for collected water. An outlet interface for collected water is connected to an inlet interface for collected water, and an inlet to the tank is connected to an outlet interface for collected water. The water tank assembly 16 is used to store collected water discharged from the protective filter element.

[00102] Alternatively, as shown in FIG. 8, the water tank assembly 16 further has at least one level switch 161. A level switch 161 is used to measure the amount of water in the water tank assembly 16. When the amount of water in the water tank assembly 16 exceeds a predetermined value, the user can be informed of the need to take action with the collected water, or the collected water is automatically released. In a possible embodiment, the water tank assembly 16 further has an outlet for the tank. Accordingly, as shown in FIG. 12, the tube interface assembly 14 further comprises an exhaust tube 143 for collected water; the tubular assembly 20 further comprises an outlet pipe for collected water, the connector 30 further has a third inlet. The outlet from the reservoir is connected to the first end of the discharge tube 143 for collected water, and the second end of the discharge tube 143 for collected water is connected to the first end of the discharge tube for collected water of the tubular assembly, and the second end of the outlet tube for collected water of the tubular assembly is connected to the third inlet hole. In addition, the third inlet of the connector 30 can be connected to the third outlet 35 through a three-way connecting element, with the collected water being discharged from the third outlet 35; or connector 30 further has a fourth outlet connected to the third inlet, and collected water is discharged from the fourth outlet.

[00103] In an alternative embodiment of the invention, as shown in FIG. 10 is a sectional view of the watercourse 12. FIG. 10 shows two watercourse chambers, i.e., the first watercourse chamber 1211 and the second watercourse chamber 1212. Each watercourse chamber has an inlet interface 121a and an outlet interface 121b. In addition, each flow chamber additionally has at least one expansion portion 121c, which is located between the inlet interface 121a and the outlet interface 121b. The inlet interface 121a smoothly flows into the expansion portion 121c, and the exhaust interface 121b smoothly flows into the expansion portion 121c. In addition, the cross-section of the flow channel in the flow chamber can be round or elliptical, or rectangular or other polygonal, etc.

[00104] In addition, the cross-sectional area of the expansion portion 121c is larger than the cross-sectional area of the inlet interface 121a and the cross-sectional area of the exhaust interface 121b.

[00105] For example, as shown in the first flow chamber 1211 in FIG. 10, when the cross section of the flow channel in the first flow chamber 1211 is circular, and if the diameter of the inlet interface 121a of the first flow chamber 1211 is A1, the diameter of the discharge interface 121b of the first flow chamber 1211 is B1 and the diameter of the expansion part 121c of the first flow chamber 1211 is C1, moreover, C1> A1> B1, the flow channel of the flow chamber is formed as a typical small-large-small structure. In this case, the speed of water or other liquid flowing in the flow channel of the flow chamber slows down, reducing friction with the side wall of the flow channel, which helps to reduce the loss of water flow, improve the amount of produced water and reduce the need for feed water.

[00106] Furthermore, as shown in the second flow chamber 1212 in FIG. 10, when the cross section of the flow channel in the second flow chamber 1211 is circular, if the diameter of the inlet interface 121a of the second flow chamber 1212 is A2, the diameter of the discharge interface 121b of the second flow chamber 1212 is B2, the diameter of the expansion part 121c of the second flow chamber 1212 is C2, and C2> B2> A2, the flow channel of the flow chamber is formed as a typical small-to-small structure. In this case, the speed of water or other liquid flowing in the flow channel of the flow chamber slows down, reducing friction with the side wall of the flow channel, which helps to reduce the loss of water flow, improve the amount of produced water and reduce the need for feed water. In addition, when the cross-sectional area of the exhaust interface 121b is larger than the cross-sectional area of the intake interface 121a, the speed on the side of the exhaust interface 121b is less than the speed on the side of the inlet interface 121a. Thus, such a design can reduce the effect of the instantaneous pressure change on the side of the inlet interface 121a on the pressure from the outlet interface 121b.

[00107] Of course, in other possible embodiments, the cross-sectional area of the inlet interface 121a of the flow chamber may be equal to the cross-sectional area of the outlet interface 121b.

[00108] Alternatively, the expansion portion of the flow chamber may accommodate a quality sensor, such as a Total Dissolved Solids TDS probe, so the expansion portion, as a receive buffer for water flow, determines the quality of water in the expansion portion to improve the reliability of the measured data.

[00109] In an alternative embodiment of the invention, as shown in FIG. 8 and 20, the housing 10 further comprises a mounting assembly 17 for the filter element. The side edge of the fastening assembly 17 for the filter element is connected to the side wall 112 by means of a hinge 171, and the fastening assembly 17 for the filter element has at least n fastening holes 172, where n is an integer. Accordingly, as shown in FIG. 13 and 14, a protrusion 134a is provided on the upper surface of each filter element and inserted into a corresponding mounting hole 172. When the mounting assembly 17 for the filter element is in the closed state, the protrusion 134 on the upper surface of each filter element is fixed by a corresponding mounting hole 172, so that the filtering the element will not fluctuate when exposed to vibration or shock. In an alternative embodiment, the fastening assembly 17 for the filter element further has an open handle 173, which may be configured as an opening, as shown in FIG. 20, or may be in the form of a protrusion or other structure that facilitates the opening and closing of the fastening assembly 17 for the filter element.

[00110] Alternatively, as shown in FIG. 8 and 20, when the housing 10 additionally has a water tank assembly 16, a tank cover 162 may be provided above the water tank assembly 16 (as shown in FIG. 21). The upper surface of the tank lid 162 has a protrusion 163. Accordingly, the fastening assembly 17 for the filter element further has an opening 174 for fastening the tank. The protrusion 163 of the reservoir cap 162 is inserted and attached to the fastening hole 174 of the reservoir so that the reservoir cap 162 does not become loose, which can cause water to pour out of the water reservoir assembly 16 when the water reservoir assembly 16 is subjected to vibration or shock.

[00111] Alternatively, as shown in FIG. 13, the protrusion 134 on the upper surface of each filter element may additionally have a handle 135 for manual operation, which facilitates the assembly and disassembly of the filter element. Alternatively, as shown in FIG. 14, the upper peripheral surface of the filter element body 133 further has a shock-absorbing adhesive 136 in order to reduce vibration and not to damage the filter element body 133 by impact.

[00112] In addition, in other possible embodiments, the inside of the housing 10 additionally has a main control chip, and the inside of the connector 30 additionally has a control circuit. The main control chip is connected to a wire control circuit that is located inside the tubular assembly 20. The main control chip is used to control the pump assembly 15 on / off in the housing 10. The control circuit is used to control the switch valve assembly 36 in the connector 30 between different operating states. When the user requires purified water, due to the interaction between the main control chip and the control circuit, the valve assembly 36 is in the first operating state, the water purifier starts purifying the water, while the purified water filtered by the water purifier flows out of the connector 30; when the user requires tap water, the valve assembly 36 is in the second operating state, the tap water flows directly from the connector 30.

[00113] In addition, in other possible embodiments, inside the connector 30 or the inlet tube of the tubular assembly, there is additionally provided a flow sensor, which is connected to the control circuit or the main control microcircuit wire. The flow sensor can be an impeller type flow sensor. The flow sensor is used to detect the flow of water from the tap outlet. When the water source is closed or does not provide a normal water supply, the water purifier does not start the booster pump for water purification in order to prevent the booster pump from pumping out all the water absorbed by the filter element and to ensure the effectiveness of the subsequent purification.

[00114] In addition, in other possible embodiments, a temperature sensor is additionally provided in the connector 30, which is connected to the control circuit or to the main control chip by a wire. A temperature sensor is used to measure the temperature of the water flowing out of the tap outlet. When the temperature is above a predetermined value, the water supply tube is closed by the cleaner to prevent high-temperature water from entering the filter element and damaging the filter elements to prolong their service life.

[00115] Thus, in accordance with embodiments of the invention, a water purifier is proposed in which a housing is connected to a tap connector by means of a tubular assembly, and a tap connector is installed directly in the tap outlet, which solves the problems of inconvenient and inefficient installation of known water purifiers and provides simplified installation procedures and increased installation efficiency.

[00116] In addition, in accordance with embodiments, an electrically controlled valve assembly is further provided in the crane connector, so that at least one open outlet always exists inside the crane connector due to the high-speed, instantaneous characteristics of the electrically controlled valve of the valve assembly 36, in which there are no problems with the pressure of connector 30, the potential risks of leakage and destruction in the joint are eliminated and safety is increased.

[00117] In addition, in accordance with embodiments, a water flow collector is additionally provided in the water purification housing to sequentially connect the respective stages of filter elements, the pump, and other components in order to avoid complicated tube connections and simplify the design.

[00118] In addition, in accordance with embodiments, water flows in and out through the base of the filter element at the bottom of the filter element. The body of the filter element is located above the base of the filter element, while an inverted vertical structure is formed. Such a design can not only preserve the location of the tubes, but also make the entire design of the filter element more compact. In addition, the filter element additionally uses a water-repellent and waterproof construction to ensure safety, as well as improve the user experience.

[00119] Other embodiments of the invention will be apparent to those skilled in the art after considering the description and use of the invention in practice. This invention is intended to cover any variations, uses or modifications of the invention that follow the general principles of the invention and include well-known or conventional means in the art not described in the description. It is assumed that the description and examples should be considered solely as illustrative only, whereas the true scope and nature of the invention are indicated in the following claims.

[00120] It should be understood that the present invention is not limited to the specific design that is described above and illustrated in the accompanying drawings, and that various modifications and changes can be made without departing from its scope. It is intended that the scope of the invention be limited only by the attached claims.

Claims (43)

1. Water purifier, characterized in that it contains: a housing and a connector for a crane connected to the cleaner body through a tubular assembly, moreover, the cleaner has an inlet and an outlet, the tubular assembly comprises at least an inlet tube and an outlet tube, the tap connector has at least a first inlet, a first outlet, a second inlet, and a second outlet, wherein the first inlet is connected to the first outlet, the first outlet is connected to the first end of the inlet tube of the tubular assembly, the second end of the inlet tube of the tubular assembly is connected to the cleaner inlet, the outlet of the cleaner is connected to the first end of the outlet tube of the tubular assembly, the second end of the outlet tube of the tubular assembly is connected to the second inlet, and the second inlet is connected to the second outlet, while housing contains: the casing containing the lower shell, side walls and the top cover, a water flow collector located on the lower shell and having m cascade water flow chambers, each of which has one inlet interface and one outlet interface, where m≥2 and m is an integer, a node of filter elements containing n stages of filter elements, each stage of filter elements having an inlet and an outlet, the inlet of the filter element of the i-th stage connected to the outlet interface of the j-th flow chamber of the i-th stage with inlet interface j + 1st flow chamber, where n≥1 and n is an integer, 1≤i≤n and i is an integer, 1≤j≤m-1 and j is an integer; a tube interface assembly comprising at least an inlet tube and an outlet tube, wherein the first end of the inlet tube is a cleaner inlet, the second end of the inlet tube is connected to the inlet interface of the first flow chamber, the first end of the discharge tube is a cleaner outlet, and the second end of the discharge tube connected to the outlet interface of the mth flow chamber. 2. Cleaner under item 1, characterized in that the connector for the valve has a third outlet connected to the first inlet, and the connector for the valve has an electrically controlled valve assembly, and said valve assembly has an inlet end, a first outlet end and a second outlet end, the inlet end is connected to the first inlet, the first outlet end is connected to the first outlet, and the second outlet end is connected to the third outlet, when the specified valve assembly is in the first operating state, the channel between the inlet end and the first outlet end is open to allow communication between them, and the channel between the inlet end and the second outlet end is closed, when the specified valve assembly is in the second operating state, the channel between the inlet end and the second outlet end is open to allow communication between them, and the channel between the inlet end and the first outlet end is closed. 3. A cleaner according to claim 2, characterized in that said valve assembly is an electrically controlled valve with one inlet and two outlets, or said valve assembly comprises two electrically controlled valves, each of which has one inlet and one outlet, and a three-way connecting element, or said valve assembly comprises one electrically controlled valve with one inlet and one outlet, and a three-way connecting element. 4. The cleaner according to claim 1, characterized in that its body contains a pumping unit having an inlet and an outlet, the pump inlet being connected to the k-th flow chamber of the outlet, the pump outlet is connected to the inlet interface of k + 1- watercourse chamber, where 1≤k≤m-1 and k is an integer. 5. The cleaner under item 1, characterized in that each step of the filter elements contains: the base of the filter element mounted on the drainage collector and having the specified inlet and outlet of the filter element; the housing of the filter element detachably connected to the upper part of the base of the filter element, the filter element housing comprising a filter space, both ends of which communicate with the first filter channel and the second filter channel, respectively, and the filter space is provided with filter material, moreover, when the filter element is used, the first filter channel communicates with the inlet of the filter element, and the second filter channel communicates with the outlet of the filter element. 6. The cleaner according to claim. 5, characterized in that the base of the filter element contains: the base body mounted on the drainage collector and having the specified inlet and outlet of the filter element, a rotatable body connected rotatably with the upper part of the base body and comprising a rotatable plate having an inlet tube of the filter element and an outlet tube of the filter element, when the filter element is used, the lower opening of the inlet tube of the filter element communicates with the inlet of the filter element, the inlet tube of the filter element is inserted into the first filter channel, and the upper opening of the inlet tube of the filter element communicates with the first filter channel, the lower hole of the outlet tube of the filter element communicates with the outlet of the filter element, the outlet tube of the filter element is inserted into the second filter channel, and the top the outlet of the outlet tube of the filter element communicates with the second filter channel, and when the filter element is in a disassembled state, the rotating plate closes the inlet of the filter element and the outlet of the filter element. 7. A cleaner according to claim 6, characterized in that the upper part of the base body has a groove, the pivoting plate is located at the bottom of the groove, the first threaded structure is located on the inner side wall of the groove, and the lower part of the filter element body has a protrusion, while the second threaded structure located on the outer side wall of the protrusion and the first threaded structure mates with the second threaded structure. 8. A cleaner according to claim 6, characterized in that both the first filter channel and the second filter channel have a waterproof protrusion, an o-ring and a waterproof block, the sealing ring is located near the base housing, the waterproof block is located above the sealing ring, and the waterproof ledge is located above the waterproof block, and when the filter element is used, the inlet tube and the outlet tube of the filter element press the waterproof unit against the waterproof ledge, so that the first filter channel communicates with the inlet hole of the filter element through the filter element inlet tube and the second filter channel communicates with the filter element outlet hole through the outlet tube filter element and when the filter element is in a disassembled state, the waterproof unit is lowered down to press the sealing ring and close the lower openings of the first and second filter channels. 9. Cleaner according to claim 1, characterized in that when at least one step of the filter elements contains a filter element for protection against harmful substances, the cleaner body additionally has a water tank assembly, and the filter element for protection against harmful substances additionally has an outlet for collected water moreover, the node of the water tank has an inlet of the tank, the water collection header additionally has a water chamber for collected water, which contains an inlet interface for the collected water and an outlet interface for the collected water, while the outlet for the collected water is connected to the inlet interface for the collected water, the inlet of the tank is connected to the outlet interface for the collected water. 10. The cleaner according to claim 9, characterized in that the water tank assembly further has a tank outlet, the tube interface assembly further comprises an outlet pipe for collected water, the tubular node further comprises an outlet pipe for collected water, and the connector for the tap has a third inlet, the outlet of the reservoir is connected to the first end of the outlet pipe for collected water, the second end of the outlet pipe for collected water is connected to the first end of the outlet pipe for collected water of the tubular assembly, the second end of the outlet pipe for collected water of the tubular assembly is connected to the third inlet. 11. A cleaner according to claim 9, characterized in that the tank assembly further has at least one level switch. 12. Cleaner according to any one of paragraphs. 1-11, characterized in that each flow chamber additionally contains at least one expansion part, which is located between the inlet interface and the outlet interface and the cross-sectional area of which is greater than the cross-sectional area of the inlet interface and the cross-sectional area of the outlet interface. 13. Cleaner according to any one of paragraphs. 1-11, characterized in that the casing of the cleaner further comprises a fixing unit for the filter element, the side edge of said fixing unit connected to the side wall by means of a hinge, and said fixing unit has at least n fixing holes, while on the upper surface of each filtering member element has a protrusion that is inserted into the corresponding mounting hole. 14. The cleaner according to claim 13, characterized in that the protrusion has a handle.

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