CN215530918U - Tower type circulating ecological system - Google Patents

Abstract

The utility model discloses a tower type circulating ecological system which comprises a support frame, a water collecting tank and a disinfection box, wherein the support frame is erected above the water collecting tank, and a plurality of ecological boxes are arranged on the support frame. A plurality of ecological boxes are arranged in a tower type mode, two rows of ecological side boxes are connected between an ecological top box and a water collecting tank in parallel, the ecological boxes can be connected in a circulating mode only by arranging a pump body in the system, and energy consumption in the system is reduced. The disinfect box in this system has two kinds of functions of ozone disinfection and ultraviolet ray disinfection simultaneously, can disinfect and the inactivation to the bacterium in the aquaculture water, has solved the medicine residue problem that produces because of disinfecting with the medicine, and the direct oxidation of ozone has the effect of degradation ammonia nitrogen simultaneously, carries out oxidative decomposition to harmful substance, becomes degradable material, and remaining ozone in the aquatic can be fast natural decomposition become oxygen, has increased the dissolved oxygen volume in the water.

Description

Tower type circulating ecological system

Technical Field

The utility model relates to the crossing field of cultivation and agriculture, in particular to a tower type circulating ecosystem.

Background

The fish and vegetable symbiotic cultivation is a compound cultivation system, effectively combines aquaculture and vegetable cultivation, does not need large-scale civil engineering, does not change land attributes, adopts a mode of recycling cultivation water, saves water resources to the maximum extent, realizes an ecological cultivation method for scientifically and nuisanceless fish and vegetable co-growth, and is very suitable for the operation and production of scattered households or agricultural micro-factories.

At present, the country vigorously supports the agricultural breeding industry, and particularly cultivates and develops rural agricultural intensive, micro or family type breeding production. The fish and vegetable symbiotic cultivation combines aquaculture and vegetable cultivation, in the fish cultivation process, excrement of fish, fish food and other organic matters can be decomposed into toxic substances such as ammonia nitrogen, nitrite and the like in water, and the toxic substances are just good fertilizers for aquatic vegetables and other plants.

However, in the actual culture process, the energy consumption is high in the culture production due to the limitation of farmer sites and the unreasonable structural design of culture equipment, and the water quality safety in the fishpond cannot be ensured for a long time.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is to provide a tower type circulating ecosystem so as to solve the problems in the background technology.

In order to solve the technical problems, the technical scheme adopted by the utility model is as follows:

the utility model provides a tower circulation ecosystem, includes the support frame, is equipped with a plurality of ecological cases on the support frame, its characterized in that: also comprises a water collecting tank and a disinfection box;

the ecological boxes are arranged in a tower shape and are provided with an ecological top box positioned at the top and a plurality of ecological side boxes distributed on two sides of the ecological top box, and the ecological side boxes on the same side are arranged at intervals up and down;

each ecological box is provided with a water treatment cavity and a water storage cavity, a tray for planting aquatic plants is horizontally arranged at the upper part of the water storage cavity, water leakage holes are formed in the tray, and a water outlet of the water treatment cavity is communicated with the water storage cavity above the tray;

the upper ecological box and the lower ecological box are communicated through a siphon drainage assembly, water in the water storage cavity of the upper ecological box is guided into the water treatment cavity or the water collection pool of the lower ecological box, the water collection pool is communicated with the water treatment cavity of the ecological top box through a first pipe, and a first pump is arranged on the first pipe;

the top of disinfect box is equipped with spray set, spray set is through pipe two and catch basin intercommunication, is equipped with pump two on pipe two, the bottom of disinfect box inner chamber is equipped with the ultraviolet ray disinfection lamp, the overflow mouth of disinfect box is located the top of ultraviolet ray disinfection lamp and communicates with the catch basin, still is equipped with the ozone entry in the upper portion of overflow mouth.

The further technical scheme is as follows: the water treatment cavity comprises a precipitation cavity and a filter cavity, wherein the precipitation cavity and the filter cavity are sequentially communicated, the filter cavity is filled with filter filler, and a first full flow port communicated with the water storage cavity is formed in the filter cavity.

The further technical scheme is as follows: the water treatment cavity comprises a precipitation cavity, a filter cavity and an adsorption cavity, wherein the precipitation cavity, the filter cavity and the adsorption cavity are sequentially communicated, the filter cavity is filled with filter fillers, aquatic plants are planted in the adsorption cavity, and a second full flow port communicated with the water storage cavity is formed in the adsorption cavity.

The further technical scheme is as follows: the tray is detachably fixed in the water storage cavity.

The further technical scheme is as follows: the catch basin is located in the subaerial foundation ditch, the tank coat has the backup pad, and the catch basin of backup pad both sides exposes, and the top of catch basin is located to a plurality of ecological case framves.

The further technical scheme is as follows: the both sides of catch basin all are equipped with the planting district that is located the foundation ditch, the bottom in planting a district covers there is the packing layer, plant the siphon subassembly intercommunication on the water storage chamber of the below ecological box in district and homonymy to pass through the siphon intercommunication with the catch basin, the siphon is used for planting the leading-in catch basin of water that is higher than the settlement water level in the district.

The further technical scheme is as follows: the both sides of catch basin all are equipped with the two districts of planting that are located the foundation ditch, it is equipped with the planting kickboard in the two districts to plant, plant the siphon subassembly intercommunication on the water storage chamber of the ecological box of the below of two districts and homonymy to pass through the siphon intercommunication with the catch basin, the siphon is used for planting in the two districts and is higher than the leading-in catch basins of water of setting for the water level.

The further technical scheme is as follows: the both sides of catch basin all are equipped with the planting first district that is located the foundation ditch and plant two districts, the bottom in planting first district covers there is the packing layer, it plants the kickboard to be equipped with in the second district of planting, all communicates in proper order through the siphon on the water storage chamber of the most below ecological box of homonymy, planting first district, planting two districts, catch basin.

The further technical scheme is as follows: the siphon drainage assembly comprises:

the siphon is arranged in the water storage cavity and used for discharging water in the water storage cavity, wherein the water is higher than a set water level;

one end of the water drainage pipe is connected with a water outlet of a siphon pipe in the upper ecological box, and the other end of the water drainage pipe extends into a water treatment cavity or a water collection pool in the lower ecological box; and

the oxygenation pipe is sleeved at the lower end of the drain pipe, an oxygenation gap is formed between the oxygenation pipe and the drain pipe, and the upper end of the oxygenation pipe extends out of the water treatment cavity or the water collecting tank.

Adopt the produced beneficial effect of above-mentioned technical scheme to lie in:

a plurality of ecological boxes in the system are arranged in a tower type mode, two rows of ecological side boxes are connected between an ecological top box and a water collecting tank in parallel, the ecological boxes can be connected in a circulating mode only by arranging one pump body in the system, and energy consumption in the system is reduced.

The disinfect box in this system has two kinds of functions of ozone disinfection and ultraviolet ray disinfection simultaneously, can disinfect and the inactivation to the bacterium in the aquaculture water, has solved the medicine residue problem that produces because of disinfecting with the medicine, and the direct oxidation of ozone has the effect of degradation ammonia nitrogen simultaneously, carries out oxidative decomposition to harmful substance, becomes degradable material, and remaining ozone in the aquatic can be fast natural decomposition become oxygen, has increased the dissolved oxygen volume in the water.

In the disinfect box, the mode through spraying increases the contact of water and ozone to the overflow mouth of disinfect box is higher than ultraviolet lamp, can ensure that the processing to the water is comparatively thorough, effective.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram of the present system;

FIG. 2 is a schematic top view of the ecological box of the system;

fig. 3 is a schematic diagram of the construction of a siphon discharge assembly in the present system.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Example one

As shown in fig. 1 to 3, a tower-type circulating ecosystem comprises a support frame, a water collecting tank 20 and a disinfection box 30, wherein the water collecting tank 20 is arranged in a foundation pit on the ground, a support plate covers the water collecting tank 20, the water collecting tank 20 on two sides of the support plate is exposed, and the support frame is erected above the water collecting tank 20 through the support plate. A plurality of ecological boxes 10 are arranged on the support frame.

A plurality of ecological cases 10 are tower-type and span in catch basin 20 top, and ecological case 10 has the ecological top case 11 that is located the top and distributes in a plurality of ecological side case 12 of ecological top case 11 both sides, and a plurality of ecological side case 12 of homonymy are interval arrangement from top to bottom.

Each ecological box 10 is provided with a water treatment cavity and a water storage cavity 101, a tray 102 for planting aquatic plants is horizontally arranged on the upper portion of the water storage cavity 101, a water leakage hole 103 is formed in the tray 102, and a water outlet of the water treatment cavity is communicated with the water storage cavity 101 above the tray 102.

Wherein, the water treatment chamber is including the precipitation chamber 104 that communicates in proper order and the filter chamber 105 that has the filter packing that fills, and precipitation chamber 104 is the income water end of water treatment chamber for impurity's sediment gets rid of the impurity of circulating water, can open the drain that is equipped with the area valve in the bottom of precipitation chamber 104, is convenient for get rid of the silt of sediment. The filter cavity 105 is provided with a first full flow port communicated with the water storage cavity 101 and is a water outlet end of the water treatment cavity, the filler filled in the filter cavity 105 is preferably red brick fragments, and the waste red brick fragments can be used as water treatment filter materials after being crushed, so that the filter material not only has the functions of adsorption and biological carrier of common filter materials, but also has the function of removing the sediment of phosphate radicals, and is low in cost, and the waste materials are recycled.

A plurality of fixed value baskets can be placed on the tray 102 for growing aquatic plants. The planting basket is filled with some insoluble particles with larger specific surface area, such as ceramsite for planting, and the ceramsite can fix vegetables on one hand and can be used as a biological filter material for circulating water on the other hand.

The two ecological boxes 10 arranged up and down and the ecological box 10 and the water collecting tank 20 at the lowest layer are communicated through a siphon drainage assembly 40, water in the water storage cavity 101 of the upper ecological box 10 is guided into the water treatment cavity or the water collecting tank 20 of the lower ecological box 10, the water collecting tank 20 is communicated with the water treatment cavity of the ecological top box 11 through a first pipe 21, and a first pump 22 is arranged on the first pipe 21. A plurality of ecological boxes 10 are arranged in a tower type, two rows of ecological side boxes 12 are connected between an ecological top box 11 and a water collecting tank 20 in parallel, and the ecological boxes 10 can be connected in a circulating mode only by arranging one pump body in the system, so that energy consumption in the system is reduced.

The siphon drain assembly 40 includes a siphon tube 41, a drain tube 42, and an oxygenation tube 43.

The siphon tube 41 is provided in the water storage chamber 101 to discharge water higher than a set water level in the water storage chamber 101. Siphon tube 41 includes an outer discharge shroud 411 and an inner siphon tube 412. On outer drainage cover 411 is vertical to be fixed in the diapire of water storage chamber 101, the top of outer drainage cover 411 seals, offers on the lateral wall of outer drainage cover 411 with set for the lower water inlet that the level flushed, has seted up the mouth of intaking in the water inlet top down. The inner siphon 412 is coaxially arranged in the outer water discharge cover 411, an annular siphon gap is formed between the inner siphon 412 and the outer water discharge cover 411, the upper end of the inner siphon 412 is positioned above the upper water inlet, and the lower end of the inner siphon 412 is connected with the water discharge pipe 42. When the water level in the water storage cavity 101 reaches the height of the lower water inlet, water in the water storage cavity 101 can enter the outer water discharge cover 411 through the lower water inlet, so that the inner liquid level and the outer liquid level of the outer water discharge cover 411 are flush, after the water level in the water storage cavity 101 continues to rise and submerge the upper water inlet, no air enters a siphon gap, a full-flow state can be formed, negative pressure is generated during water discharge, and the water in the water storage cavity 101 can be quickly sucked and discharged from the inner siphon 412.

One end of the drain pipe 42 is connected with the drain port of the siphon 41 in the upper ecological box 10, and the other end thereof extends into the water treatment cavity or the water collecting tank 20 in the lower ecological box 10.

The oxygenation pipe 43 is sleeved at the lower end of the drain pipe 42, an oxygenation gap is formed between the oxygenation pipe 43 and the drain pipe 42, and the upper end of the oxygenation pipe 43 extends out of the water treatment cavity or the water collecting tank 20.

In the circular planting of the ecological system, the siphon rapid drainage and the venturi negative pressure oxygen absorption principle are combined, so that negative pressure air absorption is realized while the upper ecological box 10 drains water, and automatic oxygen enrichment of the system is realized. When the water in the upper ecological box 10 is higher than the set water level, the siphon drainage mechanism starts to perform tidal drainage, the flow rate in the drainage pipe 42 is increased along with the reduction of the fluid pressure, and low pressure is generated near the high-speed flowing fluid, so that an adsorption effect is generated, air is sucked from an oxygenation gap between the oxygenation pipe 43 and the drainage pipe 42320, automatic oxygen supply to circulating water is realized, the use of oxygenation equipment is avoided, and the production cost is reduced.

And because the diameter of the oxygenation pipe 43 is increased, the flow velocity of water entering the oxygenation pipe 43 is reduced, and the water can be fully mixed with sucked air, so that the oxygen content in the planting water is increased, and oxygen is provided for the growth of fish and sprouts.

The negative pressure oxygen inhalation effect is far higher than that of an independent Venturi tube, and only the drainage tube 42 is sleeved with the oxygenation tube 43, so that the negative pressure oxygen inhalation device is simple in structure and low in manufacturing cost.

The top of disinfect box 30 is equipped with spray set 31, spray set 31 communicates with catch basin 20 through two 32 pipes, is equipped with two 33 pumps on two 32 pipes, the bottom of disinfect box 30 inner chamber is equipped with ultraviolet ray disinfection lamp 34, the overflow mouth 35 of disinfect box 30 is located the top of ultraviolet ray disinfection lamp 34 and communicates with catch basin 20, still is equipped with the ozone entry in the upper portion of overflow mouth 35.

Disinfect box 30 in this system has two kinds of functions of ozone disinfection and ultraviolet ray disinfection simultaneously, can disinfect and inactivate the bacterium in the aquaculture water body, has solved the medicine residue problem because of using the medicine disinfection to produce, and the direct oxidation of ozone has the effect of degradation ammonia nitrogen simultaneously, carries out oxidative decomposition to harmful substance, becomes degradable material, and remaining ozone in the aquatic can be fast natural decomposition become oxygen, has increased the dissolved oxygen volume in the water.

In the disinfect box 30, the mode through spraying increases the contact of water and ozone to the overflow mouth 35 of disinfect box 30 is higher than ultraviolet lamp, can ensure that the processing to the water is comparatively thorough, effective.

When the aquatic plants are planted in the ecological system, enough water needs to be injected into the water collecting tank 20 in advance, the water can be fish culture water, and excrement and feed residues of the fish in the fish culture water are rich in ammonia nitrogen, protein and other substances, so that nutrients are provided for the growth of the aquatic plants. The first pump 22 is operated to pump water into the settling chamber 104 of the ecological top box 11 at the uppermost layer, so that the water flows. The water is continuously pumped into the topmost sedimentation cavity 104 along with the water, the water is sedimentated through the sedimentation cavity 104 to remove impurities, supernatant enters the filter cavity 105, is subjected to one-stage or multi-stage filtration through the filler, then overflows into the tray 102 through the first full-flow port, the planting basket is soaked in shallow water, and the circulating water provides nutrition for aquatic plants. The water that constantly gushes into in the tray 102 gets into water storage chamber 101 by the hole 103 that leaks, and after the high-order water level of setting for in water storage chamber 101, siphon drainage subassembly 40 will be higher than the water of setting for the water level and discharge into the sedimentation chamber 104 of the ecological side case 12 of both sides lower floor fast, in the collecting basin 20 is advanced in the backward flow at last, circulates in proper order to realize the circulation of aquatic plant and plant.

The water in the water collecting tank 20 and the disinfection box 30 form another circulating system through the arrangement of the second pipe 32 and the second pump 33, the second pump 33 pumps the water in the water collecting tank 20 into the disinfection box 30, and the water is sprayed into the disinfection box 30 to be fully contacted with ozone and ultraviolet rays and then returns to the water collecting tank 20 from the overflow port 35.

Example two

In the implementation of the tower-type circulating ecosystem disclosed herein, the difference from the first embodiment is that the water treatment cavity comprises a sedimentation cavity 104, a filtration cavity 105 filled with filtration filler and an adsorption cavity 106 planted with aquatic plants, which are sequentially communicated, the adsorption cavity 106 is provided with a second full flow port communicated with the water storage cavity 101, and the adsorption cavity 106 adsorbs ammonia nitrogen in water through the aquatic plants.

The tray 102 is detachably arranged in the water storage cavity 101, and specifically, a plurality of supporting blocks for supporting the tray 102 are circumferentially fixed on the side wall of the water storage cavity 101, and the tray 102 is placed on the supporting blocks.

The tray 102 can be used for placing a seedling tray, treated water overflows into the tray 102 from a second full flow port, shallow water in the tray 102 provides nutrition for roots of the sprouts and cools the roots of the sprouts to ensure healthy growth of the sprouts, water continuously flowing into the tray 102 enters the water storage cavity 101 through water leakage, and fish fries can be cultured in the water storage cavity 101, so that the sprout-fish symbiotic circulation culture is realized.

EXAMPLE III

The implementation of the tower-type circulating ecosystem is based on the first embodiment, a planting area 50 located in a foundation pit is arranged on each of two sides of a water collecting tank 20, a packing layer covers the bottom of the planting area 50, the planting area 50 is communicated with a siphon component on a water storage cavity 101 of the lowest ecological tank 10 on the same side and is communicated with the water collecting tank 20 through a siphon 41, and the siphon 41 is used for guiding water higher than a set water level in the planting area 50 into the water collecting tank 20.

Based on the first embodiment, the planting area 50 is integrated into the circulating system, and the water flows out of the biological tank at the bottom layer, first enters the planting area 50, and then flows back to the water collecting tank 20. Aquatic plants can be planted in the planting area 50, and the water quality is further filtered through the packing layer, so that the water quality of the circulating water is further improved.

Example four

The implementation of the tower-type circulating ecosystem is based on the first embodiment, two planting zones 60 located in a foundation pit are arranged on two sides of the water collecting tank 20, planting floating plates are arranged in the planting zones 60, the planting zones 60 are communicated with siphon components on the water storage cavity 101 of the lowest ecological tank 10 on the same side and are communicated with the water collecting tank 20 through siphon pipes 41, and the siphon pipes 41 are used for guiding water higher than a set water level in the planting zones 60 into the water collecting tank 20.

Based on the first embodiment, the second planting area 60 is integrated into the circulating system, and the water flows out of the biological tank at the bottom layer, first enters the second planting area 60, and then flows back into the water collecting tank 20. In the second planting area 60, aquatic plants can be planted on the planting floating plates, and the water quality of the circulating water is further improved.

EXAMPLE five

In the implementation of the tower-type circulating ecosystem, the first planting area 50 and the second planting area 60 which are positioned in the foundation pit are arranged on both sides of the water collecting tank 20, the packing layer covers the bottom of the first planting area 50, the planting floating plates are arranged in the second planting area 60, and the water storage cavity 101 of the lowest ecological box 10 on the same side, the first planting area 50, the second planting area 60 and the water collecting tank 20 are sequentially communicated through the siphon 41.

Based on the first embodiment, the first planting area 50 and the second planting area 60 are simultaneously integrated into the circulating system, and the water flows out of the biological box at the bottom layer, then firstly flows into the first planting area 50 and the second planting area 60, and then flows back into the water collecting tank 20. Aquatic plants can be planted in the first planting area 50, the water quality is further filtered through the packing layer, the aquatic plants can be planted on the planting floating plates in the second planting area 60, and the water quality of circulating water is further improved.

The above is only a preferred embodiment of the utility model, and any simple modifications, variations and equivalents of the utility model may be made by anyone in light of the above teachings and fall within the scope of the utility model.

Claims (9)

1. The utility model provides a tower circulation ecosystem, includes the support frame, is equipped with a plurality of ecological cases (10) on the support frame, its characterized in that:

also comprises a water collecting tank (20) and a disinfection box (30);

the ecological boxes (10) are arranged in a tower shape and are provided with an ecological top box (11) positioned at the top and a plurality of ecological side boxes (12) distributed at two sides of the ecological top box (11), and the ecological side boxes (12) at the same side are arranged at intervals up and down;

each ecological box (10) is provided with a water treatment cavity and a water storage cavity (101), a tray (102) for planting aquatic plants is horizontally arranged at the upper part of the water storage cavity (101), a water leakage hole (103) is formed in the tray (102), and a water outlet of the water treatment cavity is communicated with the water storage cavity (101) above the tray (102);

the upper ecological box and the lower ecological box are communicated with each other through a siphon drainage assembly (40), the water storage cavity (101) of the upper ecological box (10) is led into the water treatment cavity or the water collecting tank (20) of the lower ecological box (10), the water collecting tank (20) is communicated with the water treatment cavity of the ecological top box (11) through a first pipe (21), and a first pump (22) is arranged on the first pipe (21);

the top of disinfect box (30) is equipped with spray set (31), spray set (31) are through managing two (32) and catch basin (20) intercommunication, are equipped with pump two (33) on managing two (32), the bottom of disinfect box (30) inner chamber is equipped with ultraviolet ray disinfection lamp (34), overflow mouth (35) of disinfect box (30) are located the top of ultraviolet ray disinfection lamp (34) and communicate with catch basin (20), still are equipped with the ozone entry in the upper portion of overflow mouth (35).

2. The tower-type circulating ecosystem of claim 1, wherein: the water treatment cavity comprises a precipitation cavity (104) and a filter cavity (105), wherein the precipitation cavity (104) and the filter cavity (105) are sequentially communicated, and the filter cavity (105) is provided with a first full flow port communicated with the water storage cavity (101).

3. The tower-type circulating ecosystem of claim 1, wherein: the water treatment cavity comprises a sedimentation cavity (104), a filtering cavity (105) filled with filtering filler and an adsorption cavity (106) planted with aquatic plants, which are sequentially communicated, and a second full flow port communicated with the water storage cavity (101) is arranged on the adsorption cavity (106).

4. The tower-type circulating ecosystem of claim 3, wherein: the tray (102) is detachably fixed in the water storage cavity (101).

5. The tower-type circulating ecosystem of claim 1, wherein: the utility model discloses a ecological case, including catch basin (20), catch basin (20) are located subaerial foundation ditch, the upper cover of catch basin (20) has the backup pad, and catch basin (20) of backup pad both sides expose, and the top in catch basin (20) is erect in a plurality of ecological cases (10).

6. The tower-type circulating ecosystem of claim 1, wherein: the both sides of catch basin (20) all are equipped with one planting district (50) that are located the foundation ditch, the bottom of planting a district (50) covers there is the packing layer, plant siphon subassembly intercommunication on water storage chamber (101) of district (50) and the below ecological box (10) of homonymy to communicate through siphon (41) with catch basin (20), siphon (41) are used for planting in the leading-in catch basin (20) of water that is higher than the settlement water level in district (50).

7. The tower-type circulating ecosystem of claim 1, wherein: the both sides of catch basin (20) all are equipped with two districts (60) of planting that are located the foundation ditch, be equipped with in planting two districts (60) and plant the kickboard, plant siphon subassembly intercommunication on water storage chamber (101) of two districts (60) and the below ecological box (10) of homonymy to communicate through siphon (41) with catch basin (20), siphon (41) are used for planting in two districts (60) being higher than the leading-in catch basin (20) of water of setting for the water level.

8. The tower-type circulating ecosystem of claim 1, wherein: the both sides of catch basin (20) all are equipped with planting one district (50) and planting two districts (60) that are located the foundation ditch, the bottom of planting one district (50) covers there is the packing layer, be equipped with in planting two districts (60) and plant the kickboard, all communicate in proper order through siphon (41) between water storage chamber (101) of the most below ecological box (10) of homonymy planting one district (50), planting two districts (60), catch basin (20).

9. The tower-type circulating ecosystem of claim 1, wherein: the siphon drain assembly (40) comprises:

the siphon (41) is arranged in the water storage cavity (101) and is used for discharging water higher than the set water level in the water storage cavity (101);

one end of the drain pipe (42) is connected with a drain port of a siphon pipe (41) in the upper ecological box (10), and the other end of the drain pipe extends into a water treatment cavity or a water collecting tank (20) in the lower ecological box (10); and

the oxygenation pipe (43) is sleeved at the lower end of the drain pipe (42), an oxygenation gap is formed between the oxygenation pipe and the drain pipe (42), and the upper end of the oxygenation pipe (43) extends out of the water treatment cavity or the water collecting tank (20).

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