CN215630570U - Inverted siphon system - Google Patents

Abstract

The utility model relates to a reverse siphon system which comprises an upstream reverse siphon well, a water pump assembly, a downstream reverse siphon well and a reverse siphon pipe, wherein the upstream reverse siphon well and the downstream reverse siphon well are respectively arranged at two sides of a riverway or other obstacles to be spanned, one end of the reverse siphon pipe penetrates through the upstream reverse siphon well, and the other end of the reverse siphon pipe penetrates through the riverway or other obstacles and penetrates through the downstream reverse siphon well, so that the upstream reverse siphon well is communicated with the downstream reverse siphon well through the reverse siphon pipe. The water pump adapter of the water pump assembly is arranged on an upstream equipment layer on the upstream inverted siphon well, one end of the flushing pipe is connected to the water pump adapter, and the other end of the flushing pipe penetrates through the upstream inverted siphon well and is communicated with the inverted siphon pipe. When the inverted siphon is blocked, the water source can be connected outside through the water pump adapter, and the inverted siphon is flushed through the flushing pipe. Because the water pump adapter sets up on upstream equipment layer, convenient operation reduces the degree of difficulty of mediation siphon of falling, and is better to the flushing effect of siphon of falling, and the desilting is effectual, improves the stability of mediation siphon of falling.

Description

Inverted siphon system

Technical Field

The utility model relates to the technical field of drainage engineering, in particular to an inverted siphon system.

Background

The rapid development of social economy and the increasing improvement of the living standard of people continuously accelerate the progress of urbanization, so that the requirements of residents on the living environment are higher and higher, and the improvement of infrastructure facilities such as drainage pipe networks and the like is particularly important. When the drainage canal meets obstacles such as rivers, mountain stream, hollow lands or underground structures, the drainage canal cannot be buried according to the original gradient, and the obstacle crossing of the drainage canal is generally realized by adopting an inverted siphon system. The traditional inverted siphon system is easy to block after being used, and the overflowing capacity of the inverted siphon system is greatly reduced. Furthermore, when the inverted siphon is blocked, the inverted siphon needs to be desilted. However, the traditional dredging mode is realized by improving the water pressure of water in the inverted siphon, so that the difficulty in dredging the inverted siphon is high, and the dredging effect is poor.

SUMMERY OF THE UTILITY MODEL

In view of the above, it is desirable to provide an inverted siphon system that reduces the difficulty of dredging the inverted siphon and improves the dredging effect.

An inverted siphon system comprising an upstream inverted siphon well, a water pump assembly, a downstream inverted siphon well and an inverted siphon, the upstream inverted siphon well having an upstream device layer formed thereon; the water pump assembly comprises a water pump connector and a flushing pipe, the water pump connector is arranged on the upstream equipment layer, one end of the flushing pipe is connected with the water pump connector, and the other end of the flushing pipe penetrates through the upstream inverted siphon; the downstream inverted siphon well and the upstream inverted siphon well are arranged at intervals; one end of the inverted siphon is arranged in the upstream inverted siphon well in a penetrating mode, the other end of the inverted siphon is arranged in the downstream inverted siphon well in a penetrating mode, so that the upstream inverted siphon well is communicated with the downstream inverted siphon well through the inverted siphon, and the other end of the flushing pipe is communicated with the inverted siphon in the upstream inverted siphon.

In one embodiment, a partition wall is arranged in the upstream inverted siphon and divides the upstream inverted siphon into a first well chamber and a second well chamber, one end of the inverted siphon penetrates through the second well chamber and is arranged in the first well chamber, so that the first well chamber is communicated with the downstream inverted siphon through the inverted siphon, and the flushing pipe penetrates through the second well chamber and is connected to the inverted siphon positioned in the second well chamber.

In one embodiment, the inverted siphon of the second well chamber is spaced from the bottom wall of the second well chamber such that the spacing forms a sump for the second well chamber.

In one embodiment, the number of the inverted siphon pipes is at least two, each inverted siphon pipe is arranged side by side, one end of each inverted siphon pipe penetrates through the upstream inverted siphon well, and the other end of each inverted siphon pipe penetrates through the downstream inverted siphon well; the flushing pipes comprise connecting pipes and flushing branch pipes, the number of the flushing branch pipes is the same as that of the inverted siphon pipes, one end of each flushing branch pipe can be communicated with one inverted siphon pipe, the other end of each flushing branch pipe is connected to the connecting pipe, and the connecting pipe is connected to the water pump adapter.

In one embodiment, the water pump assembly further comprises switch valves, the number of the switch valves is consistent with that of the flushing branch pipes, each switch valve is correspondingly arranged on one flushing branch pipe, and the switch valves are used for controlling the on-off of the corresponding flushing branch pipes.

In one embodiment, the connecting tube is located at the upstream equipment layer; one end of the flushing branch pipe, which is far away from the inverted siphon pipe, is arranged on the upstream equipment layer, and the switch valve is arranged on the part of the flushing branch pipe on the upstream equipment layer, so that the switch valve is positioned on the upstream equipment layer.

In one embodiment, the inverted siphon located at the downstream inverted siphon well and the bottom wall of the downstream inverted siphon well are provided with a spacing, so that the spacing forms a sludge accumulation groove.

In one embodiment, the size of the cross section of the silt collecting groove tends to increase towards the inverted siphon.

In one embodiment, the inner side wall of the silt accumulating groove is obliquely arranged relative to the vertical direction, and the inclination angle of the inner side wall of the silt accumulating groove to the vertical direction is less than or equal to 30 degrees.

In one embodiment, the inverted siphon system further comprises an upstream control gate, the upstream control gate is openably arranged at the communication position of the inverted siphon and the upstream inverted siphon, and the upstream control gate is used for controlling the on-off of the inverted siphon and the upstream inverted siphon; and/or

The downstream control gate is openably arranged at the communication position of the inverted siphon and the downstream inverted siphon well and is used for controlling the on-off of the inverted siphon and the downstream inverted siphon well; and/or

Still include the inlet tube, the inlet tube with the upper reaches falls the siphon well intercommunication, and the pipe diameter of inlet tube is greater than fall the pipe diameter of siphon.

The upstream inverted siphon well and the downstream inverted siphon well are respectively arranged at two sides of a riverway or other obstacles to be crossed, one end of the inverted siphon pipe penetrates through the upstream inverted siphon well, and the other end of the inverted siphon pipe penetrates through the riverway or other obstacles and penetrates through the downstream inverted siphon well, so that the upstream inverted siphon well is communicated with the downstream inverted siphon well through the inverted siphon pipe. The water pump adapter of the water pump assembly is arranged on an upstream equipment layer on the upstream inverted siphon well, one end of the flushing pipe is connected to the water pump adapter, and the other end of the flushing pipe penetrates through the upstream inverted siphon well and is communicated with the inverted siphon pipe. When the inverted siphon is blocked, the water pump adapter can be externally connected with a water source, and the inverted siphon is flushed through the flushing pipe, so that the inverted siphon is cleared and flushed. The water pump adapter is arranged on the upstream equipment layer, so that the operation process is convenient, and the difficulty of dredging the inverted siphon is reduced; the process of washing utilizes outside water source to realize, and is better to the washing effect of falling the siphon, and the desilting is effectual, improves the stability of mediation falling the siphon.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the utility model and, together with the description, serve to explain the utility model and not to limit the utility model.

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Furthermore, the drawings are not to scale of 1:1, and the relative dimensions of the various elements in the drawings are drawn only by way of example and not necessarily to true scale. In the drawings:

FIG. 1 is a schematic diagram of an embodiment of an inverted siphon system;

fig. 2 is a top view of the inverted siphon system shown in fig. 1.

Description of reference numerals:

10. the inverted siphon system comprises 100, an upstream inverted siphon well, 110, an upstream equipment layer, 120, a separation wall, 130, a first well chamber, 140, a second well chamber, 150, a water collecting tank, 160, an upstream control gate, 162, a first door body, 164, a first linkage, 166, a first adjusting piece, 170, an upstream communication hole, 200, a downstream inverted siphon well, 210, a downstream control gate, 212, a second door body, 214, a second linkage, 216, a second adjusting piece, 220, a downstream equipment layer, 230, a downstream communication hole, 240, a silt collecting tank, 300, an inverted siphon pipe, 400, a water pump assembly, 410, a water pump adapter, 420, a flushing pipe, 422, a connecting pipe, 424, a flushing branch pipe, 430, a switch valve, 500, a water inlet pipe, 600 and a water outlet pipe.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

Referring to fig. 1 and 2, an embodiment of the present invention provides a barb system 10, which includes an upstream barb well 100, a downstream barb well 200, and a barb 300. The upstream inverted siphon well 100 and the downstream inverted siphon well 200 are arranged at intervals, one end of the inverted siphon 300 is arranged through the upstream inverted siphon well 100, and the other end of the inverted siphon 300 is arranged through the downstream inverted siphon well 200, so that the upstream inverted siphon well 100 is communicated with the downstream inverted siphon well 200 through the inverted siphon 300. The upstream inverted siphon well 100 and the downstream inverted siphon well 200 are respectively arranged at two sides of a river channel or other obstacles to be crossed, one end of the inverted siphon 300 penetrates through the upstream inverted siphon well 100, and the other end penetrates through the river channel or other obstacles and penetrates through the downstream inverted siphon well 200, so that the upstream inverted siphon well 100 is communicated with the downstream inverted siphon well 200 through the inverted siphon 300. The inverted siphon 300 passes through a river channel or an obstacle, so that the upstream inverted siphon well 100 is communicated with the downstream inverted siphon well 200, and the obstacle crossing effect is achieved.

Specifically, the inverted siphon system 10 further comprises a water pump assembly 400, and the upstream inverted siphon well 100 is formed with an upstream device layer 110 thereon; the water pump assembly 400 comprises a water pump coupler 410 and a flushing pipe 420, wherein the water pump coupler 410 is arranged on the upstream equipment layer 110, one end of the flushing pipe 420 is connected with the water pump coupler 410, and the other end of the flushing pipe 420 is arranged in the upstream inverted siphon well 100 in a penetrating mode; the other end of the flush tube 420 communicates with the inverted siphon 300 located in the upstream inverted siphon well 100.

In the above-described inverted siphon system 10, the water pump adapter 410 of the water pump unit 400 is installed on the upstream equipment floor 110 on the upstream inverted siphon well 100, and is connected to the water pump adapter 410 through one end of the flush pipe 420, and the other end is inserted into the upstream inverted siphon well 100 and communicates with the inverted siphon pipe 300. When the inverted siphon 300 is blocked, the water pump adapter 410 can be used for connecting an external water source, and the flushing pipe 420 can be used for flushing the inverted siphon 300, so that the inverted siphon 300 can be desilted and flushed. Because the water pump adapter 410 is arranged on the upstream equipment layer 110, the operation process is convenient, and the difficulty of dredging the inverted siphon 300 is reduced; the process of washing utilizes outside water source to realize, and is better to the washing effect of falling siphon 300, and the desilting is effectual, improves the stability of mediation falling siphon 300.

In one embodiment, a partition wall 120 is disposed in the upstream inverted siphon well 100, the partition wall 120 divides the upstream inverted siphon well 100 into a first well chamber 130 and a second well chamber 140, one end of the inverted siphon 300 passes through the second well chamber 140 and is disposed in the first well chamber 130, so that the first well chamber 130 communicates with the downstream inverted siphon well 200 through the inverted siphon 300, and the flushing pipe 420 is disposed in the second well chamber 140 and is connected to the inverted siphon 300 located in the second well chamber 140. The first well chamber 130 is provided to facilitate communication with the downstream inverted siphon 200 via the inverted siphon 300, and the second well chamber 140 is provided to facilitate communication of the flushing pipe 420 with the inverted siphon 300. Meanwhile, the flushing pipe 420 can be protected by the second well chamber 140, thereby ensuring the stability of the communication between the flushing pipe 420 and the inverted siphon 300.

In one embodiment, the inverted siphon system 10 further comprises an inlet pipe 500, wherein the inlet pipe 500 is in communication with the upstream inverted siphon well 100. During drainage, sewage enters the upstream inverted siphon well 100 through the inlet pipe 500 and flows to the downstream inverted siphon well 200 through the inverted siphon 300. Specifically, the water inlet pipe 500 communicates with the first well 130.

In this embodiment, the pipe diameter of the water inlet pipe 500 is larger than that of the inverted siphon 300. When sewage enters the inverted siphon 300 through the water inlet pipe 500, the pipe diameter of the inverted siphon 300 is reduced, so that the flow velocity of the sewage in the inverted siphon 300 can be increased, and the possibility of clogging of the inverted siphon 300 can be reduced. In this embodiment, the pipe diameter of the water inlet pipe 500 is 300mm, and the pipe diameter of the inverted siphon 300 is set to 200mm, so as to increase the flow rate of the sewage in the inverted siphon 300 and enhance the hydraulic conditions. In other embodiments, the diameters of the inverted siphon 300 and the water inlet pipe 500 can be other sizes.

In one embodiment, the inverted siphon 300 located at the upstream inverted siphon well 100 is spaced from the bottom wall of the upstream inverted siphon well 100. Silt impurity that the drainage in-process deposits etc. all can gather in falling the space between siphon 300 and the upper reaches fall the siphon well 100 diapire, avoid silt impurity shutoff to fall siphon 300, and also be convenient for follow-up clearance to silt impurity.

In this embodiment, the inverted siphon 300 located in the second well chamber 140 has a spacing from the bottom wall of the second well chamber 140 such that the spacing forms the sump 150 of the second well chamber 140. Specifically, the bottom wall of the second well 140 is formed into a sump 150 by pouring concrete. The collection of leaked water or water leaking from the upper part of the second well 140 is facilitated by the water collection tank 150, and the subsequent cleaning of the accumulated water is facilitated.

In one embodiment, there are at least two inverted siphon tubes 300, each inverted siphon tube 300 is disposed in parallel, and one end of each inverted siphon tube 300 is disposed through the upstream inverted siphon well 100, and the other end is disposed through the downstream inverted siphon well 200. When one inverted siphon 300 is cleared or one inverted siphon 300 is clogged, it is convenient to continue to perform the sewage discharge through the other inverted siphon 300. In the present embodiment, there are two inverted siphon tubes 300, and the two inverted siphon tubes 300 are arranged in parallel. In other embodiments, the number of the inverted siphon tubes 300 can be three, four, etc.

Specifically, the flushing pipe 420 includes a connecting pipe 422 and flushing branch pipes 424, the number of the flushing branch pipes 424 is the same as the number of the inverted siphon 300, one end of each flushing branch pipe 424 can be communicated with one inverted siphon 300, the other end of each flushing branch pipe 424 is connected to the connecting pipe 422, and the connecting pipe 422 is connected to the water pump connector 410. Different flushing branch pipes 424 are connected with different inverted siphon pipes 300, so that flushing of different inverted siphon pipes 300 can be conveniently realized.

In an embodiment, the water pump assembly 400 further includes switch valves 430, the number of the switch valves 430 is the same as the number of the flushing branch pipes 424, each switch valve 430 is correspondingly disposed on one flushing branch pipe 424, and the switch valves 430 are used for controlling on and off of the corresponding flushing branch pipe 424. When a back siphon 300 is clogged, the back siphon 300 can be flushed through the flushing branch 424 by controlling the opening and closing valve 430 on the flushing branch 424 communicated with the back siphon 300 to be opened.

In this embodiment, the connection pipe 422 is located in the upstream device layer 110; the end of the flushing sub-pipe 424 away from the inverted siphon 300 is inserted into the upstream device layer 110, and the on-off valve 430 is disposed on the part of the flushing sub-pipe 424 located in the upstream device layer 110, so that the on-off valve 430 is located in the upstream device layer 110. Because the on-off valves 430 are disposed on the upstream device layer 110, the on-off valves 430 can be operated conveniently, and the convenience of controlling the flushing of the inverted siphon 300 is improved.

In one embodiment, the inverted siphon system 10 further comprises an upstream control gate 160, the upstream control gate 160 is openably disposed at the communication between the inverted siphon 300 and the upstream inverted siphon 100, and the upstream control gate 160 is used for controlling the on/off of the inverted siphon 300 and the upstream inverted siphon 100. The upstream control gate 160 facilitates control of the communication between the inverted siphon 300 and the upstream inverted siphon well 100. In this embodiment, each inverted siphon 300 is provided with an upstream control gate 160 in communication with the upstream inverted siphon 100.

Specifically, the upstream control gate 160 includes a first door 162, a first link 164, and a first adjusting member 166, the first adjusting member 166 is connected to the first door 162 through the first link 164, and the first door 162 covers the end of the inverted siphon tube 300 inside the upstream inverted siphon well 100 in an openable manner. The first adjusting part 166 can drive the first door 162 to open and close relative to the inverted siphon 300 through the first linking part 164, so that the on-off of the first door 162 relative to the inverted siphon 300 and the upstream inverted siphon well 100 can be controlled.

Further, a first adjustment member 166 is disposed on the upstream equipment layer 110, and a first linkage member 164 is mounted on an inner wall of the first well 130. The first adjusting member 166 is operated by the upstream equipment layer 110, so that the first door 162 is controlled.

In one embodiment, the upstream device layer 110 is provided with an upstream communication hole 170 communicating with the upstream inverted siphon well 100, so that the upstream communication hole 170 is convenient for observing or maintaining devices in the upstream inverted siphon well 100 and cleaning sludge and impurities in the upstream inverted siphon well 100.

In this embodiment, the portion of the inverted siphon 300 extending into the upstream inverted siphon well 100 is secondarily poured with concrete, which facilitates to improve the stability of the inverted siphon 300 disposed in the upstream inverted siphon well 100. Specifically, the portion of the inverted siphon 300 extending into the first well 130 is secondarily poured with concrete.

In one embodiment, the inverted siphon system 10 further comprises a downstream control gate 210, the downstream control gate 210 is openably disposed at the communication between the inverted siphon 300 and the downstream inverted siphon 200, and the downstream control gate 210 is used for controlling the on/off of the inverted siphon 300 and the downstream inverted siphon 200. The control of the communication between the inverted siphon 300 and the downstream inverted siphon well 200 is facilitated by the downstream control gate 210. In the present embodiment, each inverted siphon 300 is connected to the downstream inverted siphon well 200 by a downstream control gate 210.

Specifically, the downstream control gate 210 includes a second door body 212, a second linkage member 214, and a second adjusting member 216, wherein the second adjusting member 216 is connected to the second door body 212 through the second linkage member 214, and the second door body 212 is openably covered on one end of the inverted siphon tube 300 located in the downstream inverted siphon well 200. Adjusting second adjusting element 216 can drive second door 212 to open and close relative to inverted siphon 300 through second linkage 214, and control on/off of second door 212 relative to inverted siphon 300 and downstream inverted siphon well 200 is realized.

In this embodiment, the downstream inverted siphon well 200 has a downstream device layer 220 formed thereon. The second adjustment member 216 is disposed on the downstream equipment floor 220 and the second linkage member 214 is mounted on the inner wall of the downstream inverted siphon well 200.

In one embodiment, the downstream device layer 220 is provided with a downstream communication hole 230 communicated with the downstream inverted siphon well 200, so that the device in the downstream inverted siphon well 200 can be observed or maintained through the downstream communication hole 230, and sludge and impurities in the downstream inverted siphon well 200 can be cleaned conveniently.

In this embodiment, the portion of the inverted siphon 300 extending into the downstream inverted siphon well 200 is secondarily poured with concrete, which facilitates to improve the stability of the inverted siphon 300 disposed in the downstream inverted siphon well 200.

In one embodiment, the inverted siphon system 10 further comprises a drain 600, the drain 600 is in communication with the downstream inverted siphon well 200, and water discharged through the inverted siphon 300 enters the downstream inverted siphon well 200 and can be discharged through the drain 600.

In one embodiment, the inverted siphon 300 located in the downstream inverted siphon well 200 has a spacing from the bottom wall of the downstream inverted siphon well 200 such that the spacing forms a sludge accumulation groove 240. Sludge residue and the like flushed from the upstream inverted siphon well 100 through the inverted siphon 300 can enter the upstream inverted siphon well 100, can be accumulated in the sludge accumulation groove 240, and further facilitates subsequent cleaning.

Specifically, the size of the cross section of the accumulating groove 240 tends to increase toward the inverted siphon 300. Further, the size of the accumulating groove 240 gradually increases toward the inverted siphon 300. In this embodiment, the inner sidewall of the silt collecting groove 240 is a smooth sloping plate. Specifically, the inner side wall of the silt accumulating groove 240 is inclined with respect to the vertical direction, and the inclination angle of the inner side wall of the silt accumulating groove 240 with respect to the vertical direction is less than or equal to 30 °. Further facilitating the sludge and residue to fall into the sludge accumulating groove 240 from the outlet of the inverted siphon 300, facilitating the subsequent suction of the sludge and residue by devices such as a sludge suction machine, and achieving the purpose of dredging the inverted siphon 300.

The inverted siphon system 10 in any of the above embodiments can be applied to a small town drainage pipe network, which not only can greatly improve the drainage efficiency of the small town drainage pipe network, but also provides convenience for the operation and maintenance of the drainage pipe network.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the utility model and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the utility model.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Claims (10)

1. An inverted siphon system, comprising:

an upstream inverted siphon well having an upstream device layer formed thereon;

the water pump assembly comprises a water pump connector and a flushing pipe, the water pump connector is arranged on the upstream equipment layer, one end of the flushing pipe is connected with the water pump connector, and the other end of the flushing pipe penetrates through the upstream inverted siphon;

the downstream inverted siphon well is arranged at a distance from the upstream inverted siphon well; and

and one end of the inverted siphon is arranged in the upstream inverted siphon well in a penetrating mode, the other end of the inverted siphon is arranged in the downstream inverted siphon well in a penetrating mode, so that the upstream inverted siphon well is communicated with the downstream inverted siphon well through the inverted siphon, and the other end of the flushing pipe is communicated with the inverted siphon in the upstream inverted siphon well.

2. The inverted siphon system according to claim 1, wherein a partition wall is arranged in the upstream inverted siphon well and divides the upstream inverted siphon well into a first well chamber and a second well chamber, one end of the inverted siphon tube penetrates through the second well chamber and is arranged in the first well chamber so that the first well chamber is communicated with the downstream inverted siphon well through the inverted siphon tube, and the flushing tube penetrates through the second well chamber and is connected to the inverted siphon tube in the second well chamber.

3. The inverted siphon system of claim 2, wherein there is a spacing between the inverted siphon tube located in the second well chamber and the bottom wall of the second well chamber such that the spacing forms a water collection trough for the second well chamber.

4. The inverted siphon system according to any one of claims 1 to 3, wherein the number of inverted siphon is at least two, each of the inverted siphon is juxtaposed, and one end of each of the inverted siphon is inserted into the upstream inverted siphon well, and the other end of each of the inverted siphon is inserted into the downstream inverted siphon well; the flushing pipes comprise connecting pipes and flushing branch pipes, the number of the flushing branch pipes is the same as that of the inverted siphon pipes, one end of each flushing branch pipe can be communicated with one inverted siphon pipe, the other end of each flushing branch pipe is connected to the connecting pipe, and the connecting pipe is connected to the water pump adapter.

5. The system of claim 4, wherein the pump assembly further comprises a plurality of switch valves, the number of switch valves corresponds to the number of the flushing branch pipes, each switch valve is correspondingly arranged on one of the flushing branch pipes, and the switch valves are used for controlling the on-off of the corresponding flushing branch pipe.

6. The inverted siphon system of claim 5, wherein the connecting tube is located at the upstream device layer; one end of the flushing branch pipe, which is far away from the inverted siphon pipe, is arranged on the upstream equipment layer, and the switch valve is arranged on the part of the flushing branch pipe on the upstream equipment layer, so that the switch valve is positioned on the upstream equipment layer.

7. The inverted siphon system according to any one of claims 1 to 3, wherein the inverted siphon located at the downstream inverted siphon well has a spacing from the bottom wall of the downstream inverted siphon well such that the spacing forms a sludge accumulation groove.

8. The inverted siphon system of claim 7, wherein the size of the cross section of the silt accumulating groove tends to increase towards the inverted siphon.

9. The inverted siphon system of claim 8, wherein the inner side wall of the silt collection tank is inclined with respect to the vertical direction, and the inclination angle of the inner side wall of the silt collection tank with respect to the vertical direction is less than or equal to 30 °.

10. The inverted rainbow system of any one of claims 1-3,

the upstream control gate is openably and closably arranged at the communication position of the inverted siphon and the upstream inverted siphon well and is used for controlling the on-off of the inverted siphon and the upstream inverted siphon well; and/or

The downstream control gate is openably arranged at the communication position of the inverted siphon and the downstream inverted siphon well and is used for controlling the on-off of the inverted siphon and the downstream inverted siphon well; and/or

Still include the inlet tube, the inlet tube with the upper reaches falls the siphon well intercommunication, and the pipe diameter of inlet tube is greater than fall the pipe diameter of siphon.

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