Ecological grid water oxygen-rich nest
By designing an ecological grid-like aquatic oxygen-enriched nest, and combining floating islands, bases, fillers, and solar-powered micro-nano aerators, the problems of long restoration time and oxygen deficiency of ecological floating islands are solved, achieving efficient water treatment and aesthetically pleasing water quality improvement.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BEIJING JIUJIE QIRONG TECHNOLOGY CO LTD
- Filing Date
- 2025-06-27
- Publication Date
- 2026-07-03
AI Technical Summary
Existing ecological floating island restoration methods are time-consuming and prone to plant necrosis due to lack of oxygen, and there is a lack of targeted water treatment solutions to improve the oxygen content of the water.
It adopts an ecological grid-like water oxygen-enriching nest, which combines rectangular assembled ecological floating islands, bases, combined packing units, oxygen-enriching chambers, solar energy units, and warning light units. It uses micro-nano aerators to increase the oxygen content of the water and achieves autonomous operation through solar power.
It improves water treatment efficiency, shortens repair time, enhances water oxygen content, and is easy to install and maintain. It achieves precise control of water quality exchange and is both aesthetically pleasing and practical.
Smart Images

Figure CN224450445U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of ecological water management and sewage treatment technology, and in particular to an ecological grid-type aquatic oxygen-enriched nest. Background Technology
[0002] With the acceleration of urbanization and the increasing prominence of water pollution, water body restoration and ecological governance have become crucial aspects of environmental protection. Existing ecological floating islands rely solely on planting vegetation for simple plant restoration, which is time-consuming and often results in plant death due to oxygen deficiency. Therefore, there is a need for targeted water treatment solutions that can improve restoration time, increase oxygen levels, and are easy to install and implement. Utility Model Content
[0003] This invention provides an ecological grid-like aquatic oxygen-enriched nest to solve technical problems such as long restoration time for single plants, water hypoxia, and fixed self-generating power on ecological floating islands.
[0004] To achieve the above objectives, the present invention adopts the following technical solution:
[0005] An ecological grid-type aquatic oxygen-enriched nest includes a rectangular assembled ecological floating island, a base connected to the middle of the long axis of the ecological floating island, a combined filler unit connected to the base, an oxygen-enriched chamber connected to the base, a solar energy unit connected to the oxygen-enriched chamber with its bottom fixed to the base, a warning light unit set on the top side of the oxygen-enriched chamber, and a green plant unit set around the ecological floating island.
[0006] The base is a frame, and an ecological floating island is installed in the lower middle part of the frame. The corners of the frame are equipped with suspension plates, which are used to temporarily thread suspension ropes and to thread and fix ropes after the frame is lowered.
[0007] The bottom of the frame is also provided with a packing connecting rod, which is detachably connected to the combined packing unit.
[0008] The solar energy unit and the warning light unit are respectively connected to the micro-nano aerator installed in the oxygen-enriched room.
[0009] Furthermore, the ecological floating island is a rectangular block with a hanging basket installed in the central hole, and a green plant unit is installed in the hanging basket; the ecological floating island is spliced and connected to the floating island unit; the buoyancy of the floating island unit is adapted to bear the weight of each component installed on it; the size of the floating island unit is adapted to the size of the ecological grid divided in the water area to be treated;
[0010] The greening unit includes a planting pot set in a hanging basket and green plants planted in the planting pot; wherein the types of green plants are set according to the pollutants in the water to be treated.
[0011] The water bodies to be treated include slow-flowing rivers, lakes, reservoirs, and bays; the pollution in the water bodies to be treated is classified as minor pollution, slight pollution, and poor water exchange.
[0012] Furthermore, the base includes a lower horizontal frame, a vertical frame connected to the upper part of the lower horizontal frame, an upper horizontal frame connected to the top of the vertical frame, and a support member disposed in the upper part of the vertical frame and located at the top of the ecological floating island; the components inside the base are connected by connecting plates.
[0013] The lower horizontal frame, vertical frame, and upper horizontal frame are combined to form a cuboid frame; and the upper horizontal frame is provided with hanging plates at its four corners.
[0014] The vertical frame members are inserted into the holes of the ecological floating island, and the vertical frame members are spaced apart along the length of the lower horizontal frame members; a support member is provided between adjacent vertical frame members, and the support member is a lightweight rectangular steel pipe or a lightweight steel plate; the bottom of the support member is pressed onto the ecological floating island.
[0015] Furthermore, the upper horizontal frame includes a square-shaped upper horizontal frame side member and a straight line member connected inside the upper horizontal frame side member. Both the upper horizontal frame side member and the upper horizontal frame inner member are rod members. The upper horizontal frame inner member is arranged at intervals along the length of the upper horizontal frame side member or arranged in a vertical mesh pattern inside the upper horizontal frame side member.
[0016] The lower horizontal frame includes a lower horizontal frame edge piece in the shape of a square and a lower horizontal frame inner piece connected inside the lower horizontal frame edge piece in a straight line. Both the lower horizontal frame edge piece and the lower horizontal frame inner piece are rods. The lower horizontal frame inner piece is arranged at intervals along the length of the lower horizontal frame edge piece or arranged in a vertical mesh pattern inside the lower horizontal frame edge piece.
[0017] Furthermore, filler rods are also provided at intervals between the opposite sides of the lower horizontal frame members along their longitudinal direction. The filler rods are detachably connected to the lower horizontal frame members through a connecting rod fixing plate.
[0018] Furthermore, the combined packing unit includes vertically arranged packing rods, packing material spaced apart on the packing rods, iron weights detachably connected to the bottom of the packing rods, and packing couplings connected to the top of the packing rods; the packing couplings are correspondingly detachably connected to the packing couplings.
[0019] Furthermore, the bottom of the oxygen-enriched chamber is bolted to the upper horizontal frame edge;
[0020] The oxygen-enriched chamber includes a trapezoidal box-shaped outer shell, a pressure gauge installed on the outer shell, and an inlet and an outlet port on one side of the outer shell; a micro-nano aerator is installed inside the outer shell, and an inlet and an outlet port are provided corresponding to the micro-nano aerator.
[0021] The access hole is connected to an air inlet pipe and / or a liquid inlet pipe. The air inlet pipe is connected to an air supply source, and the liquid inlet pipe is connected to the water area to be treated. A filter screen is installed at the inlet end of the liquid inlet pipe that extends into the water area to be treated.
[0022] The output port is connected to the liquid outlet pipe, and the extended section of the liquid outlet pipe is equipped with a release device that extends into the water area to be treated.
[0023] Furthermore, the solar unit includes a pole, a keel connected to the top of the pole, and a solar panel connected to the top of the keel; the bottom of the pole is bolted to the upper horizontal frame, and the top of the pole is fixedly connected to an arc-shaped plate; the arc-shaped plate is pre-connected to the keel.
[0024] The keel is a mesh frame and is covered on the back of the solar panel. The keel is tilted, and the tilt angle corresponds to the designed tilt angle of the solar panel. The solar panel and the micro-nano aerator provide power to the battery of the micro-nano aerator.
[0025] Furthermore, the warning light unit includes a Z-shaped light bracket and a light fixture connected to the top of the light bracket. The light bracket is hollow and its top is installed on the top of the oxygen-enriched chamber. The wiring is connected to the micro-nano aerator through the outer shell of the oxygen-enriched chamber.
[0026] Furthermore, one end of the fixing rope is threaded through a hole in the suspension plate, and the other end is connected to a fixing pile, which is set on the bank of the water area to be treated; at least two fixing ropes are provided, with the two fixing points set opposite each other on the base.
[0027] The beneficial effects of this utility model are reflected in:
[0028] This invention improves the efficiency of water treatment using a single plant by incorporating biological filler. The biological filler is detachably connected to the base for easy installation and replacement, making it more adaptable to various aquatic environments. The inclusion of a micro-nano aerator in the oxygen-enriched chamber increases oxygen levels in the water, and the micro-nano bubbles further enhance water treatment efficiency. The application utilizes a solar panel for outdoor self-charging, facilitating continuous operation in water, and a warning light unit allows for monitoring of its status. The addition of micro-nano bubble technology makes it easier and more precise to maintain anaerobic, anoxic, and aerobic conditions within the gridded ecological module. The above-water section utilizes ecological floating islands. Pollutants in the water are treated by the microbial community in the underwater biological filler and then absorbed by the roots of aquatic plants planted in the ecological floating bed, resulting in more effective removal. The plants on the ecological floating bed are selected from superior varieties and integrated with landscaping, incorporating fountain-type or push-flow-type aerators, which not only enhance aesthetics but also significantly increase water exchange.
[0029] Other features and advantages of this invention will be set forth in the description which follows, and will be apparent in part from the description, or may be learned by practicing the invention; the main objectives and other advantages of this invention may be realized and obtained by means of the methods particularly pointed out in the description. Attached Figure Description
[0030] Figure 1 This is a side view of an ecological grid-like aquatic oxygen-enriched nest;
[0031] Figure 2 This is a front view of an ecological grid-like aquatic oxygen-enriched nest;
[0032] Figure 3 This is an aerial view of an ecological grid-like aquatic oxygen-enriched nest.
[0033] Figure 4 This is a schematic diagram of the connection structure between the ecological floating island and its base;
[0034] Figure 5 This is a schematic diagram of the connection structure between the base and the combined packing unit;
[0035] Figure 6 This is a schematic diagram of the combined packing unit structure;
[0036] Figure 7 This is a schematic diagram of the ecological floating island, oxygen-enriched chamber, solar energy unit, and their connection structure.
[0037] Figure 8 This is a schematic diagram of the base and its fixed connection installation.
[0038] Attached reference numerals: 1-Ecological floating island, 2-Base, 21-Lower horizontal frame, 22-Vertical frame, 23-Upper horizontal frame, 231-Upper horizontal frame edge, 232-Upper horizontal frame inner part, 24-Supporting component, 25-Hanging plate, 26-Connecting plate, 27-Filling rod, 28-Ribing fixing plate, 3-Combined filler unit, 31-Filling upright, 32-Filling, 33-Iron weight, 34-Filling hoop, 4-Oxygen-enriched chamber, 41-Outer shell, 42-Pressure gauge, 43-Inlet hole, 44-Outlet hole, 5-Solar unit, 51-Upright, 52-Keel, 53-Solar panel, 6-Warning light unit, 61-Lamp bracket, 62-Light fixture, 7-Green plant unit, 71-Planting pot, 72-Green plant, 8-Fixing rope, 9-Fixing stake, 10-Water area to be treated, 11-Shoreside. Detailed Implementation
[0039] Taking a water environment management project in a certain river basin as an example, such as Figures 1 to 8As shown, the ecological grid-type aquatic oxygen-enriched nest includes a rectangular assembled ecological floating island 1, a base 2 connected to the middle of the long axis of the ecological floating island 1, a combined filler unit 3 connected below the base 2, an oxygen-enriched chamber 4 connected above the base 2, a solar energy unit 5 connected above the oxygen-enriched chamber 4 with its bottom fixed to the base 2, a warning light unit 6 set on the top side of the oxygen-enriched chamber 4, and green plant units 72 set around the ecological floating island 1.
[0040] The base 2 is a lightweight steel frame, with the ecological floating island 1 installed in the lower middle part of the frame; the corners of the frame are equipped with hanging plates 25, which are used for temporary connection of hanging ropes and connection of fixing ropes 8 after hoisting; the bottom of the frame is also equipped with a packing connecting rod 27, which is used for detachable connection of the combined packing unit 3; the solar unit 5 and the warning light unit 6 are respectively connected to the micro-nano aerator installed in the oxygen-enriched chamber 4.
[0041] In this embodiment, the ecological floating island 1 is a rectangular block with a hanging basket installed in the central hole, and green plant 72 units 7 are installed in the hanging basket; the ecological floating island 1 is spliced to connect the floating island units; the buoyancy of the floating island unit is adapted to bear the weight of each component installed on it; the size of the floating island unit is adapted to the size of the ecological grid divided in the water area to be treated 10;
[0042] In this embodiment, the green plant unit 72 includes a planting pot 71 set in a hanging basket and green plants 72 planted in the planting pot 71; wherein the types of green plants 72 correspond to the pollutants in the water area 10 to be treated, and the types of green plants 72 include sedge, water celery and calamus, etc.
[0043] In this embodiment, the base 2 includes a lower horizontal frame 21, a vertical frame 22 connected to the upper part of the lower horizontal frame 21, an upper horizontal frame 23 connected to the top of the vertical frame 22, and a support member 24 disposed in the upper part of the vertical frame 22 and located at the top of the ecological floating island 1; the components inside the base 2 are connected by a connecting plate 26.
[0044] In this embodiment, the lower horizontal frame 21, the vertical frame 22, and the upper horizontal frame 23 are all rectangular tubes made of corrosion-resistant lightweight steel plates or aluminum plates and are combined to form a cuboid frame; and the four corners of the upper horizontal frame 23 are provided with hanging plates 25; the vertical frame 22 is inserted into the holes of the ecological floating island 1, and the vertical frame 22 is spaced apart along the length of the lower horizontal frame 21; a support member 24 is provided between adjacent vertical frame members 22, and the support member 24 is a lightweight rectangular steel pipe or a lightweight steel plate; the bottom of the support member 24 is pressed onto the ecological floating island 1.
[0045] In this embodiment, the upper horizontal frame 23 includes a U-shaped upper horizontal frame side member 231 and a straight line member connected inside the upper horizontal frame side member 231. Both the upper horizontal frame side member 231 and the upper horizontal frame inner member 232 are rod members. The upper horizontal frame inner member 232 is arranged at intervals along the length of the upper horizontal frame side member 231 or is arranged in a vertical mesh pattern and intersecting inside the upper horizontal frame side member 231. The lower horizontal frame 21 includes a U-shaped lower horizontal frame side member and a straight line member connected inside the lower horizontal frame side member. Both the lower horizontal frame side member and the lower horizontal frame inner member are rod members. The lower horizontal frame inner member is arranged at intervals along the length of the lower horizontal frame side member or is arranged in a vertical mesh pattern and intersecting inside the lower horizontal frame side member.
[0046] In addition, filler rods 27 are spaced apart between the opposite sides of the lower horizontal frame members along the longitudinal direction. The filler rods 27 are lightweight steel pipes and are detachably connected between the lower horizontal frame members through the rod fixing plate 28.
[0047] In this embodiment, the combined packing unit 3 includes a vertically arranged packing rod 31, packing 32 spaced apart on the packing rod 31, an iron weight 33 detachably connected to the bottom of the packing rod 31, and a packing clamp 34 connected to the top of the packing rod 31; the packing clamp 34 is detachably connected to the packing connecting rod 27.
[0048] In this embodiment, the bottom of the oxygen-enriched chamber 4 is bolted to the upper horizontal frame 231. The oxygen-enriched chamber 4 includes a trapezoidal box-shaped outer shell 41, a pressure gauge 42 installed on the outer shell 41, and an inlet hole 43 and an outlet hole 44 on one side of the outer shell 41. A micro-nano aerator is installed inside the outer shell 41, and the inlet hole 43 and outlet hole 44 are provided corresponding to the micro-nano aerator. The inlet hole 43 is connected to an air inlet pipe and / or a liquid inlet pipe, and the air inlet pipe is connected to an air supply source. The air source can be air, ozone, pure oxygen, carbon dioxide, or other gases depending on the water body requirements. The liquid inlet pipe is connected to the water area 10 to be treated, and a filter screen is installed at the inlet end of the liquid inlet pipe that extends into the water area 10 to be treated. The outlet hole 44 is connected to an outlet pipe, and a release device is installed on the extended section of the outlet pipe that extends into the water area 10 to be treated.
[0049] In this embodiment, the solar unit 5 includes a pole 51, a keel 52 connected to the top of the pole 51, and a solar panel 53 connected to the top of the keel 52; the bottom of the pole 51 is bolted to the upper horizontal frame 231, and the top of the pole 51 is fixedly connected to an arc-shaped plate; the arc-shaped plate is pre-connected to the keel 52; the keel 52 is a mesh frame and is covered on the back of the solar panel 53; the keel 52 is inclined, and the inclination angle corresponds to the designed inclination angle of the solar panel 53; the solar panel 53 and the micro-nano aerator provide power to the battery of the micro-nano aerator.
[0050] In this embodiment, the warning light unit 6 includes a Z-shaped light bracket 61 and a light fixture 62 connected to the top of the light bracket. The light bracket 61 is hollow and its top is mounted on the top of the oxygen-enriched chamber 4. The wiring is connected to the micro-nano aerator through the outer shell 41 of the oxygen-enriched chamber 4. The light fixture 62 uses a combination of flashing and color to indicate the operation of the micro-nano aerator and the status of the battery.
[0051] In addition, one end of the fixing rope 8 is threaded through the hole in the suspension plate 25, and the other end is connected to the fixing pile 9, which is set on the bank 11 of the water area to be treated 10; at least two fixing ropes 8 are provided, with the two fixing points set opposite each other on the base 2.
[0052] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any changes or substitutions that can be conceived by those skilled in the art within the technical scope disclosed in the present utility model should be included within the protection scope of the present utility model.
Claims
1. An ecological grid water oxygen-rich nest, characterized in that, It includes an ecological floating island (1) assembled in a rectangular shape, a base (2) connected to the middle of the long direction of the ecological floating island (1), a combined filler unit (3) connected to the bottom of the base (2), an oxygen-enriched chamber (4) connected to the top of the base (2), a solar energy unit (5) connected to the top of the oxygen-enriched chamber (4) with the bottom of the solar energy unit (5) fixed to the base (2), a warning light unit (6) set on the top of the side of the oxygen-enriched chamber (4), and a green plant (72) unit (7) set around the ecological floating island (1); The base (2) is a frame frame, and an ecological floating island (1) is installed in the middle and lower part of the frame frame; a hanging plate (25) is provided at the corner of the frame frame, and the hanging plate (25) is used to temporarily thread the hanging rope and to thread the fixing rope (8) after the hoisting. The bottom of the frame is also provided with a packing rod (27), which is detachably connected to the combined packing unit (3). The solar energy unit (5) and the warning light unit (6) are respectively connected to the micro-nano aerator installed in the oxygen-enriched chamber (4).
2. An ecological mesh overwater oxygen-rich nest according to claim 1, characterized in that, The ecological floating island (1) is a rectangular block with a hanging basket installed in the central hole, and a green plant (72) unit (7) is installed in the hanging basket; the ecological floating island (1) is spliced to connect the floating island units; the buoyancy of the floating island unit is adapted to bear the weight of each component installed on it; the size of the floating island unit is adapted to the size of the ecological grid divided in the water area to be treated (10); The green plant (72) unit (7) includes a planting pot (71) set in a hanging basket and green plants (72) planted in the planting pot (71); wherein the types of green plants (72) correspond to the pollutants in the water area (10) to be treated; The water area to be treated (10) includes rivers, lakes, reservoirs and bays with slow flow rates; the pollution of the water area to be treated (10) is slight pollution, mild pollution and poor water exchange.
3. An ecological mesh overwater oxygen-rich nest according to claim 1, characterized in that, The base (2) includes a lower horizontal frame (21), a vertical frame (22) connected to the upper part of the lower horizontal frame (21), an upper horizontal frame (23) connected to the top of the vertical frame (22), and a support (24) located in the upper part of the vertical frame (22) and at the top of the ecological floating island (1); the components inside the base (2) are connected by a connecting plate (26); The lower horizontal frame (21), the vertical frame (22) and the upper horizontal frame (23) are combined to form a cuboid frame; and the four corners of the upper horizontal frame (23) are provided with hanging plates (25). The vertical frame (22) is inserted into the hole of the ecological floating island (1). The vertical frame (22) is arranged at intervals along the length of the lower horizontal frame (21). A support (24) is arranged between adjacent vertical frame (22). The support (24) is a lightweight rectangular steel pipe or a lightweight steel plate. The bottom of the support (24) is pressed onto the ecological floating island (1).
4. An ecological mesh overwater oxygen-rich nest according to claim 3, characterized in that, The upper horizontal frame (23) includes an upper horizontal frame side member (231) in the shape of a square and a straight line connected inside the upper horizontal frame side member (231). Both the upper horizontal frame side member (231) and the upper horizontal frame inner member (232) are rods. The upper horizontal frame inner member (232) is arranged at intervals along the length of the upper horizontal frame side member (231) or arranged in a vertical mesh pattern inside the upper horizontal frame side member (231). The lower horizontal frame (21) includes a lower horizontal frame edge piece in the shape of a square and a lower horizontal frame inner piece connected inside the lower horizontal frame edge piece and in a straight line. Both the lower horizontal frame edge piece and the lower horizontal frame inner piece are rods. The lower horizontal frame inner piece is arranged at intervals along the length of the lower horizontal frame edge piece or arranged in a vertical mesh pattern inside the lower horizontal frame edge piece.
5. An ecological grid-type aquatic oxygen-enriched nest as described in claim 4, characterized in that, Filler rods (27) are also provided at intervals between the opposite sides of the lower horizontal frame members along the longitudinal direction. The filler rods (27) are detachably connected to the lower horizontal frame members through the rod fixing plate (28).
6. An ecological mesh overwater oxygen-rich nest according to claim 5, characterized in that, The combined packing unit (3) includes a vertically arranged packing rod (31), packing material (32) spaced on the packing rod (31), an iron weight (33) detachably connected to the bottom of the packing rod (31), and a packing coupling (34) connected to the top of the packing rod (31); the packing coupling (34) is detachably connected to the packing connecting rod (27).
7. An ecological mesh overwater oxygen-rich nest according to claim 4, characterized in that, The bottom of the oxygen-enriched chamber (4) is bolted to the upper horizontal frame side piece (231); The oxygen-enriched chamber (4) includes a trapezoidal box-shaped outer shell (41), a pressure gauge (42) installed on the outer shell (41), and an inlet hole (43) and an outlet hole (44) provided on one side of the outer shell (41); a micro-nano aerator is installed inside the outer shell (41), and an inlet hole (43) and an outlet hole (44) are provided corresponding to the micro-nano aerator. The access hole (43) is connected to an air inlet pipe and / or a liquid inlet pipe. The air inlet pipe is connected to an air supply source, and the liquid inlet pipe is connected to the water area to be treated (10). A filter screen is installed at the inlet end of the liquid inlet pipe that extends into the water area to be treated (10). The output hole (44) is connected to the liquid outlet pipe, and the extended section of the liquid outlet pipe is equipped with a release device and extends into the water area to be treated (10).
8. An ecological mesh overwater oxygen-rich nest according to claim 4, characterized in that, The solar unit (5) includes a pole (51), a keel (52) connected to the top of the pole (51), and a solar panel (53) connected to the top of the keel (52); the bottom of the pole (51) is bolted to the upper horizontal frame (231), and the top of the pole (51) is fixedly connected to an arc plate; the arc plate is pre-connected to the keel (52); The keel (52) is a mesh frame and is covered on the back of the solar panel (53). The keel (52) is tilted and the tilt angle corresponds to the tilt angle designed for the solar panel (53). The solar panel (53) and the micro-nano aerator provide power for the battery of the micro-nano aerator.
9. An ecological mesh overwater oxygen-rich nest according to claim 4, characterized in that, The warning light unit (6) includes a Z-shaped lamp bracket (61) and a lamp (62) connected to the top of the lamp bracket. The lamp bracket (61) is hollow and is installed on the top of the oxygen-enriched chamber (4). The wiring is connected to the micro-nano aerator through the outer shell (41) of the oxygen-enriched chamber (4). The lamp (62) is used to characterize the operation of the micro-nano aerator and the state of the battery.
10. An ecological mesh overwater oxygen-rich nest according to claim 1, characterized in that, One end of the fixing rope (8) is threaded through the hole in the suspension plate (25), and the other end is connected to the fixing pile (9). The fixing pile (9) is set on the bank (11) of the water area (10) to be treated. There are at least two fixing ropes (8), and the two fixing points are set opposite each other on the base (2).