Energy-saving irrigation device

By designing an energy-saving irrigation device with a collection box, protective box, and cleaning mechanism, the corrosion problem caused by exposed sprinkler heads and pipe blockage problem are solved, achieving sprinkler head protection and efficient energy utilization, and improving the service life and energy-saving effect of the irrigation device.

CN224460798UActive Publication Date: 2026-07-07宁波市奉化区横山水库管理站

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
宁波市奉化区横山水库管理站
Filing Date
2025-08-06
Publication Date
2026-07-07

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  • Figure CN224460798U_ABST
    Figure CN224460798U_ABST
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Abstract

This utility model relates to the field of irrigation equipment technology and discloses an energy-saving irrigation device, including a collection box. An isolation net is fitted on the top of the collection box, and a cleaning mechanism is installed on the top of the isolation net. A pump is installed inside the collection box, and a diversion pipe is fixedly installed at the water outlet of the pump. Multiple connecting pipes are fixedly installed on the top of the diversion pipe, and irrigation mechanisms are fixedly installed on the top of the connecting pipes. In this utility model, by setting multiple irrigation mechanisms, when in use, an electric telescopic rod is activated to move the annular pipe and multiple spray pipes upwards, cooperating with the sprinklers to spray water for irrigation. After use, the electric telescopic rod drives the protective cover to form a closed state with the protective box, storing the multiple spray pipes and sprinklers inside the protective box, effectively preventing the sprinklers from being exposed to the outside for a long time, thus avoiding corrosion, discoloration, or damage.
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Description

Technical Field

[0001] This utility model relates to the field of irrigation equipment technology, and in particular to an energy-saving irrigation device. Background Technology

[0002] Green space refers to various parks, zoos, botanical gardens, memorial gardens, small parks, and street squares that are used for public recreation and sightseeing. Public green space is an important indicator reflecting the level of urban residents' recreational and rest areas and the quality of urban greening environment. In order to maintain public green space, irrigation devices are installed in all public green space areas.

[0003] Patent document CN210726258U discloses a garden green space water storage and irrigation device, including a water storage tank and a water tank. A No. 1 water pump is fixedly installed on the lower outer side of the water tank. A metal mesh cover is fixedly installed on the lower inner side of the water tank. A water pump is fixedly connected to the inlet of the No. 1 water pump, and the other end of the water pump is located inside the metal mesh cover. A No. 2 water pump is fixedly installed on the lower outer side of the water tank. A main water pipe is fixedly connected to the outlet of the No. 2 water pump. Several branch water pipes are fixedly connected to the main water pipe. Spray heads are fixedly installed on the upper end of each branch water pipe. A motor is fixedly installed in the middle of the upper end face of the water tank. A stirring shaft is fixedly connected to the output end of the motor. The stirring shaft is located inside the water tank. Several stirring blades are fixedly installed on the outer periphery of the stirring shaft. Several water inlets are evenly provided on the outer periphery of the upper end face of the water tank. This utility model solves the problem of traditional garden green space water storage and irrigation devices having a single function and being prone to pipe blockage.

[0004] This application addresses the problem that traditional garden and green space water storage irrigation devices have limited functionality and are prone to pipe blockage. However, these devices suffer from the problem that the spray heads are exposed to the elements for extended periods, which may lead to corrosion, discoloration, or damage. This is detrimental to the long-term use of the irrigation device. Therefore, this application provides an energy-saving irrigation device to improve upon this issue. Utility Model Content

[0005] To overcome the above shortcomings, this utility model provides an energy-saving irrigation device, which aims to improve the problem that the spray head of the irrigation device in the prior art is exposed to the outside for a long time, which may cause the faucet to corrode, discolor or break after long-term exposure.

[0006] To achieve the above objectives, the present invention adopts the following technical solution: an energy-saving irrigation device, including a collection box, an isolation net fitted on the top of the collection box, a cleaning mechanism on the top of the isolation net, a pump installed inside the collection box, a diversion pipe fixedly installed at the water outlet of the pump, multiple connecting pipes fixedly installed on the top of the diversion pipe, and an irrigation mechanism fixedly installed on the top of the connecting pipe.

[0007] The irrigation mechanism includes a protective box and an electric telescopic rod. The electric telescopic rod is fixedly installed inside the protective box. An annular tube is fixedly installed at the top of the electric telescopic rod. A protective cover is fixedly installed at the top of the annular tube. Multiple water spray pipes with an L-shaped structure are installed through the annular tube. Multiple nozzles are fixedly installed on the outside of the water spray pipes. A telescopic water pipe is installed at the front of the electric telescopic rod, and the top of the telescopic water pipe extends into the annular tube. The bottom of the telescopic water pipe is fixedly connected to a connecting pipe. A reinforcing ring is provided at the connection between the telescopic water pipe and the connecting pipe. The protective cover is movably connected to the protective box.

[0008] As a further description of the above technical solution:

[0009] The cleaning mechanism includes a support plate and a threaded rod. The threaded rod is installed inside the support plate. One end of the threaded rod is rotatably connected to the inner wall of the support plate, and the other end of the threaded rod is equipped with a drive motor. The drive motor is fixedly connected to the outside of the collection box. The drive end of the drive motor passes through the collection box and is fixedly connected to the threaded rod. A movable frame is sleeved on the outside of the threaded rod. A movable block is fixedly installed on the top of the movable frame. Movable plates are fixedly installed at both ends of the movable block. A cleaning brush is fixedly installed at the bottom of the movable plate.

[0010] As a further description of the above technical solution:

[0011] The cleaning brush is in contact with the isolation net, the connection between the movable frame and the support plate is provided with a matching movable groove, and the movable block has a U-shaped structure.

[0012] As a further description of the above technical solution:

[0013] A support rod is fixedly installed at the top of the support plate away from the moving plate. A solar photovoltaic panel is installed at the top of the support rod, and a photoelectric sensor is fixedly installed at the top of the solar photovoltaic panel. An electric telescopic cylinder is fixedly installed at one end of the support rod, and the other end of the electric telescopic cylinder is fixedly connected to the solar photovoltaic panel. The solar photovoltaic panel and the support rod are movably connected by a hinge.

[0014] As a further description of the above technical solution:

[0015] A control panel is fixedly installed on the front side of the collection box, and a water inlet pipe is installed through the inside of the collection box. The control panel is a PLC controller, which electrically controls the pump, drive motor, electric telescopic rod, electric telescopic cylinder and solar photovoltaic panel.

[0016] As a further description of the above technical solution:

[0017] The bottom of the protective box is fixedly equipped with green space, and the collection box, connecting pipe and diversion pipe are all buried inside the green space.

[0018] This utility model has the following beneficial effects:

[0019] In this invention, multiple irrigation mechanisms are set up. When in use, the electric telescopic rod is activated to move the annular pipe and multiple water spray pipes upward, which work together with the nozzles to spray water for irrigation. After use, the electric telescopic rod moves the protective cover and the protective box to form a closed state, storing the multiple water spray pipes and nozzles in the protective box. This effectively avoids the problem of the nozzles being exposed to the outside for a long time, which could lead to corrosion, discoloration or damage.

[0020] In this invention, a cleaning mechanism is set up, and a timed control of the drive motor drives the threaded rod to move the moving frame, thereby moving the cleaning brush on the isolation net, effectively sweeping away the debris on the isolation net, and preventing the debris from entering the collection box and causing blockage of various water pipes.

[0021] In this invention, rainwater is collected by a collection box to provide a stable water source for irrigating green spaces. At the same time, a photoelectric sensor receives light energy signals, thereby controlling an electric telescopic cylinder to tilt the solar photovoltaic panels at an angle to maximize the utilization of solar energy resources, improve the power generation efficiency of solar photovoltaics, and provide stable power to multiple electrical devices, thus achieving the goal of energy saving. Attached Figure Description

[0022] Figure 1 This is a three-dimensional view of the overall structure of an energy-saving irrigation device proposed in this utility model;

[0023] Figure 2 This is a cross-sectional view of the connection between the collection box and the green space of an energy-saving irrigation device proposed in this utility model;

[0024] Figure 3 This is a perspective view of the protective box structure of an energy-saving irrigation device proposed in this utility model;

[0025] Figure 4 This is an enlarged view of point A of an energy-saving irrigation device proposed in this utility model;

[0026] Figure 5 This is an enlarged view of section B of an energy-saving irrigation device proposed in this utility model.

[0027] Legend:

[0028] 1. Collection box; 2. Isolation net; 3. Pump; 4. Diversion pipe; 5. Connecting pipe; 6. Protective box; 7. Electric telescopic rod; 8. Ring pipe; 9. Protective cover; 10. Spray pipe; 11. Sprayer head; 12. Telescopic water pipe; 13. Support plate; 14. Threaded rod; 15. Drive motor; 16. Moving frame; 17. Moving block; 18. Moving plate; 19. Cleaning brush; 20. Support rod; 21. Solar photovoltaic panel; 22. Electric telescopic cylinder; 23. Control panel; 24. Green space. Detailed Implementation

[0029] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0030] Reference Figure 1-5 This utility model provides an embodiment of an energy-saving irrigation device, comprising a collection box 1, an isolation net 2 fitted on the top of the collection box 1, a cleaning mechanism on the top of the isolation net 2, a pump 3 inside the collection box 1, a diversion pipe 4 fixedly installed at the outlet of the pump 3, a plurality of connecting pipes 5 fixedly installed at the top of the diversion pipe 4, and an irrigation mechanism fixedly installed at the top of the connecting pipes 5; the irrigation mechanism includes a protective box 6 and an electric telescopic rod 7, the electric telescopic rod 7 fixedly installed inside the protective box 6, and the top of the electric telescopic rod 7... A ring pipe 8 is fixedly installed in the part, and a protective cover 9 is fixedly installed on the top of the ring pipe 8. Multiple water spray pipes 10 are installed through the outside of the ring pipe 8. The water spray pipes 10 have an L-shaped structure and multiple nozzles 11 are fixedly installed on the outside of the water spray pipes 10. A telescopic water pipe 12 is installed on the front side of the electric telescopic rod 7, and the top of the telescopic water pipe 12 extends into the inside of the ring pipe 8. The bottom of the telescopic water pipe 12 is fixedly connected to the connecting pipe 5. A reinforcing ring is installed at the connection between the telescopic water pipe 12 and the connecting pipe 5. The protective cover 9 is movably connected to the protective box 6.

[0031] The electric telescopic rod 7 moves the protective cover 9 upward, and at the same time, the telescopic water pipe 12 is stretched until the water pipe 10 reaches the set height, at which point the nozzle 11 can spray water to irrigate the green area 24. After irrigation, the electric telescopic rod 7 moves the water pipe 10 into the protective box 6, and at the same time, the protective cover 9 comes into contact with the protective box 6 to form a closed state, storing the multiple water pipes 10 and nozzles 11 in the protective box 6. This effectively prevents the nozzles 11 from being exposed to the outside for a long time, which could lead to corrosion, discoloration or damage.

[0032] The cleaning mechanism includes a support plate 13 and a threaded rod 14. The threaded rod 14 is provided inside the support plate 13. One end of the threaded rod 14 is rotatably connected to the inner wall of the support plate 13. The other end of the threaded rod 14 is provided with a drive motor 15. The drive motor 15 is fixedly connected to the outside of the collection box 1. The drive end of the drive motor 15 passes through the collection box 1 and is fixedly connected to the threaded rod 14. A movable frame 16 is sleeved on the outside of the threaded rod 14. A movable block 17 is fixedly provided on the top of the movable frame 16. Movable plates 18 are fixedly provided on both ends of the movable block 17. A cleaning brush 19 is fixedly provided on the bottom of the movable plate 18.

[0033] The isolation net 2 isolates debris in the rainwater, preventing it from entering the collection box 1. At the same time, the drive motor 15 drives the threaded rod 14 to rotate. The rotation of the threaded rod 14 drives the moving frame 16 to move left and right on the support plate 13. During the movement, the moving plate 18 drives the cleaning brush 19 to sweep the isolation net 2, effectively removing debris from the isolation net 2.

[0034] The cleaning brush 19 comes into contact with the isolation net 2, and a matching moving groove is provided at the connection between the moving frame 16 and the support plate 13. The moving block 17 has a U-shaped structure.

[0035] When the movable block 17 comes into contact with the support rod 20, its U-shaped structure can abut against the outer wall of the support rod 20, preventing the support rod 20 from becoming an obstacle when the cleaning brush 19 is cleaning, so that the cleaning brush 19 can clean the isolation net 2 more thoroughly.

[0036] A support rod 20 is fixedly installed at the top of the support plate 13 away from the movable plate 18. A solar photovoltaic panel 21 is installed on the top of the support rod 20, and a photoelectric sensor is fixedly installed on the top of the solar photovoltaic panel 21. An electric telescopic cylinder 22 is fixedly installed at one end of the support rod 20, and the other end of the electric telescopic cylinder 22 is fixedly connected to the solar photovoltaic panel 21. The solar photovoltaic panel 21 and the support rod 20 are movably connected by a hinge.

[0037] The photoelectric sensor receives light energy signals and transmits them to the control panel 23. The control panel 23 then controls the electric telescopic cylinder 22 to extend and retract, causing the solar photovoltaic panel 21 to tilt at an angle. This maximizes the utilization of solar energy resources, improves the power generation efficiency of solar photovoltaic, and provides stable power to multiple electrical devices, thereby achieving energy conservation.

[0038] A control panel 23 is fixedly installed on the front side of the collection box 1. A water inlet pipe is installed through the inside of the collection box 1. The control panel 23 is a PLC controller. The control panel 23 electrically controls the pump 3, drive motor 15, electric telescopic rod 7, electric telescopic cylinder 22 and solar photovoltaic panel 21.

[0039] The bottom of the protective box 6 is fixedly equipped with a green space 24, and the collection box 1, connecting pipe 5 and diversion pipe 4 are all buried inside the green space 24.

[0040] The protective box 6 is fixedly connected to the green space 24, which ensures stability during use.

[0041] Working principle: During daily irrigation, the pump 3 is activated via the control panel 23, causing the pump 3 to transfer the rainwater collected in the collection tank 1 to the various connecting pipes 5 through the diversion pipe 4. Simultaneously, the control panel 23 activates the electric telescopic rod 7, causing it to move the protective cover 9 upwards until the sprinkler pipe 10 reaches the set height. Finally, the water source is guided into the telescopic water pipe 12, and then sprayed from the nozzles 11 on each sprinkler pipe 10, thus irrigating the green area 24. After irrigation, the electric telescopic rod 7 moves the sprinkler pipe 10 into the protective box 6, causing the protective cover 9 to contact the protective box 6, forming a sealed state. This effectively prevents the sprinkler pipes 10 and nozzles 11 from being exposed for extended periods, thus avoiding corrosion, discoloration, or damage to the sprinkler pipes 11. During daily use, the collected... The collection box 1 collects rainwater, while the isolation net 2 isolates debris from the rainwater, preventing debris from entering the collection box 1. The control panel 23 controls the drive motor 15 to start, causing the drive motor 15 to drive the threaded rod 14 to rotate. The rotation of the threaded rod 14 drives the moving frame 16 to move left and right on the support plate 13. During the movement, the moving plate 18 drives the cleaning brush 19 to sweep the isolation net 2, effectively removing debris from the isolation net 2. During use, the photoelectric sensor receives light energy signals and transmits the signals to the control panel 23, causing the control panel 23 to control the electric telescopic cylinder 22 to extend and retract, causing it to tilt the solar photovoltaic panel 21 at an angle to maximize the utilization of solar energy resources, improve the power generation efficiency of solar photovoltaic, provide stable power to multiple electrical devices, and achieve the purpose of energy saving.

[0042] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. An energy-saving irrigation device, comprising a collection box (1), characterized in that: The top of the collection box (1) is fitted with an isolation net (2), and the top of the isolation net (2) is equipped with a cleaning mechanism. The inside of the collection box (1) is equipped with a pump (3), and the outlet end of the pump (3) is fixedly equipped with a diversion pipe (4). The top of the diversion pipe (4) is fixedly equipped with multiple connecting pipes (5), and the top of the connecting pipes (5) is fixedly equipped with an irrigation mechanism. The irrigation mechanism includes a protective box (6) and an electric telescopic rod (7). The electric telescopic rod (7) is fixedly installed inside the protective box (6). An annular pipe (8) is fixedly installed on the top of the electric telescopic rod (7). A protective cover (9) is fixedly installed on the top of the annular pipe (8). Multiple water spray pipes (10) are installed through the outer side of the annular pipe (8). The water spray pipe (10) has an L-shaped structure. Multiple nozzles (11) are fixedly installed on the outer side of the water spray pipe (10). A telescopic water pipe (12) is installed on the front side of the electric telescopic rod (7). The top of the telescopic water pipe (12) extends into the annular pipe (8). The bottom of the telescopic water pipe (12) is fixedly connected to the connecting pipe (5). A reinforcing ring is installed at the connection between the telescopic water pipe (12) and the connecting pipe (5). The protective cover (9) is movably connected to the protective box (6).

2. The energy-saving irrigation device according to claim 1, characterized in that: The cleaning mechanism includes a support plate (13) and a threaded rod (14). The support plate (13) has a threaded rod (14) inside. One end of the threaded rod (14) is rotatably connected to the inner wall of the support plate (13). The other end of the threaded rod (14) is provided with a drive motor (15). The drive motor (15) is fixedly connected to the outside of the collection box (1). The drive end of the drive motor (15) passes through the collection box (1) and is fixedly connected to the threaded rod (14). A movable frame (16) is sleeved on the outside of the threaded rod (14). A movable block (17) is fixedly provided on the top of the movable frame (16). Movable plates (18) are fixedly provided at both ends of the movable block (17). A cleaning brush (19) is fixedly provided at the bottom of the movable plate (18).

3. The energy-saving irrigation device according to claim 2, characterized in that: The cleaning brush (19) is in contact with the isolation net (2), and the connection between the movable frame (16) and the support plate (13) is provided with a matching movable groove. The movable block (17) has a U-shaped structure.

4. The energy-saving irrigation device according to claim 3, characterized in that: A support rod (20) is fixedly installed at the top of the support plate (13) away from the moving plate (18). A solar photovoltaic panel (21) is installed on the top of the support rod (20), and a photoelectric sensor is fixedly installed on the top of the solar photovoltaic panel (21). An electric telescopic cylinder (22) is fixedly installed at one end of the support rod (20), and the other end of the electric telescopic cylinder (22) is fixedly connected to the solar photovoltaic panel (21). The solar photovoltaic panel (21) and the support rod (20) are movably connected by a hinge.

5. An energy-saving irrigation device according to claim 4, characterized in that: A control panel (23) is fixedly installed on the front side of the collection box (1). A water inlet pipe is installed through the inside of the collection box (1). The control panel (23) is a PLC controller. The control panel (23) electrically controls the pump (3), drive motor (15), electric telescopic rod (7), electric telescopic cylinder (22) and solar photovoltaic panel (21).

6. An energy-saving irrigation device according to claim 5, characterized in that: The bottom of the protective box (6) is fixedly provided with a green space (24), and the collection box (1), connecting pipe (5) and diversion pipe (4) are all buried inside the green space (24).