Mountainous area intelligentization beam yard equipment

Abstract

The application belongs to the technical field of precast beam yard construction, and particularly relates to a mountainous intelligent beam yard device, which comprises a foundation, the upper surface of the foundation is provided with an inclined flow guide groove, the side surface of the flow guide groove is provided with water spray pipes in an arrayed and symmetrical manner, the vertical direction of the water spray pipes is provided with nozzles in an arrayed manner, and the opening direction of the nozzles is 45 degrees to the inclined inner bottom wall of the flow guide groove. The device is driven by an electric telescopic rod to swing the longitudinal baffle, so that sundries automatically slide off, self-cleaning is realized, manual frequent cleaning is avoided, and the operation efficiency of the drainage system is improved. The backflow mechanism is arranged, the hydraulic cylinder automatically adjusts the inclination angle of the main flow guide plate according to the rainfall intensity detected by the rainfall sensor, and the accurate control of the rainwater flow rate is realized. The auxiliary flow guide plate and the buffer strip can effectively absorb the rainwater impact kinetic energy, reduce noise and vibration, ensure smooth inflow of rainwater into the flow guide groove, and prevent splashing and overflow.

Description

Technical Field

[0001] This invention relates to the field of precast beam yard construction technology, and in particular to a digitalized beam yard equipment for mountainous areas. Background Technology

[0002] In the construction of bridges in mountainous areas, precast beam yards are typically located in valleys or on slopes, where the terrain presents significant challenges in designing drainage systems. Traditional beam yard drainage systems often rely on open ditches or culverts, which are easily clogged by rainwater carrying debris such as mud, leaves, and stones, leading to poor drainage, waterlogging, and even disruption to normal production at the beam yard. Existing drainage systems lack effective debris interception and automatic cleaning capabilities, requiring frequent manual cleaning, which is labor-intensive, inefficient, and poses safety hazards.

[0003] Furthermore, mountainous rainfall is characterized by its sudden onset and large volume. Traditional drainage ditches have limited capacity and cannot adjust water flow according to rainfall intensity, easily causing splashing and overflow, exacerbating muddy conditions. Simultaneously, a large amount of rainwater is directly discharged without effective collection and utilization, resulting in water waste. Rainwater storage tanks, as rainwater storage facilities, accumulate sediment at the bottom after long-term use. Manual dredging is difficult and costly, and requires interrupting tank operation, affecting water supply continuity.

[0004] To address the above problems, this invention proposes a digital intelligent beam yard device for mountainous areas. Summary of the Invention

[0005] Based on the technical problems of existing drainage systems, such as easy blockage by debris, poor rainwater diversion, difficulty in dredging water storage tanks, and inability to recycle rainwater resources, this invention proposes a digital intelligent beam yard equipment for mountainous areas.

[0006] This invention proposes a digital intelligent beam yard equipment for mountainous areas, comprising a foundation, an inclined guide channel on the upper surface of the foundation, water spray pipes symmetrically arranged on the side of the guide channel, nozzles arranged vertically on the water spray pipes, the opening direction of the nozzles being at a 45-degree angle to the inclined inner bottom wall of the guide channel, a backflow mechanism at the upper end of the foundation, a shielding mechanism at the upper end of the guide channel, a water storage tank on one side of the foundation, and a fixed connection between the inner wall of one end of the guide channel and the inner wall of the water storage tank, and a cleaning mechanism inside the water storage tank; The shielding mechanism performs a preliminary filtering action to prevent debris from entering the guide channel; The reverse flow mechanism is designed to regulate the rapid falling of rainwater. The cleaning mechanism is used to clean the bottom wall of the water storage tank.

[0007] Preferably, the shielding mechanism includes symmetrically arranged horizontal baffles, a vertical baffle is provided between the two horizontal baffles, a connecting component is rotatably connected between the side of the horizontal baffle and the side of the vertical baffle, filter grooves are arrayed on the upper surface of the horizontal baffle and the upper surface of the vertical baffle, and an electric telescopic rod is symmetrically rotatably connected to the side of the vertical baffle along its length direction, the electric telescopic rod being embedded in the foundation.

[0008] Preferably, the connecting component consists of a ball and a rod, with the two ends of the rod being spheres.

[0009] Preferably, the reversing mechanism includes symmetrically arranged support frames, with arc-shaped main flow plates symmetrically arranged at the upper end of the support frames. A cylindrical connecting rod is arranged between the two main flow plates, and the surface of the connecting rod is rotatably connected to the surface of the two main flow plates. Hydraulic cylinders are arranged in an array on the upper surface of the main beam of the support frame, and the upper end of the hydraulic cylinder is fixedly connected to the surface of the connecting rod. A guide flow plate is arranged above the connecting rod, and a buffer strip is arranged in a rectangular array on the lower surface of the guide flow plate. The surface of the buffer strip is in close contact with the upper surface of the main flow plate.

[0010] Preferably, a guide plate is provided between two adjacent support frames, and the inner wall of the guide plate is symmetrically set as an outward inclined surface along its length direction.

[0011] Preferably, the cleaning mechanism includes a hydraulic motor, and the horizontal axis of the water storage tank is symmetrically embedded with sealed bearings. The inner ring of the sealed bearing is fixedly connected to the output shaft of the hydraulic motor. A lead screw is connected between the inner rings of the two longitudinal sealed bearings, and a lead screw nut is slidably connected to the surface of the lead screw. A sprocket is provided at the end of each of the two transverse lead screws, and a chain meshes between the two sprockets. The two sides of the longitudinal water storage tank are symmetrically provided with L-shaped mounting grooves adapted to the lead screws.

[0012] Preferably, an adsorption head is connected between the two lead screw nuts, a negative pressure adsorption tube is fixedly connected to the upper end of the adsorption head, an adsorption chamber is arranged in an array at intervals on one side of the adsorption head, the inner wall of the adsorption tube is fixedly connected to the inner top wall of the adsorption chamber, and the other end of the adsorption tube is externally connected to a spring-type telescopic vacuum pipeline and a high negative pressure vacuum suction machine.

[0013] Preferably, the lower surface of the adsorption head is provided with a wear-resistant bristle layer that contacts the bottom wall of the water storage tank.

[0014] Preferably, a water supply pump is installed on the inner bottom wall of the water storage tank, and the outlet end of the water supply pump is fixedly connected to the inlet end of the spray pipe through a hose.

[0015] Preferably, a rain sensor is provided on the upper surface of the guide plate, and the rain sensor is electrically connected to the hydraulic cylinder.

[0016] The beneficial effects of this invention are as follows: 1. By setting up a shielding mechanism, the filter grooves on the horizontal and vertical baffles can perform preliminary filtration of rainwater entering the diversion channel, intercepting large debris such as leaves and stones; the electric telescopic rod drives the vertical baffle to swing, causing the debris to slide off automatically, achieving self-cleaning, avoiding frequent manual cleaning, and improving the operating efficiency of the drainage system.

[0017] 2. By setting up a reverse flow mechanism, the hydraulic cylinder automatically adjusts the tilt angle of the main flow vane according to the rainfall intensity detected by the rain sensor, so as to achieve precise control of the rainwater flow rate; the main flow vane and its buffer strip can effectively absorb the impact kinetic energy of rainwater, reduce noise and vibration, ensure that rainwater flows smoothly into the guide channel, and prevent splashing and overflow.

[0018] 3. By setting up a cleaning mechanism, the hydraulic motor drives the lead screw to move the adsorption head back and forth in the water storage tank, and works with the high negative pressure vacuum suction machine to adsorb and clean the sediment at the bottom of the tank; the wear-resistant bristle layer on the lower surface of the adsorption head can brush up the attached stains, significantly improving the cleaning effect, ensuring the long-term effective operation of the water storage tank, and reducing the cost of manual dredging.

[0019] 4. By setting up water spray pipes and water supply pumps, the rainwater collected in the water storage tank is pressurized and used for flushing the diversion channel, realizing the recycling of water resources; the 45-degree angle design of the spray pipe nozzles forms a rotating flushing flow field, which enhances the cleaning effect, reduces water consumption, and meets the requirements of green construction and energy conservation and environmental protection. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of a digitalized beam yard equipment for mountainous areas proposed in this invention; Figure 2 This is a diagram showing the location of the guide channel for a digitalized beam yard device in mountainous areas, as proposed in this invention. Figure 3 This is a perspective view of a shielding mechanism for a digitalized beam yard equipment in mountainous areas proposed in this invention; Figure 4 This is a perspective view of the connecting components of a digital intelligent beam yard equipment for mountainous areas proposed in this invention; Figure 5 This is a front view of a digitalized beam yard equipment for mountainous areas proposed in this invention; Figure 6 This invention proposes a digital intelligent beam yard equipment for mountainous areas. Figure 5 Enlarged view of point A in the middle; Figure 7 This is a cross-sectional view of the water storage tank of a digitalized beam yard equipment in mountainous areas proposed in this invention; Figure 8 This is a three-dimensional view of the adsorption tube of a digital intelligent beam yard device for mountainous areas proposed in this invention.

[0021] In the diagram: 1. Foundation; 10. Guide channel; 11. Spray pipe; 2. Shielding mechanism; 21. Horizontal baffle; 22. Vertical baffle; 23. Connecting component; 24. Electric telescopic rod; 3. Reverse flow mechanism; 31. Support frame; 32. Guide plate; 33. Connecting rod; 34. Assisted flow plate; 35. Hydraulic cylinder; 36. Drainage plate; 4. Water storage tank; 5. Cleaning mechanism; 51. Hydraulic motor; 52. Sealed bearing; 53. Lead screw; 54. Sprocket; 55. Chain; 56. Installation trough; 57. Adsorption pipe; 58. Adsorption head. Detailed Implementation

[0022] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.

[0023] Reference Figures 1-8 A digitalized beam yard equipment for mountainous areas includes a foundation 1. An inclined guide channel 10 is formed on the upper surface of the foundation 1. Water spray pipes 11 are symmetrically arranged on the side of the guide channel 10. Nozzles are arranged in a vertical array on the water spray pipes 11. The opening direction of the nozzles is at a 45-degree angle to the inclined inner bottom wall of the guide channel 10. A backflow mechanism 3 is provided at the upper end of the foundation 1. A blocking mechanism 2 is provided at the upper end of the guide channel 10. A water storage tank 4 is formed on one side of the foundation 1. The inner wall of one end of the guide channel 10 is fixedly connected to the inner wall of the water storage tank 4. A cleaning mechanism 5 is provided inside the water storage tank 4.

[0024] The shielding mechanism 2 performs a preliminary filtering action to prevent debris from entering the guide channel 10.

[0025] The reverse flow mechanism 3 is designed to regulate the rapid falling of rainwater.

[0026] The cleaning mechanism 5 is designed to clean the bottom wall of the water storage tank 4.

[0027] In this embodiment, the shielding mechanism 2 includes symmetrically arranged horizontal baffles 21, and a vertical baffle 22 is arranged between the two horizontal baffles 21. A connecting component 23 is rotatably connected between the side of the horizontal baffle 21 and the side of the vertical baffle 22. Filter grooves are arrayed on the upper surface of the horizontal baffle 21 and the upper surface of the vertical baffle 22. An electric telescopic rod 24 is symmetrically rotatably connected to the side of the vertical baffle 22 along its length direction. The electric telescopic rod 24 is embedded inside the foundation 1.

[0028] Specifically, the telescopic end of the electric telescopic rod 24 is rotatably connected to the side of the longitudinal baffle 22. The telescopic movement of the electric telescopic rod 24 drives the longitudinal baffle 22 to swing around the connecting component 23, thereby changing the angle between the transverse baffle 21 and the longitudinal baffle 22. When rainwater falls, the filter tank initially intercepts debris; when too much debris accumulates, the electric telescopic rod 24 pushes the longitudinal baffle 22 to tilt, causing the debris to slide down the transverse baffle 21 to the ground, achieving automatic cleaning. The connecting component 23 consists of balls and rods. The balls at both ends of the rod are embedded in corresponding sockets in the transverse baffle 21 and the longitudinal baffle 22, forming a universal hinge structure, allowing the longitudinal baffle 22 to rotate flexibly at multiple angles.

[0029] In this embodiment, the connecting component 23 is composed of a ball and a rod, with the two ends of the rod being balls.

[0030] Specifically, the balls at both ends of the rod of the connecting component 23 are respectively engaged with the ball sockets on the sides of the horizontal baffle 21 and the vertical baffle 22 to form a ball joint connection.

[0031] In this embodiment, the reversing mechanism 3 includes a symmetrically arranged support frame 31. An arc-shaped main flow plate 32 is symmetrically arranged on the upper end of the support frame 31. A cylindrical connecting rod 33 is arranged between the two main flow plates 32. The surface of the connecting rod 33 is rotatably connected to the surface of the two main flow plates 32. A hydraulic cylinder 35 is arranged in an array on the upper surface of the main beam of the support frame 31. The upper end of the hydraulic cylinder 35 is fixedly connected to the surface of the connecting rod 33. A guide flow plate 34 is arranged above the connecting rod 33. A buffer strip is arranged in a rectangular array on the lower surface of the guide flow plate 34. The surface of the buffer strip is in close contact with the upper surface of the main flow plate 32.

[0032] Specifically, the piston rod of the hydraulic cylinder 35 extends upward, pushing the connecting rod 33 to rise and fall, which in turn drives the two main flow plates 32 to rotate synchronously around their hinge point with the support frame 31, thereby adjusting the tilt angle of the main flow plates 32 and controlling the rainwater flow rate. The auxiliary flow plate 34 makes elastic contact with the upper surface of the main flow plate 32 through a buffer strip. When rainwater impacts, the buffer strip absorbs some of the kinetic energy, reducing noise and vibration. At the same time, the auxiliary flow plate 34 further guides the rainwater to flow smoothly into the guide channel 10, preventing rainwater splashing. The buffer strip is made of rubber or silicone material, which has good elasticity and wear resistance.

[0033] In this embodiment, a guide plate 36 is provided between two adjacent support frames 31, and the inner wall of the guide plate 36 is symmetrically set as an outward inclined surface along its length direction.

[0034] Specifically, the drainage plate 36 is fixed between adjacent support frames 31, and its symmetrically arranged outward inclined surfaces form an inverted V-shaped flow guiding structure, which allows rainwater falling on the drainage plate 36 to be quickly diverted to both sides, preventing rainwater from accumulating between the support frames 31. At the same time, a gap is left between the lower edge of the drainage plate 36 and the upper surface of the main flow plate 32, so that rainwater falls directly into the flow channel 10, ensuring the continuity of drainage.

[0035] In this embodiment, the cleaning mechanism 5 includes a hydraulic motor 51. Each horizontal axis of the water storage tank 4 is symmetrically embedded with a sealed bearing 52. The inner ring of the sealed bearing 52 is fixedly connected to the output shaft of the hydraulic motor 51. A lead screw 53 is connected between the inner rings of the two longitudinal sealed bearings 52. A lead screw nut is slidably connected to the surface of the lead screw 53. A sprocket 54 is provided at the end of each of the two transverse lead screws 53. A chain 55 meshes between the two sprockets 54. The two sides of the longitudinal water storage tank 4 are symmetrically provided with L-shaped mounting grooves 56 that are adapted to the lead screw 53.

[0036] Specifically, the hydraulic motor 51 drives the lead screw 53 connected to it to rotate. Through the transmission of the sprocket 54 and the chain 55, the two lead screws 53 arranged laterally rotate synchronously. The lead screw 53 drives the lead screw nut to move axially, thereby driving the adsorption head 58 connected between the two lead screw nuts to reciprocate within the water storage tank 4. The sealed bearing 52 ensures the sealing of the lead screw 53 where it passes through the tank wall, preventing water leakage.

[0037] In this embodiment, an adsorption head 58 is connected between two lead screw nuts. A negative pressure adsorption tube 57 is fixedly connected to the upper end of the adsorption head 58. Adsorption chambers are arranged in an array at intervals on one side of the adsorption head 58. The inner wall of the adsorption tube 57 is fixedly connected to the inner top wall of the adsorption chamber. The other end of the adsorption tube 57 is externally connected to a spring-type telescopic vacuum pipeline and a high negative pressure vacuum suction machine.

[0038] Specifically, as the adsorption head 58 moves with the lead screw nut, the high-negative-pressure vacuum feeder generates negative pressure in the adsorption chamber through the adsorption pipe 57, drawing the sediment at the bottom of the water storage tank 4 into the adsorption chamber and discharging it along the adsorption pipe 57. The spring-loaded telescopic vacuum pipeline automatically extends and retracts with the movement of the adsorption head 58, preventing pipeline tangling. The openings of the adsorption chambers face the bottom of the tank and are spaced apart to ensure uniform suction coverage and improve cleaning efficiency.

[0039] In this embodiment, the lower surface of the adsorption head 58 is provided with a wear-resistant bristle layer that contacts the bottom wall of the water storage tank 4.

[0040] Specifically, the wear-resistant bristle layer is formed by embedding high-strength nylon bristles into the lower surface of the adsorption head 58. As the adsorption head 58 moves, the bristles sweep across the bottom of the pool, brushing up the sludge, moss, and other sediments attached to the bottom, suspending them in the water for easy absorption by the adsorption chamber. The bristles are in close contact with the bottom of the pool, effectively removing stubborn stains while protecting the bottom coating from damage.

[0041] In this embodiment, a water supply pump is installed on the inner bottom wall of the water storage tank 4, and the outlet end of the water supply pump is fixedly connected to the inlet end of the spray pipe 11 through a hose.

[0042] Specifically, the water pump pressurizes the rainwater stored in the reservoir 4 and delivers it to the spray pipe 11. Multiple nozzles in the vertical direction of the spray pipe 11 spray water at a 45-degree angle to the inner bottom wall of the guide channel 10, washing away the mud and debris remaining in the guide channel 10 and keeping the guide channel unobstructed. The angle design of the nozzles creates a rotating flushing effect, enhancing the cleaning ability.

[0043] In this embodiment, a rain sensor is provided on the upper surface of the deflector plate 32, and the rain sensor is electrically connected to the hydraulic cylinder 35.

[0044] Specifically, the rain sensor detects rainfall intensity in real time and transmits the signal to the controller. The controller controls the extension and retraction of the hydraulic cylinder 35 according to a preset program, automatically adjusting the tilt angle of the main flow deflector 32. When the rainfall is heavy, the angle of the main flow deflector 32 increases, accelerating the speed at which rainwater flows into the guide channel 10; when the rainfall is light, the angle of the main flow deflector 32 decreases, slowing the water flow and preventing splashing. This intelligent control improves rainwater collection efficiency and reduces manual intervention.

[0045] Reference Figures 1-8 A method for recycling water in a digitalized beam yard in mountainous areas, the specific steps of which are as follows: Step 1: During rainfall, the filter grooves on the horizontal baffle 21 and vertical baffle 22 of the shielding mechanism 2 initially intercept debris such as leaves and stones in the rainwater. The rain sensor detects the real-time rainfall intensity and transmits the signal to the controller. The controller controls the hydraulic cylinder 35 to extend and retract, pushing the connecting rod 33 to rotate the main flow plate 32 to a suitable angle. After being buffered by the auxiliary flow plate 34, the rainwater flows along the main flow plate 32 and the guide plate 36 into the guide channel 10, and then flows into the water storage tank 4 along the inclined guide channel 10. When too much debris accumulates, the electric telescopic rod 24 pushes the vertical baffle 22 to tilt, causing the debris to automatically slide off to the ground. Step 2: Periodically start the hydraulic motor 51, which drives the two horizontal lead screws 53 to rotate synchronously through the sprocket 54 and chain 55, causing the lead screw nut and the adsorption head 58 to move back and forth along the length of the water storage tank 4; at the same time, the external high negative pressure vacuum suction machine works, and the wear-resistant brush layer on the lower surface of the adsorption head 58 brushes up the sediment at the bottom of the tank. The adsorption chamber sucks in the sediment under negative pressure and discharges it outside the tank through the adsorption pipe 57 and the spring-type telescopic vacuum pipeline, thus realizing the automatic cleaning of the bottom wall of the water storage tank 4. Step 3: The water pump in the water storage tank 4 pressurizes the stored rainwater and delivers it through a hose to the spray pipe 11 on the side of the diversion channel 10. Multiple nozzles in the vertical direction of the spray pipe 11 spray high-pressure water at a 45-degree angle to the bottom wall of the diversion channel 10, rotating and washing away residual mud, sand and debris. The washed water flows back into the diversion channel 10 and back into the water storage tank 4, realizing the recycling of rainwater and keeping the drainage system unobstructed.

[0046] The above description is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.

Claims

1. A digitalized beam yard equipment for mountainous areas, characterized in that: The foundation (1) includes an inclined guide channel (10) on its upper surface. Water spray pipes (11) are symmetrically arranged on the side of the guide channel (10). Nozzles are arranged in the vertical direction of the water spray pipes (11). The opening direction of the nozzles is at a 45-degree angle to the inclined inner bottom wall of the guide channel (10). A backflow mechanism (3) is provided at the upper end of the foundation (1). A shielding mechanism (2) is provided at the upper end of the guide channel (10). A water storage tank (4) is provided on one side of the foundation (1). The inner wall of one end of the guide channel (10) is fixedly connected to the inner wall of the water storage tank (4). A cleaning mechanism (5) is provided inside the water storage tank (4). The shielding mechanism (2) performs a preliminary filtering action to prevent debris from entering the guide channel (10); The reverse flow mechanism (3) is designed to regulate the rapid falling of rainwater; The cleaning mechanism (5) is used to clean the bottom wall of the water storage tank (4).

2. The intelligent beam yard equipment for mountainous areas according to claim 1, characterized in that: The shielding mechanism (2) includes symmetrically arranged horizontal baffles (21), and a vertical baffle (22) is arranged between the two horizontal baffles (21). A connecting component (23) is rotatably connected between the side of the horizontal baffle (21) and the side of the vertical baffle (22). Filter grooves are arrayed on the upper surface of the horizontal baffle (21) and the upper surface of the vertical baffle (22). An electric telescopic rod (24) is symmetrically rotatably connected to the side of the vertical baffle (22) along its length direction. The electric telescopic rod (24) is embedded inside the foundation (1).

3. The intelligent beam yard equipment for mountainous areas according to claim 2, characterized in that: The connecting component (23) consists of a ball and a rod, with the two ends of the rod being balls.

4. The intelligent beam yard equipment for mountainous areas according to claim 3, characterized in that: The reverse flow mechanism (3) includes a symmetrically arranged support frame (31). An arc-shaped main flow plate (32) is symmetrically arranged on the upper end of the support frame (31). A cylindrical connecting rod (33) is arranged between the two main flow plates (32). The surface of the connecting rod (33) is rotatably connected to the surface of the two main flow plates (32). A hydraulic cylinder (35) is arranged in an array on the upper surface of the main beam of the support frame (31). The upper end of the hydraulic cylinder (35) is fixedly connected to the surface of the connecting rod (33). A guide flow plate (34) is arranged above the connecting rod (33). A buffer strip is arranged in a rectangular array on the lower surface of the guide flow plate (34). The surface of the buffer strip is in close contact with the upper surface of the main flow plate (32).

5. The intelligent beam yard equipment for mountainous areas according to claim 4, characterized in that: A guide plate (36) is provided between two adjacent support frames (31), and the inner wall of the guide plate (36) is symmetrically set as an outward inclined surface along its length direction.

6. The intelligent beam yard equipment for mountainous areas according to claim 5, characterized in that: The cleaning mechanism (5) includes a hydraulic motor (51). The horizontal axis of the water storage tank (4) is symmetrically embedded with sealed bearings (52). The inner ring of the sealed bearing (52) is fixedly connected to the output shaft of the hydraulic motor (51). A lead screw (53) is connected between the inner rings of the two longitudinal sealed bearings (52). A lead screw nut is slidably connected to the surface of the lead screw (53). A sprocket (54) is provided at the end of the two transverse lead screws (53). A chain (55) meshes between the two sprockets (54). The two sides of the longitudinal water storage tank (4) are symmetrically provided with L-shaped mounting grooves (56) that are adapted to the lead screws (53).

7. The intelligent beam yard equipment for mountainous areas according to claim 6, characterized in that: An adsorption head (58) is connected between the two lead screw nuts. A negative pressure adsorption tube (57) is fixedly connected to the upper end of the adsorption head (58). Adsorption chambers are arranged in an array at intervals on one side of the adsorption head (58). The inner wall of the adsorption tube (57) is fixedly connected to the inner top wall of the adsorption chamber. The other end of the adsorption tube (57) is externally connected to a spring-type telescopic vacuum pipeline and a high negative pressure vacuum suction machine.

8. The intelligent beam yard equipment for mountainous areas according to claim 7, characterized in that: The lower surface of the adsorption head (58) is provided with a wear-resistant bristle layer that contacts the bottom wall of the water storage tank (4).

9. The intelligent beam yard equipment for mountainous areas according to claim 8, characterized in that: The inner bottom wall of the water storage tank (4) is equipped with a water supply pump, and the outlet end of the water supply pump is fixedly connected to the inlet end of the spray pipe (11) through a hose.

10. A digitalized beam yard equipment for mountainous areas according to claim 9, characterized in that: A rain sensor is provided on the upper surface of the guide plate (32), and the rain sensor is electrically connected to the hydraulic cylinder (35).

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