Drought mountain greening irrigation water pipe device

By introducing a delivery pump and a timed reversing switch into the irrigation water supply pipe device for afforestation in arid mountainous areas, the problem of existing devices being unable to add fertilizer or pesticides in a quantitative manner has been solved, realizing the quantitative delivery of pesticides and improving the efficiency of afforestation in arid mountainous areas.

CN224470108UActive Publication Date: 2026-07-07SHANDONG HAOKUN RUNTU WATER CONSERVANCY EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANDONG HAOKUN RUNTU WATER CONSERVANCY EQUIP CO LTD
Filing Date
2025-07-10
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing irrigation pipe systems for afforestation in arid mountainous areas cannot quantitatively add fertilizers or pesticides during the water delivery process.

Method used

A device comprising an input pipe, a fixed flange, a diverter, a delivery pump, a storage tank, and a timed reversing switch was designed. The delivery pump draws the agent from the storage tank and delivers it quantitatively to the output pipe, thereby realizing the quantitative addition of fertilizer or pesticide.

Benefits of technology

It enables the quantitative delivery of fertilizers or pesticides during water conveyance, improving the efficiency and effectiveness of afforestation in arid mountainous areas.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model provides a kind of drought mountain afforestation irrigation water delivery pipe device, it belongs to drought mountain irrigation technical field, it includes input pipe and fixed flange, the outer surface of the input pipe is fixedly connected with fixed flange, the tail end of the input pipe is fixedly connected with first shunt plug, the outer surface of the first shunt plug is connected with first delivery pipe, the tail end of the first delivery pipe is fixedly connected with second shunt plug, the outer surface of the second shunt plug is connected with second delivery pipe.The utility model adds output pipe, delivery pump, extraction pipe and timing reversing switch to storage tank, timing reversing switch sets reversing time to deliver electric energy to the inside of delivery pump, at this time, delivery pump generates suction to the medicine inside storage tank via extraction pipe, and medicine is delivered to the inside of output pipe, at this time, output pipe delivers medicine to the inside of first shunt plug, and the quantitative delivery of fertilizer or insecticide is completed.
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Description

Technical Field

[0001] This utility model belongs to the field of irrigation technology for arid mountainous areas, and in particular relates to a water supply pipe device for irrigation of arid mountainous greening areas. Background Technology

[0002] In the process of using arid mountainous areas, as a common geological condition in modern times, prolonged drought often leads to soil erosion due to sandification, which in turn affects the safety of arid mountainous areas. Therefore, in order to stabilize the state of arid mountainous areas, it is necessary to green them and stabilize them. In the existing greening process of arid mountainous areas, irrigation water supply pipe devices are required to deliver water stably to the interior of arid mountainous areas. However, the existing irrigation water supply pipe devices for arid mountainous areas lack auxiliary components, making it impossible to add fertilizers or pesticides quantitatively during the water delivery process. Utility Model Content

[0003] To achieve the above objectives, the present invention adopts the following technical solution:

[0004] An irrigation water supply pipe device for afforestation in arid mountainous areas includes an input pipe and a fixed flange. The input pipe is characterized by having a fixed flange fixedly connected to its outer surface, a first diverter fixedly connected to its tail end, a first delivery pipe penetrating the outer surface of the first diverter, a second diverter fixedly connected to its tail end, a second delivery pipe penetrating the outer surface of the second diverter, and an output nozzle fixedly connected to its tail end.

[0005] Preferably, the bottom of the output nozzle is fixedly connected with an insertion pin, and four insertion pins are provided.

[0006] Preferably, an output pipe is connected through the top of the first diverter, and two output pipes are provided, with a delivery pump fixedly connected to the tail end of the output pipe.

[0007] Preferably, a storage tank is fixedly connected to the front of the two conveying pumps, an extraction pipe is fixedly connected to the input end of the conveying pump, and the tail end of the extraction pipe extends into the interior of the storage tank. A feed pipe is connected through the top of the storage tank.

[0008] Preferably, a timed reversing switch is fixedly connected to the back of the storage box.

[0009] Preferably, shock absorbers are fixedly connected to both sides of the storage box, and four shock absorbers are provided.

[0010] Preferably, the tail end of the shock absorber is fixedly connected to a fixing plate, and the outer surface of the fixing plate is provided with a threaded fixing hole, and there are two threaded fixing holes.

[0011] Compared with the prior art, the present invention has the following advantages:

[0012] This invention adds an output pipe, a delivery pump, an extraction pipe, and a timed reversing switch. The timed reversing switch sets the reversing time to deliver electrical energy to the delivery pump. At this time, the delivery pump generates suction on the pesticide inside the storage tank through the extraction pipe and delivers the pesticide to the output pipe. The output pipe then delivers the pesticide to the first diverter plug, completing the quantitative delivery of fertilizer or pesticide. Attached Figure Description

[0013] Figure 1 This is a schematic diagram of the structure of an irrigation water supply pipe device for afforestation in arid mountainous areas proposed in this utility model;

[0014] Figure 2 This is a schematic diagram of the back structure of an irrigation water supply pipe device for afforestation in arid mountainous areas proposed in this utility model;

[0015] Figure 3 This is a schematic diagram of the structure of the storage box connection part proposed in this utility model;

[0016] Figure 4 This is a cross-sectional view of the output nozzle connection proposed in this utility model.

[0017] In the diagram: 1. Input pipe; 2. Fixed flange; 3. First diverter; 4. First delivery pipe; 5. Second diverter; 6. Second delivery pipe; 7. Output nozzle; 8. Insert pin; 9. Output pipe; 10. Delivery pump; 11. Storage tank; 12. Extraction pipe; 13. Feed pipe; 14. Timer reversing switch; 15. Vibration damper; 16. Fixing plate; 17. Threaded fixing hole. Detailed Implementation

[0018] The technical solution of this utility model will be further described below with reference to the accompanying drawings and embodiments.

[0019] Reference Figures 1-4A water supply pipe device for irrigation in arid mountainous areas includes an input pipe 1 and a fixed flange 2. The fixed flange 2 is fixedly connected to the outer surface of the input pipe 1, providing a fixing point for the fixed flange 2 and the first diversion plug 3. When water needs to be transported to the inside of the input pipe 1 via an external conveying component, the input pipe 1 transports the water to the inside of the first diversion plug 3. The fixed flange 2 is connected to an external conveying pipe. When the input pipe 1 needs to be fixed, an external bolt can be inserted into the inside of the fixed flange 2 by external force, and the external bolt is inserted into the inside of the external fixed plane to complete the fixing of the input pipe 1. The tail end of the input pipe 1 is fixedly connected to the first diversion plug 3. When water is transported to the inside of the external conveying component, the water supply pipe 1 transports the water to the inside of the first diversion plug 3. When the inlet pipe 1 delivers water to the interior of the first diversion plug 3, the first diversion plug 3 delivers water or chemicals to the interior of the four first delivery pipes 4. The outer surface of the first diversion plug 3 is connected to the first delivery pipes 4. When water or chemicals are delivered to the interior of the first diversion plug 3, the first delivery pipes 4 deliver water to the interior of the second diversion plug 5. The tail end of the first delivery pipe 4 is fixedly connected to the second diversion plug 5. When water is delivered to the interior of the second diversion plug 5, the second diversion plug 5 delivers water or chemicals to the interior of the four second delivery pipes 6 respectively. The outer surface of the second diversion plug 5 is connected to the second delivery pipes 6. When water is delivered to the interior of the second delivery pipes 6, the second delivery pipes 6 deliver water to the output nozzle 7. Inside the storage tank 11, the tail end of the second delivery pipe 6 is fixedly connected to an output nozzle 7. When water is delivered to the inside of the output nozzle 7, the output nozzle 7 delivers the water to the outer surface of the arid mountain, thereby irrigating the arid mountain and improving the greening efficiency of the arid mountain. The bottom of the output nozzle 7 is fixedly connected to an insertion nail 8. When it is necessary to fix the output nozzle 7, the insertion nail 8 can be inserted into the top of the arid mountain by external force to complete the fixation of the output nozzle 7. There are four insertion nails 8. Both sides of the storage tank 11 are fixedly connected to shock absorbers 15. The shock absorbers 15 are fixedly connected to both sides of the storage tank 11 to provide fixing points for the fixing plate 16 fixedly connected to its tail end. When the impact force of the external environment is transmitted to the shock absorber, the shock absorber 15 will provide a fixing point for the fixing plate 16 fixedly connected to its tail end. When the shock absorber 15 is inside the shock absorber 15, the shock absorber 15 undergoes elastic deformation and absorbs the impact force through sliding friction, thereby improving the stability of the storage box 11 after it is fixed. There are four shock absorbers 15. The tail end of the shock absorber 15 is fixedly connected to a fixing plate 16. The fixing plate 16 is fixedly connected to the tail end of the shock absorber 15 and provides a fixing point for the threaded fixing hole 17 through the outer surface of the fixing plate 16. When it is necessary to fix the storage box 11 as a whole, the external bolt can be inserted into the threaded fixing hole 17 by external force and then inserted into the external fixing plane to complete the fixing of the storage box 11. There are two threaded fixing holes 17.

[0020] Reference Figures 1-3The top of the first diverter 3 is connected to an output pipe 9. When the medicine is delivered to the inside of the output pipe 9 by the delivery pump 10, the output pipe 9 delivers the medicine to the inside of the first diverter 3. There are two output pipes 9. The tail end of the output pipe 9 is fixedly connected to the delivery pump 10. When electrical energy is delivered to the inside of the delivery pump 10 by the timer reversing switch 14, the delivery pump 10 generates suction on the medicine inside the storage tank 11 through the extraction pipe 12 and delivers the medicine to the inside of the output pipe 9. The front of the two delivery pumps 10 is fixedly connected to the storage tank 11. The storage tank 11 is fixedly connected to the front of the delivery pump 10, providing a fixing point for the feed pipe 13, the timer reversing switch 14 and the shock absorber 15 fixedly connected to its outer surface, and at the same time providing storage space for the medicine stored inside. The input end of the delivery pump 10 is fixedly connected to the extraction pipe 12. Under the suction of the delivery pump 10, the extraction pipe 12 delivers the medicine to the inside of the output pipe 9, and the tail end of the extraction pipe 12 extends into the inside of the storage tank 11. The top of the storage tank 11 is connected to the feed pipe 13, which is connected to the top of the storage tank 11 and connected to the external pipeline to deliver the medicine into the storage tank 11 to complete the addition of the medicine. The back of the storage tank 11 is fixedly connected to the timed reversing switch 14. When it is necessary to output the medicine in a quantitative manner, the reversing time of the timed reversing switch 14 can be set by external force. At this time, the timed reversing switch 14 will deliver the electrical energy into the pump 10. When the reversing time is reached, the timed reversing switch 14 will cut off the electrical energy conducted to the inside of the delivery pump 10.

[0021] The functional principle of this utility model can be explained through the following operation: First, the device is moved to a designated position by external force, and the external bolt is inserted into the threaded fixing hole 17 and the external bolt is inserted into the external fixing plane to complete the overall fixation of the device. Then, the external bolt is inserted into the fixing flange 2 by external force and the external conveying component. When the water is conveyed to the inside of the input pipe 1, the input pipe 1 conveys the water to the inside of the first diversion plug 3. The first diversion plug 3 conveys the water to the inside of the four first conveying pipes 4. The first conveying pipes 4 convey the water to the inside of the second diversion plug 5. The second diversion plug 5 conveys the water to the inside of the four second conveying pipes 6 respectively. The second conveying pipes 6 convey the water to the inside of the output nozzle 7. The output nozzle 7 conveys the water to the outer surface of the arid mountain, thereby irrigating the arid mountain and improving the greening efficiency of the arid mountain.

[0022] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this utility model and are not intended to limit it. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of this utility model without departing from the spirit and scope of the technical solutions of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.

Claims

1. A water supply pipe device for irrigation in arid mountainous areas, comprising an inlet pipe (1) and a fixed flange (2), characterized in that, A fixed flange (2) is fixedly connected to the outer surface of the input pipe (1). A first diverter (3) is fixedly connected to the tail end of the input pipe (1). A first delivery pipe (4) is connected through the outer surface of the first diverter (3). A second diverter (5) is fixedly connected to the tail end of the first delivery pipe (4). A second delivery pipe (6) is connected through the outer surface of the second diverter (5). An output nozzle (7) is fixedly connected to the tail end of the second delivery pipe (6).

2. The irrigation water supply pipe device for afforestation in arid mountainous areas according to claim 1, characterized in that, The bottom of the output nozzle (7) is fixedly connected with an insertion pin (8), and there are four insertion pins (8).

3. The irrigation water supply pipe device for afforestation in arid mountainous areas according to claim 1, characterized in that, The top of the first diverter (3) is connected to an output pipe (9), and there are two output pipes (9). The tail end of the output pipe (9) is fixedly connected to a delivery pump (10).

4. The irrigation water supply pipe device for afforestation in arid mountainous areas according to claim 3, characterized in that, A storage tank (11) is fixedly connected to the front of the two conveying pumps (10), and an extraction pipe (12) is fixedly connected to the input end of the conveying pump (10), with the tail end of the extraction pipe (12) extending into the interior of the storage tank (11). A feed pipe (13) is connected through the top of the storage tank (11).

5. The irrigation water supply pipe device for afforestation in arid mountainous areas according to claim 4, characterized in that, A timer reversing switch (14) is fixedly connected to the back of the storage box (11).

6. The irrigation water supply pipe device for afforestation in arid mountainous areas according to claim 4, characterized in that, Both sides of the storage box (11) are fixedly connected to shock absorbers (15), and four shock absorbers (15) are provided.

7. The irrigation water supply pipe device for afforestation in arid mountainous areas according to claim 6, characterized in that, The tail end of the shock absorber (15) is fixedly connected to a fixing plate (16), and the outer surface of the fixing plate (16) is provided with a threaded fixing hole (17), and there are two threaded fixing holes (17).