High impact water saving toilet

CN224412722UActive Publication Date: 2026-06-26GUANGDONG OULU SANITARY WARE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUANGDONG OULU SANITARY WARE CO LTD
Filing Date
2025-08-04
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing toilets have low flushing power and are not water-saving because the water tanks fill slowly and the wastewater from the sink cannot be reused.

Method used

A high-flush water-saving toilet was designed, which uses an electrode-type water level sensor to control an electric booster pump and an electric booster pump. The combination of the two booster pumps filters the wastewater from the washbasin and stores it in a wastewater tank through an electronically controlled valve and a reuse pipeline. When the water level reaches the set position, the electronically controlled valve is opened or closed to achieve wastewater reuse. At the same time, the electric booster pump is used to quickly add water to ensure that the water tank can quickly meet the flushing needs.

Benefits of technology

It achieves water conservation and increased flushing power, avoiding the problem of insufficient flushing power when the water tank is not full, and achieving the effect of high flushing power and water saving.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The utility model provides a kind of high-impact water-saving closestool, it is related to bathroom product technical field, and it includes: bucket body, the top of bucket body is equipped with siphon inner basin, the bottom of siphon inner basin inner chamber is equipped with sewage pipeline, the two sides of one end of bucket body top are equipped with closestool cover closestool seat component mounting hole, and closestool cover closestool seat component mounting hole is equipped with closestool cover closestool seat component inside two.The utility model discloses when electrode type water level sensor circuit is connected, control electric control valve one opens electric control valve two, washbasin wastewater is discharged to the pipeline of drainage system by wastewater drain pipe two, when circuit is disconnected, control electric control valve one closes electric control valve two, washbasin wastewater is discharged by recycling pipeline, and washbasin wastewater is utilized, to save water resource's purpose, electric booster pump one and electric booster pump two can make water tank more quickly continue to fill, make water tank more quickly continue to fill, reduce the condition that water tank is not filled possibly caused by continuous flushing force lower.
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Description

Technical Field

[0001] This utility model relates to the field of bathroom product technology, and in particular to a high-flush water-saving toilet. Background Technology

[0002] Bathroom fixtures refer to hygiene and bathing. The bathroom, commonly known as a toilet, is a space and place for residents to perform daily hygiene activities such as urination, defecation, bathing, and washing. A toilet, commonly known as a commode, is a common bathroom product. Toilets on the market are classified into four types according to their sewage discharge method: flushing type, siphon flushing type, siphon jet type, and siphon vortex type. The glaze of a toilet should be smooth, flat, without ripples, crystal clear, and free of pinholes or impurities.

[0003] However, in the current technology, it has been found that some toilets can only be supplied with water from the water supply pipes inside the wall. Wastewater from the sink cannot be reused to supply the toilet, which means that the toilet cannot save water resources. At the same time, because the water tank fills up slowly, the water tank is not full when flushing continuously, resulting in low flushing power.

[0004] To address this issue, a high-flush, water-saving toilet was proposed. Utility Model Content

[0005] The purpose of this invention is to solve the problems existing in the prior art.

[0006] To achieve the above objectives, this utility model adopts the following technical solution: a high-flush water-saving toilet, comprising: a toilet body, a siphon inner basin at the top of the toilet body, a drain pipe extending through the bottom of the inner cavity of the siphon inner basin, toilet seat and toilet lid assembly mounting holes on both sides of one end of the top of the toilet body, a toilet seat and toilet lid assembly mounted on the top of the toilet body through the two mounting holes, a water tank fixedly connected to one side of the toilet body, a water storage tank at the top of the water tank, a water distribution trough in the middle of the water tank, and a water distribution trough in the lower middle part of the water tank. The system includes a wastewater tank, a water tank cover that is movably fitted into the top of the inner cavity of the water tank, a flushing switch that is fitted into the inner cavity of the water tank cover, a water inlet channel that extends through one end of the bottom of the inner cavity of the water tank, a water inlet valve that is fitted into the top of the inner cavity of the water inlet channel, a drain channel one that is located in the middle of the bottom of the inner cavity of the water tank, a drain valve that is fitted into the top of the inner cavity of the drain channel one, the top of the drain valve that is fitted into the bottom of the flushing switch, a control terminal that is fixedly connected to one side of the water tank, a filter assembly that is installed inside the wastewater tank, and a water-saving assembly that is installed on one side of the water tank.

[0007] Furthermore, a second drainage trough is formed on one side of the bottom of the inner cavity of the first drainage trough, and a flushing trough is formed at the bottom of the inner cavity of the second drainage trough. The flushing trough is connected to the inner cavity of the sewage pipe. A surrounding drainage trough is formed around the other end of the inner cavity of the second drainage trough. Multiple flushing holes are formed around the bottom of the inner cavity of the surrounding drainage trough. Multiple water distribution holes are formed through the bottom of the inner cavity of the water distribution trough. A cleaning trough is formed through the top of one side of the inner cavity of the water distribution trough. A filter basket trough is formed through the top of one side of the inner cavity of the wastewater trough. Support plates are fixedly connected to both sides of the inner cavity of the wastewater trough. The tops of the two support plates are flush with the bottom of the inner cavity of the filter basket trough. A check valve overflow pipe is fixedly connected to one side of the bottom of the water storage tank. The check valve overflow pipe is connected to the interior of the second drainage trough.

[0008] Furthermore, the filter assembly includes a filter basket, one end of which is fixedly connected to a handle, an overflow groove is provided through the top of one side of the filter basket's inner cavity, and a filter screen is fixedly embedded in the bottom of the filter basket's inner cavity.

[0009] Furthermore, the water-saving component includes a wastewater drain pipe 1, a tee 2, and a mounting plate. The bottom end of the wastewater drain pipe 1 is connected to a tee 1, the bottom end of the tee 1 is connected to an electrically controlled valve 1, the bottom end of the electrically controlled valve 1 is connected to a wastewater drain pipe 2, one end of the tee 1 is connected to an electrically controlled valve 2, the other end of the electrically controlled valve 2 is connected to a reuse pipe, one side of the wastewater drain pipe 2 is connected to a check valve overflow pipe, the other end of the reuse pipe is fixedly embedded inside the water distribution tank, and the other end of the check valve overflow pipe is fixedly embedded inside the wastewater tank.

[0010] Furthermore, one end of the three-way valve 2 is connected to an electric booster pump 1 via a pipe, the output end of the electric booster pump 1 is connected to a four-way valve via a check valve pipe, the bottom end of the three-way valve 2 is connected to a check valve pipe, a manual valve is embedded in the inner cavity of the check valve pipe, the other end of the check valve pipe is connected to one end of the four-way valve, the bottom end of the four-way valve is connected to an electric booster pump 2 via a check valve pipe, and an electrode-type water level sensor is fixedly connected to the bottom of the mounting plate.

[0011] Furthermore, the surface of one end of the filter basket is movably embedded inside the filter basket groove, and the two sides of the bottom of the filter basket are attached to the top of the two support plates.

[0012] Furthermore, one side of the electric booster pump is fixedly connected to one side of the water tank, one end of the four-way valve is connected to the other end of the water inlet tank cavity through a pipe, the bottom of the electric booster pump is fixedly connected to the bottom of the wastewater tank cavity, and one end of the mounting plate is fixedly connected to one side of the wastewater tank cavity and located below the support plate.

[0013] Compared with the prior art, the advantages and positive effects of this utility model are as follows:

[0014] In this invention, when the electrode-type water level sensor circuit is connected, the water level reaches the set position, and the control terminal controls the opening of the first electrically controlled valve and the closing of the second electrically controlled valve. The wastewater from the washbasin is discharged into the drainage system through the second wastewater drain pipe. When the electrode-type water level sensor circuit is disconnected, the water level does not reach the set position, and the control terminal controls the closing of the first electrically controlled valve and the opening of the second electrically controlled valve. The wastewater from the washbasin is discharged through the reuse pipe. This design allows the wastewater discharged from the washbasin to be utilized, achieving the goal of saving water resources. The first and second electric booster pumps can quickly add water, making the water tank full faster and reducing the possibility of low flushing power due to an insufficient water tank during continuous flushing. Attached Figure Description

[0015] Figure 1 A schematic diagram of the overall structure of a high-flush water-saving toilet provided by this utility model;

[0016] Figure 2 A partial separation diagram of a high-flush water-saving toilet provided by this utility model;

[0017] Figure 3 A side sectional view of a high-flush water-saving toilet provided by this utility model;

[0018] Figure 4 A rear sectional view of a high-flush water-saving toilet provided by this utility model;

[0019] Figure 5 This is a top sectional view of a high-flush water-saving toilet provided by this utility model.

[0020] Legend:

[0021] 1. Toilet body; 101. Siphon inner basin; 102. Drain pipe; 103. Toilet seat / seat assembly mounting holes; 104. Toilet seat / seat assembly; 105. Water tank; 106. Water storage tank; 107. Water distribution tank; 108. Wastewater tank; 109. Water storage tank cover; 110. Flushing switch; 111. Water inlet tank; 112. Water inlet valve; 113. Drainage tank one; 114. Drain valve; 115. Drainage tank two; 116. Flushing tank; 117. Surrounding drainage tank; 118. Flushing hole; 119. Water distribution hole; 120. Filter basket; 121. Support plate; 122. Cleaning tank; 123. Control Terminal; 124. Check valve overflow pipe; 2. Filter assembly; 201. Filter basket; 202. Handle; 203. Overflow trough; 204. Filter screen; 3. Water-saving assembly; 301. Wastewater drain pipe one; 302. T-junction one; 303. Electrically controlled valve one; 304. Wastewater drain pipe two; 305. Electrically controlled valve two; 306. Reuse pipe; 307. Check valve overflow pipe; 308. T-junction two; 309. Electric booster pump one; 310. Four-way valve; 311. Check valve pipe; 312. Manual valve; 313. Electric booster pump two; 314. Mounting plate; 315. Electrode-type water level sensor. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0023] Please see Figure 1-5This utility model provides a technical solution: a high-flush water-saving toilet, comprising: a toilet body 1, a siphon inner basin 101 at the top of the toilet body 1, a drain pipe 102 penetrating through the bottom of the inner cavity of the siphon inner basin 101, toilet seat and toilet seat assembly mounting holes 103 on both sides of the top end of the toilet body 1, a toilet seat and toilet seat assembly 104 mounted on the top of the toilet body 1 through the two toilet seat and toilet seat assembly mounting holes 103, a water tank 105 fixedly connected to one side of the toilet body 1, a water storage tank 106 at the top of the water tank 105, a water distribution tank 107 in the middle of the water tank 105, and a wastewater tank 108 in the lower middle part of the water tank 105. A water storage tank cover 109 is movably embedded in the top of the inner cavity of the tank 106. A flushing switch 110 is embedded in the inner cavity of the water storage tank cover 109. A water inlet trough 111 is opened through one end of the bottom of the inner cavity of the water storage tank 106. A water inlet valve 112 is installed in the top of the inner cavity of the water inlet trough 111. A drain trough 113 is opened in the middle of the bottom of the inner cavity of the water storage tank 106. A drain valve 114 is installed in the top of the inner cavity of the drain trough 113. The top of the drain valve 114 is attached to the bottom of the flushing switch 110. A control terminal 123 is fixedly connected to one side of the water tank 105. A filter assembly 2 is installed inside the wastewater tank 108. A water-saving assembly 3 is installed on one side of the water tank 105.

[0024] Specifically: When the electrode-type water level sensor 315 circuit is connected, the water level reaches the set position, and the control terminal 123 controls the opening of the first electrically controlled valve 303 and the closing of the second electrically controlled valve 305. The wastewater from the washbasin is discharged into the drainage system through the second wastewater drain pipe 304. When the electrode-type water level sensor 315 circuit is disconnected, the water level has not reached the set position, and the control terminal 123 controls the closing of the first electrically controlled valve 303 and the opening of the second electrically controlled valve 305. The wastewater from the washbasin is discharged through the reuse pipe 306. This design allows for the reuse of wastewater from the washbasin, achieving the goal of water conservation. Booster pump 1 (309) and electric booster pump 2 (313) can quickly add water, allowing the water tank to fill faster and reducing the possibility of insufficient flushing force due to continuous flushing. The water storage capacity in wastewater tank 108 is slightly larger than that in water storage tank 106, and the water in the cavity of wastewater tank 108 can meet the filling needs of water storage tank 106 in a single flush. The flushing switch 110 has a commonly used existing structure, and its specific structure will not be described here. The inlet valve 112 is a commonly used inlet valve with a mechanical float and a mechanical contact switch, and its specific structure will not be described here. The drain valve 114 has a commonly used existing structure, and its specific structure will not be described here.

[0025] In one embodiment, a second drainage channel 115 is formed on one side of the bottom of the inner cavity of the first drainage channel 113, and a flushing channel 116 is formed at the bottom of the inner cavity of the second drainage channel 115. The flushing channel 116 communicates with the inner cavity of the sewage pipe 102. A surrounding drainage channel 117 is formed around the other end of the inner cavity of the second drainage channel 115, and a plurality of flushing holes 118 are formed around the bottom of the inner cavity of the surrounding drainage channel 117. A plurality of water distribution holes 11 are formed through the bottom of the inner cavity of the water distribution channel 107. 9. A cleaning groove 122 is provided through the top of one side of the inner cavity of the water distribution tank 107. A filter basket groove 120 is provided through the top of one side of the inner cavity of the wastewater tank 108. Support plates 121 are fixedly connected to both sides of the inner cavity of the wastewater tank 108. The top of the two support plates 121 is flush with the bottom of the inner cavity of the filter basket groove 120. A check valve overflow pipe 124 is fixedly connected to one side of the bottom of the water storage tank 106. The check valve overflow pipe 124 is connected to the interior of the drainage trough 115.

[0026] Specifically, such as Figure 3-5 As shown: the check valve overflow pipe 124 is a pipe equipped with a check valve to prevent water in the water storage tank 106 from flowing out of the check valve overflow pipe 124 due to excessive water pressure when the drain valve 114 is opened; the cleaning tank 122 provides cleaning space for cleaning the water distribution hole 119, and at the same time, the water flowing into the water distribution tank 107 from the reuse pipe 306 flows slowly and will not overflow from the cleaning tank 122; the water distribution hole 119 reduces the filtration pressure at a certain point of the filter screen 204 by diverting the water flowing in from the reuse pipe 306.

[0027] In one embodiment, the filter assembly 2 includes a filter basket 201, one end of which is fixedly connected to a handle 202, an overflow groove 203 is provided through the top of one side of the inner cavity of the filter basket 201, and a filter screen 204 is fixedly embedded in the bottom of the inner cavity of the filter basket 201.

[0028] Specifically, such as Figure 2 As shown: Overflow groove 203 can provide overflow space for water in the inner cavity of filter basket 201 when filter screen 204 is clogged.

[0029] In one embodiment, the water-saving component 3 includes a wastewater drain pipe 301, a tee 308, and a mounting plate 314. The bottom end of the wastewater drain pipe 301 is connected to a tee 302, the bottom end of the tee 302 is connected to an electrically controlled valve 303, the bottom end of the electrically controlled valve 303 is connected to a wastewater drain pipe 304, one end of the tee 302 is connected to an electrically controlled valve 305, the other end of the electrically controlled valve 305 is connected to a reuse pipe 306, one side of the wastewater drain pipe 304 is connected to a check valve overflow pipe 307, the other end of the reuse pipe 306 is fixedly embedded inside the water distribution tank 107, and the other end of the check valve overflow pipe 307 is fixedly embedded inside the wastewater tank 108.

[0030] Specifically, such as Figure 1 As shown: In the event of a power outage, when the first electrically controlled valve 303 is closed and the second electrically controlled valve 305 is open, the water overflowing from the inner cavity of the wastewater tank 108 flows into the second wastewater drain pipe 304 through the overflow pipe 307 of the check valve; under the action of the check valve, the overflow pipe 307 of the check valve only allows water to flow from the inner cavity of the wastewater tank 108 into the second wastewater drain pipe 304; only one of the first electrically controlled valve 303 and the second electrically controlled valve 305 is allowed to be open at the same time.

[0031] In one embodiment, one end of the three-way valve 2 308 is connected to an electric booster pump 1 309 via a pipe. The output end of the electric booster pump 1 309 is connected to a four-way valve 310 via a check valve pipe. The bottom end of the three-way valve 2 308 is connected to a check valve pipe 311. A manual valve 312 is installed inside the check valve pipe 311. The other end of the check valve pipe 311 is connected to one end of the four-way valve 310. The bottom end of the four-way valve 310 is connected to an electric booster pump 2 313 via a check valve pipe. An electrode-type water level sensor 315 is fixedly connected to the bottom of the mounting plate 314.

[0032] Specifically, such as Figure 4 As shown: Electric booster pump 309 and electric booster pump 313 are commonly used electric booster pumps with built-in pressure sensing function. After the inlet valve 112 is closed, electric booster pump 309 and electric booster pump 313 automatically stop due to increased resistance. The output end of electric booster pump 309 is connected to a four-way valve 310 through a check valve pipe. The check valve pipe only allows water to flow from electric booster pump 309 to four-way valve 310. The bottom end of three-way valve 308 is connected to check valve pipe 311, allowing water to flow from three-way valve 308 to four-way valve 310. A manual valve 312 is embedded in check valve pipe 311. The other end of the check valve pipe 311 is connected to the four-way valve 310 to prevent water in the wastewater tank 108 from flowing to the electric booster pump 309 and the check valve pipe 311 when the electric booster pump 2 313 is started. The bottom end of the four-way valve 310 is connected to the electric booster pump 2 313 through the check valve pipe. The check valve pipe only allows water to flow from the electric booster pump 2 313 into the four-way valve 310 to prevent water from flowing into the electric booster pump 2 313 and the check valve pipe 311 when the electric booster pump 1 309 is started. In the event of a power failure, when the manual valve 312 is opened, water is prevented from flowing into the electric booster pump 1 309 and the electric booster pump 2 313.

[0033] In one embodiment, the surface of one end of the filter basket 201 is movably embedded inside the filter basket groove 120, and the two sides of the bottom of the filter basket 201 are attached to the top of the two support plates 121.

[0034] Specifically, such as Figure 2 As shown: the filter assembly 2 can be pulled out from the inner cavity of the filter basket 120 by holding the handle 202 to clean the filter screen 204.

[0035] In one embodiment, one side of the electric booster pump 309 is fixedly connected to one side of the water tank 105, one end of the four-way valve 310 is connected to the other end of the inner cavity of the water inlet tank 111 through a pipe, the bottom of the electric booster pump 313 is fixedly connected to the bottom of the inner cavity of the wastewater tank 108, and one end of the mounting plate 314 is fixedly connected to one side of the inner cavity of the wastewater tank 108 and located below the support plate 121.

[0036] Specifically, such as Figure 4 As shown: Electric booster pump 309 is fixed to the side of water tank 105, and electric booster pump 313 is fixedly connected to the bottom of the inner cavity of wastewater tank 108 to prevent electric booster pump 309 and electric booster pump 313 from shaking during operation and affecting the normal operation of the toilet; one end of check valve overflow pipe 307 is fixedly embedded in one side of wastewater tank 108 inner cavity, and support plate 121, check valve overflow pipe 307 and electrode water level sensor 315 are arranged from top to bottom.

[0037] Working principle: Connect this toilet to an external power supply device to provide power to the toilet. Control terminal 123 is associated with and controls electric booster pump 1 309 and electric booster pump 2 313. Control terminal 123 can detect the on / off status of the electrode-type water level sensor 315 to determine whether the water level has reached the set position. Control terminal 123 can detect the on / off status of the mechanical contact switch of the inlet valve 112 to determine whether water needs to be added. Use the toilet flange to connect the toilet drain pipe 102 to the toilet drain pipe of the drainage system. Connect the top of wastewater drain pipe 1 301 to the sink drain pipe. Connect the bottom of wastewater drain pipe 2 304 to the drainage system pipe. Connect one end of tee 2 308 to the angle valve through a pipe. Connect the other end of the angle valve to the water supply pipe inside the wall through a pipe.

[0038] The control terminal 123 can detect the on / off status of the electrode-type water level sensor 315 circuit in real time to determine whether the water level has reached the set position. When the electrode-type water level sensor 315 circuit is on, the water level reaches the set position, and the control terminal 123 controls the opening of the first electric valve 303 and the closing of the second electric valve 305. The wastewater from the washbasin is discharged into the drainage system through the second wastewater drain pipe 304. When the electrode-type water level sensor 315 circuit is off, the water level has not reached the set position, and the control terminal 123 controls the closing of the first electric valve 303 and the opening of the second electric valve 305. The wastewater from the washbasin is discharged through the reuse pipe 306 and then filtered by the filter assembly 2 before being stored in the inner cavity of the wastewater tank 108.

[0039] When flushing is needed, press the flush switch 110. The flush switch 110 is turned on, and the water in the inner cavity of the water storage tank 106 passes through the first drain trough 113, the second drain trough 115, and the surrounding drain trough 117, and finally flushes the siphon inner basin 101 and the sewage pipe 102 from the flush hole 118 and the flush trough 116.

[0040] When the mechanical float of the inlet valve 112 drops, the mechanical contact switch closes. The control terminal 123 detects the closure of the mechanical contact switch and determines that water needs to be added. Then, the control terminal 123 detects the on / off status of the electrode-type water level sensor 315 circuit. When the electrode-type water level sensor 315 circuit is on, the water level reaches the set position, and the control terminal 123 controls the electric booster pump 313 to start, adding water from the inner cavity of the wastewater tank 108 to the water storage tank 106. When the electrode-type water level sensor 315 circuit is off, the water level has not reached the set position, and the control terminal 123 controls the electric booster pump 309 to start, adding water from the water supply pipe inside the wall to the water storage tank 106.

[0041] This toilet design utilizes wastewater from the sink, thus saving water resources. The electric booster pump 309 and electric booster pump 313 can quickly add water, filling the tank faster and reducing the possibility of insufficient flushing power due to continuous flushing.

[0042] The above description is merely a preferred embodiment of the present utility model and is not intended to limit the present utility model in any other way. Any person skilled in the art may make changes or modifications to the above-disclosed technical content to create equivalent embodiments for application in other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of the present utility model without departing from the technical solution of the present utility model shall still fall within the protection scope of the technical solution of the present utility model.

Claims

1. A high-flush water-saving toilet, characterized in that, include: The bucket body (1) has a siphon inner basin (101) at its top. A sewage pipe (102) is provided through the bottom of the inner cavity of the siphon inner basin (101). Toilet seat and toilet seat assembly mounting holes (103) are provided on both sides of the top end of the bucket body (1). Toilet seat and toilet seat assemblies (104) are installed on the top of the bucket body (1) through the two toilet seat and toilet seat assembly mounting holes (103). A water tank (105) is fixedly connected to one side of the bucket body (1). A water storage tank (106) is provided at the top of the water tank (105). A water distribution trough (107) is provided in the middle part of the water tank (105). A wastewater trough (108) is provided in the lower middle part of the water tank (105). A movably embedded part is provided at the top of the inner cavity of the water storage tank (106). A water storage tank cover (109) is provided, and a flushing switch (110) is embedded in the inner cavity of the water storage tank cover (109). A water inlet groove (111) is provided through one end of the bottom of the inner cavity of the water storage tank (106). A water inlet valve (112) is installed at the top of the inner cavity of the water inlet groove (111). A drain groove (113) is provided at the middle position of the bottom of the inner cavity of the water storage tank (106). A drain valve (114) is installed at the top of the inner cavity of the drain groove (113). The top of the drain valve (114) is in contact with the bottom of the flushing switch (110). A control terminal (123) is fixedly connected to one side of the water tank (105). A filter assembly (2) is provided inside the wastewater tank (108). A water-saving assembly (3) is provided on one side of the water tank (105).

2. A high-flush water-saving toilet according to claim 1, characterized in that: A second drainage trough (115) is provided on one side of the bottom of the inner cavity of the first drainage trough (113). A flushing trough (116) is provided at the bottom of the inner cavity of the second drainage trough (115). The flushing trough (116) is connected to the inner cavity of the sewage pipe (102). A surrounding drainage trough (117) is provided around the other end of the inner cavity of the second drainage trough (115). A plurality of flushing holes (118) are provided around the bottom of the inner cavity of the surrounding drainage trough (117). A plurality of water distribution holes (119) are provided through the bottom of the inner cavity of the water distribution trough (107). A cleaning groove (122) is provided through the top of one side of the inner cavity of the water distribution tank (107). A filter basket groove (120) is provided through the top of one side of the inner cavity of the wastewater tank (108). Support plates (121) are fixedly connected to both sides of the inner cavity of the wastewater tank (108). The top of the two support plates (121) is flush with the bottom of the inner cavity of the filter basket groove (120). A check valve overflow pipe (124) is fixedly connected to one side of the bottom of the water storage tank (106). The check valve overflow pipe (124) is connected to the interior of the drainage trough (115).

3. A high-flush water-saving toilet according to claim 1, characterized in that: The filter assembly (2) includes a filter basket (201), one end of which is fixedly connected to a handle (202). An overflow groove (203) is provided through the top of one side of the inner cavity of the filter basket (201), and a filter screen (204) is fixedly embedded in the bottom of the inner cavity of the filter basket (201).

4. A high-flush water-saving toilet according to claim 1, characterized in that: The water-saving component (3) includes a wastewater drain pipe (301), a tee (308), and a mounting plate (314). The bottom end of the wastewater drain pipe (301) is connected to a tee (302). The bottom end of the tee (302) is connected to an electrically controlled valve (303). The bottom end of the electrically controlled valve (303) is connected to a wastewater drain pipe (304). One end of the tee (302) is connected to an electrically controlled valve (305). The other end of the electrically controlled valve (305) is connected to a reuse pipe (306). One side of the wastewater drain pipe (304) is connected to a check valve overflow pipe (307). The other end of the reuse pipe (306) is fixedly embedded inside the water distribution tank (107). The other end of the check valve overflow pipe (307) is fixedly embedded inside the wastewater tank (108).

5. A high-flush water-saving toilet according to claim 4, characterized in that: One end of the three-way connector 2 (308) is connected to an electric booster pump 1 (309) via a pipe. The output end of the electric booster pump 1 (309) is connected to a four-way connector (310) via a check valve pipe. The bottom end of the three-way connector 2 (308) is connected to a check valve pipe (311). A manual valve (312) is installed inside the check valve pipe (311). The other end of the check valve pipe (311) is connected to one end of the four-way connector (310). The bottom end of the four-way connector (310) is connected to an electric booster pump 2 (313) via a check valve pipe. An electrode-type water level sensor (315) is fixedly connected to the bottom of the mounting plate (314).

6. A high-flush water-saving toilet according to claim 3, characterized in that: The surface of one end of the filter basket (201) is movably embedded inside the filter basket groove (120), and the two sides of the bottom of the filter basket (201) are attached to the top of the two support plates (121).

7. A high-flush water-saving toilet according to claim 5, characterized in that: One side of the electric booster pump (309) is fixedly connected to one side of the water tank (105), one end of the four-way valve (310) is connected to the other end of the inner cavity of the water inlet tank (111) through a pipe, the bottom of the electric booster pump (313) is fixedly connected to the bottom of the inner cavity of the wastewater tank (108), and one end of the mounting plate (314) is fixedly connected to one side of the inner cavity of the wastewater tank (108) and located below the support plate (121).