Sewage reaction device

By introducing a multi-stage filtration system and vibration module into the wastewater reaction device, the problem of poor filtration effect caused by a single filter plate is solved, realizing multi-stage filtration and full catalytic reaction of wastewater, and improving wastewater treatment efficiency.

CN224325176UActive Publication Date: 2026-06-05北斗航天环保科技(宁波)有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
北斗航天环保科技(宁波)有限公司
Filing Date
2025-08-21
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

Existing wastewater treatment devices rely on a single filter plate, resulting in poor filtration efficiency and difficulty in effectively removing harmful substances from wastewater.

Method used

A multi-stage filtration system is adopted, including a first filter plate, a reaction component, and a second filter plate. The reaction component has built-in catalytic reactants and the gap is adjusted by a vibration module. The combination of catalytic reaction and vibration module achieves multi-stage filtration and improves the filtration effect.

Benefits of technology

Multi-stage filtration of wastewater is achieved, improving the filtration effect of the wastewater reaction device, ensuring that the catalytic reactants fully react with the wastewater, and converting harmful substances into harmless substances.

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Patent Text Reader

Abstract

The sewage reaction device comprises a shell, a first filter plate, a reaction assembly and a second filter plate; the first filter plate is installed in the shell; the first filter plate is used for filtering sewage input through a sewage inlet; a vibration module vibrates each catalytic reactant to adjust the gap between two adjacent catalytic reactants; the sewage filtered through the first filter plate passes through a reaction cavity and catalytically reacts with the catalytic reactant to output fluid; the second filter plate is installed in the shell; the second filter plate is used for filtering the fluid output through the reaction cavity and is connected with a fluid outlet; the fluid outlet is used for discharging the fluid discharged through the second filter plate, so that the sewage is subjected to primary filtration by the first filter plate, catalytic reaction by the catalytic reactant and final filtration by the second filter plate, multi-stage filtration is realized, and the filtering effect of the sewage reaction device is improved.
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Description

Technical Field

[0001] This utility model relates to the technical field of wastewater reaction devices, and in particular to a wastewater reaction device. Background Technology

[0002] With the development of technology, wastewater reaction devices are being applied in industry. These devices are used to filter wastewater through chemical reactions and biodegradation processes, converting harmful substances in wastewater into harmless ones, reducing environmental pollution, improving water quality, and protecting the ecological environment. In existing technologies, wastewater reaction devices include a shell and a first filter plate connected to the inside of the shell. The first filter plate filters the wastewater entering the shell; however, relying solely on the first filter plate results in poor filtration efficiency in existing wastewater reaction devices. Utility Model Content

[0003] The purpose of this utility model is to provide a wastewater reaction device. The housing includes a wastewater inlet, a receiving cavity, and a fluid outlet. The wastewater inlet is used to connect to an external wastewater input pipe. The receiving cavity extends along the length of the housing and serves as the internal space of the housing. The receiving cavity is connected to the wastewater inlet. A first filter plate is located in the receiving cavity and installed inside the housing. The first filter plate is used to filter wastewater input through the wastewater inlet. The reaction assembly includes a reaction chamber and a vibration module. The reaction chamber is located below the first filter plate and contains corresponding catalytic reactants. The vibration module is located in the middle of the reaction chamber and vibrates the catalytic reactants. The system moves to adjust the gap between two adjacent catalytic reactants. Wastewater filtered by the first filter plate passes through the reaction chamber and reacts with the catalytic reactants to produce a fluid output. A second filter plate is located on the lower side of the reaction assembly and installed inside the housing. The second filter plate filters the fluid output from the reaction chamber and connects to a fluid outlet, which discharges the fluid that has passed through the second filter plate. This facilitates primary filtration by the first filter plate, wastewater reaction with the catalytic reactants, and final filtration by the second filter plate, achieving multi-stage filtration and avoiding filtration solely through the first filter plate, thus improving the filtration efficiency of the wastewater reaction device. Simultaneously, the vibration module ensures the catalytic reactants fully react with the wastewater.

[0004] To achieve the above objectives, this utility model provides the following technical solution: a wastewater reaction device, comprising:

[0005] The housing includes a sewage inlet, a receiving cavity, and a fluid outlet. The sewage inlet is used to connect to an external sewage input pipe. The receiving cavity extends along the length of the housing and serves as the internal space of the housing. The receiving cavity is connected to the sewage inlet.

[0006] A first filter plate is located in the receiving cavity and installed inside the housing; the first filter plate is used to filter sewage input through the sewage inlet;

[0007] The reaction assembly includes a reaction chamber and a vibration module. The reaction chamber is located below the first filter plate and contains corresponding catalytic reactants. The vibration module is located in the middle of the reaction chamber and vibrates each catalytic reactant to adjust the gap between two adjacent catalytic reactants. Wastewater filtered by the first filter plate passes through the reaction chamber and undergoes a catalytic reaction with the catalytic reactants to output fluid.

[0008] The second filter plate is disposed on the lower side of the reaction assembly and installed inside the housing; the second filter plate is used to filter the fluid output from the reaction chamber and is connected to the fluid outlet, which is used to discharge the fluid discharged through the second filter plate.

[0009] Optionally, the vibration module extends along the length of the housing, vibrates at a preset frequency, and the catalytic reactant fills the outer periphery of the vibration module.

[0010] Optionally, the reaction chamber is an annular cavity containing multiple catalytic reactants, and the vibration module is arranged in a cylindrical shape and located in the middle of the reaction chamber.

[0011] Optionally, the first filter plate is provided with a plurality of first filter holes, which are arranged in an array along a ring or square direction; the plurality of first filter holes are connected to the sewage inlet and the reaction chamber in the vertical direction, and perform primary filtration on the sewage input through the sewage inlet;

[0012] The catalytic reactants in the reaction chamber react with the wastewater and perform intermediate filtration to output the corresponding fluid.

[0013] The second filter plate is located below the reaction chamber and performs final filtration on the fluid output from the reaction chamber.

[0014] Optionally, the first filter plate is connected to a first converging member, which is disposed on the lower side of the first filter plate and is distributed in a conical shape;

[0015] The inner wall of the first converging element is arranged at an angle and along a ring direction. The inner wall of the first converging element converges towards the center, and the wastewater output from the first filter plate converges towards the center through the inner wall of the first converging element.

[0016] Optionally, a bottom support frame is formed in the reaction chamber to support the catalytic reactants inside the reaction chamber;

[0017] The vibration module is located above the bottom support frame, which has a water passage hole that connects to the fluid outlet via the second filter plate.

[0018] Optionally, the sewage inlet is located at the top of the housing; the fluid outlet is located at the bottom of the housing, and the orientation of the fluid outlet and the sewage inlet are in different directions.

[0019] Optionally, the second filter plate is provided with a plurality of second filter holes, which are arranged in an array along a ring or square direction; the plurality of second filter holes are connected to the reaction chamber and the fluid outlet along the vertical direction, and perform final filtration on the fluid output from the reaction chamber.

[0020] Optionally, the second filter plate is provided with a cross support frame;

[0021] The housing includes an upper shell and a lower shell, the upper shell being disposed on the upper side of the lower shell and sealingly connected to the lower shell;

[0022] The upper shell integrates the first filter plate, the reaction chamber, and the vibration module; the lower shell integrates the second filter plate.

[0023] The lower shell is detachably connected to the upper shell. A connector is connected to the outer side wall of the lower shell. The connector is located on the outer side of the lower shell and is swayably connected to the lower shell to lock it to the upper shell.

[0024] Optionally, when the first filter plate or the reaction chamber is blocked, fluid is introduced into the fluid outlet. The fluid flows along the second filter plate toward the first filter plate and impacts the catalytic reactants in the reaction chamber and the first filter plate to adjust the blockage state of the reaction chamber and the state of the first filter plate.

[0025] Compared with the prior art, the beneficial effects of this utility model are:

[0026] This invention provides a wastewater reaction device. The housing includes a wastewater inlet, a receiving cavity, and a fluid outlet. The wastewater inlet connects to an external wastewater input pipe. The receiving cavity extends along the length of the housing and serves as its internal space. The receiving cavity is connected to the wastewater inlet. A first filter plate is located within the receiving cavity and installed inside the housing. The first filter plate filters the wastewater input through the wastewater inlet. The reaction assembly includes a reaction chamber and a vibration module. The reaction chamber is located below the first filter plate and contains corresponding catalytic reactants. The vibration module is located in the center of the reaction chamber and vibrates the catalytic reactants. The system adjusts the gap between two adjacent catalytic reactants. Wastewater filtered by the first filter plate passes through the reaction chamber and reacts with the catalytic reactants to produce a fluid output. A second filter plate is located on the lower side of the reaction assembly and installed inside the housing. This second filter plate filters the fluid output from the reaction chamber and connects to a fluid outlet, which discharges the fluid that has passed through the second filter plate. This multi-stage filtration—combining primary filtration by the first filter plate, wastewater reaction with the catalytic reactants, and final filtration by the second filter plate—avoids filtration solely through the first filter plate and improves the filtration efficiency of the wastewater reaction device. Simultaneously, a vibration module ensures the catalytic reactants fully react with the wastewater. Attached Figure Description

[0027] To more clearly illustrate the technical solutions in the embodiments of this application, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application, and those skilled in the art can obtain other drawings based on these drawings without creative effort.

[0028] To gain a more complete understanding of this application and its beneficial effects, the following description will be provided in conjunction with the accompanying drawings. In the following description, the same reference numerals denote the same parts.

[0029] Figure 1 A schematic diagram of a wastewater reaction apparatus according to an embodiment of this application is shown.

[0030] Figure 2 A front view of a wastewater reaction apparatus according to an embodiment of this application is shown.

[0031] Figure 3 A cross-sectional view of a wastewater reaction apparatus according to an embodiment of this application is shown.

[0032] Figure 4 Another cross-sectional view of a wastewater reaction apparatus according to an embodiment of this application is shown.

[0033] Attached Figure

[0034] 100. Wastewater reaction equipment;

[0035] 10. Shell; 10a. Sewage inlet; 10b. Receiving cavity; 10c. Fluid outlet; 11. Upper shell; 12. Lower shell; 121. Connecting parts;

[0036] 20. First filter plate; 20a. First filter hole; 21. First converging element;

[0037] 30. Reaction assembly; 31. Reaction chamber; 311. Bottom support frame; 311a. Water passage hole; 32. Vibration module;

[0038] 40. Second filter plate; 40a. Second filter hole; 41. Cross support frame. Detailed Implementation

[0039] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only a part of the embodiments of this application, and not all of them. All other embodiments obtained by those skilled in the art based on the embodiments of this application without creative effort are within the scope of protection of this application.

[0040] Please refer to the attached document. Figures 1-4 This application provides a wastewater reaction device 100, which is used to perform multi-stage filtration reaction on wastewater.

[0041] Please refer to the attached document. Figures 1-4In this embodiment, the wastewater reaction device 100 includes a housing 10, a first filter plate 20, a reaction assembly 30, and a second filter plate 40. The housing 10 is provided with a wastewater inlet 10a, a receiving cavity 10b, and a fluid outlet 10c. The wastewater inlet 10a is used to connect to an external wastewater input pipe. The receiving cavity 10b extends along the length of the housing 10 and serves as the internal space of the housing 10. The receiving cavity 10b is connected to the wastewater inlet 10a. The first filter plate 20 is located in the receiving cavity 10b and installed inside the housing 10. The first filter plate 20 is used to filter the wastewater input through the wastewater inlet 10a. The reaction assembly 30 includes a reaction chamber 31 and a vibration module 32. The reaction chamber 31 is located below the first filter plate 20 and contains corresponding catalytic reactants. The vibration module 40... The first filter plate 20 is positioned in the middle of the reaction chamber 31 and vibrates each catalytic reactant to adjust the gap between adjacent catalytic reactants. Wastewater filtered by the first filter plate 20 passes through the reaction chamber 31 and reacts with the catalytic reactants to output fluid. The second filter plate 40 is located on the lower side of the reaction assembly 30 and installed inside the housing 10. The second filter plate 40 filters the fluid output from the reaction chamber 31 and is connected to the fluid outlet 10c, which discharges the fluid discharged through the second filter plate 40. This facilitates primary filtration by the first filter plate 20, wastewater reaction with the catalytic reactants, and final filtration by the second filter plate 40, achieving multi-stage filtration and avoiding filtration solely through the first filter plate 20, thus improving the filtration effect of the wastewater reaction device 100. Simultaneously, the vibration module 32 ensures sufficient reaction of the catalytic reactants with the wastewater.

[0042] Please refer to the attached document. Figures 1-4 In this embodiment, the housing 10 is provided with a sewage inlet 10a, a receiving cavity 10b, and a fluid outlet 10c. The housing 10 is arranged vertically. The sewage inlet 10a is used to connect to an external sewage input pipe. The receiving cavity 10b extends along the length of the housing 10 and serves as the internal space of the housing 10. The receiving cavity 10b is connected to the sewage inlet 10a so that sewage output from the external sewage input pipe can enter the receiving cavity 10b from top to bottom through the sewage inlet 10a. The fluid outlet 10c is used to discharge fluid.

[0043] The first filter plate 20 is located in the receiving cavity 10b and installed inside the housing 10 so that the first filter plate 20 is fixed to the inside of the housing 10; the first filter plate 20 is used to filter the sewage input through the sewage inlet 10a so that the sewage input through the sewage inlet 10a can be subjected to primary filtration.

[0044] The reaction assembly 30 includes a reaction chamber 31 and a vibration module 32. The reaction chamber 31 is located below the first filter plate 20 and contains corresponding catalytic reactants. The vibration module 32 is located in the middle of the reaction chamber 31 and vibrates each catalytic reactant to adjust the gap between adjacent catalytic reactants. Wastewater filtered by the first filter plate 20 passes through the reaction chamber 31 and undergoes a catalytic reaction with the catalytic reactants to output fluid. This ensures that harmful substances in wastewater can be converted into harmless substances through chemical reaction and biodegradation processes. The vibration module 32 ensures that the catalytic reactants fully react with the wastewater.

[0045] The second filter plate 40 is disposed on the lower side of the reaction assembly 30 and installed inside the housing 10. The second filter plate 40 is used to filter the fluid output from the reaction chamber 31 and is connected to the fluid outlet 10c. The fluid outlet 10c is used to discharge the fluid discharged through the second filter plate 40 so as to facilitate the primary filtration of the first filter plate 20, the wastewater reaction of the catalytic reactants, and the final filtration of the second filter plate 40, so as to achieve multi-stage filtration, avoid filtration only through the first filter plate 20, and improve the filtration effect of the wastewater reaction device 100.

[0046] Please refer to the attached document. Figures 1-4 In this embodiment, the vibration module 32 extends along the length of the housing 10 so that the vibration module 32 is aligned with the housing 10. The vibration module 32 outputs vibration energy to its outer periphery, and the outer periphery of the vibration module 32 is filled with catalytic reactants, which are granular or have a pre-processed shape. Under the vibration of the vibration module 32, the gaps of the catalytic reactants are adjusted to regulate the flow space of the wastewater after filtration by the first filter plate 20 relative to the catalytic reactants, thereby increasing the capacity for wastewater. The vibration module 32 ensures that the catalytic reactants fully react with the wastewater.

[0047] Please refer to the attached document. Figures 1-4 In this embodiment of the application, the reaction chamber 31 is an annular receiving chamber 10b, which contains the catalytic reactants. The vibration module 32 is arranged in a cylindrical shape and is located in the middle of the reaction chamber 31. It vibrates the catalytic reactants so that the catalytic reactants can make full use of the peripheral space of the vibration module 32, thereby ensuring that the catalytic reactants are all subjected to the vibration energy of the vibration module 32.

[0048] Please refer to the attached document. Figures 1-4In this embodiment, the first filter plate 20 is provided with a plurality of first filter holes 20a, which are arranged in an array along a ring or square direction. The plurality of first filter holes 20a are connected to the sewage inlet 10a and the reaction chamber 31 in the vertical direction, and perform primary filtration on the sewage input through the sewage inlet 10a. This allows the sewage input through the sewage inlet 10a to flow into the reaction chamber 31 after being filtered through the plurality of first filter holes 20a. The catalytic reactants in the reaction chamber 31 react with the sewage and perform intermediate filtration on the sewage to output the corresponding fluid. This ensures that the harmful substances in the sewage can be converted into harmless substances through chemical reaction and biodegradation processes. The second filter plate 40 is located below the reaction chamber 31 and performs final filtration on the fluid output through the reaction chamber 31, and blocks the dirt formed by the catalytic reactants, thereby achieving multi-stage filtration and avoiding filtration by only the first filter plate 20, thus improving the filtration effect of the sewage reaction device 100.

[0049] Please refer to the attached document. Figures 1-4 In this embodiment, the first filter plate 20 is connected to a first converging member 21, which is disposed on the lower side of the first filter plate 20 and is distributed in a conical shape. The inner wall of the first converging member 21 is arranged at an incline and along the annular direction. The inner wall of the first converging member 21 converges towards the center. The inner wall of the first converging member 21 will converge the sewage output from the first filter plate 20 towards the center, so that the sewage after primary filtration can flow to the reaction chamber 31 after being converged by the first converging member 21, thus ensuring the concentrated flow of sewage.

[0050] Please refer to the attached document. Figures 1-4 In this embodiment, a bottom support frame 311 is formed in the reaction chamber 31. The bottom support frame 311 supports the catalytic reactants in the reaction chamber 31 and is arranged in a figure-eight shape. The vibration module 32 is located above the bottom support frame 311 to ensure the storage of the catalytic reactants in the reaction chamber 31. The bottom support frame 311 is provided with a water passage hole 311a. The water passage hole 311a is connected to the fluid outlet 10c through the second filter plate 40 so that the fluid after the reaction in the reaction chamber 31 flows through the water passage hole 311a and the second filter plate 40 to the fluid outlet 10c.

[0051] Please refer to the attached document. Figures 1-4 In this embodiment, the fluid outlet 10c and the sewage inlet are located at different positions on the housing 10, with the sewage inlet located at the top of the housing 10 and the fluid outlet 10c located at the bottom of the housing 10. The orientation of the fluid outlet 10c and the sewage inlet are in different directions, thus avoiding interference between the connecting pipe of the fluid outlet 10c and the connecting pipe of the sewage inlet.

[0052] Please refer to the attached document. Figures 1-4In this embodiment, the second filter plate 40 is provided with a plurality of second filter holes 40a, which are arranged in an array along a ring or square direction. The plurality of second filter holes 40a are connected to the reaction chamber 31 and the fluid outlet 10c in the vertical direction, and perform final filtration on the fluid output from the reaction chamber 31, so that the fluid in the reaction chamber 31 can flow to the fluid outlet 10c through the plurality of second filter holes 40a. The filtration efficiency of the fluid is further increased by arranging the plurality of second filter holes 40a.

[0053] Please refer to the attached document. Figures 1-4 In this embodiment, the second filter plate 40 is provided with a cross support frame 41 to enhance the longitudinal rigidity of the second filter plate 40 and improve its load-bearing capacity; the housing 10 includes an upper housing 11 and a lower housing 12, the upper housing 11 is disposed on the upper side of the lower housing 12 and is sealed to the lower housing 12; this ensures the sealing effect between the upper housing 11 and the lower housing 12 and prevents sewage from leaking through the connection between the upper housing 11 and the lower housing 12. Optionally, the upper housing 11 and the lower housing 12 are sealed by a sealing ring.

[0054] The upper shell 11 integrates a first filter plate 20, a reaction chamber 31, and a vibration module 32; the lower shell 12 integrates a second filter plate 40; the lower shell 12 is detachably connected to the upper shell 11 so that the lower shell 12 can be connected to or detached from the upper shell 11, ensuring the disassembly effect of the lower shell 12. A connector 121 is connected to the outer side of the lower shell 12. The connector 121 is located on the outer side of the lower shell 12 and can be oscillatingly connected to the lower shell 12 to lock it to the upper shell 11, ensuring the connection strength between the lower shell 12 and the upper shell 11 and preventing the lower shell 12 from detaching from the upper shell 11.

[0055] Please refer to the attached document. Figures 1-4 In this embodiment of the application, when the first filter plate 20 or the reaction chamber 31 is blocked, fluid is introduced into the fluid outlet 10c. The fluid flows along the second filter plate 40 toward the first filter plate 20 and impacts the catalytic reactants in the reaction chamber 31 and the first filter plate 20 to adjust the blockage state of the reaction chamber 31 and the state of the first filter plate 20, so as to facilitate the reverse flushing of the reaction chamber 31 and the first filter plate 20 and ensure the unobstructed effect of the reaction chamber 31 and the first filter plate 20.

[0056] Compared with the prior art, the beneficial effects of this utility model are:

[0057] This utility model provides a wastewater reaction device 100. The housing 10 has a wastewater inlet 10a, a receiving cavity 10b, and a fluid outlet 10c. The wastewater inlet 10a is used to connect to an external wastewater input pipe. The receiving cavity 10b extends along the length of the housing 10 and serves as the internal space of the housing 10. The receiving cavity 10b is connected to the wastewater inlet 10a. A first filter plate 20 is located in the receiving cavity 10b and installed inside the housing 10. The first filter plate 20 is used to filter the wastewater input through the wastewater inlet 10a. The reaction assembly 30 includes a reaction chamber 31 and a vibration module 32. The reaction chamber 31 is located below the first filter plate 20 and contains corresponding catalytic reactants. The vibration module 32 is located in the middle of the reaction chamber 31 and vibrates the fluid. Each catalytic reactant vibrates to adjust the gap between adjacent catalytic reactants. Wastewater filtered by the first filter plate 20 passes through the reaction chamber 31 and undergoes a catalytic reaction with the catalytic reactants to output fluid. The second filter plate 40 is located below the reaction assembly 30 and installed inside the housing 10. The second filter plate 40 filters the fluid output from the reaction chamber 31 and is connected to the fluid outlet 10c, which discharges the fluid discharged through the second filter plate 40. This facilitates primary filtration by the first filter plate 20, wastewater reaction with the catalytic reactants, and final filtration by the second filter plate 40, achieving multi-stage filtration and avoiding filtration solely through the first filter plate 20, thus improving the filtration efficiency of the wastewater reaction device 100. Simultaneously, the vibration module 32 ensures sufficient reaction of the catalytic reactants with the wastewater.

[0058] The above description is only a preferred embodiment of the present utility model and does not limit the patent scope of the present utility model. All equivalent structural transformations made under the inventive concept of the present utility model using the contents of the present utility model specification and drawings, or direct / indirect applications in other related technical fields, are included within the patent protection scope of the present utility model.

Claims

1. A wastewater reaction device, characterized in that, include: The housing includes a sewage inlet, a receiving cavity, and a fluid outlet. The sewage inlet is used to connect to an external sewage input pipe. The receiving cavity extends along the length of the housing and serves as the internal space of the housing. The receiving cavity is connected to the sewage inlet. A first filter plate is located in the receiving cavity and installed inside the housing; the first filter plate is used to filter sewage input through the sewage inlet; The reaction assembly includes a reaction chamber and a vibration module. The reaction chamber is located below the first filter plate and contains corresponding catalytic reactants. The vibration module is located in the middle of the reaction chamber and vibrates each catalytic reactant to adjust the gap between two adjacent catalytic reactants. Wastewater filtered by the first filter plate passes through the reaction chamber and undergoes a catalytic reaction with the catalytic reactants to output fluid. The second filter plate is disposed on the lower side of the reaction assembly and installed inside the housing; the second filter plate is used to filter the fluid output from the reaction chamber and is connected to the fluid outlet, which is used to discharge the fluid discharged through the second filter plate.

2. The wastewater reaction apparatus according to claim 1, characterized in that, The vibration module extends along the length of the shell and vibrates at a preset frequency band. The catalytic reactant fills the outer periphery of the vibration module.

3. The wastewater reaction apparatus according to claim 2, characterized in that, The reaction chamber is an annular cavity containing multiple catalytic reactants. The vibration module is arranged in a cylindrical shape and located in the middle of the reaction chamber.

4. The wastewater reaction apparatus according to claim 1, characterized in that, The first filter plate is provided with a plurality of first filter holes, which are arranged in an array along a ring or square direction; the plurality of first filter holes are connected to the sewage inlet and the reaction chamber in the vertical direction, and perform primary filtration on the sewage input through the sewage inlet; The catalytic reactants in the reaction chamber react with the wastewater and perform intermediate filtration to output the corresponding fluid. The second filter plate is located below the reaction chamber and performs final filtration on the fluid output from the reaction chamber.

5. The wastewater reaction apparatus according to claim 4, characterized in that, The first filter plate is connected to a first converging component, which is disposed on the lower side of the first filter plate and is distributed in a conical shape; The inner wall of the first converging element is arranged at an angle and along a ring direction. The inner wall of the first converging element converges towards the center, and the wastewater output from the first filter plate converges towards the center through the inner wall of the first converging element.

6. The wastewater reaction apparatus according to claim 4, characterized in that, A bottom support frame is formed in the reaction chamber, which supports the catalytic reactants inside the reaction chamber. The vibration module is located above the bottom support frame, which has a water passage hole that connects to the fluid outlet via the second filter plate.

7. The wastewater reaction apparatus according to claim 1, characterized in that, The sewage inlet is located at the top of the housing; the fluid outlet is located at the bottom of the housing, and the fluid outlet and the sewage inlet are oriented in different directions.

8. The wastewater reaction apparatus according to claim 1, characterized in that, The second filter plate is provided with a plurality of second filter holes, which are arranged in an array along a ring or square direction; the plurality of second filter holes are connected to the reaction chamber and the fluid outlet along the vertical direction, and perform final filtration on the fluid output from the reaction chamber.

9. The wastewater reaction apparatus according to claim 8, characterized in that, The second filter plate is equipped with a cross-shaped support frame; The housing includes an upper shell and a lower shell, the upper shell being disposed on the upper side of the lower shell and sealingly connected to the lower shell; The upper shell integrates the first filter plate, the reaction chamber, and the vibration module; the lower shell integrates the second filter plate. The lower shell is detachably connected to the upper shell. A connector is connected to the outer side wall of the lower shell. The connector is located on the outer side of the lower shell and is swayably connected to the lower shell to lock it to the upper shell.

10. The wastewater reaction apparatus according to claim 1, characterized in that, When the first filter plate or the reaction chamber is blocked, fluid is introduced into the fluid outlet. The fluid flows along the second filter plate toward the first filter plate and impacts the catalytic reactants in the reaction chamber and the first filter plate to adjust the blockage state of the reaction chamber and the state of the first filter plate.