An artificial intelligence-based digital integrated pump station
By using a segmented ladder and floating block drive design, the problems of ladder corrosion and slippage were solved, thereby improving the reliability and ease of maintenance of the pumping station.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WUHAN XIANLONG TECH CO LTD
- Filing Date
- 2025-07-21
- Publication Date
- 2026-06-05
AI Technical Summary
In existing AI-based digital integrated pumping stations, ladders are easily submerged and corroded by water, reducing their service life. Furthermore, operators face the risk of slipping while climbing, and maintenance is inconvenient.
The ladder adopts a segmented design, with a float that moves the lower section of the ladder up and down with the water level, ensuring that the bottom of the lower section is always above the water surface. It is also equipped with a cleaning roller to clean up dirt as the lower section moves up and down, improving climbing safety and maintenance convenience.
It extends the service life of the lower ladder, reduces the risk of slipping, and improves the reliability of climbing and the convenience of maintenance for operators.
Smart Images

Figure CN224325835U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of pump station technology, specifically relating to a digital integrated pump station based on artificial intelligence. Background Technology
[0002] An integrated pumping station is a type of equipment used for the scheduling, lifting, and transportation of water resources. Artificial intelligence-based digital integrated pumping stations achieve intelligent and efficient operation by integrating technologies such as the Internet of Things and data integration. Existing AI-based digital integrated pumping stations mainly consist of a cylinder, a pump body, and a ladder. Water enters the cylinder through the inlet, and the pump body moves the water to the outlet for discharge. The ladder allows operators to climb into the cylinder for inspection and maintenance.
[0003] In existing AI-based digital integrated pump stations, the ladder is typically fixed from the top to the bottom of the cylinder. When the water level rises, the lower end of the ladder is easily submerged, corroding it and reducing its lifespan. When operators need to climb the ladder to the bottom of the cylinder, the dirt remaining on the lower surface of the ladder can reduce friction, causing operators to slip or even fall, resulting in insufficient reliability. Some pump stations do not extend the lower end of the ladder to the bottom of the cylinder. Although this reduces the contact between water and the ladder, it makes it inconvenient for operators to climb down the ladder to the bottom of the cylinder for inspection and maintenance, resulting in insufficient convenience for inspection and maintenance. Utility Model Content
[0004] The purpose of this invention is to provide a digital integrated pump station based on artificial intelligence. It can move the lower ladder up and down with the rise and fall of the water level through the buoyancy of the float, so that the lower end of the lower ladder is always above the water surface, reducing the contact between water and the lower ladder, improving reliability. In addition, the cleaning roller can clean the dirt on the lower ladder as the upper ladder moves up and down along the lower ladder, making it easier for operators to climb up the lower ladder to the bottom of the cylinder, improving the convenience of inspection and maintenance.
[0005] The specific technical solution adopted by this utility model is as follows:
[0006] A digital integrated pump station based on artificial intelligence includes a cylindrical body, wherein several pump bodies are fixedly connected inside the cylindrical body, and further includes:
[0007] The segmented ladder is located inside the cylinder. The segmented ladder includes an upper ladder fixedly connected to the top of the cylinder, a lower ladder slidably connected to the lower end of the upper ladder in the vertical direction, and several floating blocks fixedly connected to the lower end of the lower ladder. A cleaning roller is rotatably installed on the upper ladder, and the cleaning roller rolls in cooperation with the lower ladder.
[0008] The float moves up and down with the water level, causing the lower ladder to move up and down, and the cleaning roller rolls along the lower ladder.
[0009] A connecting frame is slidably installed on the upper section of the ladder along the vertical direction, and the cleaning roller is rotatably connected to the connecting frame.
[0010] The connecting frame is slidably connected to the upper ladder in the vertical direction. The connecting frame is provided with a first limiting hole, and the upper ladder is provided with a plurality of second limiting holes in the vertical direction. The first limiting hole and the second limiting hole are slidably connected with limiting pins.
[0011] The cleaning roller includes a roller body rotatably connected to a connecting frame, and a plurality of bristles are fixedly connected to the roller body, the bristles being in close contact with the lower ladder section.
[0012] A sliding strip is fixedly connected to the upper section of the ladder, and a sliding groove is fixedly connected to the lower section of the ladder. The sliding strip and the sliding groove slide in a vertical direction.
[0013] A vent is fixedly connected to the float, and the vent communicates with the interior of the float.
[0014] The technical effects achieved by this utility model are as follows:
[0015] The upper and lower ladder sections of this utility model are designed in sections. The float moves the lower ladder up and down with the rise and fall of the water level under the action of buoyancy, so that the lower end of the lower ladder is always higher than the water surface, reducing the contact between water and the lower ladder. Compared with the prior art, this improves the service life of the lower ladder, reduces the stains left by water on the surface of the lower ladder, and reduces the risk of operators slipping or even falling when climbing, thus improving reliability.
[0016] The cleaning roller in this invention cleans the dirt remaining on the lower ladder as the upper ladder moves up and down along the lower ladder, further reducing the amount of water leaving dirt on the surface of the lower ladder. The cleaning process does not require an additional motor to drive it, making it easier for operators to climb up the lower ladder to the bottom of the cylinder, thus improving the convenience of inspection and maintenance. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0018] Figure 2 This is a cross-sectional schematic diagram of the middle cylinder of this utility model;
[0019] Figure 3 This is a schematic diagram of the segmented ladder in this utility model;
[0020] Figure 4 This utility model Figure 3 Enlarged view of point A in the middle;
[0021] Figure 5 This utility model Figure 3 Enlarged view of point B in the middle;
[0022] Figure 6 This is a schematic diagram of the structure of the cleaning roller and the connecting frame in this utility model;
[0023] Figure 7 This is a cross-sectional view of the upper and lower sections of the ladder in this utility model.
[0024] The attached diagram lists the components represented by each number as follows:
[0025] 10. Cylinder; 11. Pump body; 20. Segmented ladder; 21. Upper ladder; 22. Lower ladder; 23. Float; 24. Cleaning roller; 31. Connecting frame; 32. First limiting hole; 33. Second limiting hole; 34. Limiting pin; 35. Roller body; 36. Brush bristles; 37. Sliding strip; 38. Sliding groove; 39. Vent. Detailed Implementation
[0026] To make the objectives and advantages of this utility model clearer, the following detailed description is provided in conjunction with embodiments. It should be understood that the following text is merely used to describe one or more specific implementations of this utility model and does not strictly limit the scope of protection specifically claimed by this utility model.
[0027] like Figures 1 to 7 As shown, an artificial intelligence-based digital integrated pump station includes a cylinder 10, with several pump bodies 11 fixedly connected inside the cylinder 10, and also includes a segmented ladder 20. The segmented ladder 20 is disposed inside the cylinder 10. The segmented ladder 20 includes an upper ladder 21 fixedly connected to the top of the cylinder 10, a lower ladder 22 slidably connected to the lower end of the upper ladder 21 in the vertical direction, several floats 23 fixedly connected to the lower end of the lower ladder 22, and a cleaning roller 24 rotatably mounted on the upper ladder 21, the cleaning roller 24 and the lower ladder 22 rollingly engaging.
[0028] It should be noted that both the cylinder 10 and the pump body 11 are existing technologies. The cylinder 10 has an inlet and an outlet, both of which are connected to the interior of the cylinder 10. The outlet is connected to the output end of the pump body 11. The pump body 11 is used to move the water inside the cylinder 10 to the outlet. The cylinder 10 is equipped with sensor components (such as visual sensors and sound sensors) to map the physical equipment status inside the cylinder 10, which facilitates the subsequent construction of a digital intelligent model of the pump station and optimization of the operation strategies of several pump bodies 11. This is existing technology and will not be described in detail here.
[0029] In this embodiment, when water is present inside the cylinder 10, the float 23 floats on the water surface under buoyancy, making the lower end of the lower ladder 22 higher than the water surface. When the water level rises or falls, the float 23 moves up and down with the water level under buoyancy, causing the float 23 to move the lower ladder 22 up and down along the upper ladder 21. This ensures that the lower end of the lower ladder 22 is always higher than the water surface. Compared with the existing ladders that are fixed from the top to the bottom of the cylinder 10, this design reduces water damage to the lower ladder 22, increases its service life, and reduces the likelihood of water stains on its surface. This also reduces the risk of slipping or falling while climbing the lower ladder 22, improving reliability. Furthermore, during the movement of the lower ladder 22 along the upper ladder 21, a relative displacement occurs between the lower ladder 22 and the cleaning roller 24, causing the cleaning roller 24 to roll along the lower ladder 22. To further reduce water residue on the lower ladder section 22, the system cleans away any remaining stains. When operators need to descend to the bottom of the cylinder 10 for maintenance, the water inside the cylinder 10 is drained, causing the float 23 to fall to the bottom of the cylinder 10 as the water level drops. The float 23 then moves the lower ladder section 22 down along the upper ladder section 21, bringing the lower end of the lower ladder section 22 to the bottom of the cylinder 10, thus aligning the upper ladder section 21 and the lower ladder section 22. The top and bottom of the cylinder 10 are connected, making it easier for operators to climb from the top to the bottom of the cylinder 10 via the upper ladder 21 and the lower ladder 22, thus improving the convenience of inspection and maintenance. When the lower end of the lower ladder 22 moves down to the bottom of the cylinder 10, the float 23 is located between the lower end of the lower ladder 22 and the bottom inner wall of the cylinder 10, providing a buffer for the descent of the lower ladder 22 and preventing the lower end of the lower ladder 22 from directly hitting the bottom inner wall of the cylinder 10.
[0030] like Figure 4 and Figure 6 As shown, a connecting frame 31 is slidably installed on the upper section of the ladder 21 along the vertical direction, and the cleaning roller 24 is rotatably connected to the connecting frame 31.
[0031] like Figure 4 and Figure 6 As shown, the connecting frame 31 is slidably connected to the upper ladder 21 in the vertical direction. The connecting frame 31 is provided with a first limiting hole 32, and the upper ladder 21 is provided with a plurality of second limiting holes 33 in the vertical direction. The first limiting hole 32 and the second limiting hole 33 are slidably connected with limiting pins 34.
[0032] It should be noted that both ends of the connecting frame 31 are fixedly connected with grooves, and the grooves slide in a vertical direction with the upper ladder 21.
[0033] In this embodiment, when it is necessary to adjust the position of the cleaning roller 24 on the upper ladder 21, the limiting pin 34 is pulled out from the inside of the first limiting hole 32 and the second limiting hole 33, and the connecting frame 31 is moved up and down along the upper ladder 21 so that the first limiting hole 32 is aligned with the second limiting hole 33 at a suitable position. The limiting pin 34 is then inserted into the inside of the first limiting hole 32 and the second limiting hole 33 to limit the connecting frame 31 and the upper ladder 21, so that the relative position between the cleaning roller 24 and the upper ladder 21 remains fixed, thereby adjusting the position of the cleaning roller 24 on the upper ladder 21, improving flexibility, and facilitating the cleaning roller 24 to clean the lower ladder 22 during the up and down movement of the lower ladder 22 along the upper ladder 21.
[0034] like Figure 6 and Figure 7 As shown, the cleaning roller 24 includes a roller body 35 rotatably connected to the connecting frame 31, and a plurality of bristles 36 are fixedly connected to the roller body 35. The bristles 36 are in close contact with the lower ladder 22.
[0035] It should be noted that the bristles 36 are made of an elastic material, preferably nylon. There is a gap in the horizontal direction between the roller body 35 and the lower ladder 22 to prevent the roller body 35 from colliding with the lower ladder 22 when the lower ladder 22 moves up and down along the upper ladder 21. The length of the bristles 36 is greater than the width of the gap so that the lower ladder 22 can push the bristles 36 to rotate during the relative displacement between the lower ladder 22 and the cleaning roller 24. The lower ladder 22 includes two vertical rods and several horizontal rods. The vertical rods and horizontal rods are existing technologies. The two vertical rods are parallel to each other, and the several horizontal rods are distributed vertically between the two vertical rods. The two ends of the horizontal rods are fixedly connected to the two vertical rods respectively. This will not be described in detail here.
[0036] In this embodiment, as the lower ladder 22 moves up and down along the upper ladder 21, the crossbar of the lower ladder 22 contacts the bristles 36 and squeezes the bristles 36, causing them to deform. As the lower ladder 22 continues to move, the crossbar of the lower ladder 22 pushes the bristles 36 and the roller 35 to rotate along the connecting frame 31, thereby causing the cleaning roller 24 to roll along the lower ladder 22. The bristles 36 carry away the dirt remaining on the lower ladder 22 and separate it from the lower ladder 22, thereby allowing the cleaning roller 24 to clean the lower ladder 22.
[0037] like Figure 4 As shown, a slide bar 37 is fixedly connected to the upper section of the ladder 21, and a slide groove 38 is fixedly connected to the lower section of the ladder 22. The slide bar 37 and the slide groove 38 slide in a vertical direction.
[0038] It should be noted that the cross-sectional shapes of the slider 37 and the groove 38 are both dovetail-shaped or "T"-shaped, and the dovetail shape is preferred in this utility model.
[0039] In this embodiment, the slide bar 37 cooperates with the slide groove 38 to make the process of the lower section of the ladder 22 sliding along the upper section of the ladder 21 more stable.
[0040] like Figure 5 As shown, a vent 39 is fixedly connected to the float 23, and the vent 39 is connected to the interior of the float 23.
[0041] It should be noted that the float 23 is hollow and made of an elastic material. The preferred material for this invention is soft polyvinyl chloride (with added plasticizer).
[0042] In this embodiment, air is introduced into the float 23 through the vent 39 or the float 23 is vented, causing the float 23 to expand or contract, thereby increasing or decreasing its volume. This adjusts the buoyancy of the float 23 in the water, improves its flexibility, and facilitates the float 23 to move the lower ladder 22 up and down under the action of buoyancy.
[0043] The working principle of this utility model is as follows: When the water level inside the cylinder 10 rises or falls, the float 23, under the action of buoyancy, drives the lower ladder 22 to move up and down along the upper ladder 21. This not only keeps the lower end of the lower ladder 22 above the water surface, reducing water contact with the lower ladder 22 and extending its service life, but also reduces water residue on the surface of the lower ladder 22, improving reliability. Furthermore, it causes relative displacement between the lower ladder 22 and the cleaning roller 24, allowing the cleaning roller 24 to roll along the lower ladder 22 and clean the residue on it. This makes it easier for operators to climb up the lower ladder 22 to the bottom of the cylinder 10 for inspection and maintenance, improving the convenience of inspection and maintenance.
[0044] The above description is merely a preferred embodiment of this utility model. It should be noted that those skilled in the art can make various improvements and modifications without departing from the principles of this utility model, and these improvements and modifications should also be considered within the scope of protection of this utility model. Structures, devices, and operating methods not specifically described or explained in this utility model, unless otherwise specified or limited, shall be implemented using conventional methods in the field.
Claims
1. A digital integrated pumping station based on artificial intelligence, characterized in that, The system includes a cylinder (10), which has several pump bodies (11) fixedly connected inside, and also includes: The segmented ladder (20) is located inside the cylinder (10). The segmented ladder (20) includes an upper ladder (21) fixedly connected to the top of the cylinder (10). The lower end of the upper ladder (21) is slidably connected to a lower ladder (22) in the vertical direction. The lower end of the lower ladder (22) is fixedly connected to several floats (23). A cleaning roller (24) is rotatably installed on the upper ladder (21). The cleaning roller (24) and the lower ladder (22) are in rolling cooperation. The float (23) moves the lower ladder (22) up and down as the water level rises and falls, causing the cleaning roller (24) to roll along the lower ladder (22).
2. The artificial intelligence-based digital integrated pumping station according to claim 1, characterized in that: A connecting frame (31) is slidably installed on the upper ladder (21) along the vertical direction, and the cleaning roller (24) is rotatably connected to the connecting frame (31).
3. The artificial intelligence-based digital integrated pumping station according to claim 2, characterized in that: The connecting frame (31) is slidably connected to the upper ladder (21) in the vertical direction. The connecting frame (31) is provided with a first limiting hole (32), and the upper ladder (21) is provided with a plurality of second limiting holes (33) in the vertical direction. The first limiting hole (32) and the second limiting hole (33) are slidably connected with limiting pins (34).
4. The artificial intelligence-based digital integrated pumping station according to claim 2, characterized in that: The cleaning roller (24) includes a roller body (35) rotatably connected to a connecting frame (31), and a plurality of bristles (36) are fixedly connected to the roller body (35), the bristles (36) being in close contact with the lower ladder (22).
5. The artificial intelligence-based digital integrated pumping station according to claim 1, characterized in that: A slide bar (37) is fixedly connected to the upper section of the ladder (21), and a slide groove (38) is fixedly connected to the lower section of the ladder (22). The slide bar (37) and the slide groove (38) slide together in the vertical direction.
6. The artificial intelligence-based digital integrated pumping station according to claim 1, characterized in that: A vent (39) is fixedly connected to the float (23), and the vent (39) is connected to the interior of the float (23).