Intelligent water conservancy utilizes remote control water gate
By introducing a lifting mechanism and radar flow meter into the sluice gate, smart water conservancy utilizes remote control of the sluice gate to solve the problem of filter screen blockage affecting water flow, realizes automated cleaning, and improves the operating efficiency and safety of the sluice gate.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI YIFAN WATER CONSERVANCY CONSTR SUPERVISION CO LTD
- Filing Date
- 2025-06-16
- Publication Date
- 2026-06-23
AI Technical Summary
During operation, the existing sluice gate's filter screen becomes clogged, affecting water flow and requiring shutdown for cleaning. This disrupts normal use and poses a safety hazard.
Design a smart water conservancy system that utilizes a remotely controlled sluice gate. Employ a lifting mechanism and radar flow meter within the filter housing. The radar flow meter monitors water flow and automatically controls the lifting mechanism to clear blockages in the central perforated mesh plate. A brush is then used for cleaning, achieving automatic cleaning without human intervention.
It enables automatic cleaning of the filter screen without affecting the water flow, avoiding the safety hazards of stopping the machine for cleaning, and improving the efficiency and safety of the sluice gate.
Smart Images

Figure CN224395504U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of sluice gate control technology, specifically to a smart water conservancy system that utilizes remote control of sluice gates. Background Technology
[0002] Water conservancy projects utilize and regulate groundwater and surface water to maximize benefits and minimize harm. They are beneficial projects that can efficiently and conveniently utilize water resources. In the construction of water conservancy projects, the construction of river channels is crucial. As the connecting points between rivers, between rivers and fields, and between rivers and lakes, river channels play a vital role in facilitating the construction of water conservancy projects. To facilitate control and use, smart water utilization control sluice gates are now widely used. However, during the opening of the sluice gates, colloids and large solid waste are discharged along with the water flow. Excessive garbage scattered on the water surface can affect the subsequent dredging work and progress.
[0003] To address the aforementioned problems, existing sluice gates incorporate filtration components such as filters. For example, Chinese Patent [Application No. CN202322533561.5] discloses an intelligent water conservancy project spillway gate, comprising: a gate base; a support frame fixedly connected to the top of the gate base; a clamping frame movably connected to the top of the gate base; a filter box fixedly installed inside the gate base; a filter screen fixedly connected inside the filter box; a discharge pipe fixedly connected to the top of the filter box; and an interface fixedly connected to the top of the discharge pipe. The clamping frame is fixedly connected to one side. Although the patent can provide protection through the anti-friction frame and avoid friction damage between the gate structures, and the clamping frame and the gate are movably connected, it is convenient to replace the anti-friction frame structure regularly, increasing the practicality of this type of intelligent water conservancy project spillway gate. However, the above patent has certain defects in use. For example, if the filter screen becomes clogged during use, it will affect the water flow. When the filter screen needs to be cleaned, the gate needs to be lowered to ensure the safety of the staff, which will affect the normal use of the sluice gate. Utility Model Content
[0004] The purpose of this utility model is to address the shortcomings of existing technologies by proposing a smart water conservancy system that utilizes remotely controlled sluice gates.
[0005] To achieve the above objectives, this utility model provides the following technical solution:
[0006] A smart water conservancy system utilizes a remotely controlled sluice gate, comprising a gate body and a filter housing installed on the right side of the gate body. The top of the filter housing has two sets of sliding grooves, with mounting frames slidably connected inside each groove. A central perforated mesh plate is fixedly installed inside each mounting frame. The top of the filter housing is fixedly connected to two sets of lifting mechanisms, each fixedly connected to one of the two mounting frames. The inside of the filter housing is fixedly installed with two sets of radar flow meters, each located to the right of one of the two central perforated mesh plates. The top of the filter housing is fixedly connected to a cleaning mechanism. The lifting mechanisms and radar flow meters are electrically connected to an external controller.
[0007] Preferably, the lifting mechanism includes a connecting frame (61) fixedly connected to the filter housing. A lead screw is rotatably connected inside the connecting frame, and a slider is threadedly connected to the outer surface of the lead screw. A guide rod is fixedly connected inside the connecting frame, and a connecting block is slidably connected to the outer surface of the guide rod. The connecting block is fixedly connected to the slider. A drive motor is fixedly installed at the bottom of the connecting frame. The output end of the drive motor is fixedly connected to the lead screw through a coupling. One side of the slider in each of the two sets of lifting mechanisms is fixedly connected to one of the two sets of mounting frames, and the drive motor is electrically connected to an external controller.
[0008] Preferably, the cleaning mechanism includes a mounting plate fixedly connected to the top of the filter housing, and brushes are fixedly mounted on both sides of the mounting plate.
[0009] Preferably, a battery connected to a drive motor is installed on the top of the filter housing.
[0010] The beneficial effects of this utility model are as follows: The intelligent water conservancy system utilizing a remotely controlled sluice gate provided by this utility model allows for drainage when the gate in the sluice gate body rises. The water passes through the sluice gate body and then through the filter housing before being discharged. Debris in the water flow is blocked and filtered out by the central perforated mesh plate. During this process, the radar flow meter transmits signals to the external controller. When the data from the radar flow meter on the left is normal while the data from the radar flow meter on the right is abnormal, it indicates that the central perforated mesh plate on the right is blocked. Then, the external controller activates the lifting mechanism connected to the right-side mounting frame, causing the mounting frame to move the central perforated mesh plate. As the flow meter rises, the brush cleans the central perforated mesh plate. The bristles on the brush can also pass through the holes in the central perforated mesh plate to clean it. If the data from both sets of radar flow meters are abnormal, it indicates that the central perforated mesh plate on the left is blocked. Simply activate the lifting mechanism connected to the mounting frame on the left. While the central perforated mesh plate is being cleaned, the other set of central perforated mesh plates can continue to block debris in the water flow without affecting drainage. By setting up two sets of radar flow meters on one side of the two sets of central perforated mesh plates, it is possible to determine whether the central perforated mesh plate is blocked. Attached Figure Description
[0011] Figure 1 This is a schematic diagram of the basic structure of this utility model;
[0012] Figure 2 This is a cross-sectional view of the present invention;
[0013] Figure 3 This is a schematic diagram of the lifting mechanism of this utility model. Detailed Implementation
[0014] 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.
[0015] In the description of this utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc., indicating the orientation or positional relationship are based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing this utility model and simplifying the description, and are not intended to indicate or imply that the device or component referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model.
[0016] like Figure 1 - Figure 3As shown, this utility model provides a smart water conservancy system utilizing a remotely controlled sluice gate, comprising a gate body 1 and a filter housing 2 installed on the right side of the gate body 1. The top of the filter housing 2 has two sets of sliding grooves 3, with mounting frames 4 slidably connected inside the grooves 3. A central perforated mesh plate 5 is fixedly installed inside the mounting frames 4. Two sets of lifting mechanisms 6 are fixedly connected to the top of the filter housing 2, and are respectively fixedly connected to the two sets of mounting frames 4. Two sets of radar flow meters 7 are fixedly installed inside the filter housing 2, located to the right of the two sets of central perforated mesh plates 5. A cleaning mechanism is fixedly connected to the top of the filter housing 2. The lifting mechanisms 6 and the radar flow meters 7 are electrically connected to an external controller. When the gate in the gate body 1 rises, drainage begins. The water passes through the gate body 1 and then through the filter housing 2 before being discharged. Debris in the water flow is blocked and filtered out by the central perforated mesh plate 5. During this process, the radar flow meter 7 transmits a signal to the external controller. When the data of the radar flow meter 7 on the left is normal but the data of the radar flow meter 7 on the right is abnormal, it indicates that the middle hollow mesh plate 5 on the right is blocked. Then, the external controller starts the lifting mechanism 6 connected to the right mounting frame 4, causing the mounting frame 4 to lift the middle hollow mesh plate 5. During the lifting process, the brush 9 cleans the middle hollow mesh plate 5. The bristles on the brush 9 can also pass through the holes on the middle hollow mesh plate 5 to clean it. If the data of both sets of radar flow meters 7 are abnormal, it indicates that the middle hollow mesh plate 5 on the left is blocked. The lifting mechanism 6 connected to the mounting frame 4 on the left can be started. During the cleaning of the middle hollow mesh plate 5, the other set of middle hollow mesh plates 5 can continue to block the debris in the water flow without affecting the drainage.
[0017] The lifting mechanism 6 includes a connecting frame 61 fixedly connected to the filter housing 2. A lead screw 62 is rotatably connected inside the connecting frame 61, and a slider 63 is threadedly connected to the outer surface of the lead screw 62. A guide rod 64 is fixedly connected inside the connecting frame 61, and a connecting block 65 is slidably connected to the outer surface of the guide rod 64. The connecting block 65 is fixedly connected to the slider 63. A drive motor 66 is fixedly installed at the bottom of the connecting frame 61. The output end of the drive motor 66 is fixedly connected to the lead screw 62 through a coupling. One side of the slider 63 in the two sets of lifting mechanisms 6 is fixedly connected to the two sets of mounting frames 4 respectively. The drive motor 66 is electrically connected to an external controller. By starting the drive motor 66, the lead screw 62 can be rotated, causing the slider 63 to move the mounting frame 4.
[0018] The cleaning mechanism includes a mounting plate 8 fixedly connected to the top of the filter housing 2, and brushes 9 are fixedly installed on both sides of the mounting plate 8; the brushes 9 facilitate cleaning of the middle perforated mesh plate 5.
[0019] A battery 10 connected to a drive motor 66 is installed on the top of the filter housing 2.
[0020] Working principle: When the gate in gate body 1 rises, drainage begins. Water passes through gate body 1 and then through filter housing 2 before being discharged. Debris in the water flow is blocked and filtered out by the middle perforated mesh plate 5. During this process, the radar flow meter 7 transmits a signal to the external controller. When the data of the radar flow meter 7 on the left is normal but the data of the radar flow meter 7 on the right is abnormal, it indicates that the middle perforated mesh plate 5 on the right is blocked. Then, the external controller starts the lifting mechanism 6 connected to the right mounting frame 4, causing the mounting frame 4 to lift the middle perforated mesh plate 5. During the lifting process, the brush 9 cleans the middle perforated mesh plate. The hollow mesh plate 5 is cleaned, and the bristles on the brush 9 can also pass through the holes in the middle hollow mesh plate 5 to clean it. If the data of both sets of radar flow meters 7 are abnormal, it means that the middle hollow mesh plate 5 on the left is blocked. The lifting mechanism 6 connected to the mounting frame 4 on the left can be started. During the cleaning of the middle hollow mesh plate 5, the other set of middle hollow mesh plates 5 can continue to block the garbage in the water flow without affecting the drainage. The blockage of the hollow mesh plate can be remotely known through the external controller and it can be cleaned. No manual cleaning and monitoring are required. It can be applied to the construction of smart water conservancy.
[0021] A shielding frame can be installed on the filter housing to prevent garbage from falling in.
[0022] The radar flow meter model 7 is RD-600s-R.
[0023] The drive motor 66, radar flow meter 7, drive motor 66 and external controller are all general standard parts or components known to those skilled in the art. Their structure and principle can be learned by those skilled in the art through technical manuals or obtained through conventional experimental methods.
[0024] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely preferred examples and are not intended to limit the utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A smart water conservancy utilization remote control water gate, comprising a gate body (1) and a filter housing (2) installed on the right side of the gate body (1), characterized in that: The top of the filter housing (2) is provided with two sets of sliding grooves (3), and the inside of the sliding grooves (3) is connected to the mounting frame (4). The inside of the mounting frame (4) is fixedly installed with a middle hollow mesh plate (5). The top of the filter housing (2) is fixedly connected with two sets of lifting mechanisms (6). The two sets of lifting mechanisms (6) are fixedly connected to the two sets of mounting frames (4) respectively. The inside of the filter housing (2) is fixedly installed with two sets of radar flow meters (7). The two sets of radar flow meters (7) are located on the right side of the two sets of middle hollow mesh plates (5) respectively. The top of the filter housing (2) is fixedly connected with a cleaning mechanism. The lifting mechanism (6) and the radar flow meter (7) are electrically connected to an external controller.
2. The remote control water gate for intelligent water conservancy utilization according to claim 1, characterized in that: The lifting mechanism (6) includes a connecting frame (61) fixedly connected to the filter housing (2). A lead screw (62) is rotatably connected inside the connecting frame (61). A slider (63) is threadedly connected to the outer surface of the lead screw (62). A guide rod (64) is fixedly connected inside the connecting frame (61). A connecting block (65) is slidably connected to the outer surface of the guide rod (64). The connecting block (65) is fixedly connected to the slider (63). A drive motor (66) is fixedly installed at the bottom of the connecting frame (61). The output end of the drive motor (66) is fixedly connected to the lead screw (62) through a coupling. One side of the slider (63) in the two sets of lifting mechanisms (6) is fixedly connected to the two sets of mounting frames (4) respectively. The drive motor (66) is electrically connected to an external controller.
3. The remote control water gate for intelligent water conservancy utilization according to claim 1, characterized in that: The cleaning mechanism includes a mounting plate (8) fixedly connected to the top of the filter housing (2), and brushes (9) are fixedly installed on both sides of the mounting plate (8).
4. The intelligent water conservancy remote control sluice gate according to claim 2, characterized in that: The top of the filter housing (2) is equipped with a battery (10) connected to the drive motor (66).