Integrated monitoring equipment for water conservancy emergency rescue

By designing an integrated monitoring device for water conservancy emergency rescue, the problem of stable installation on uneven ground in the field was solved by utilizing the rotation adjustment of the outriggers and rotating ring. Furthermore, the diverse monitoring and power generation needs were met through the adjustment of the solar panels, thus achieving portability and efficient use of the equipment.

CN224455837UActive Publication Date: 2026-07-03GUANGDONG JIANKE YUANSHENG ENG INSPECTION CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUANGDONG JIANKE YUANSHENG ENG INSPECTION CO LTD
Filing Date
2025-07-24
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Existing water conservancy monitoring equipment is inconvenient to carry, unsuitable for installation and fixation in the field, lacks adjustment mechanisms, and cannot meet different monitoring needs.

Method used

An integrated monitoring device for water conservancy emergency rescue was designed, including a fixed plate, support legs, a rotating ring, a sliding plate, and a sliding frame. By rotating the support legs and adjusting the extension length of the support plate, combined with the position adjustment of the sliding plate and the rotating ring, the device can be stably installed on uneven ground. At the same time, by adjusting the angle and position of the solar panel, diverse monitoring and power generation needs can be met.

Benefits of technology

It enables stable installation of water conservancy monitoring equipment in uneven areas in the field and meets diverse monitoring needs, improves power generation efficiency, and is convenient to carry and use.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses an integrated monitoring device for water conservancy emergency rescue, specifically relating to the field of water conservancy monitoring technology. It includes a fixed plate with multiple legs rotatably connected to its bottom. A rotating ring is located at the top of the fixed plate, and a sliding plate is located at the top of the rotating ring. A sliding frame is fitted onto the end of the sliding plate away from the fixed plate. A screw rod is threaded through the interior of the rotating ring. A solar panel is mounted on the top of the sliding frame, and a load-bearing bag is mounted on the bottom of the fixed plate. The screw rod is fixedly connected to the center of the top of the fixed plate, and its outer wall is fitted onto the center of the rotating ring. A rectangular hole is formed at the center of the sliding plate, and movable grooves are formed on both sides of the end of the sliding plate near the rotating ring, each groove containing a rotating rod. A through hole corresponding to the sliding plate is formed at the center of the sliding frame, and a monitoring module is mounted on the bottom of the sliding frame. This utility model has the advantages of convenient installation and storage, and easy adjustment and setting.
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Description

Technical Field

[0001] This utility model relates to the field of water conservancy monitoring technology, specifically to an integrated monitoring device for water conservancy emergency rescue. Background Technology

[0002] my country has numerous rivers and lakes, and the southern region enters the flood season in summer. Once a flood occurs, it will cause great harm to people's lives and property. Therefore, it is necessary to carry out water conservancy monitoring. In addition to setting up permanent and long-term monitoring points, it is also necessary to set up temporary monitoring equipment according to the needs of emergency rescue when the water rises.

[0003] However, in actual use, the storage and carrying of monitoring equipment is not convenient enough, and there is usually a lack of good monitoring locations during emergency rescue. Therefore, there is a need for an integrated monitoring device for water conservancy emergency rescue that can be easily adjusted during installation to adapt to different outdoor placement environments. At the same time, the detection equipment also needs to be adjustable for different monitoring locations to meet different detection needs. Utility Model Content

[0004] The purpose of this utility model is to provide an integrated monitoring device for water conservancy emergency rescue, which solves the problems of existing water conservancy monitoring devices being inconvenient to carry, unsuitable for field installation and fixation, and lacking adjustment structures.

[0005] To achieve the above objectives, this utility model provides the following technical solution: an integrated monitoring device for water conservancy emergency rescue, including a fixed plate, a plurality of legs rotatably connected to the bottom of the fixed plate, a rotating ring provided at the top of the fixed plate, a sliding plate provided at the top of the rotating ring, a sliding frame sleeved at the end of the sliding plate away from the fixed plate, a screw rod passing through the interior of the rotating ring, a solar panel installed at the top of the sliding frame, and a load-bearing bag installed at the bottom of the fixed plate.

[0006] The top center of the fixed plate is fixedly connected to the screw, and the outer wall of the screw is sleeved with the center of the rotating ring;

[0007] A rectangular hole is provided at the center of the sliding plate, and a moving groove is provided on both sides of the end of the sliding plate near the rotating ring. A rotating rod is provided inside the moving groove.

[0008] A through hole corresponding to the sliding plate is provided at the center of the sliding frame, and a monitoring module is installed at the bottom of the sliding frame.

[0009] Preferably, an extension rod is slidably connected to the bottom end of the support leg, a support plate is rotatably connected to the bottom of the extension rod, and a fixing bolt is threadedly connected to the outer wall of the bottom end of the support leg. One end of the fixing bolt passes through the interior of the support leg and fits against the outer wall of the extension rod.

[0010] Preferably, an adjusting rod is rotatably connected to the top of the sliding frame, and the solar panel is rotatably connected to the top of the sliding frame through the adjusting rod. A pressing bolt is threadedly connected to one side of the outer wall of the sliding frame, and the pressing bolt passes through the side wall of the sliding frame and fits against the side wall of the sliding plate.

[0011] Preferably, the bottom of the fixing plate is rotatably connected to the top of the support leg, one side of the bottom of the support leg is fixedly connected to the top outer wall of the load-bearing bag, the inside of the load-bearing bag is provided with a waterproof coating, and a sealing plug is provided at the center of the bottom of the load-bearing bag.

[0012] Preferably, a groove is provided at the top center of the rotating ring, the width of the groove corresponds to the width of the sliding plate, the outer wall of the sliding plate is slidably connected to the groove, and both sides of the end of the rotating ring away from the sliding frame are rotatably connected to the rotating rod.

[0013] Preferably, the width of the rectangular hole corresponds to the diameter of the screw, and a nut is threaded onto the top outer wall of the screw, with the bottom of the nut pressed against the top of the sliding plate.

[0014] The technical effects and advantages provided by this utility model in the above technical solution are as follows:

[0015] 1. Rotating multiple outriggers extends the extension rods at the bottom of the outriggers, allowing the support plate to rest against the ground. The extension length of the extension rods can be easily adjusted according to the ground's inclination and location. The fixing bolts are then turned to secure the extension rods, facilitating support adjustment and making it easy to install the device in uneven outdoor areas. Rotating the outriggers also opens the load-bearing bag, allowing users to easily add soil, stones, water, or other counterweights. This enables the load-bearing bag to easily pull the outriggers, preventing accidental tilting or tipping during installation.

[0016] 2. Move the sliding plate to adjust its position. Rotate the rotating ring to adjust the position and direction of the sliding groove, thereby adjusting the position and direction of the sliding plate. Then rotate the nut to press the top of the sliding plate, thus fixing the sliding plate. Move the sliding frame along the sliding plate to move the monitoring module at the bottom and the solar panel at the top, thereby adjusting their positions to meet the needs of monitoring and power generation. At the same time, the adjusting rod can be rotated as needed to adjust the position and angle of the solar panel, making it suitable for installation in different positions and directions, improving power generation efficiency, and making the device easy to adjust to meet diverse monitoring needs. Attached Figure Description

[0017] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in this utility model. For those skilled in the art, other drawings can be obtained based on these drawings.

[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0019] Figure 2 This is a top view of the present invention;

[0020] Figure 3 This is a side view of the present invention;

[0021] Figure 4 This is a schematic diagram of the connection structure between the fixing plate and the support leg of this utility model;

[0022] Figure 5 This is a schematic diagram of the external connection structure of the sliding plate of this utility model.

[0023] Explanation of reference numerals in the attached figures:

[0024] 1. Fixed plate; 101. Rotating ring; 102. Slide groove; 2. Support leg; 201. Extending rod; 202. Fixing bolt; 203. Support plate; 3. Sliding plate; 301. Rectangular hole; 302. Moving groove; 303. Rotating rod; 4. Sliding frame; 401. Pressing bolt; 402. Monitoring module; 5. Screw; 501. Nut; 6. Load-bearing bag; 7. Solar panel; 701. Adjusting rod. Detailed Implementation

[0025] To enable those skilled in the art to better understand the technical solution of this utility model, the present utility model will be further described in detail below with reference to the accompanying drawings.

[0026] This utility model provides, for example Figure 1-5The integrated monitoring equipment for water conservancy emergency rescue shown includes a fixed plate 1, with multiple support legs 2 rotatably connected to the bottom of the fixed plate 1, a rotating ring 101 at the top of the fixed plate 1, a sliding plate 3 at the top of the rotating ring 101, a sliding frame 4 sleeved at the end of the sliding plate 3 away from the fixed plate 1, a screw 5 penetrating through the interior of the rotating ring 101, a solar panel 7 installed at the top of the sliding frame 4, and a load-bearing bag 6 installed at the bottom of the fixed plate 1; the top center of the fixed plate 1 is fixedly connected to the screw 5, and the outer wall of the screw 5 is sleeved with the center of the rotating ring 101; a rectangular hole 301 is opened at the center of the sliding plate 3, and moving grooves 302 are opened on both sides of the end of the sliding plate 3 near the rotating ring 101, with rotating rods 303 installed inside each moving groove 302; a through hole corresponding to the sliding plate 3 is opened at the center of the sliding frame 4, and a monitoring module 402 is installed at the bottom of the sliding frame 4.

[0027] Extending the extension rod 201 at the bottom of the outrigger 2 allows the support plate 203 to rest against the ground. The extension length of the extension rod 201 can be easily adjusted according to the ground's inclination and location. The fixing bolt 202 is then rotated to secure the extension rod 201, facilitating support adjustment and allowing the device to be installed in uneven terrain. Adding soil, pebbles, water, or other weights inside the load-bearing bag 6 allows the outrigger 2 to be easily pulled, preventing accidental tilting or tipping during installation. Furthermore, during storage and transport, the outrigger 2 can be rotated and the extension rod 201 retracted. By reducing the storage volume, the sliding plate 3 is moved along the slide groove 102 to adjust its position. Rotating the rotating ring 101 adjusts the position and orientation of the slide groove 102, thereby adjusting the position and orientation of the sliding plate 3. Rotating the nut 501 then presses the top of the sliding plate 3 to fix it in place. Moving the sliding frame 4 along the sliding plate 3 moves the monitoring module 402 at the bottom and the solar panel 7 at the top, adjusting their positions to meet the needs of monitoring and power generation. The adjusting rod 701 can also be rotated as needed to adjust the position and angle of the solar panel 7.

[0028] like Figure 3 , Figure 4As shown, an extension rod 201 is slidably connected to the bottom end of the outrigger 2. A support plate 203 is rotatably connected to the bottom of the extension rod 201. A fixing bolt 202 is threadedly connected to the outer wall of the bottom end of the outrigger 2. One end of the fixing bolt 202 passes through the interior of the outrigger 2 and fits against the outer wall of the extension rod 201. During installation, multiple outriggers 2 can be easily rotated, and then the extension rod 201 at the bottom of the outrigger 2 can be extended, so that the support plate 203 can be supported on the ground. At the same time, the extension length of the extension rod 201 can be easily adjusted according to the slope and position of the ground. Then, the fixing bolt 202 is rotated to fix the extension rod 201, which facilitates the adjustment of the support and makes it easy to set up the device in uneven areas in the field.

[0029] like Figure 1 , Figure 5 As shown, an adjusting rod 701 is rotatably connected to the top of the sliding frame 4. The solar panel 7 is rotatably connected to the top of the sliding frame 4 via the adjusting rod 701. A clamping bolt 401 is threadedly connected to one side of the outer wall of the sliding frame 4. The clamping bolt 401 passes through the side wall of the sliding frame 4 and fits against the side wall of the sliding plate 3. Moving the sliding frame 4 along the sliding plate 3 can drive the monitoring module 402 at the bottom and the solar panel 7 at the top to move, thereby adjusting their positions to meet the needs of monitoring and power generation. At the same time, the adjusting rod 701 can be rotated as needed to adjust the position and angle of the solar panel 7, making it suitable for installation in different positions and directions, improving power generation efficiency, and making the device easy to adjust to meet diverse monitoring needs.

[0030] like Figure 2 , Figure 3 As shown, the bottom of the fixing plate 1 is rotatably connected to the top of the support leg 2. One side of the bottom of the support leg 2 is fixedly connected to the top outer wall of the load-bearing bag 6. The inside of the load-bearing bag 6 is provided with a waterproof coating. A sealing plug is provided at the center of the bottom of the load-bearing bag 6. When the support leg 2 rotates, the load-bearing bag 6 can also be opened, so that the user can easily add counterweights such as soil, stones, and water inside the load-bearing bag 6. This allows the load-bearing bag 6 to easily pull the support leg 2, thereby preventing the support leg 2 from accidentally tilting or tipping over during installation.

[0031] like Figure 4 , Figure 5As shown, a groove 102 is provided at the top center of the rotating ring 101. The width of the groove 102 corresponds to the width of the sliding plate 3. The outer wall of the sliding plate 3 is slidably connected to the groove 102. Both sides of the end of the rotating ring 101 away from the sliding frame 4 are rotatably connected to the rotating rod 303. The width of the rectangular hole 301 corresponds to the diameter of the screw 5. A nut 501 is threadedly connected to the top outer wall of the screw 5. The bottom of the nut 501 is pressed against the top of the sliding plate 3, rotating the sliding plate 3 into the groove 102. This allows the screw 5 to pass through the rectangular hole 301 at the center of the sliding plate 3. At the same time, the sliding plate 3 can be easily moved along the groove 102 to adjust its position. Rotating the rotating ring 101 can adjust the position and direction of the groove 102, thereby adjusting the position and direction of the sliding plate 3. Rotating the nut 501 further presses the top of the sliding plate 3, thus fixing the sliding plate 3.

[0032] During use, the device can be easily installed at the location requiring monitoring, ensuring that the end of the sliding plate 3 furthest from the fixed plate 1 is above the water surface. The monitoring module 402 can then monitor the water level. The monitoring module 402 can be conveniently powered by the solar panel 7, eliminating the need for additional power supply when the device is used in the field. During installation, multiple support legs 2 can be easily rotated, extending the extension rods 201 at the bottom of the support legs 2. This allows the support plate 203 to be supported on the ground. The extension length of the extension rods 201 can be easily adjusted according to the ground's inclination and location. The extension rods 201 are then fixed by rotating the fixing bolts 202. The support is easy to adjust, making it convenient to set up the device in uneven outdoor areas. When the support leg 2 rotates, the load-bearing bag 6 can also be opened, allowing users to add counterweights such as soil, stones, and water inside the load-bearing bag 6. This allows the load-bearing bag 6 to easily pull the support leg 2, thus preventing the support leg 2 from accidentally tilting or tipping over during installation. Moreover, when storing and carrying it, the storage volume can be reduced by rotating the support leg 2 and the storage extension rod 201. Furthermore, by releasing the nut 501 at the top of the screw 5, the nut 501 can be released from its pressure on the sliding plate 3, making it easy to rotate the sliding plate 3 around the rotating rod 303 to one side of the support leg 2, thereby further reducing the storage volume and making it convenient to carry and transport.

[0033] In use, the sliding plate 3 can be easily rotated into the sliding groove 102, allowing the screw 5 to pass through the rectangular hole 301 at the center of the sliding plate 3. Simultaneously, the sliding plate 3 can be easily moved along the sliding groove 102 to adjust its position. Rotating the rotating ring 101 adjusts the position and orientation of the sliding groove 102, thus adjusting the position and orientation of the sliding plate 3. Rotating the nut 501 presses against the top of the sliding plate 3, fixing it in place. Moving the sliding frame 4 along the sliding plate 3 moves the monitoring module 402 at the bottom and the solar panel 7 at the top, adjusting their positions to meet monitoring and power generation needs. The adjusting rod 701 can also be rotated as needed to adjust the position and angle of the solar panel 7, making it suitable for installation in different positions and orientations, improving power generation efficiency. This allows for easy adjustment of the device to meet diverse monitoring requirements.

[0034] The foregoing description only illustrates certain exemplary embodiments of the present invention. Undoubtedly, those skilled in the art can modify the described embodiments in various ways without departing from the spirit and scope of the present invention. Therefore, the above drawings and descriptions are illustrative in nature and should not be construed as limiting the scope of protection of the claims of the present invention.

Claims

1. Integrated monitoring equipment for water conservancy emergency rescue, comprising a fixed plate (1), characterized in that: The bottom of the fixed plate (1) is rotatably connected to multiple support legs (2), the top of the fixed plate (1) is provided with a rotating ring (101), the top of the rotating ring (101) is provided with a sliding plate (3), the end of the sliding plate (3) away from the fixed plate (1) is sleeved with a sliding frame (4), a screw (5) is provided through the inside of the rotating ring (101), a solar panel (7) is installed on the top of the sliding frame (4), and a load-bearing bag (6) is installed on the bottom of the fixed plate (1). The top center of the fixed plate (1) is fixedly connected to the screw (5), and the outer wall of the screw (5) is sleeved with the center of the rotating ring (101); A rectangular hole (301) is provided at the center of the sliding plate (3), and a moving groove (302) is provided on both sides of the end of the sliding plate (3) near the rotating ring (101). A rotating rod (303) is provided inside the moving groove (302). The sliding frame (4) has a through hole at its center that corresponds to the sliding plate (3) and a monitoring module (402) is installed at the bottom of the sliding frame (4).

2. The integrated monitoring device for water conservancy emergency rescue according to claim 1, characterized in that: The bottom end of the support leg (2) is slidably connected to an extension rod (201), and the bottom of the extension rod (201) is rotatably connected to a support plate (203). The bottom end of the support leg (2) is threadedly connected to a fixing bolt (202), one end of which penetrates the interior of the support leg (2) and fits against the outer wall of the extension rod (201).

3. The integrated monitoring device for water conservancy emergency rescue according to claim 1, characterized in that: An adjusting rod (701) is rotatably connected to the top of the sliding frame (4). The solar panel (7) is rotatably connected to the top of the sliding frame (4) through the adjusting rod (701). A pressing bolt (401) is threadedly connected to one side of the outer wall of the sliding frame (4). The pressing bolt (401) passes through the side wall of the sliding frame (4) and fits against the side wall of the sliding plate (3).

4. The integrated monitoring device for water conservancy emergency rescue according to claim 1, characterized in that: The bottom of the fixed plate (1) is rotatably connected to the top of the support leg (2), and the bottom side of the support leg (2) is fixedly connected to the top outer wall of the load-bearing bag (6). The inside of the load-bearing bag (6) is provided with a waterproof coating, and a sealing plug is provided at the bottom center of the load-bearing bag (6).

5. The integrated monitoring equipment for water conservancy emergency rescue as described in claim 1, characterized in that: The rotating ring (101) has a groove (102) at the top center. The width of the groove (102) corresponds to the width of the sliding plate (3). The outer wall of the sliding plate (3) is slidably connected to the groove (102). The two sides of the end of the rotating ring (101) away from the sliding frame (4) are rotatably connected to the rotating rod (303).

6. The integrated monitoring device for water conservancy emergency rescue according to claim 1, characterized in that: The width of the rectangular hole (301) corresponds to the diameter of the screw (5). A nut (501) is threaded onto the top outer wall of the screw (5). The bottom of the nut (501) is pressed against the top of the sliding plate (3).