CN212819173U

CN212819173U - Simple filtering component with side water outlet

Info

Publication number: CN212819173U
Application number: CN202020218349.3U
Authority: CN
Inventors: 林声安; 冯永刚; 张金燎; 陈逢北
Original assignee: Guangdong Wapu Technology Co Ltd
Current assignee: Guangdong Lingshang Water Purification Technology Co Ltd
Priority date: 2019-09-17
Filing date: 2020-02-27
Publication date: 2021-03-30
Anticipated expiration: 2030-02-27
Also published as: CN212142144U; CN212819175U; CN212819176U; CN212142142U; CN212790510U; CN212819177U; CN213467412U; CN212142143U; CN213467413U; CN212819174U; CN212790509U; CN212523680U; CN212523679U; CN212790511U

Abstract

The utility model discloses a simple and easy type filtering component, include: the filter material module comprises a central pipe and a reverse osmosis membrane layer arranged around the central pipe, wherein one end of the reverse osmosis membrane layer is arranged as a raw water input end; the reverse osmosis membrane layer is sealed for the other end of raw water input, and the side of reverse osmosis membrane layer is provided with the waste water output, and waste water output position is provided with the water-collecting part that is used for guiding waste water to collect, and the waste water of water-collecting part collects the end and is provided with the one-way water guide structure that is used for guiding waste water to leave away from the filter media module along the unilateralism and exports. Has the advantages that: the waste water is effectively guided to be led out in one direction and is far away from the filter material module, so that the waste water is prevented from being accumulated, the situation that the waste water permeates towards a pure water end is avoided, the problem that the TDS of the initial outlet water of the water purifying device exceeds the standard is effectively solved, and the drinking water health of a user is ensured; if the filtering component is transversely arranged, the best waste water discharging effect can be achieved.

Description

Simple filtering component with side water outlet

Technical Field

The utility model relates to a water purification unit technical field, concretely relates to simple and easy filtering component of side play water.

Background

In the water purifier in the prior art, or a reverse osmosis filter element is applied for filtration, after the water purifier is shut down for a long time, water originally on a raw water side or a concentrated water side in the reverse osmosis filter element permeates to a pure water end of a membrane, and a solute with high TDS on the concentrated water side of the membrane permeates to the pure water side, so that the TDS of the pure water end is higher; when the water purifier discharges water again, the TDS exceeds the standard.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a simple and easy type filtering component and use its filter core structure of side play water solves the problem that TDS exceeds standard when going out water once more after the water purifier shuts down.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a compact filter assembly comprising: the filter material module comprises a central pipe and a reverse osmosis membrane layer arranged around the central pipe, wherein one end of the reverse osmosis membrane layer is arranged as a raw water input end; the periphery side of the reverse osmosis membrane layer is provided with a side water retaining layer around the reverse osmosis membrane layer, a wastewater outlet is formed in the side water retaining layer, a water collecting part used for guiding the collected wastewater is arranged on the wastewater outlet, and a one-way water guide structure used for guiding the wastewater to be led out along a one-way direction away from the filter material module is arranged at the wastewater collecting end of the water collecting part.

The working principle of the scheme is as follows:

raw water enters the inner cavity from the raw water port and enters the reverse osmosis membrane layer through the raw water input end. Filtering by a reverse osmosis membrane layer to obtain pure water and wastewater, wherein the pure water obtained after filtering enters a central tube, flows through the central tube and then flows out through a pure water port; and the waste water obtained after filtration flows to a waste water output end on the reverse osmosis membrane layer, and the waste water flowing out from the waste water output end is discharged outside the filter material module in a single direction from the filter material module through the one-way water guide structure and then is discharged out of the filter element structure through the waste water outlet.

Specifically, the water collecting part comprises a sealing and blocking piece which is sealed at the waste water output end by using viscose, and a water collecting hole is formed in the sealing and blocking piece and is communicated with a waste water outlet to form a waste water collecting end; the one-way water guide structure is connected to the water collecting hole. The waste water reaches the sealing separation blade after flowing out from the waste water output end, and flows into the one-way water guide structure through the water collecting hole of the sealing separation blade.

Specifically, the water collecting part comprises a seat body, a water collecting cavity used for being matched with the waste water output end in an assembling mode is arranged on the seat body, a water receiving opening is formed in the bottom of the water collecting cavity, and a one-way water guide structure is arranged in a position corresponding to the water receiving opening. The waste water flows out through the waste water outlet and is collected in the water collecting cavity, and the waste water in the water collecting cavity enters the one-way water guide structure through the water receiving port and is discharged after being guided by the one-way water guide structure.

Specifically, the bottom in the water collecting cavity is provided with a plurality of supporting blocks for supporting the filter material module, and the upper surface side of each supporting block and the position of the water receiving port have a height difference. A certain space is reserved between the upper surface side of the supporting block and the water receiving port for storing wastewater, and the functions of collecting and buffering the wastewater are achieved.

Specifically, the water receiving port is arranged in the central position of the water collecting cavity, at least 3 supporting blocks are arranged, and each supporting block is arranged around the water receiving port and uniformly distributed along the radial direction of the water collecting cavity.

Specifically, the one-way water guide structure is a deformation water guide structure which can generate deformation change under the gravity of a water source; the deformed water guide structure guides the wastewater output by the wastewater output end to be led out along a direction away from the filter material module. The wastewater utilizes gravity to deform the deformation water guide structure, so that the wastewater can be discharged.

Specifically, the deformation change of the deformation water guide structure caused by the pressure of the water source is an elastic deformation change.

Specifically, the one-way water guide structure is an elastic water guide structure which can generate elastic movement under the gravity of a water source, and the elastic water guide structure after movement guides the wastewater output by the wastewater output end to be led out along a single direction away from the filter material module.

Specifically, the waste water output end position is provided with a water collecting installation position which is used for assembling and disassembling the sealing separation sheet or the base body in a uniform specification mode.

The scheme provides a filter element structure which comprises a shell with an inner cavity, wherein the shell is provided with a raw water port, a pure water port and a waste water port which are communicated with the inner cavity; the inner cavity is internally provided with the filtering component, the raw water port is communicated with the raw water input end, the pure water port is communicated with the central pipe, and the waste water port is communicated with the waste water output end.

The beneficial effects of the utility model reside in that:

this filter core structure's setting, through the application of its deformation water guide structure, effectively the filter media module is kept away from in the one-way derivation of guide waste water, avoids waste water to pile up in the waste water output to avoid waste water to the condition of the pure water end infiltration of reverse osmosis filter core effectively, effectively solve the problem that corresponding purifier initial effluent TDS exceeds standard, guarantee that user's drinking water is healthy. Meanwhile, when the filtering component is transversely placed, the best waste water discharging effect can be achieved.

Drawings

Fig. 1 is a schematic structural diagram of a filter element structure in embodiment 2 of the present invention;

FIG. 2 is an enlarged view of a portion A of FIG. 1;

fig. 3 is a schematic structural view of the first seat in embodiment 1 of the present invention;

fig. 4 is a partial schematic view of a combined use state of the water collecting part and the deformation water guiding structure in embodiment 1 of the present invention;

fig. 5 is a schematic structural view of a second structure of a filter element in embodiment 2 of the present invention;

FIG. 6 is a partial enlarged view of portion B of FIG. 4;

fig. 7 is a schematic view of a combined structure of a reverse osmosis membrane layer and an elastic water guide structure in embodiment 2 of the present invention;

fig. 8 is a schematic structural view of a filter element structure when the single-direction water guide structure in embodiment 3 of the present invention is applied as a check valve;

fig. 9 is a schematic structural view of the filter element structure when the single water guide structure in embodiment 3 of the present invention is applied as an elastic water guide structure;

fig. 10 is a partial enlarged view of portion C of fig. 9;

fig. 11 to 13 are different structural schematic diagrams of the filter element structure.

Reference numeral 01, pure water gap; 02. a raw water port; 03. a waste water port; 04; a central tube; 05. a reverse osmosis membrane layer; 06. a housing; 07. a raw water input end; 08. a side water retaining layer; 09. a first water receiving port; 10. sealing the stop block; 11. assembling a connecting shaft; 12. a first water collection cavity; 13. mounting holes; 14. a support block; 15. a first seat body; 16. a waste water outlet; 20. a second seat body; 21. a second water collecting cavity; 22. a second water receiving port; 23. a valve mounting portion; 24. a valve cavity is arranged; 25. a valve body; 26. a water inlet; 27. a water outlet; 28. a valve cavity; 29. a water retaining block; 30. a spring; 31. a water outlet; 32. a valve waterproof gasket; 33. a second support block; 34. sealing the blocking piece; 35. a water collection port; 36. an elastic water guide structure; 37. a deformation water guide structure; 38. a waste water output end; 39. a one-way water guide structure; 40. a water collection installation site; 41. a one-way valve.

Detailed Description

In order to make the technical solution of the present invention better understood and make the above objects, features and advantages of the present invention more obvious and understandable, the present invention is further described below with reference to the accompanying drawings and examples.

As shown in fig. 1-13, the embodiment of the present invention includes a filter element structure, which includes a casing 06 having an inner cavity, and the casing 06 is provided with a raw water port 02, a pure water port 01 and a waste water port 03 communicated with the inner cavity; be provided with simple and easy type filtering component in the inner chamber, filtering component includes the filter media module, and the filter media module includes center tube 04 and the reverse osmosis membrane layer 05 around the center tube 04 setting, and reverse osmosis membrane layer 05 one end is established respectively and is provided with raw water input 07, and reverse osmosis membrane layer 05 side is provided with the waste water output.

A side water retaining layer 08 is also arranged around the periphery of the reverse osmosis membrane layer 05, and a wastewater outlet 16 is arranged on the side water retaining layer 08 and serves as a wastewater outlet end. The waste water output end position is provided with catchment installation position 40, be provided with the portion of catchmenting that is used for guiding waste water to collect on the catchment installation position 40, catchment installation position 40 sets up unified specification form to be used for the portion of catchmenting of different forms to carry out the dismouting. And a one-way water guide structure 39 for guiding the wastewater away from the filter material module in a single direction is arranged at the wastewater collection end of the water collection part.

In the following embodiments, the waste water outlet 38, i.e. the waste water outlet 16 opened on the side water retaining layer 08, and the waste water outlet 16 also serves as a water collecting installation position 40 for installing each one-way water guiding structure 39. The catchment installation sites 40 all have a uniform standard, so in the following embodiments the waste water outlets 16 are of the same size.

Under the normal condition, the filter element is in the water-making state, and the waste water in the filter element can be smoothly discharged in a single direction through the pressurization effect of the pressurization component outside the filter element, so that a dynamic balance state is achieved. But at the outside pressure boost subassembly stop work of filter core, under the state that the filter core got into to stop system water, under the effect of gravity, the condition that waste water still has the gathering, nevertheless because pressure boost subassembly shut down can not reach dynamic balance this moment, in the reverse osmosis rete 05 can be reinfiltrated to exhaust waste water or can, when leading to system water again, the condition that the TDS value is on the high side appears in exhaust pure water. And through the arrangement of the corresponding one-way water guide structure 39, the wastewater source at the wastewater output end 38 after shutdown can be effectively discharged in a one-way guide manner, and the wastewater back-seepage is avoided. Additionally, based on the utility model discloses the one-way water guide structure 39's that the side direction set up application, when this filter assembly or this filter core structure are horizontal, under the effect of gravity, the waste water in the reverse osmosis rete 05 can gather in the side, and under this condition, the one-way water guide structure 39 who sets up in reverse osmosis rete side can discharge waste water more effectively.

Specifically, the water collecting part and the one-way water guiding structure 39 are arranged in a matching manner as follows:

example 1

The water collecting part comprises a first base body 15 arranged on the water collecting installation position 40, the first base body 15 is arranged on the water collecting installation position 40, and the specific form is as follows: the end face of the first seat body 15 abuts against the reverse osmosis membrane layer 05, the outer edge of the first seat body is fixedly connected with the inner wall of the wastewater outlet 16 through glue or other viscous connecting substances, and the first seat body 15 is installed.

A first water collecting chamber 12 is formed in the first seat body 15. The reverse osmosis membrane layer 05 is closed relative to one end of the raw water input end 07, and the wastewater flows out of the reverse osmosis membrane layer 05 through the wastewater outlet 16 and then flows into the first water collecting cavity 12 under the action of gravity to form wastewater collection.

The bottom of the first water collecting cavity 12 is provided with a mounting hole 13, six first water receiving openings 09 are arranged around the mounting hole 13, and the mounting hole 13 is located at the center of the six first water receiving openings 09. A blocking block 10 made of elastic materials is arranged below the first water receiving port 09, and the elastic materials can be rubber; the central position of the blocking piece 10 extends upwards to be provided with an assembling shaft 11. The mounting shaft 11 is mounted in cooperation with the mounting hole 13, and particularly, a fixed state relative to the mounting hole 13 is achieved in a clamping mode with the mounting hole 13. Through the cooperation of the mounting shaft 11 and the mounting hole 13, the packaging block 10 and the first water receiving opening 09 are mounted in a matched manner, so that the upper side surface of the sealing block 10 seals the six first water receiving openings 09.

Each first water receiving mouth 09 is the trend setting of keeping away from first water-collecting chamber 12 from the one side of being close to mounting hole 13 to the one side of keeping away from mounting hole 13, and the downside of each first water receiving mouth 09 is the arc form of encircleing, and is corresponding, seals dog 10 for sealing first water receiving mouth 09 better, also is the arc form of encircleing and sets up.

The bottom of the first water collecting cavity 12 is also provided with six first supporting blocks 14, and the six first supporting blocks 14 are arranged around the position of the first water receiving opening 09 and are uniformly distributed along the radial direction of the water collecting cavity 12 and are used for supporting the filter material module.

In this embodiment, the deformation water guide structure 37 mainly utilizes the elasticity of the blocking block 10 made of elastic material to control the circulation of the wastewater: according to the weight of the waste water born by the blocking block 10, pressure is formed on the blocking block 10, so that the blocking block 10 deforms or deforms and recovers, the first water receiving port 09 is automatically opened or closed, and the one-way water guiding function of the deformation water guiding structure 37 is realized.

The working principle of the filter assembly in the embodiment is as follows:

raw water enters the reverse osmosis membrane layer 05 from the raw water input end 07, is filtered by the reverse osmosis membrane layer 05 and then flows out of the reverse osmosis membrane layer 05 from the wastewater outlet 16 of the side water blocking layer 08. The waste water flowing out through the waste water outlet 38 is collected in the first water collecting chamber 12 in the first seat body 15.

When the wastewater in the first water collecting cavity 12 is gathered to a certain weight, under the action of gravity, pressure is applied to the blocking block 10 below the first water receiving port 09 until the blocking block 10 is pressed to be elastically deformed, so that the outer edge of the blocking block 10 moves downwards. At this time, the first water receiving port 09 is communicated with the external space, and the wastewater is discharged from the reverse osmosis membrane layer 05 through the first water receiving port 09.

When the waste water is discharged to a certain degree until the waste water in the first water collecting cavity 12 is not enough to enable the blocking block 10 to be elastically deformed, the outer edge of the blocking block 10 rebounds upwards until the first water receiving opening 09 is closed again. At this time, the wastewater of the external space cannot enter the first water collecting chamber 12 and the reverse osmosis membrane layer 05.

Example 2

The difference between this embodiment and embodiment 1 is that the one-way water guide structure 39 is an elastic water guide structure 36 that can generate elastic movement under the pressure of the water source, and the elastic water guide structure 36 after movement guides the wastewater output from the wastewater output end to be led away from the filter material module in one direction.

The water collecting part comprises a second seat body 20, the second seat body 20 is installed in a manner of being matched with a side water retaining layer 08 of the reverse osmosis membrane layer 05, the second seat body 20 is installed on a water collecting installation position, and the specific form is as follows: the end face of the second seat 20 abuts against the reverse osmosis membrane layer 05, and the outer edge of the second seat is fixedly connected with the inner wall of the wastewater outlet 16 by glue or other viscous connecting substances, so that the second seat 20 is installed.

A second water collecting cavity 21 is formed in the second seat body 20. The wastewater flows out of the reverse osmosis membrane layer 05 through the wastewater outlet 16 and then flows into the second water collecting cavity 21 under the action of gravity to form wastewater collection.

The bottom of the second water collecting cavity 21 is provided with a second water receiving opening 22, a valve mounting part 23 is arranged below the position, corresponding to the second water receiving opening 22, of the bottom of the second seat body 20, a valve mounting part 24 is arranged in the valve mounting part 23, the valve mounting part 24 is communicated with the second water receiving opening 22, and an elastic water guide structure is connected in the valve mounting part 24. The elastic water guide structure comprises a valve body 25, and the valve body 25 comprises a water inlet 26 and a water outlet 27; a valve cavity 28 communicated with the water inlet 26 and the water outlet 27 is arranged in the valve body 25, a water retaining block 29 for closing the water inlet 26 is arranged in the valve cavity 28, a spring 30 is arranged between the water retaining block 29 and the water outlet 27, and the spring 30 exerts a return elastic force towards the water inlet 26 on the water retaining block 29; the bottom of the valve containing cavity 24 is provided with a water outlet 31; the height of the valve accommodating cavity 24 is greater than or equal to the height of the valve body 25. The periphery of the valve body 25 is sleeved with a valve waterproof gasket 32, and the valve waterproof gasket 32 and the valve containing cavity 24 form interference fit.

At the bottom of the second water collecting chamber 21, a second supporting block 33 is further provided. The upper surface of the second supporting block 33 is higher than the second water receiving opening 22, mainly to make the waste water have a space for buffering and collecting.

In this embodiment, the elastic water guide structure 36 realizes the on-off of the wastewater flow through the linkage of the water blocking block 29 and the spring 30: the compressed or extended state of the spring 30 is controlled according to the water pressure of the wastewater from the first water collecting cavity 12, which is borne by the water blocking block 29, so as to form automatic opening and closing control of the water inlet 26, thereby realizing the one-way water guiding function of the elastic water guiding structure 36.

The working principle of the filter assembly in the embodiment is as follows:

raw water enters the reverse osmosis membrane layer 05 from the raw water input end 07, is filtered by the reverse osmosis membrane layer 05 and then flows out of the reverse osmosis membrane layer 05 from the wastewater outlet 16 of the side water blocking layer 08. The waste water flowing out through the waste water outlet 38 is collected in the second water collecting chamber 21 in the second seat body 20.

The waste water in the second water collecting cavity 21 flows into the valve containing cavity 24 through the second water receiving opening 22, when the waste water in the second water collecting cavity 21 is collected to a certain amount, the waste water applies pressure to the water retaining block 29 in the elastic water guiding structure 36 under the action of gravity to press the water retaining block 29 downwards, the water retaining block 29 compresses the spring 30, at this time, the water inlet 26 is opened, the waste water enters the valve cavity 28 from the second water collecting cavity 21 through the water inlet 26, and is discharged out of the valve cavity 28 from the water outlet 27 through the valve cavity 28, and finally the waste water is discharged out of the valve containing cavity 24 through the water outlet 31.

And when the waste water is discharged to a certain degree, the pressure applied by the waste water to the water blocking block 29 is smaller than the reset elastic force of the spring 30. The restoring spring pushes the water stop 29 upwards until the water stop 29 closes the water inlet 26 again. So set up, after water purification equipment shut down, just can not get into reverse osmosis membrane layer 05 through elasticity water guide structure at the outer waste water of reverse osmosis membrane layer 05 in.

Example 3:

the present embodiment differs from the above embodiments in that: the water collecting part comprises a sealing and blocking piece 34 which is sealed and arranged on a water collecting installation position 40 of the waste water output end 38 through viscose, a water collecting hole 35 is formed in the sealing and blocking piece 34 to form a waste water collecting end, and a one-way water guide structure is connected to the water collecting hole 35.

The blocking piece 34 is arranged on the water collecting installation position 40, and the concrete form is as follows: the outer edge of the blocking piece 34 is attached to the inner wall of the waste water outlet 16, and the surface facing the reverse osmosis membrane layer 05 is fixedly connected with the reverse osmosis membrane layer 05 through glue or other viscous connecting substances, so that the blocking piece 34 is installed.

In the embodiment 3, the one-way water guiding structure 39 can be applied based on the elastic water guiding structure 36 in the above embodiment 2, or based on other one-way water guiding valve structure forms in the prior art, so as to satisfy the corresponding one-way water guiding function.

As shown in fig. 10 to 12, in response to actual use requirements, the filter assembly of the present invention can be applied to a filter element structure, and the raw water port 02, the pure water port 01, and the waste water port 03 of the filter element structure of the present invention can be arbitrarily set at two ends of the filter element structure based on the change adjustment of the internal structure and the water path. For example:

example 4:

as shown in fig. 11, which is a schematic view of the filter element structure of embodiment 4, embodiment 4 differs from embodiment 3 in that: in this embodiment, the raw water port 02 and the waste water port 03 are provided at the same end of the housing 06, and the pure water port 01 is provided at the other end. Through the arrangement, the filter element structure can meet the requirement for setting the position of the water gap due to the change and adjustment of the inner structure and the water path of the filter element structure, and meet the actual use requirements of different users.

Example 5:

example 5 differs from example 3 in that: in this embodiment, the pure water port 01 and the waste water port 03 are located at the same end of the housing 06, and the two ends of the housing are provided with the raw water ports 02. Through the arrangement, the filter element structure can meet the requirement for setting the position of the water gap due to the change and adjustment of the inner structure and the water path of the filter element structure, and meet the actual use requirements of different users.

Example 6:

as shown in fig. 12, which is a schematic view of the filter element structure of embodiment 6, embodiment 6 is different from embodiment 3 in that: in this embodiment, the raw water port 02, the pure water port 01, and the waste water port 03 are provided at the same end of the housing 06. Through the arrangement, the filter element structure can meet the requirement for setting the position of the water gap due to the change and adjustment of the inner structure and the water path of the filter element structure, and meet the actual use requirements of different users.

Example 7:

example 5 differs from example 3 in that: in this embodiment, the pure water port 01 and the raw water port 02 are provided at the same end of the housing 06, and the other end of the housing 06 is provided with the waste water port 03. Through the arrangement, the filter element structure can meet the requirement for setting the position of the water gap due to the change and adjustment of the inner structure and the water path of the filter element structure, and meet the actual use requirements of different users.

Example 8:

example 8 differs from example 3 in that: in this embodiment, the pure water port 01 and the waste water port 03 are located at the same end of the housing 06, and the two ends of the housing are provided with the raw water ports 02. Through the arrangement, the filter element structure can meet the requirement for setting the position of the water gap due to the change and adjustment of the inner structure and the water path of the filter element structure, and meet the actual use requirements of different users.

Example 9:

example 9 differs from example 3 in that: in this embodiment, the pure water port 01 and the raw water port 02 are provided at the same end of the housing 06, and the waste water ports 03 are provided at both ends of the housing. Through the arrangement, the filter element structure can meet the requirement for setting the position of the water gap due to the change and adjustment of the inner structure and the water path of the filter element structure, and meet the actual use requirements of different users.

Example 10:

as shown in fig. 13, which is a schematic view of the filter element structure of embodiment 10, embodiment 10 differs from embodiment 3 in that: in this embodiment, the pure water port 01 and the waste water port 03 are respectively provided at both ends of the housing 06, and both ends of the housing are provided with the raw water ports 02. Through the arrangement, the filter element structure can meet the requirement for setting the position of the water gap due to the change and adjustment of the inner structure and the water path of the filter element structure, and meet the actual use requirements of different users.

Example 11:

example 11 differs from example 3 in that: in this embodiment, the pure water port 01 is provided at one end of the housing 06, and the raw water port 02 and the waste water port 03 are provided at both ends of the housing 06. Through the arrangement, the filter element structure can meet the requirement for setting the position of the water gap due to the change and adjustment of the inner structure and the water path of the filter element structure, and meet the actual use requirements of different users.

The preferred embodiment of the present invention is only listed in the present specification, and all the technical changes equivalent to those made under the working principle and thought of the present invention are considered as the protection scope of the present invention.

Claims

1. A side-outlet, compact filter assembly comprising: the filter material module comprises a central pipe and a reverse osmosis membrane layer arranged around the central pipe, wherein one end of the reverse osmosis membrane layer is arranged as a raw water input end; the method is characterized in that: the utility model discloses a filter material module, including reverse osmosis rete periphery side, the filter material module is used for leading the filter material module to carry out the export, the reverse osmosis rete periphery side is around being provided with the side manger plate layer, be provided with the waste water export on the side manger plate layer in order to be formed with the waste water output, be provided with the water-collecting part that is used for guiding waste water to collect on the waste water output, the waste water of water-collecting part collects the end and is provided with.

2. The compact filtration module of claim 1 wherein: the water collecting part comprises a sealing baffle plate sealed at the wastewater output end by using viscose, and the sealing baffle plate is provided with a water collecting hole to be communicated with the wastewater outlet to form the wastewater collecting end; the one-way water guide structure is connected to the water collecting hole.

3. The compact filtration module of claim 2 wherein: the water collecting part comprises a seat body, a water collecting cavity used for being matched with the waste water output end in an assembling mode is arranged on the seat body, a water receiving opening is formed in the bottom of the water collecting cavity, and the one-way water guide structure is arranged corresponding to the position of the water receiving opening.

4. The compact filtration module of claim 3 wherein: the bottom in the water collecting cavity is provided with a plurality of supporting blocks for supporting the filter material module, and the upper surface sides of the supporting blocks and the position of the water receiving port have a height difference.

5. The compact filtration module of claim 4 wherein: the water receiving port is arranged in the central position of the water collecting cavity, at least 3 supporting blocks are arranged, and the supporting blocks are arranged around the position of the water receiving port and are uniformly distributed along the radial direction of the water collecting cavity.

6. A compact filter module as claimed in any one of claims 2 to 5, wherein: the one-way water guide structure is a deformation water guide structure which can generate deformation change under the gravity of a water source; the deformed water guide structure guides the wastewater output by the wastewater output end to be led out along a direction away from the filter material module.

7. The compact filtration module of claim 6 wherein: the deformation change of the deformation water guide structure caused by the gravity of the water source is elastic deformation change.

8. A compact filter module as claimed in any one of claims 2 to 5, wherein: the one-way water guide structure is an elastic water guide structure which can generate elastic movement under the gravity of a water source, and the elastic water guide structure after movement guides the wastewater output by the wastewater output end to be led out away from the filter material module along a single direction.

9. The simplified filtering assembly as set forth in claim 3 wherein the waste water outlet is provided with a water collecting installation position for the blocking sheet or the seat body to be assembled and disassembled in a uniform specification.