A guiding device applied to an adjustable non-contact precision radar water level monitoring cable way
The guiding device, which connects the cable with a guide plate and a pulley system, solves the problems of blind spots in radar probe monitoring and the inability to monitor low water levels, and enables flexible movement of radar sensors and cost optimization.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BUREAU OF HYDROLOGY CHANGJIANG WATER RESOURCES COMMISSION
- Filing Date
- 2025-06-19
- Publication Date
- 2026-06-23
AI Technical Summary
Existing radar probes have problems with blind spots and inability to monitor low water levels when monitoring rivers, and adding more probes will increase construction costs.
A guiding device including a first guide plate and a second guide plate is used. The cable is connected by a pulley block and a hanging ring to realize the reciprocating movement of the radar sensor on both sides of the river or reservoir, providing a cableway.
It enables radar sensors to move flexibly on both sides of rivers or reservoirs, reducing monitoring blind spots and lowering additional construction costs.
Smart Images

Figure CN224397483U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of hydrological surveying, and in particular to a guiding device for adjustable non-contact precision radar water level monitoring cableway. Background Technology
[0002] The bracket guide plate assembly provides a cableway for non-contact radar sensors. Its core value lies in building an all-weather adaptive intelligent hydrological monitoring system under complex working conditions, significantly improving the real-time data reliability of water conservancy facilities in key scenarios such as flood warning and reservoir scheduling, providing high-performance new sensing equipment for smart water conservancy construction, and promoting the iterative upgrading of hydrological monitoring technology towards intelligence, remoteness, and high precision.
[0003] Currently, radar probes are fixed in place when monitoring rivers, resulting in blind spots or additional radar probes being added to increase the monitoring range, which incurs additional construction costs. In addition, there is also the problem of being unable to monitor when the water level is low. Summary of the Invention
[0004] The purpose of this invention is to address the shortcomings of the prior art by providing a guiding device for adjustable non-contact precision radar water level monitoring cableways, thereby providing a cableway for the radar probe.
[0005] To achieve the above objectives, the present invention adopts the following technical solution:
[0006] This invention provides a guiding device for adjustable non-contact precision radar water level monitoring cableways, comprising a first guide plate and a second guide plate used in conjunction.
[0007] The first guide plate includes a first wire rope guide plate, and a first pulley block, a second pulley block and a wire rope fixing plate are installed on one side of the first wire rope guide plate.
[0008] Furthermore, the first pulley group, the second pulley group, and the wire rope fixing plate are spaced apart and coaxially arranged.
[0009] Furthermore, the wire rope fixing plate includes a fixing plate bracket, and a first lifting ring is installed on the fixing plate bracket.
[0010] Furthermore, a second lifting ring is installed on the side of the first pulley group that is separate from the second pulley group.
[0011] Furthermore, the second guide plate includes a second wire rope guide plate, and a third pulley block is installed on one side of the second wire rope guide plate.
[0012] Furthermore, a third lifting ring is installed on one side of the third pulley block, and a fourth lifting ring is installed on the other side of the third pulley block.
[0013] The beneficial effects of this utility model are: the first guide plate and the second guide plate are used together to facilitate the radar sensor to move back and forth on both sides of the river or reservoir. Attached Figure Description
[0014] Figure 1 This is a schematic diagram of the structure of the first guide plate;
[0015] Figure 2 This is a schematic diagram of the second guide plate.
[0016] Figure 3 This is a schematic diagram of the operating structure of a guide device for an adjustable non-contact precision radar water level monitoring cableway. Detailed Implementation
[0017] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are merely illustrative of the present utility model and are not intended to limit the scope of the present utility model.
[0018] Please see Figure 1 and Figure 2 A guiding device for adjustable non-contact precision radar water level monitoring cableways includes a first guide plate 1 and a second guide plate 2 used in conjunction.
[0019] In one specific implementation, the first guide plate 1 is installed on one bank of a river or reservoir, and the second guide plate 2 is installed on the other bank of the river or reservoir. The first guide plate 1 and the second guide plate 2 are connected by multiple cables.
[0020] In addition, the first guide plate 1 and the second guide plate 2 can be installed on steel frames installed on both sides of the riverbank or reservoir.
[0021] The first guide plate 1 includes a first wire rope guide plate 11, on one side of which a first pulley block 101, a second pulley block 102 and a wire rope fixing plate are installed.
[0022] The first pulley block 101, the second pulley block 102, and the wire rope fixing plate are spaced apart and coaxially arranged.
[0023] In one specific embodiment, the first pulley block 101, the second pulley block 102, and the wire rope fixing plate are installed on the same straight line, that is, coaxially.
[0024] The wire rope fixing plate includes a fixing plate bracket 1031, and a first lifting ring 1032 is installed on the fixing plate bracket 1031.
[0025] The function of the fixed plate bracket 1031 is to keep the installation height of the first lifting ring 1032 consistent with the installation height of the first pulley group 101 and the second pulley group 102.
[0026] A second lifting ring 104 is installed on the side of the first pulley block 101 that is separate from the second pulley block 102.
[0027] The second guide plate 2 includes a second wire rope guide plate 201, and a third pulley block 203 is installed on one side of the second wire rope guide plate 201.
[0028] A third lifting ring 204 is installed on one side of the third pulley block 203, and a fourth lifting ring 205 is installed on the other side of the third pulley block 203.
[0029] The first pulley block 101, the second pulley block 102, and the third pulley block 203 are all used for the sliding of the cable;
[0030] The first lifting ring 1032, the second lifting ring 104, the third lifting ring 204, and the fourth lifting ring 205 are all used to secure the cable in order to provide a cableway for the radar sensor.
[0031] Please see Figure 3 The operation mode of a guide device applied to an adjustable non-contact precision radar water level monitoring cableway is as follows:
[0032] The first guide plate 1 and the second guide plate 2 are respectively installed on the steel frame on both sides of the river or reservoir. The second lifting ring 104 is connected to the third lifting ring 204 on the opposite bank through the first cable 401. The first lifting ring 1032 and the fourth lifting ring 205 are connected through the second cable 402. The radar sensor can slide on the first cable 401 and the second cable 402, thereby providing a cableway for the radar sensor to move from one side of the river or reservoir to the other side.
[0033] One end of the third cable 403 is connected to one end 3021 of the second radar sensor 302. Then the third cable 403 passes through the third pulley group 203, then through the first pulley group 101, then through the hand crank arm 4, then through the second pulley group 102, and is connected to one end 3011 of the first radar sensor 301.
[0034] In addition, to facilitate the movement of the first radar sensor 301 and the second radar sensor 302, the first radar sensor 301 and the second radar sensor 302 are also connected by a cable.
[0035] By cranking the hand crank arm, driven by the third cable 403, the first radar sensor 301 and the second radar sensor 302 can move back and forth on both sides of the river or reservoir using the first cable 401 and the second cable 402 as tracks. Under the control of the hand crank arm 4, the first radar sensor 301 and the second radar sensor 302 can be accurately positioned.
[0036] The embodiments described above merely illustrate the implementation of this utility model, and while the descriptions are relatively specific and detailed, they should not be construed as limiting the scope of this utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be defined by the appended claims.
Claims
1. A guiding device applied to an adjustable non-contact precision radar water level monitoring cableway, characterized in that: Including a first guide plate (1) and a second guide plate (2) used in conjunction, The first guide plate (1) includes a first wire rope guide plate (11), and a first pulley block (101), a second pulley block (102) and a wire rope fixing plate are installed on one side of the first wire rope guide plate (11).
2. The guiding device for the adjustable non-contact precision radar water level monitoring cableway according to claim 1, characterized in that: The first pulley group (101), the second pulley group (102), and the wire rope fixing plate are spaced apart and coaxially arranged.
3. The guiding device for the adjustable non-contact precision radar water level monitoring cableway according to claim 2, characterized in that: The wire rope fixing plate includes a fixing plate bracket (1031), on which a first lifting ring (1032) is installed.
4. The guiding device for the adjustable non-contact precision radar water level monitoring cableway according to claim 3, characterized in that: A second lifting ring (104) is installed on the side of the first pulley group (101) that is away from the second pulley group (102).
5. The guiding device for the adjustable non-contact precision radar water level monitoring cableway according to claim 4, characterized in that: The second guide plate (2) includes a second wire rope guide plate (201), and a third pulley block (203) is installed on one side of the second wire rope guide plate (201).
6. The guiding device for the adjustable non-contact precision radar water level monitoring cableway according to claim 5, characterized in that: A third lifting ring (204) is installed on one side of the third pulley block (203), and a fourth lifting ring (205) is installed on the other side of the third pulley block (203).