Water conservancy construction water conservancy irrigation equipment
By incorporating features such as a limit frame, a storage plate, snap-fit installation, and a rotating seal, the problem of swaying and damage to the conduit during equipment movement has been solved, thus achieving stability and adaptability of the irrigation equipment and improving irrigation quality and water resource utilization.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUBEI SHUITOU WATER RESOURCES & HYDROPOWER ENG CO LTD
- Filing Date
- 2025-07-31
- Publication Date
- 2026-07-14
Smart Images

Figure CN224482455U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of irrigation technology, specifically to a water conservancy irrigation device for water conservancy construction. Background Technology
[0002] In the field of water conservancy construction, irrigation equipment is a key tool for ensuring the smooth progress of projects and the normal growth of surrounding vegetation and crops. With the increasing complexity and diversification of water conservancy construction projects, higher demands are being placed on the functionality, stability, and adaptability of irrigation equipment. However, existing irrigation equipment still faces many problems in practical applications, which seriously affect irrigation efficiency and effectiveness, hindering the efficient implementation of water conservancy construction.
[0003] At water conservancy construction sites, the operating environment of equipment is complex and variable. As a critical component for water delivery, the guide pipe needs to maintain a relatively stable position to ensure smooth water flow to the sprinklers. However, the guide pipe limiting devices in existing irrigation equipment are often quite simple, failing to provide sufficient support and restraint. During equipment movement, the guide pipe is easily shaken, displaced, or even detached due to external forces (such as collisions with other equipment or bumps caused by uneven ground). This not only leads to uneven irrigation and affects irrigation quality but may also cause equipment failure, increasing maintenance costs and the risk of construction delays. Furthermore, existing equipment lacks adequate protection for the guide pipe. During equipment movement, surrounding debris (such as stones and clods of soil) can easily collide with the guide pipe, causing damage or affecting its normal operation. Utility Model Content
[0004] To address the shortcomings of existing technologies, this utility model provides a water conservancy irrigation device for water conservancy construction, which solves the problems mentioned in the background art.
[0005] The solution of this utility model to the above-mentioned technical problems is as follows:
[0006] A water conservancy construction irrigation device, comprising:
[0007] A mobile platform with wheels on both sides and a fixed base on the mobile platform;
[0008] A limiting frame, which is provided with a base and is installed on a mobile platform by cooperating with a fixed seat through the base to limit its position; the limiting frame is a square pyramid shape.
[0009] The conduit is mounted on the moving platform by the limiting frame and is located on the center line of the limiting frame. A rotating seal is installed at the top of the conduit and a connecting pipe is rotatably connected through the rotating seal. A valve is installed at the bottom of the conduit and a nozzle is installed through the valve.
[0010] Based on the above technical solution, the present invention can be further improved as follows.
[0011] Furthermore, the limiting frame is provided with a placement plate, which is used to assist in limiting the position of the catheter.
[0012] The beneficial effects of adopting the above-mentioned further solutions are:
[0013] During equipment operation, the conduit needs to maintain a relatively stable position to ensure that water can flow smoothly through the conduit to the sprinkler head. The mounting plate on the limiting frame provides additional support and limiting for the conduit, preventing it from shaking, shifting, or even falling off when the equipment moves or is subjected to external forces. This ensures the stability and continuity of irrigation operations and avoids problems such as uneven irrigation or equipment failure caused by abnormal conduit positioning.
[0014] Furthermore, the shelf is provided with side panels around its perimeter, and the side panels are provided with windows.
[0015] The beneficial effects of adopting the above-mentioned further solutions are:
[0016] The side panels provide some protection for the conduits placed on the shelf, preventing them from being damaged or affected by surrounding debris or tools during equipment movement. Additionally, the windows on the side panels serve multiple purposes. Firstly, the windows allow staff to easily observe the conduits' placement on the shelf, promptly identifying any loosening, twisting, or other abnormalities for timely adjustment and maintenance.
[0017] Furthermore, the fixed base and the base foot adopt a snap-fit structure to achieve limited installation.
[0018] The beneficial effects of adopting the above-mentioned further solutions are:
[0019] The snap-fit structure offers the advantage of convenient installation and disassembly. When installing the limit frame, workers simply align the base of the limit frame with the fixed seat and press gently to complete the installation, eliminating the need for complex tools or tedious operations, significantly saving installation time and labor costs. When maintenance, replacement, or repositioning of the limit frame is required, it can also be easily removed from the fixed seat. Furthermore, the snap-fit structure ensures a stable connection between the limit frame and the mobile platform, effectively preventing the limit frame from shaking or falling off during equipment movement and irrigation, ensuring the stability and reliability of the entire equipment structure.
[0020] Furthermore, the rotary seal includes a static sealing ring and a dynamic sealing ring that cooperate with each other. The static sealing ring is fixedly connected to the top end of the conduit, and the dynamic sealing ring is fixedly connected to the connecting pipe.
[0021] The beneficial effects of adopting the above-mentioned further solutions are:
[0022] During equipment movement, the connecting pipe needs to rotate with the equipment's direction and angle of movement, while the conduit needs to maintain a relatively fixed position to stably deliver water. The rotating seal design cleverly solves this contradiction. The static sealing ring is fixedly connected to the top of the conduit, while the dynamic sealing ring is fixedly connected to the connecting pipe. When the connecting pipe rotates, the dynamic sealing ring rotates relative to the static sealing ring, but the sealing surfaces between the two always remain tightly fitted, effectively preventing water leakage at the connection point. This not only improves water resource utilization and reduces irrigation costs but also ensures the continuity of water supply during equipment movement, enabling continuous and stable irrigation operations and avoiding problems such as irrigation interruptions or poor irrigation results due to water leakage.
[0023] Furthermore, the valve is a ball valve structure with adjustable flow, and the nozzle is a replaceable structure, including at least one of a rotary nozzle, a fan-shaped nozzle, or an atomizing nozzle.
[0024] The beneficial effects of adopting the above-mentioned further solutions are:
[0025] The adjustable flow ball valve structure allows operators to flexibly adjust the valve opening based on factors such as the size and shape of the irrigation area, the water requirements of the crop, and the speed of equipment movement, thereby achieving precise control of water flow. This helps meet the needs of different irrigation scenarios, avoids water waste, and improves irrigation efficiency. The sprinkler heads are replaceable and include various types, such as rotary sprinklers for large-area, uniform irrigation; fan-shaped sprinklers for irrigating narrow areas; and atomizing sprinklers for applications requiring high irrigation precision and uniform, fine spraying. Operators can easily change to suitable sprinklers according to actual irrigation needs, greatly improving the equipment's applicability and enabling it to adapt to various irrigation tasks and meet diverse irrigation requirements.
[0026] Furthermore, the wheel is a rubber wheel with anti-slip treads and is equipped with a braking device.
[0027] The beneficial effects of adopting the above-mentioned further solutions are:
[0028] Rubber wheels with anti-slip treads increase tire-to-ground friction, allowing the equipment to move easily across various terrains, such as muddy farmland and uneven construction sites, improving its maneuverability and adaptability. The rubber material itself has a degree of elasticity, cushioning bumps during movement, reducing impact on internal components, and extending the equipment's lifespan. Simultaneously, the equipped braking system can bring the equipment to a complete stop at any time, ensuring safety and stability during irrigation. When the equipment reaches a designated location or irrigation needs to be paused, workers can quickly secure it using the braking system to prevent it from continuing to move due to inertia, which could affect irrigation efficiency or cause safety accidents.
[0029] This utility model provides a water conservancy irrigation device for water conservancy construction. It has the following beneficial effects:
[0030] The rotary seal installed at the top of the conduit consists of a stationary sealing ring and a dynamic sealing ring that cooperate with each other. The stationary sealing ring is fixedly connected to the top of the conduit, while the dynamic sealing ring is fixedly connected to the connecting pipe. When the connecting pipe rotates with the movement of the equipment, the dynamic sealing ring rotates relative to the stationary sealing ring, but the sealing surfaces between the two remain tightly fitted to prevent water leakage. This rotary seal design cleverly resolves the contradiction between the rotation of the connecting pipe and the sealing of the water source during equipment movement.
[0031] Thanks to the rotary seal, the connecting pipe can rotate freely during equipment movement, ensuring a continuous water supply. Simultaneously, the adjustable flow valve allows operators to adjust the water flow in real time based on the moving speed and the conditions of the irrigated area. During movement, water continuously sprays from the nozzles, achieving uniform irrigation while the equipment is in motion. Attached Figure Description
[0032] The accompanying drawings, which are included to provide a further understanding of the present invention and form part of this application, illustrate exemplary embodiments of the present invention and are used to explain the present invention, but do not constitute an undue limitation of the present invention.
[0033] In the attached diagram:
[0034] Figure 1 This is a schematic diagram of the main appearance of this utility model;
[0035] Figure 2 This is a schematic diagram of the main appearance of the limiting frame of this utility model;
[0036] Figure 3 This is a bottom view of the limiting frame of this utility model.
[0037] The attached diagram lists the components represented by each number as follows:
[0038] 1. Mobile platform; 101. Fixed base; 102. Wheels; 2. Conduit; 201. Rotary seal; 202. Valve; 203. Nozzle; 3. Connecting pipe; 4. Limiting frame; 401. Window; 402. Shelf; 403. Side plate; 404. Foot. Detailed Implementation
[0039] 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.
[0040] Please see Figures 1 to 3 As shown, the embodiments provided by this utility model are as follows:
[0041] Example 1
[0042] A water conservancy construction irrigation device, comprising:
[0043] The mobile platform 1 is equipped with wheels 102 on both sides. The wheels 102 are rubber tires with anti-slip treads and are equipped with brakes. The anti-slip treads increase the friction between the tires and the ground, allowing the equipment to move easily on various terrains, such as muddy farmland and uneven construction sites, improving its passability and adaptability. The rubber material itself has a certain degree of elasticity, which can cushion bumps during movement, reduce impact on internal components, and extend the equipment's service life. Simultaneously, the brakes can bring the equipment to a stop at any time, ensuring safety and stability during irrigation. When the equipment reaches a designated location or irrigation needs to be paused, workers can quickly secure the equipment using the brakes to prevent it from continuing to move due to inertia, which could affect irrigation efficiency or cause safety accidents. The mobile platform 1 is equipped with a fixed base 101.
[0044] The limiting frame 4 is provided with a base 404 and is installed on the mobile platform 1 by cooperating with the fixed seat 101 through the base 404. The limiting frame 4 is a square pyramid shape.
[0045] The conduit 2 is mounted on the mobile platform 1 via the limiting frame 4 and is located on the center line of the limiting frame 4. A rotating seal 201 is installed at the top of the conduit 2 and a connecting pipe 3 is rotatably connected to it through the rotating seal 201. A valve 202 is installed at the bottom of the conduit 2 and a nozzle 203 is installed through the valve 202.
[0046] Example 2
[0047] To further improve the operational stability of the equipment in complex construction environments and effectively protect the conduit, for example, such as Figures 1 to 3 As shown, this utility model also includes:
[0048] The limiting frame 4 is equipped with a shelf 402, which assists in limiting the position of the conduit 2. During equipment operation, the conduit 2 needs to maintain a relatively stable position to ensure that water can flow smoothly from the conduit 2 to the nozzle 203. The shelf 402 on the limiting frame 4 provides additional support and limiting for the conduit 2, preventing it from shaking, shifting, or even falling off when the equipment moves or is subjected to external forces. This ensures the stability and continuity of irrigation operations and avoids problems such as uneven irrigation or equipment failure caused by abnormal conduit 2 positioning. Side plates 403 are provided around the shelf 402, and windows 401 are provided on the side plates 403. The side plates 403 provide a certain degree of protection for the conduit 2 placed on the shelf 402, preventing surrounding debris or tools from colliding with the conduit 2 during equipment movement, thus preventing damage or affecting its normal operation. At the same time, the windows 401 on the side plates 403 have multiple functions. Window 401 allows staff to easily observe the placement of the guide tube 2 on the shelf 402, promptly identifying any abnormalities such as loosening or twisting, and facilitating timely adjustments and maintenance. The limiting bracket 4 is installed using a snap-fit structure between the fixing seat 101 and the base 404, offering convenient installation and disassembly. When installing the limiting bracket 4, staff simply align the base 404 of the limiting bracket 4 with the fixing seat 101 and gently press to complete the installation, eliminating the need for complex tools or cumbersome operations, significantly saving installation time and labor costs. When maintenance, replacement, or repositioning of the limiting bracket 4 is required, it can also be easily removed from the fixing seat 101. Furthermore, the snap-fit structure ensures the stable connection between the limiting bracket 4 and the mobile platform 1, effectively preventing the limiting bracket 4 from shaking or falling off during equipment movement and irrigation, ensuring the stability and reliability of the entire equipment structure.
[0049] Example 3
[0050] To optimize the water delivery efficiency and irrigation adaptability of equipment, and to better meet the diverse irrigation needs of water conservancy construction, for example, such as Figures 1 to 3 As shown, this utility model also includes:
[0051] The rotary seal 201 comprises a stationary sealing ring and a dynamic sealing ring that cooperate with each other. The stationary sealing ring is fixedly connected to the top of the conduit 2, and the dynamic sealing ring is fixedly connected to the connecting pipe 3. During equipment movement, the connecting pipe 3 needs to rotate with the direction and angle of equipment movement, while the conduit 2 needs to maintain a relatively fixed position to stably deliver water. The design of the rotary seal 201 cleverly solves this contradiction. The stationary sealing ring is fixedly connected to the top of the conduit 2, and the dynamic sealing ring is fixedly connected to the connecting pipe 3. When the connecting pipe 3 rotates, the dynamic sealing ring rotates relative to the stationary sealing ring, but the sealing surfaces between the two remain tightly fitted, effectively preventing water leakage at the connection point. This not only improves water resource utilization and reduces irrigation costs, but also ensures the continuity of water supply during equipment movement, enabling irrigation operations to proceed continuously and stably, and avoiding problems such as irrigation interruption or poor irrigation effect caused by water leakage. Valve 202 is an adjustable flow ball valve, and nozzle 203 is a replaceable type, including at least one of a rotary nozzle, a fan-shaped nozzle, or a misting nozzle. The adjustable flow ball valve structure allows operators to flexibly adjust the opening of valve 202 according to factors such as the size and shape of the irrigation area, the water requirements of the crop, and the speed of equipment movement, thereby achieving precise control of water flow. This helps meet the needs of different irrigation scenarios, avoids water waste, and improves irrigation efficiency. The replaceable nozzle 203 includes various types, such as rotary nozzles 203 suitable for large-area, uniform irrigation; fan-shaped nozzles 203 suitable for irrigating narrow areas; and misting nozzles 203 suitable for applications requiring high irrigation precision and uniform, fine spraying. Operators can easily replace the appropriate nozzle 203 according to actual irrigation needs, greatly improving the equipment's applicability and enabling it to adapt to various irrigation tasks and meet diverse irrigation requirements.
[0052] Working principle:
[0053] The staff first pushes the irrigation equipment to the starting position of the area to be irrigated. The rubber wheels with anti-slip textures on both sides of the mobile platform 1, thanks to their increased friction and anti-slip design, allow the equipment to easily adapt to different road conditions and move conveniently, while the braking device can stop the equipment at any time. Once in the appropriate position, the limiting frame 4 is securely installed on the mobile platform 1 using the snap-fit structure between the fixed base 101 and the base 404 of the limiting frame 4. The four-sided pyramidal structure of the limiting frame 4 provides reliable support for subsequent components. Next, the conduit 2 is mounted on the mobile platform 1 via the limiting frame 4 and positioned at the center line. The shelf 402 of the limiting frame 4 serves as an auxiliary limiting element, while the side panels 403 and window 401 provide protection and auxiliary functions.
[0054] Next, connect the connecting pipe 3 to the external water source pipe. The connecting pipe 3 is connected to the top of the conduit 2 via a rotating seal 201. The rotating seal 201 consists of a static sealing ring and a dynamic sealing ring. The static sealing ring is fixed to the top of the conduit 2, and the dynamic sealing ring is fixed to the connecting pipe 3. This design allows the connecting pipe 3 to rotate freely within a certain range while ensuring a good seal at the connection to prevent water leakage.
[0055] Open valve 202 at the bottom of conduit 2. This valve 202 is an adjustable flow ball valve structure, which allows operators to control the water flow according to irrigation needs. Water enters conduit 2 from connecting pipe 3 and then flows to sprinkler head 203. Sprinkler head 203 is replaceable and comes in various types, such as rotary sprinkler head 203, fan-shaped sprinkler head 203, or atomizing sprinkler head 203. Operators can select the appropriate sprinkler head 203 based on the characteristics of the irrigation area and the needs of the crop.
[0056] At this point, the staff pushes the equipment to begin moving, and water continues to spray from the nozzle 203 during the movement. Due to the rotating seal 201, the connecting pipe 3 can rotate flexibly with the direction and angle of the equipment's movement, ensuring a continuous water supply. Simultaneously, the adjustable flow valve 202 allows the staff to adjust the water flow in real time according to the moving speed and the irrigation area, achieving uniform irrigation while moving. For example, when the equipment moves quickly through a large open area, the flow rate of valve 202 can be appropriately increased to ensure that the large area receives sufficient irrigation; when passing through areas with dense crops and precise irrigation needs, the flow rate of valve 202 can be decreased to achieve precise irrigation.
[0057] After irrigating the current area, close valve 202 to stop the water supply. If other areas need to be irrigated, workers can move the equipment to the new area and repeat the above operation, continuing irrigation during the move.
[0058] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. It will be apparent to those skilled in the art that this utility model is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or basic characteristics of this utility model. Therefore, the embodiments should be considered exemplary and non-limiting in all respects. The scope of this utility model is defined by the appended claims rather than the foregoing description, and thus all variations falling within the meaning and scope of equivalents of the claims are intended to be included within this utility model. No reference numerals in the claims should be construed as limiting the scope of the claims.
[0059] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.
Claims
1. A water conservancy irrigation device for water conservancy construction, characterized in that, include: A mobile platform (1) is equipped with wheels (102) on both sides, and a fixed seat (101) is provided on the mobile platform (1); The limiting frame (4) is provided with a base (404) and is installed on the mobile platform (1) by cooperating with the fixed seat (101) through the base (404). The limiting frame (4) is a square pyramid shape. The conduit (2) is mounted on the mobile platform (1) via the limiting frame (4) and is located on the center line of the limiting frame (4). A rotating seal (201) is installed at the top of the conduit (2) and a connecting pipe (3) is rotatably connected through the rotating seal (201). A valve (202) is installed at the bottom of the conduit (2) and a nozzle (203) is installed through the valve (202).
2. The irrigation equipment for water conservancy construction according to claim 1, characterized in that: The limiting frame (4) is provided with a placement plate (402), which is used to assist in limiting the conduit (2).
3. The irrigation equipment for water conservancy construction according to claim 2, characterized in that: The shelf (402) is provided with side panels (403) around its perimeter, and the side panels (403) are provided with windows (401).
4. The irrigation equipment for water conservancy construction according to claim 1, characterized in that: The fixed base (101) and the base (404) adopt a snap-fit structure to achieve limited installation.
5. The irrigation equipment for water conservancy construction according to claim 1, characterized in that: The rotary seal (201) includes a static sealing ring and a dynamic sealing ring that cooperate with each other. The static sealing ring is fixedly connected to the top end of the conduit (2), and the dynamic sealing ring is fixedly connected to the connecting pipe (3).
6. The irrigation equipment for water conservancy construction according to claim 1, characterized in that: The valve (202) is a ball valve structure with adjustable flow rate, and the nozzle (203) is a replaceable structure, including at least one of a rotary nozzle, a fan-shaped nozzle, or an atomizing nozzle.
7. The irrigation equipment for water conservancy construction according to claim 1, characterized in that: The wheel (102) is a rubber wheel with anti-slip treads and is equipped with a braking device.