Intelligent monitoring device for urban rainwater pipe network flow
By adopting a new protective power supply structure and a solar power supply device, the problem of easy aging and power outage of intelligent traffic monitoring devices at the bottom of urban roads has been solved, achieving stable power supply and convenient installation, and improving the environmental adaptability and maintenance efficiency of the device.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- TIANJIN UNIV
- Filing Date
- 2026-01-30
- Publication Date
- 2026-06-05
AI Technical Summary
When existing intelligent traffic monitoring devices are installed at the bottom of urban roads, the wiring is easily affected by environmental factors and ages, leading to power outages and failure to work properly. In addition, the extensive wiring reduces the convenience of installation and maintenance.
A new protective power supply structure is adopted, including anti-corrosion pipes, connecting sleeves, and solar power supply structure. The intelligent monitoring body is covered by an anti-corrosion box, and solar panels are used to convert solar energy into power supply. The circuit is protected by anti-rust pillars and limit rings to prevent the circuit from directly contacting the environment, thus eliminating the need for extensive wiring.
It improves the stability and convenience of the monitoring device, prevents line aging and damage, adapts to long-term operation in various environments, and simplifies the installation and maintenance process.
Smart Images

Figure CN122149585A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of rainwater flow monitoring technology, and more specifically to an intelligent monitoring device for urban rainwater pipe network flow. Background Technology
[0002] Stormwater drainage networks are the "flood discharge channels" of a city, mainly used to collect and discharge rainwater to prevent water accumulation and flooding in the city and ensure the normal operation of the city's drainage system. When stormwater drainage networks are in use, they are combined with dedicated intelligent flow monitoring devices to monitor the amount of rainwater discharged in real time, so as to intuitively display the amount of rainwater discharged in the current time period and determine whether the stormwater drainage network in the current area is blocked by comparing the periodic discharge volume. In summary, the inventors have found that existing intelligent traffic flow monitoring devices have the following main drawbacks: Before being installed at the bottom of urban roads and connected to the corresponding rainwater pipe network for monitoring operations, current intelligent traffic flow monitoring devices require extensive wiring and data connection to the corresponding terminals. Furthermore, due to the constant changes in ambient air, water molecules, and temperature at the bottom of roads, these ordinary wirings are prone to aging, leading to hardening of the rubber insulation and subsequent cracking. This can expose the internal electrical wires, causing damage and resulting in power outages that render the intelligent monitoring device inoperable. Therefore, extensive wiring reduces the stability of the intelligent monitoring device, making it unable to operate continuously in any environment, indirectly reducing the intelligence of the device. Additionally, the extensive wiring reduces the convenience of installation and subsequent maintenance. Summary of the Invention
[0003] The technical solution adopted by the present invention to achieve the technical objective is: an intelligent monitoring device for urban rainwater pipe network flow, the structure of which includes: a novel protective power supply structure, an intelligent monitoring body, an anti-corrosion pipe, a connecting sleeve, and a threaded cavity. The novel protective power supply structure covers the outer layer of the intelligent monitoring body, and the anti-corrosion pipe is embedded in the top side of the intelligent monitoring body. The anti-corrosion pipe is connected to the external water pipe through the threaded cavity of the top connecting sleeve and extends through the internal center of the intelligent monitoring body, and the other end penetrates the side center of the protective power supply structure.
[0004] As a further improvement of the present invention, the novel power supply protection structure is provided with a disassembly cover, a connecting groove, an anti-corrosion box, an assembly cavity, a limiting ring, and a solar power supply structure. The disassembly cover is inserted and connected to the front end of the anti-corrosion box through the connecting groove, and the anti-corrosion box allows the intelligent monitoring body to be horizontally embedded through the internal assembly cavity. Then, the top limiting ring is connected to the bottom of the anti-corrosion pipe. The solar power supply structure is installed on the top left side of the anti-corrosion box and is spaced to the limiting ring. The bottom of the solar power supply structure passes through the anti-corrosion box and enters the assembly cavity to make an electrical connection with the intelligent monitoring body.
[0005] As a further improvement of the present invention, the solar power supply structure is provided with a solar panel, which is embedded in the internal area of the reinforcing frame and the lower side of the reinforcing frame is connected with a rust-proof column. The rust-proof column completes the fixed connection with the positioning block. The bottom center of the positioning block is also connected with an insert block and a power-conducting block.
[0006] As a further improvement of the present invention, the protective box of the new protective power supply structure covers the outside of the intelligent monitoring body through the connecting groove, and then the side is closed by disassembling the cover. At the same time, the anti-corrosion box and the anti-corrosion pipe with the limiting ring vertically limit the rainwater pipe. Then, the side solar power supply structure absorbs natural light energy through the solar panel and converts it into electrical energy. The electrical energy is input to the power block through the built-in circuit of the anti-rust column, so that the power block is inserted into the intelligent monitoring body to supply power.
[0007] As a further improvement of the present invention, the novel protective power supply structure covers the exterior of the intelligent monitoring body, and then the anti-corrosion pipe is in the shape of a cylinder to cover the edge of the rainwater pipe, and the threaded cavity of the connecting sleeve is opened in a vertical direction.
[0008] As a further improvement of the present invention, the disassembly cover carries two protrusions of the same size as the connecting groove, the anti-corrosion box is in the shape of a cuboid and covers the intelligent monitoring body, and the limiting ring limits the bottom edge of the anti-corrosion pipe.
[0009] As a further improvement of the present invention, the reinforcing frame is also provided with a parallel plate, and an assembly block is welded to the center of the upper end of the parallel plate. The surface of the assembly block is also provided with a through groove to allow the anti-rust column to carry the wire through and enter the bearing groove inside the protective frame to splice with the bottom of the solar panel. The edge area of the protective frame is also provided with a magnetic groove to allow the metal block to be vertically embedded. The metal block is fixed to the lower left and right sides of the tempered transparent plate, so that the tempered transparent plate covers the surface of the bearing groove through the metal block and covers the surface of the solar panel.
[0010] As a further improvement of the present invention, the parallel plate and the assembly block are perpendicular to each other and then spliced with the bottom of the protective frame in an interlocking manner. The size of the through groove matches the size of the anti-rust column. The edge of the protective frame is solid and the open bearing groove is rectangular and matches the shape of the solar panel. The magnetic groove has a built-in magnetic block and is consistent with the shape of the metal block. The area of the tempered transparent plate can cover the surface of the bearing groove.
[0011] As a further improvement of the present invention, the edge of the penetration groove is also provided with a splicing block, the splicing block is welded to the center of the edge of the vertical frame and the vertical frame covers the edge of the penetration groove and is connected to the assembly block and the bottom of the protective frame through the splicing block. The inner wall of the vertical frame is also equipped with a locking block to fix the clamping block.
[0012] As a further improvement of the present invention, the splicing block is provided in two pieces in the vertical frame edge area and set in a symmetrical orientation. The locking block inside the vertical frame is trapezoidal in shape and positions the rectangular rubber clamping block. The clamping block communicates with the edge of the penetration groove and contacts the edge of the anti-rust column.
[0013] As a further improvement of the present invention, the anti-corrosion pipe is provided with a locking bolt, which is welded to the lower end of the pipe body and the upper edge of the pipe body is provided with an external thread layer that is threaded to the inner wall of the connecting sleeve. The cavity in the central area of the pipe body is vertically penetrated and the center of the locking bolt is penetrated through the cavity. The buffer block is fixed through the cavity so that the buffer block contacts the edge of the rainwater pipe.
[0014] As a further improvement of the present invention, the center of the locking bolt coincides with the center of the pipe body, and the cavity is equipped with three rubber buffer blocks set in a triangular orientation, and the contact area between the buffer blocks and the rainwater pipe is arc-shaped.
[0015] As a further improvement of the present invention, the tube body is also provided with a ring inside, and the inner wall of the ring is connected to a limiting block. The spacing of the limiting block forms a slot for the buckle to be embedded and connected with the buffer block.
[0016] As a further improvement of the present invention, the ring is fitted to the inner wall area of the tube body and the three limiting blocks are all arc-shaped solid shapes and the slot shape between them matches the shape of the buffer block. Each slot carries a set of buckles.
[0017] Compared with the prior art, the present invention has the following beneficial effects: 1. This invention, through further improvements to the novel protective power supply structure, covers the exterior of the intelligent monitoring unit by using an anti-corrosion box assembly cavity, preventing damage caused by continuous contact with external microorganisms after installation at the bottom of urban roads. Furthermore, the anti-rust pillars and positioning blocks of the top solar power supply structure protect the circuitry carried by the solar panels, ensuring protection against damage to the bottom wiring during solar panel installation on the road surface. This replaces the original extensive wiring process, avoiding the difficulties in maintenance and the inability to accurately repair damaged wiring caused by extensive wiring. It improves the stability of the intelligent monitoring device and allows it to operate in various environments.
[0018] 2. This invention further improves the reinforcing frame of the solar panel. The position of the penetration groove can be determined by the parallel plate and assembly block at the bottom of the protective frame. Then, the penetration groove can ensure that the anti-rust column is set in a vertical position, which improves the accuracy of the wiring carried by the solar panel. Furthermore, the protective frame can use its solid characteristics and the magnetic grooves on both sides combined with the metal block to position the tempered transparent plate, ensuring that the tempered transparent plate can cover the surface of the solar panel, achieving the effect of protecting the surface of the solar panel and preventing damage caused by rolling on the road surface.
[0019] 3. The present invention further improves the anti-corrosion pipe by enhancing the connection stability of the connecting sleeve through the external thread layer of the pipe body. At the same time, the locking bolt at the lower end can be installed in the limiting ring in a vertical position, so that the anti-corrosion pipe can achieve the effect of quick disassembly and assembly. Then, the three buffer blocks in the internal cavity can contact the edge of the rainwater pipe, and the rebound clamping effect can improve the vertical connection stability of the urban rainwater pipe. Attached Figure Description
[0020] Figure 1 This is a structural schematic diagram of an intelligent monitoring device for urban stormwater pipe network flow.
[0021] Figure 2 This is a three-dimensional structural diagram of a new type of improved power supply protection structure.
[0022] Figure 3 This is a cross-sectional schematic diagram of an improved solar power supply structure.
[0023] Figure 4 This is a schematic diagram of a three-dimensional structure after an improvement of a reinforced frame.
[0024] Figure 5 This is a top view of a component with a through groove edge.
[0025] Figure 6 This is a three-dimensional structural diagram of an improved anti-corrosion pipe.
[0026] Figure 7 This is a top-view structural diagram of an improved internal structure of a tube.
[0027] In the diagram: Novel protective power supply structure-1, intelligent monitoring body-2, anti-corrosion pipe-3, connecting sleeve-4, threaded cavity-5; 11. Disassembly cover - 12. Connecting groove - 13. Corrosion-resistant box - 14. Assembly cavity - 15. Limiting ring - 16. Solar power supply structure; Solar panel-161, reinforced frame-162, rust-proof column-163, positioning block-164, insertion block-165, power-conducting block-166; Parallel plate-1621, assembly block-1622, through groove-1623, protective frame-1624, bearing groove-1625, magnetic groove-1626, metal block-1627, tempered transparent plate-1628; 6231 splicing block, 6232 vertical frame, 6233 locking block, 6234 clamping block; Locking bolt-31, tube body-32, external thread layer-33, cavity-34, buffer block-35; Ring-321, Limiting block-322, Slot-323, Buckle-324. Detailed Implementation
[0028] The present invention will be further described below with reference to the accompanying drawings: Example 1: Figures 1 to 5 As shown: This invention provides an intelligent monitoring device for urban stormwater drainage network flow. Its structure includes a novel protective power supply structure 1, an intelligent monitoring body 2, an anti-corrosion pipe 3, a connecting sleeve 4, and a threaded cavity 5. The novel protective power supply structure 1 covers the outer area of the intelligent monitoring body 2, and the anti-corrosion pipe 3 is embedded in the top side of the intelligent monitoring body 2. The anti-corrosion pipe 3 is connected to the external water pipe through the threaded cavity 5 of the top connecting sleeve 4 and extends through the internal center of the intelligent monitoring body 2, and the other end penetrates the side center of the protective power supply structure 1.
[0029] The novel power supply protection structure 1 includes a disassembly cover 11, a connecting groove 12, an anti-corrosion box 13, an assembly cavity 14, a limiting ring 15, and a solar power supply structure 16. The disassembly cover 11 is inserted and connected to the front end of the anti-corrosion box 13 through the connecting groove 12, and the anti-corrosion box 13 allows the intelligent monitoring body 2 to be horizontally embedded through the internal assembly cavity 14. Then, the top limiting ring 15 is connected to the bottom of the anti-corrosion pipe 3. The solar power supply structure 16 is installed on the top left side of the anti-corrosion box 13, which is spaced to the limiting ring 15, and the bottom penetrates the anti-corrosion box 13 and enters the assembly cavity 14 to be electrically connected to the intelligent monitoring body 2.
[0030] The solar power supply structure 16 is provided with a solar panel 161, which is embedded in the internal area of the reinforcing frame 162. The lower side of the reinforcing frame 162 is connected to a rust-proof column 163, which is fixedly connected to the positioning block 164 through the rust-proof column 163. The bottom center of the positioning block 164 is also connected to an insert block 165 and a power-conducting block 166.
[0031] In this process, the protective box 13 of the new protective power supply structure 1 covers the outside of the intelligent monitoring body 2 through the connecting groove 12, and then closes the side through the disassembly cover 11. At the same time, the anti-corrosion box 13, together with the anti-corrosion pipe 3 of the limiting ring 15, vertically limits the rainwater pipe. Then, the solar power supply structure 16 on the side absorbs natural light energy through the solar panel 161 and converts it into electrical energy. The electrical energy is input into the power block 166 through the built-in circuit of the anti-rust column 163, so that the power block 166 is inserted into the interior of the intelligent monitoring body 2 to supply power.
[0032] The novel protective power supply structure 1 covers the outside of the intelligent monitoring body 2, and the anti-corrosion pipe 3 is cylindrical to cover the edge of the rainwater pipe. The threaded cavity 5 of the connecting sleeve 4 is opened in a vertical direction.
[0033] The disassembly cover 11 has two protrusions of the same size as the connecting groove 12, the anti-corrosion box 13 is a cuboid shape that covers the intelligent monitoring body 2, and the limiting ring 15 limits the bottom edge of the anti-corrosion pipe 3.
[0034] The reinforcing frame 162 is further provided with a parallel plate 1621. An assembly block 1622 is welded to the center of the upper end of the parallel plate 1621. The surface of the assembly block 1622 is also provided with a through groove 1623 to allow the anti-rust column 163 to carry the wire through and enter the bearing groove 1625 inside the protective frame 1624 to splice with the bottom of the solar panel 161. The edge area of the protective frame 1624 is also provided with a magnetic groove 1626 to allow the metal block 1627 to be vertically embedded. The metal block 1627 is fixed to the lower left and right sides of the tempered transparent plate 1628, so that the tempered transparent plate 1628 covers the surface of the bearing groove 1625 through the metal block 1627, thus covering the surface of the solar panel 161.
[0035] The parallel plate 1621 and the assembly block 1622 are perpendicular to each other and are spliced to the bottom of the protective frame 1624 in an interlocking manner. The size of the through groove 1623 matches the size of the anti-rust column 163. The edge of the protective frame 1624 is solid and the open bearing groove 1625 is rectangular and matches the shape of the solar panel 161. The magnetic groove 1626 has a built-in magnetic block and is consistent with the shape of the metal block 1627. The area of the tempered transparent plate 1628 can cover the surface of the bearing groove 1625.
[0036] The edge of the penetrating groove 1623 is also provided with a splicing block 6231. The splicing block 6231 is welded to the center of the edge of the vertical frame 6232, and the vertical frame 6232 covers the edge of the penetrating groove 1623 and is connected to the assembly block 1622 and the bottom of the protective frame 1624 through the splicing block 6231. The inner wall of the vertical frame 6232 is also equipped with a locking block 6233, which fixes the clamping block 6234.
[0037] Among them, the splicing block 6231 has two blocks in the edge area of the vertical frame 6232 and is set in a symmetrical position. The locking block 6233 inside the vertical frame 6232 is trapezoidal and positions the rectangular rubber clamping block 6234. The clamping block 6234 communicates with the edge of the through groove 1623 and contacts the edge of the anti-rust column 163.
[0038] The specific functions and operation procedures of this embodiment are as follows: In this invention, the intelligent monitoring device for urban stormwater pipe network flow can achieve a stable vertical thread connection with the outside of the stormwater pipe through the anti-corrosion pipe 3, connecting sleeve 4, and threaded cavity 5, thereby achieving the effect of easy disassembly and assembly. Furthermore, the anti-corrosion pipe 3 allows the stormwater pipe to extend into the intelligent monitoring body 2. The received rainwater will then pass through the intelligent monitoring body 2. Based on the flow monitoring program and accessories of the intelligent monitoring body 2, the rainwater flow can be effectively monitored. Finally, the rainwater will flow out from the side of the intelligent monitoring body 2, thus completing the flow monitoring. The information protection power supply structure 1 mounted on the intelligent monitoring body 2 can replace the original large-scale wiring process and improve the protection effect of the intelligent monitoring body 2, preventing line damage caused by large-scale wiring. The difficulty in maintenance caused by damage reduces the usability of the monitoring device. The intelligent monitoring body 2 can be parallelly embedded through the assembly cavity 14 of the anti-corrosion box 13, and then the disassembly cover 11 can be installed through the connecting groove 12, ensuring complete coverage of the intelligent monitoring body 2. The limiting ring 15 on the anti-corrosion box 13 can be vertically spliced with the bottom of the anti-corrosion pipe 3, improving the connection stability between the rainwater pipe and the intelligent monitoring body 2. Simultaneously, the solar power supply structure 16 replaces the original extensive wiring process, enabling the monitoring device to adapt to various environments and operate continuously. For this purpose, the positioning block 164 of the solar power supply structure 16 can be combined with the plug block 165 carrying the power-conducting block 166 and vertically inserted into the upper end of the anti-corrosion box 13. Then, through the power-conducting block 166 and... The intelligent monitoring unit 2 is electrically connected. For this purpose, the anti-rust pillar 163 on the positioning block 164, along with the reinforcing frame 162, can cover and protect the solar panel 161 and its power lines. This allows the wiring carried by the solar panel 161 to pass through the anti-rust pillar 163 and connect to the power block 166. Simultaneously, the solar panel 161 can be positioned on urban roads to receive sunlight, taking into account the height of the anti-rust pillar 163 and the reinforcing frame 162. This effectively replaces the rapid aging and damage caused by direct contact between the wiring and water molecules and microorganisms at the bottom of the road surface, resulting from large-area wiring, indirectly achieving resource conservation. Furthermore, the protective frame 1624 of the reinforcing frame 162 can be aligned with the bottom assembly block 1622 and the parallel... The plate 1621 and the penetrating groove 1623 are spliced with the top of the anti-rust column 163. The protective frame 1624 allows the solar panel 161 to be arranged parallel to the bearing groove 1625. Then, the metal block 1627 is embedded in the two magnetic grooves 1626, allowing the tempered transparent plate 1628 to cover the surface of the solar panel 161, achieving a protective effect and preventing damage from external crushing caused by direct exposure of the solar panel 161. This improves the protection strength of the solar panel 161. Furthermore, the edge of the penetrating groove 1623 is equipped with a vertical frame 6232, which covers the edge of the penetrating groove 1623. Simultaneously, two splicing blocks 6231 are used to connect with the protective frame 1624 and the parallel plate 1621.This improves the overall connection strength of the components and enhances the hardness of the edge of the penetration groove 1623. Furthermore, the locking block 6233 arranged on the inner wall can position the clamping block 6234, allowing it to contact the edge of the anti-rust pillar 163. This ensures reinforcement at the intersection of the anti-rust pillar 163 and the penetration groove 1623, improving the accuracy of the wiring layout and preventing tilting or loosening.
[0039] Example 2: Figures 6 to 7 As shown: This invention provides an intelligent monitoring device for urban stormwater drainage network flow. Its structure includes a locking bolt 31 on the anti-corrosion pipe 3, which is welded to the lower end of the pipe body 32 and has an external thread layer 33 on the upper edge of the pipe body 32 that is threaded to the inner wall of the connecting sleeve 4. The cavity 34 in the central area of the pipe body 32 is vertically penetrated and the center of the locking bolt 31 is penetrated through it. The buffer block 35 is fixed through the cavity 34 so that the buffer block 35 contacts the edge of the rainwater pipe.
[0040] The center of the locking bolt 31 coincides with the center of the pipe body 32, and the cavity 34 is equipped with three rubber buffer blocks 35 set in a triangular position. The contact area between the buffer block 35 and the rainwater pipe is arc-shaped.
[0041] The tube body 32 is also provided with a ring 321 inside. The inner wall of the ring 321 is connected to a limiting block 322. The spacing of the limiting block 322 forms a slot 323 so that the buckle 324 can be embedded and connected to the buffer block 35.
[0042] The ring 321 fits into the inner wall area of the tube 32, and the three limiting blocks 322 are all arc-shaped solid shapes. The shape of the slots 323 between them matches the shape of the buffer block 35. Each slot 323 carries a set of buckles 324.
[0043] The specific functions and operation procedures of this embodiment are as follows: In this invention, the pipe body 32 of the anti-corrosion pipe 3 can be connected to the limiting ring 15 through the bottom locking bolt 31, and the top external thread layer 33 can be connected to the connecting sleeve 4. The threaded connection can improve the convenience of subsequent disassembly and assembly. After the urban rainwater pipe passes through the internal cavity 34 of the pipe body 32, it can be clamped at its edge with the buffer block 35 to prevent the shaking and collision caused by the continuous flow of rainwater during use due to the spacing. This can effectively protect the rainwater pipe. The circular ring 321 inside the pipe body 32 can generate the position and shape of the slot 323 through three limiting blocks 322, and then connect with the buffer block 35 with the built-in buckle 324. The arc-shaped limiting block 322 and the arc-shaped buffer block 35 can improve the matching effect with the shape of the urban rainwater pipe.
[0044] Any technical solution that achieves the above-mentioned technical effects by utilizing the technical solutions described in this invention, or by designing similar technical solutions by those skilled in the art under the inspiration of the technical solutions described in this invention, falls within the protection scope of this invention.
Claims
1. An intelligent monitoring device for urban stormwater drainage network flow, comprising: The new protective power supply structure (1), intelligent monitoring body (2), anti-corrosion pipe (3), connecting sleeve (4), and threaded cavity (5) are described. The new protective power supply structure (1) covers the outer area of the intelligent monitoring body (2), and the anti-corrosion pipe (3) is embedded in the top side of the intelligent monitoring body (2). The anti-corrosion pipe (3) is connected to the external water pipe through the threaded cavity (5) of the top connecting sleeve (4) and extends through the internal center of the intelligent monitoring body (2). The other end penetrates the side center of the protective power supply structure (1). The characteristics are as follows: The new power supply protection structure (1) is provided with a disassembly cover (11), a connecting groove (12), an anti-corrosion box (13), an assembly cavity (14), a limiting ring (15), and a solar power supply structure (16). The disassembly cover (11) is connected to the front end of the anti-corrosion box (13) through the connecting groove (12), and the anti-corrosion box (13) allows the intelligent monitoring body (2) to be horizontally embedded through the internal assembly cavity (14). Then, the top limiting ring (15) is connected to the bottom of the anti-corrosion pipe (3). The solar power supply structure (16) is installed on the top left side of the anti-corrosion box (13) and is spaced with the limiting ring (15). The bottom penetrates the anti-corrosion box (13) and enters the assembly cavity (14) to be electrically connected to the intelligent monitoring body (2). The solar power supply structure (16) is provided with a solar panel (161), which is embedded in the internal area of the reinforcing frame (162) and the lower side of the reinforcing frame (162) is connected to a rust-proof column (163). The rust-proof column (163) completes the fixed connection with the positioning block (164). The bottom center of the positioning block (164) is also connected to an insert block (165) and a power-conducting block (166). The protective box (13) of the new protective power supply structure (1) covers the outside of the intelligent monitoring body (2) through the connecting groove (12), and then closes the side through the disassembly cover (11). At the same time, the anti-corrosion box (13) and the anti-corrosion pipe (3) with the limiting ring (15) vertically limit the rainwater pipe. Then, the solar power supply structure (16) on the side absorbs the natural light energy through the solar panel (161) and converts it into electrical energy. The electrical energy is input into the power block (166) through the built-in circuit of the anti-rust column (163), so that the power block (166) is inserted into the intelligent monitoring body (2) to supply power.
2. The intelligent monitoring device for urban stormwater pipe network flow according to claim 1, characterized in that: The new protective power supply structure (1) covers the outside of the intelligent monitoring body (2), and then the anti-corrosion pipe (3) is in the shape of a cylinder to cover the edge of the rainwater pipe, and the threaded cavity (5) of the connecting sleeve (4) is opened in a vertical direction.
3. The intelligent monitoring device for urban stormwater pipe network flow according to claim 1, characterized in that: The disassembly cover (11) carries two protrusions of the same size as the connecting groove (12), the anti-corrosion box (13) is a cuboid shape that covers the intelligent monitoring body (2), and the limiting ring (15) limits the bottom edge of the anti-corrosion pipe (3).
4. The intelligent monitoring device for urban stormwater pipe network flow according to claim 1, characterized in that: The reinforcing frame (162) is also provided with a parallel plate (1621). An assembly block (1622) is welded to the center of the upper end of the parallel plate (1621). The surface of the assembly block (1622) is also provided with a through groove (1623) to allow the anti-rust column (163) to carry the wire through and enter the bearing groove (1625) inside the protective frame (1624) to splice with the bottom of the solar panel (161). The edge area of the protective frame (1624) is also provided with a magnetic groove (1626) to allow the metal block (1627) to be vertically embedded. The metal block (1627) is fixed to the lower left and right sides of the tempered transparent plate (1628), so that the tempered transparent plate (1628) covers the surface of the bearing groove (1625) through the metal block (1627) and covers the surface of the solar panel (161). The parallel plate (1621) and the assembly block (1622) are perpendicular to each other and are spliced to the bottom of the protective frame (1624) in an interlocking manner. The size of the through groove (1623) matches the size of the anti-rust column (163). The edge of the protective frame (1624) is solid and the open bearing groove (1625) is rectangular and matches the shape of the solar panel (161). The magnetic groove (1626) has a built-in magnetic block and is consistent with the shape of the metal block (1627). The area of the tempered transparent plate (1628) can cover the surface of the bearing groove (1625).
5. The intelligent monitoring device for urban stormwater pipe network flow according to claim 4, characterized in that: The edge of the through groove (1623) is also provided with a splicing block (6231). The splicing block (6231) is welded to the center of the edge of the vertical frame (6232), and the vertical frame (6232) covers the edge of the through groove (1623) and is connected to the bottom of the assembly block (1622) and the protective frame (1624) through the splicing block (6231). The inner wall of the vertical frame (6232) is also equipped with a locking block (6233) to fix the clamping block (6234). The splicing block (6231) has two blocks in the edge area of the vertical frame (6232) and is set in a symmetrical position. The locking block (6233) inside the vertical frame (6232) is trapezoidal and positions the rectangular rubber clamping block (6234). The clamping block (6234) communicates with the edge of the through groove (1623) and contacts the edge of the anti-rust column (163).
6. The intelligent monitoring device for urban stormwater pipe network flow according to claim 1, characterized in that: The anti-corrosion pipe (3) is provided with a locking bolt (31). The locking bolt (31) is welded to the lower end of the pipe body (32) and the upper edge of the pipe body (32) is provided with an external thread layer (33) that is threaded to the inner wall of the connecting sleeve (4). The cavity (34) in the center area of the pipe body (32) is vertically penetrated and the center of the locking bolt (31) is penetrated. The buffer block (35) is fixed through the cavity (34) so that the buffer block (35) contacts the edge of the rainwater pipe. The center of the locking bolt (31) coincides with the center of the pipe body (32), and the cavity (34) is equipped with three rubber buffer blocks (35) set in a triangular orientation. The contact area between the buffer block (35) and the rainwater pipe is arc-shaped.
7. The intelligent monitoring device for urban stormwater pipe network flow according to claim 6, characterized in that: The tube body (32) is also provided with a ring (321) inside. The inner wall of the ring (321) is connected to a limiting block (322). The spacing of the limiting block (322) forms a slot (323) so that the buckle (324) can be embedded and connected with the buffer block (35). The ring (321) fits into the inner wall area of the tube (32) and the three limiting blocks (322) are all arc-shaped solid shapes and the slots (323) between them are shaped to match the shape of the buffer block (35). Each slot (323) carries a set of buckles (324).