An orchard water and fertilizer integrated fertilization equipment
By introducing a detachable frame, short rod limiting ring, and solar panels into the orchard fertigation equipment, the problems of inconvenient equipment movement, single spraying mode, and low energy efficiency have been solved. Precise adjustment of height and angle and green power supply have been achieved, improving the flexibility and efficiency of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HEBEI YUHE AGRICULTURAL TECHNOLOGY CO LTD
- Filing Date
- 2025-07-24
- Publication Date
- 2026-06-19
Smart Images

Figure CN224368392U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of fertilization equipment, specifically relating to an integrated water and fertilizer fertilization device for orchards. Background Technology
[0002] In the field of modern agricultural orchard planting, integrated water and fertilizer management is an important means to ensure the healthy growth of fruit trees and the quality of fruit. Orchards have complex and varied terrain, including both flat and sloping land, and the height of fruit trees varies greatly. The water and fertilizer requirements of different growth stages are also different. This requires fertilization equipment to have good terrain adaptability, flexible height adjustment function and diversified spraying modes.
[0003] In existing technologies, the support structures of orchard fertigation equipment are mostly fixed or simply foldable, resulting in large volumes during transportation and long installation and debugging times. This is especially problematic when frequently moving between multiple orchards, leading to low efficiency in equipment transportation and deployment. Furthermore, traditional supports often use heavy materials such as steel, making them extremely inconvenient to move in orchards with complex terrain. Their height adjustment function is also limited, failing to meet the fertilization needs of fruit trees of different heights. Currently, traditional orchard fertigation equipment generally suffers from problems such as inconvenient equipment movement, limited spraying modes, difficulty in adjusting nozzle height and spraying, and low energy efficiency. These shortcomings make it difficult to meet the demands of modern agriculture for efficient, energy-saving, and precise operations, and require further improvement. Utility Model Content
[0004] To overcome the problems of traditional integrated water and fertilizer application equipment, such as inconvenient equipment mobility, single spraying mode, inconvenience in adjusting nozzle height and spraying, and low energy efficiency, a new integrated water and fertilizer application equipment for orchards is proposed.
[0005] The technical solution of this utility model is: an integrated water and fertilizer application device for orchards, including a base plate, with a water tank, a water pump, a bottom block and a fixing column fixedly connected to the upper end of the base plate;
[0006] An electric cylinder and two uprights are fixedly connected to the upper end of the base block. A lifting block is fitted on the side wall of the two uprights. One end of an adjustment block is hinged to each side of the lifting block.
[0007] A bearing ring is fixed to the upper end of the fixed column, and two fixed blocks are fixed to the side wall of the bearing ring. The first fixed pipe is fixed to the side end of each fixed block, and a U-shaped block is hinged to the fixed block. A long block is fixed to the side end of the U-shaped block, and the other end of the adjusting block is hinged to the lower end of the long block.
[0008] The first short rod is fixed to the side wall of the first fixed tube, and the second short rod is fixed to the side wall of the long block. The side walls of the first short rod and the second short rod are fitted with a sleeve frame, and the sleeve frame is connected to the mounting block through a detachable structure.
[0009] An installation tube is fixedly connected to the mounting block, with one end of the installation tube open and the other end fixedly connected to the first nozzle.
[0010] A water spray mechanism is installed at the top of the long block;
[0011] The base plate is equipped with a diversion mechanism, which is connected to the outlet end of the water pump and the opening end of the installation pipe through pipes respectively;
[0012] A moving mechanism is provided at the lower end of the base plate.
[0013] Furthermore, the detachable structure consists of screw grooves and threaded posts. The inner wall of the sleeve frame has equally spaced screw grooves, one of which has a threaded post threadedly installed on its inner wall. One end of the threaded post is fixed to the side wall of the mounting block, and the other end of the threaded post has a nut threadedly installed on its side wall.
[0014] Furthermore, solar panels are installed on the two uprights. The solar panels include a fixing cylinder, a control box, and a solar panel. The side walls of the two uprights are fixed with fixing cylinders, and the side walls of the fixing cylinders are fixed with connecting blocks. The side walls of the two connecting blocks are jointly fixed with a control box. The upper end of the control box is fixed with a solar panel. The control box contains a solar controller, a battery, and an inverter.
[0015] Furthermore, a first limiting ring is fixed to the side wall of the first short rod, and a second limiting ring is fixed to the side wall of the second short rod. The end of the first limiting ring near the first fixed tube is in contact with the end of the sleeve frame away from the first fixed tube, and the end of the second limiting ring near the long block is in contact with the end of the sleeve frame away from the long block. When the sleeve frame moves, both the first limiting ring and the second limiting ring can cover the groove part of the sleeve frame.
[0016] Furthermore, a water injection pipe and a second fixed pipe are installed on the side wall of the water tank. A second valve body is installed on the water injection pipe, and a third valve body is installed on the second fixed pipe.
[0017] Furthermore, the diversion mechanism includes a hollow box, an inlet pipe, an outlet pipe, and a first valve body. The hollow box is fixedly connected to the upper end of the base plate, and the inlet pipe and multiple outlet pipes are fixedly connected through the side end of the hollow box. The first valve body is installed on the outlet pipe. The outlet pipe of the water pump is connected to the inlet pipe, and the pumping pipe of the water pump is connected to the second fixed pipe.
[0018] Furthermore, the water spraying mechanism includes a long pipe, a third nozzle, and a mounting base. Multiple mounting bases are fixed to the upper end of the long pipe, and the long pipe is fixed to the inner wall of the multiple mounting bases. Multiple third nozzles are installed on the long pipe, and the lower end of the long pipe is the water inlet.
[0019] Furthermore, the two uprights are symmetrical about the electric cylinder, with the upper end of the uprights higher than the upper end of the electric cylinder's output shaft.
[0020] Furthermore, the lower end of the first fixed tube is open, and a second nozzle is fixedly connected to the side wall of the first fixed tube.
[0021] Furthermore, the moving mechanism includes casters and push rods. Casters are fixed to the four corners of the lower end of the base plate, and push rods are fixed to the side walls of the base plate.
[0022] The beneficial effects of this utility model are:
[0023] 1. By setting up a frame, a first short rod, a second short rod, and a multi-nozzle structure, the height and angle of the nozzles can be precisely adjusted. The frame can slide along the side walls of the first and second short rods and maintain a stable trajectory under the constraint of the first and second limit rings. Through the detachable connection of the screw groove and the threaded column, the orientation of the mounting block and the first nozzle can be adjusted circumferentially. At the same time, the water spraying mechanism at the top of the long block cooperates with the second nozzle on the side wall of the first fixed pipe to support the switching between downward fan-shaped root irrigation and upward atomized foliar fertilization modes, solving the cumbersome problem of manually changing nozzles in traditional equipment.
[0024] 2. By setting up solar panels, the solar controller, battery and inverter in the control box realize the conversion and storage of light energy into electrical energy, and power the electric cylinder, water pump and intelligent control module. This design does not require an external power supply, adapts to the temperature difference between day and night and rainy environment in the open, and realizes energy-saving and low-consumption green power supply.
[0025] 3. A stable support system is formed by setting up symmetrical uprights, electric cylinders and bearing rings. The two uprights are symmetrically arranged about the electric cylinders. The upper end of the uprights is higher than the output shaft of the electric cylinders, providing ample space for the lifting blocks to move. The long block is hinged to the fixed block through a U-shaped block. With the linkage of the adjusting block, the height of the bracket can be adjusted, making it convenient to use.
[0026] 4. By setting up a diversion mechanism linked to the water pump, the diversion mechanism can divide the pressurized water into multiple streams, making it convenient to connect the inlet ends of each water pipe using hoses. By setting up an electric cylinder, lifting block, adjusting block, and moving mechanism, the electric cylinder drives the lifting block to slide up and down along the upright. The lifting block pulls the long block around the U-shaped block through the adjusting block, realizing the rapid unfolding and folding of the scissor-type bracket. With the universal wheels at the four corners of the bottom plate and the side wall push rods, the equipment can be moved flexibly in complex open-field terrain, significantly improving the relocation efficiency in large-scale planting scenarios and solving the problems of time-consuming transportation and difficult deployment of traditional fixed or heavy-duty brackets. Attached Figure Description
[0027] Figure 1 The diagram shown is a three-dimensional structural schematic of this utility model;
[0028] Figure 2 The diagram shown is a three-dimensional structural schematic of the adjustment mechanism of this utility model;
[0029] Figure 3 The diagram shown is a three-dimensional structural schematic of the first fixing tube of this utility model;
[0030] Figure 4 The diagram shown is a three-dimensional disassembled structural diagram of the sleeve, mounting tube, and nut of this utility model.
[0031] Figure 5 The diagram shown is a three-dimensional structural schematic of the solar energy module of this utility model;
[0032] Figure 6 The diagram shown is a three-dimensional structural schematic of the diversion mechanism of this utility model;
[0033] Figure 7 The diagram shown is a three-dimensional structural schematic of the long tube of this utility model.
[0034] The labels in the attached diagram are as follows: 1. Base plate; 2. Water tank; 3. Water pump; 4. Base block; 5. Upright pole; 6. Electric cylinder; 7. Lifting block; 8. Adjusting block; 9. Fixed column; 10. Bearing ring; 11. Fixed block; 12. U-shaped block; 13. Long block; 14. First fixed pipe; 15. First short rod; 16. Second short rod; 17. Sleeve frame; 18. Mounting block; 19. Mounting pipe; 20. First nozzle; 21. Screw groove; 22. Threaded post; 23. Nut; 24. First limiting ring; 25. Second limiting ring; 26. Fixed cylinder; 27. Control box; 28. Solar panel; 29. Hollow box; 30. Water inlet pipe; 31. Water outlet pipe; 32. First valve body; 33. Water injection pipe; 34. Second valve body; 35. Second fixed pipe; 36. Third valve body; 37. Second nozzle; 38. Long pipe; 39. Third nozzle; 40. Mounting base. Detailed Implementation
[0035] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0036] Example 1: An integrated water and fertilizer application device for orchards, comprising a base plate 1, a water tank 2, a water pump 3, a bottom block 4, and a fixing column 9 fixedly connected to the upper end of the base plate 1;
[0037] The upper end of the bottom block 4 is fixedly connected to the electric cylinder 6 and two uprights 5. The side walls of the two uprights 5 are jointly fitted with the lifting block 7. The two sides of the lifting block 7 are respectively hinged to one end of the adjusting block 8.
[0038] The upper end of the fixed column 9 is fixed to the bearing ring 10, and the side wall of the bearing ring 10 is fixed to two fixed blocks 11. The side ends of each fixed block 11 are respectively fixed to the first fixed tube 14, and the fixed block 11 is hinged to the U-shaped block 12. The side end of the U-shaped block 12 is fixed to the long block 13, and the other end of the adjusting block 8 is hinged to the lower end of the long block 13.
[0039] The first short rod 15 is fixed to the side wall of the first fixed tube 14, and the second short rod 16 is fixed to the side wall of the long block 13. The side walls of the first short rod 15 and the second short rod 16 are fitted together with a sleeve frame 17, and the sleeve frame 17 is connected to the mounting block 18 through a detachable structure.
[0040] Mounting pipe 19 is fixedly connected to mounting block 18. One end of mounting pipe 19 is open and the other end is fixedly connected to first nozzle 20.
[0041] The upper end of the long block 13 is equipped with a water spraying mechanism;
[0042] A diversion mechanism is provided on the base plate 1. The diversion mechanism is connected to the outlet end of the water pump 3 and the opening end of the installation pipe 19 through pipes respectively.
[0043] A moving mechanism is provided at the lower end of the base plate 1.
[0044] In use, the electric cylinder 6 is activated, causing the lifting block 7 to move upward along the two uprights 5. Since the bearing ring 10, the fixing block 11, and the first fixing pipe 14 remain fixed, the adjusting block 8 will drive the long block 13 to move, thereby adjusting the position of the long block 13. Since the sleeve frame 17 is fitted onto the side wall of the first fixing pipe 14 and the second short rod 16, the angle of the sleeve frame 17 can be changed, thereby changing the angle of the first nozzle 20 and enabling fertilizer spraying from more angles. At the same time, since the mounting block 18 is detachably mounted on the sleeve frame 17, the position of the mounting block 18 on the sleeve frame 17 can be adjusted as needed. In addition, water can be supplied to the diversion mechanism through the water pump 3, and then to the mounting pipe 19 and the spraying mechanism through the diversion mechanism, enabling pesticide spraying from more angles. This solves the problems of inconvenient movement, single spraying mode, inconvenient adjustment of nozzle height and spraying angle, and low energy efficiency of existing equipment.
[0045] Please see Figure 1 and Figure 5 In this embodiment, solar panels are installed on the two uprights 5. The solar panels include a fixed cylinder 26, a control box 27, and a solar panel 28. The fixed cylinder 26 is fixed to the side wall of each of the two uprights 5. A connecting block is fixed to the side wall of the fixed cylinder 26. The control box 27 is fixed to the side wall of the two connecting blocks. The solar panel 28 is fixed to the upper end of the control box 27. The control box 27 contains a solar controller, a battery, and an inverter. The solar panel 28 is fixed to the upper end of the control box 27 and is responsible for converting light energy into direct current. The solar controller integrated inside the control box 27 can adjust the input voltage in real time to protect the built-in battery from overcharging and discharging damage. The inverter further converts the direct current of the battery into the alternating current required by the equipment to power the electric cylinder 6 and the water pump 3.
[0046] Please see Figure 1 , Figure 3 and Figure 4In this embodiment, a first limiting ring 24 is fixed to the side wall of the first short rod 15, and a second limiting ring 25 is fixed to the side wall of the second short rod 16. The end of the first limiting ring 24 near the first fixed tube 14 is in contact with the end of the sleeve frame 17 away from the first fixed tube 14, and the end of the second limiting ring 25 near the long block 13 is in contact with the end of the sleeve frame 17 away from the long block 13. When the sleeve frame 17 moves, both the first limiting ring 24 and the second limiting ring 25 can cover the groove part of the sleeve frame 17. The movement state of the sleeve frame 17 is to slide directionally along the side wall of the double short rods as the long block 13 rotates. The limiting rings constrain the precise position and angle. This design not only realizes the dynamic adjustment of the height and spraying angle of the first nozzle 20, but also ensures the stability and safety of the movement process through mechanical limiting.
[0047] Please see Figure 1 and Figure 7 In this embodiment, a water injection pipe 33 and a second fixing pipe 35 are installed on the side wall of the water tank 2. A second valve body 34 is provided on the water injection pipe 33, and a third valve body 36 is provided on the second fixing pipe 35 to facilitate water injection into the water tank 2.
[0048] Please see Figure 1 and Figure 6 In this embodiment, the diversion mechanism includes a hollow box 29, an inlet pipe 30, an outlet pipe 31, and a first valve body 32. The hollow box 29 is fixedly connected to the upper end of the base plate 1. The inlet pipe 30 and multiple outlet pipes 31 are fixedly connected through the side end of the hollow box 29. The first valve body 32 is provided on the outlet pipe 31. The outlet pipe of the water pump 3 is connected to the inlet pipe 30, and the pumping pipe of the water pump 3 is connected to the second fixed pipe 35. The inlet pipe 30 on the hollow box 29 can receive the water-fertilizer mixture delivered by the water pump 3. The multiple outlet pipes 31 are independently controlled by the first valve body 32 to achieve precise distribution of one input and multiple outputs. It forms a closed-loop water system with the water pump 3 and the water tank 2, which can provide a basis for flow regulation for differentiated spraying of different nozzles.
[0049] Please see Figure 1 and Figure 7 In this embodiment, the water spraying mechanism includes a long pipe 38, a third nozzle 39, and a mounting base 40. Multiple mounting bases 40 are fixedly connected to the upper end of the long block 13. The long pipe 38 is fixedly connected to the inner wall of the multiple mounting bases 40. Multiple third nozzles 39 are installed on the long pipe 38. The lower end of the long pipe 38 is a water inlet. The long pipe 38 is securely installed on the upper end of the long block 13 through the mounting bases 40. The multiple third nozzles 39 are evenly distributed along the long pipe 38. The lower water inlet is connected to the water outlet pipe 31 of the diversion mechanism to form a multi-point spraying structure at the top, which improves the spraying capacity.
[0050] Please see Figure 1In this embodiment, the two uprights 5 are symmetrical about the electric cylinder 6. The upper end of the uprights 5 is higher than the upper end of the output shaft of the electric cylinder 6, which provides sufficient travel space for the lifting block 7 to slide up and down.
[0051] Please see Figure 1 and Figure 7 In this embodiment, the lower end of the first fixed pipe 14 is open, and a second nozzle 37 is fixedly connected to the side wall of the first fixed pipe 14. The second nozzle 37 fixedly connected to the side wall of the first fixed pipe 14 can realize lateral fan-shaped spraying. The water and fertilizer utilization efficiency is improved by the differentiated layout of the nozzle positions.
[0052] Please see Figure 1 In this embodiment, the moving mechanism includes casters and push rods. Casters are fixed to the four corners of the lower end of the base plate 1, and push rods are fixed to the side walls of the base plate 1, making it convenient for the user to push the device.
[0053] Example 2: Please refer to Figure 4 This application provides a technical solution: the detachable structure consists of a screw groove 21 and a threaded post 22. The inner wall of the sleeve frame 17 is provided with equally spaced screw grooves 21. A threaded post 22 is threadedly installed on the inner wall of one of the screw grooves 21. One end of the threaded post 22 is fixed to the side wall of the mounting block 18, and a nut 23 is threadedly installed on the other end of the side wall of the threaded post 22. The screw grooves 21 and the threaded post 22 are connected by a thread, which is simple in structure and highly reliable. The equally spaced screw grooves 21 allow the mounting block 18 to be adjusted in position within the circumferential range of the sleeve frame 17 to meet different spraying angle requirements. One end of the threaded post 22 is fixed to the mounting block 18, and the other end is locked by the nut 23, forming a detachable and stable connection structure, which facilitates the quick disassembly and maintenance of the mounting block 18 and the first nozzle 20.
[0054] Working principle: When in use, first move the equipment to the designated position by the universal wheels at the four corners of the bottom of the base plate 1 and the push rod on the side wall. Then, turn on the electric cylinder 6 to drive the lifting block 7 to move upward along the two uprights 5. Since the bearing ring 10, the fixed block 11 and the first fixed tube 14 are fixed, the adjusting block 8 will drive the long block 13 to rotate around the U-shaped block 12, thereby realizing the position adjustment of the long block 13.
[0055] During this process, the sleeve 17 is fitted onto the first short rod 15 on the side wall of the first fixed pipe 14 and the second short rod 16 on the side wall of the long block 13. As the long block 13 rotates, it slides directionally along the side wall of the double short rods. It is constrained by the first limiting ring 24 on the side wall of the first short rod 15 and the second limiting ring 25 on the side wall of the second short rod 16, maintaining a precise position and angle. This allows the angle of the sleeve 17 to change, which in turn drives the angle of the mounting block 18, the mounting pipe 19 and the first nozzle 20 to change, so as to meet the spraying needs of more angles.
[0056] Meanwhile, the circumferential position of the mounting block 18 on the sleeve 17 can be adjusted as needed through the threaded connection between the screw groove 21 and the threaded post 22, and then locked and fixed with the nut 23.
[0057] When water is needed, the water pump 3 draws water from the water tank 2 through the second fixed pipe 35. The water injection pipe 33 on the side wall of the water tank 2 is connected to an external water source or fertilizer pipeline through a pipe to deliver the water-fertilizer mixture to the diversion mechanism on the bottom plate 1. After receiving the mixture, the water inlet pipe 30 at the side end of the hollow box 29 independently controls the opening and closing of the liquid through multiple water outlet pipes 31 and the first valve body 32 to distribute the liquid to the opening end of the mounting pipe 19 and the spraying mechanism at the top end of the long block 13. The first nozzle 20 at the other end of the mounting pipe 19 and the second nozzle 37 on the side wall of the first fixed pipe 14 can realize lateral and fan-shaped spraying at different angles. In the spraying mechanism, the long pipe 38 is fixed to the top end of the long block 13 through the mounting base 40, and its multiple third nozzles 39 form a top multi-point spraying structure to realize multi-directional spraying.
[0058] The power required for the equipment to operate is provided by solar panels. Solar panels 28 are fixed to the upper end of control box 27 and convert light energy into direct current. The solar controller inside control box 27 adjusts the input voltage in real time to protect the built-in battery from overcharging and discharging damage. The inverter converts the direct current of the battery into alternating current to power the electric cylinder 6, water pump 3 and other equipment, thereby realizing the overall operation of the equipment.
Claims
1. A water and fertilizer integrated fertilization device for orchards, comprising a base plate (1), a water tank (2), a water pump (3), a base block (4), and a fixing column (9) fixedly connected to the upper end of the base plate (1); characterized in that: The upper end of the bottom block (4) is fixed with an electric cylinder (6) and two uprights (5). The side walls of the two uprights (5) are fitted with lifting blocks (7). The two sides of the lifting blocks (7) are respectively hinged to one end of the adjusting blocks (8). The upper end of the fixed column (9) is fixed to the bearing ring (10), and two fixed blocks (11) are fixed to the side wall of the bearing ring (10). The side ends of each fixed block (11) are respectively fixed to the first fixed tube (14), and a U-shaped block (12) is hinged on the fixed block (11). The side end of the U-shaped block (12) is fixed to the long block (13), and the other end of the adjusting block (8) is hinged to the lower end of the long block (13). The first fixed tube (14) is fixed to the side wall of the first short rod (15), and the long block (13) is fixed to the side wall of the second short rod (16). The side walls of the first short rod (15) and the second short rod (16) are fitted with a sleeve frame (17), and the sleeve frame (17) is connected to the mounting block (18) through a detachable structure. Mounting pipe (19) is fixedly connected to mounting block (18), with one end of mounting pipe (19) open and the other end fixedly connected to first nozzle (20); The upper end of the long block (13) is equipped with a water spraying mechanism; A diversion mechanism is provided on the base plate (1), and the diversion mechanism is connected to the outlet end of the water pump (3) and the opening end of the installation pipe (19) through pipes respectively; A moving mechanism is provided at the lower end of the base plate (1).
2. The orchard fertigation equipment according to claim 1, characterized in that: The detachable structure consists of a screw groove (21) and a threaded post (22). The inner wall of the sleeve (17) is provided with equally spaced screw grooves (21). A threaded post (22) is threadedly installed on the inner wall of one of the screw grooves (21). One end of the threaded post (22) is fixed to the side wall of the mounting block (18), and a nut (23) is threadedly installed on the other end of the side wall of the threaded post (22).
3. The orchard fertigation equipment according to claim 1, characterized in that: Solar modules are installed on two uprights (5). The solar modules include a fixed cylinder (26), a control box (27), and a solar panel (28). The side walls of the two uprights (5) are fixed with a fixed cylinder (26). The side walls of the fixed cylinder (26) are fixed with a connecting block. The side walls of the two connecting blocks are fixed with a control box (27). The upper end of the control box (27) is fixed with a solar panel (28). The control box (27) contains a solar controller, a battery, and an inverter.
4. The orchard fertigation equipment according to claim 1, characterized in that: The first short rod (15) is fixed to the side wall with a first limiting ring (24), and the second short rod (16) is fixed to the side wall with a second limiting ring (25). The end of the first limiting ring (24) near the first fixed tube (14) is in contact with the end of the sleeve frame (17) away from the first fixed tube (14), and the end of the second limiting ring (25) near the long block (13) is in contact with the end of the sleeve frame (17) away from the long block (13). When the sleeve frame (17) moves, both the first limiting ring (24) and the second limiting ring (25) can cover the groove part of the sleeve frame (17).
5. The orchard fertigation equipment according to claim 1, characterized in that: The side wall of the water tank (2) is equipped with a water injection pipe (33) and a second fixed pipe (35). A second valve body (34) is provided on the water injection pipe (33), and a third valve body (36) is provided on the second fixed pipe (35).
6. The orchard fertigation equipment according to claim 1, characterized in that: The diversion mechanism includes a hollow box (29), an inlet pipe (30), an outlet pipe (31), and a first valve body (32). The hollow box (29) is fixedly connected to the upper end of the base plate (1). The inlet pipe (30) and multiple outlet pipes (31) are fixedly connected through the side end of the hollow box (29). The first valve body (32) is installed on the outlet pipe (31). The outlet pipe of the water pump (3) is connected to the inlet pipe (30), and the pumping pipe of the water pump (3) is connected to the second fixed pipe (35).
7. The orchard fertigation equipment according to claim 1, characterized in that: The water spraying mechanism includes a long pipe (38), a third nozzle (39) and a mounting base (40). Multiple mounting bases (40) are fixed to the upper end of the long block (13). The long pipe (38) is fixed to the inner wall of the multiple mounting bases (40). Multiple third nozzles (39) are installed on the long pipe (38). The lower end of the long pipe (38) is the water inlet.
8. The orchard fertigation equipment according to claim 1, characterized in that: The two uprights (5) are symmetrical about the electric cylinder (6), and the upper end of the uprights (5) is higher than the upper end of the output shaft of the electric cylinder (6).
9. The orchard fertigation equipment according to claim 1, characterized in that: The lower end of the first fixed tube (14) is open, and the second nozzle (37) is fixed to the side wall of the first fixed tube (14).
10. The orchard fertigation equipment according to claim 1, characterized in that: The moving mechanism includes casters and push rods. Casters are fixed to the four corners of the lower end of the base plate (1), and push rods are fixed to the side walls of the base plate (1).