Intelligent communication operation management and control system deployment device and method of use thereof

By deploying the lifting cylinder and limit mechanism of the equipment through the intelligent communication operation and control system, the area division is completed automatically, which solves the problem of low efficiency of manual operation in the existing technology and realizes the rapid division and efficient deployment of communication control areas.

CN116005663BActive Publication Date: 2026-06-23GUANGZHOU POWER SUPPLY BUREAU GUANGDONG POWER GRID CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
GUANGZHOU POWER SUPPLY BUREAU GUANGDONG POWER GRID CO LTD
Filing Date
2022-11-30
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

The regional division and deployment of the existing communication operation and management system relies on manual operation, resulting in high workload and low efficiency.

Method used

Design an intelligent communication operation and control system deployment device, including a lifting cylinder, a limiting mechanism and an intermittent pushing mechanism. Through the coordinated work of the power drive mechanism and the sensing control mechanism, it automatically completes the area division operation, forms equidistant deep holes and pushes wooden piles.

Benefits of technology

It enables rapid division of communication control areas, significantly improving work efficiency and reducing the intensity of manual operations.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application relates to the field of communication, in particular to an intelligent communication operation management and control system deployment device and a use method thereof. The intelligent communication operation management and control system deployment device comprises a base, further comprises a lifting cylinder movably arranged on the base, the outer periphery of the lifting cylinder is provided with spiral blades, and the lifting cylinder is connected with a power driving mechanism mounted on the base; the power driving mechanism is used for driving the lifting cylinder to maintain a rotating state and execute a lifting action; a limiting mechanism is mounted on the base and is used for limiting wood piles arranged at equal distances; the limiting mechanism is connected with a sensing control mechanism mounted on the base; the sensing control mechanism communicates with the power driving mechanism; finally, when a physical construction of a communication operation management and control system is carried out, through mutual cooperation between various mechanisms and components in the device, effective deployment auxiliary functions are realized, the communication management and control area is quickly divided, and the work efficiency is remarkably improved.
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Description

Technical Field

[0001] This invention relates to the field of communications, specifically to a deployment device for an intelligent communication operation and management system and its usage method. Background Technology

[0002] Before we knew it, we had already stepped into the threshold of the 5G era. In just a few decades, from the 1G era to the 5G era, the whole world has undergone earth-shaking changes. Every communication upgrade is a new industrial revolution, driving the whole society forward.

[0003] A large-scale communication system needs to be built on a sound operation and management system. The implementation of a communication operation and management system can effectively improve the accuracy of resource data and the efficiency of resource allocation when services are launched; it also enables the correlation between faults and alarms, allowing network faults to be proactively detected and optimizing communication.

[0004] Currently, when implementing a communication operation and control system, it is necessary to first select a suitable area and deploy relevant control measures within that area. This requires site selection and area division. However, when dividing and deploying areas, staff need to mark the edges of the areas with stakes to facilitate the construction of physical structures within the designated areas. This work is usually done by staff, which is labor-intensive and inefficient. Summary of the Invention

[0005] The purpose of this invention is to provide a deployment device for an intelligent communication operation and management system and a method for using it, so as to solve the problems mentioned in the background art.

[0006] To achieve the above objectives, the present invention provides the following technical solution:

[0007] A deployment device for an intelligent communication operation and control system, used to assist in the area division operation of the communication operation and control system, includes a base and further includes:

[0008] A lifting cylinder is movably mounted on the base. It has spiral blades on its outer periphery and is connected to a power drive mechanism mounted on the base. The power drive mechanism is used to drive the lifting cylinder to maintain a rotating state and perform lifting actions, so that the lifting cylinder forms a deep hole in the ground of the controlled area through the spiral blades.

[0009] A limiting mechanism is installed on the base to limit the equidistant wooden stakes, and the limiting mechanism is connected to a sensing and control mechanism installed on the base, and the sensing and control mechanism communicates with the power drive mechanism.

[0010] An intermittent ejection mechanism is installed on the base and connected to the power drive mechanism. The intermittent ejection mechanism is triggered during the latter part of the upward stroke of the lifting cylinder and performs an ejection action on the wooden stake so that the wooden stake enters the deep hole.

[0011] As a further aspect of the present invention: the power drive mechanism includes a power component mounted on the base and a lifting execution component connected to the power component, the power component including a drive shaft rotatably mounted on the base and a drive motor mounted on the base;

[0012] The output end of the drive motor is connected to the drive shaft, which is slidably engaged with the lifting cylinder via a locking structure and connected to the lifting actuator.

[0013] As a further embodiment of the present invention: the lifting execution component cooperates with the sensing and control mechanism and is connected to the intermittent pushing mechanism. The lifting execution component includes a first lead screw rotatably mounted on the base and a threaded sleeve disposed on and threadedly connected to the first lead screw.

[0014] The threaded sleeve has two protruding posts fixed on it, and a push-pull rod is rotatably mounted on each of the two protruding posts. One end of the first lead screw is connected to the drive shaft through a third bevel gear set, and a connecting plate is rotatably mounted on the lifting cylinder. The connecting plate is rotatably connected to the end of the two push-pull rods away from the protruding posts.

[0015] As a further embodiment of the present invention: the limiting mechanism includes a horizontal clamping structure mounted on the base and an elastic pressing structure disposed on the base, and the elastic pressing structure is connected to the sensing and control mechanism.

[0016] The horizontal clamping structure includes multiple straight rods fixed to the base by protrusions and a clamping plate slidably disposed on the multiple straight rods. Two first cylindrical springs are also sleeved on the outer periphery of the straight rods, and the two ends of the first cylindrical springs are respectively connected to the clamping plate and the protrusions.

[0017] As a further embodiment of the present invention: the elastic pressure-resistant structure includes two stepped shafts slidably disposed on the base, a horizontal plate fixedly installed on the upper end of the two stepped shafts, and a second cylindrical spring respectively sleeved on the outer periphery of the two stepped shafts.

[0018] The stepped shaft has a parting surface at one end away from the horizontal plate, and the two ends of the second cylindrical spring are respectively connected to the base and the parting surface.

[0019] As a further embodiment of the present invention: the sensing and control mechanism includes a geared transmission structure and a connecting structure mounted on the base and connected to the horizontal plate. The connecting structure includes two drive wheels rotatably mounted on the base, a connector that rolls between the two drive wheels, two guide rods fixed on the base, and a transverse plate slidably mounted on the two guide rods and connected to the connector. A fixing rod is fixed on the threaded sleeve. A pressure sensor is mounted on the side of the transverse plate facing the fixing rod. The pressure sensor communicates with the drive motor.

[0020] The gear transmission structure includes a rack plate fixedly mounted on the horizontal plate and a transmission shaft and a second gear rotatably mounted on the bottom of the base. The second gear meshes with the rack plate. One end of the transmission shaft is connected to the rotating shaft of the second gear through a second transmission belt, and the other end is connected to the rotating shaft of one of the drive wheels through a second bevel gear set.

[0021] As a further embodiment of the present invention: the intermittent ejection mechanism includes a one-way triggering structure connected to the threaded sleeve and a circumferential drive assembly mounted on the base and connected to the one-way triggering structure;

[0022] The one-way triggering structure includes a long bar fixedly installed at the end of the protrusion away from the threaded sleeve and a ratchet rotatably installed at the bottom of the base. The bottom of the long bar has multiple inclined slots equidistantly opened along its length direction, and each inclined slot has a pawl that cooperates with the ratchet.

[0023] As a further embodiment of the present invention: the circumferential drive assembly includes an elastic sliding structure mounted on the base and a rotating structure connected to the elastic sliding structure, and the rotating structure is connected to the rotating shaft of the ratchet;

[0024] The elastic sliding structure includes two long rods fixedly installed on the base by a vertical plate, a reciprocating plate slidably disposed on the two long rods, and two third columnar springs respectively sleeved on the outer periphery of the two long rods;

[0025] The third cylindrical spring is connected to the reciprocating plate and the vertical plate at both ends, respectively. Two push rods are fixed on one side of the reciprocating plate and a strip rod is fixed on the other side. The strip rod is connected to the rotating structure.

[0026] As a further embodiment of the present invention: the rotating structure includes a rotating plate rotatably mounted on the base, a pulley movably disposed on the rotating plate and abutting against the bar, and the rotating shaft of the rotating plate is connected to the rotating shaft of the ratchet through a first transmission belt;

[0027] A second lead screw is rotatably mounted on the rotating plate. The second lead screw is provided with a threaded block that is threadedly connected to it. The pulley is rotatably mounted on the side of the threaded block that is away from the rotating plate.

[0028] A first gear is rotatably mounted on the rotating plate. The rotating shaft of the first gear is connected to the second lead screw through a first bevel gear set. An arc-shaped component is also fixedly mounted on the base. The inner wall of the arc-shaped component is provided with teeth that cooperate with the first gear.

[0029] A method for using the deployment equipment of the intelligent communication operation management and control system includes the following steps:

[0030] Step 1: Determine the communication operation and control area, and move the equipment to the periphery of the area;

[0031] Step 2: Add wooden stakes into the limiting mechanism and check whether the communication between the sensing and control mechanism and the power drive mechanism is normal.

[0032] Step 3: The power drive mechanism works and communicates with the sensor control mechanism to drive the lifting cylinder to perform the opening action, and the intermittent pushing mechanism pushes the wooden pile to fall into the deep hole in the ground.

[0033] Step four: After the equipment moves a certain distance, the power drive mechanism works again, and the cycle repeats to complete the deployment of communication operation and control.

[0034] Compared with the prior art, the beneficial effects of the present invention are as follows: The present invention has a novel design. In actual use, multiple wooden stakes can be arranged on the base through the limiting mechanism. The device moves intermittently and equidistantly within the communication control area. When the power drive mechanism is working, it drives the lifting cylinder to maintain rotation and simultaneously drives the lifting cylinder to perform a lifting action to form a deep hole for pile driving on the bottom surface of the communication control area. Subsequently, the device moves so that the limiting mechanism corresponds to the deep hole, and the lifting cylinder moves to the next opening. When the power drive mechanism works again, it performs a second opening. During the latter part of the lifting cylinder's upward stroke, the intermittent pushing mechanism is triggered, pushing the wooden stake in the limiting mechanism into a deep hole on the ground. This cycle repeats. In the actual construction of the communication operation control system, the mutual cooperation between the various mechanisms and components in the device realizes an effective deployment auxiliary function, accelerates the rapid division of the communication control area, and significantly improves work efficiency. Attached Figure Description

[0035] Figure 1 A schematic diagram of one embodiment of the equipment deployed for an intelligent communication operation and control system.

[0036] Figure 2A schematic diagram of another aspect of an embodiment of deploying equipment for an intelligent communication operation and control system.

[0037] Figure 3 A schematic diagram of the structure from another angle of one embodiment of the equipment deployment for the intelligent communication operation and management system.

[0038] Figure 4 for Figure 1 Enlarged view of the structure at point A in the middle.

[0039] Figure 5 for Figure 2 Enlarged view of the structure at point B in the middle.

[0040] Figure 6 for Figure 3 Enlarged view of the structure at point C.

[0041] Figure 7 for Figure 3 Enlarged view of the structure at point D.

[0042] Figure 8 A schematic diagram of the power drive mechanism and the sensing control mechanism in one embodiment of the equipment deployed for the intelligent communication operation and management system.

[0043] Figure 9 A schematic diagram of the intermittent push mechanism in one embodiment of the equipment deployed for the intelligent communication operation and control system.

[0044] In the diagram: 1. Base; 101. Lug; 2. Lifting cylinder; 201. Strip groove; 3. Drive motor; 4. Drive shaft; 401. Strip protrusion; 5. First lead screw; 6. Threaded sleeve; 601. Protrusion; 7. Connecting plate; 8. Push-pull rod; 9. Fixing rod; 10. Pressure sensor; 11. Guide rod; 12. Transverse plate; 13. Drive wheel; 14. Connecting piece; 15. Long bar; 16. Ratchet; 17. First transmission belt; 18. Rotating plate; 19. Pulley; 20. Second lead screw; 21. Thread 21. Block; 22. First bevel gear set; 23. First gear; 24. Arc-shaped component; 25. Vertical plate; 26. Long rod; 27. Reciprocating plate; 2701. Push rod; 2702. Strip rod; 28. Protruding block; 29. ​​Straight rod; 30. First cylindrical spring; 31. Clamping plate; 32. Stepped shaft; 33. Second cylindrical spring; 34. Horizontal plate; 35. Rack plate; 36. Second gear; 37. Drive shaft; 38. Second bevel gear set; 39. Third bevel gear set; 40. Second drive belt; 41. Third cylindrical spring. Detailed Implementation

[0045] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0046] Furthermore, elements in this invention are referred to as being "fixed to" or "set on" another element, which may be directly on the other element or may also include an intervening element. When an element is considered to be "connected" to another element, it may be directly connected to the other element or may also include an intervening element. The terms "vertical," "horizontal," "left," "right," and similar expressions used herein are for illustrative purposes only and do not represent the only possible implementations.

[0047] Please see Figure 1-9 In this embodiment of the invention, an intelligent communication operation and control system deployment device is provided to assist the area division operation of the communication operation and control system. It includes a base 1 and a lifting cylinder 2, which is movably disposed on the base 1. The cylinder has spiral blades on its outer periphery and is connected to a power drive mechanism installed on the base 1. The power drive mechanism is used to drive the lifting cylinder 2 to maintain a rotating state and perform lifting actions so that the lifting cylinder 2 forms a deep hole in the ground of the control area through the spiral blades.

[0048] A limiting mechanism is installed on the base 1 to limit the wooden stakes arranged at equal intervals. The limiting mechanism is connected to a sensing and control mechanism installed on the base 1, and the sensing and control mechanism communicates with the power drive mechanism.

[0049] An intermittent ejection mechanism is installed on the base 1 and connected to the power drive mechanism. The intermittent ejection mechanism is triggered during the latter part of the upward stroke of the lifting cylinder 2 and performs an ejection action on the wooden stake so that the wooden stake enters the deep hole.

[0050] It should be noted that the base 1 is also provided with multiple support legs at its bottom, and each support leg is provided with a walking wheel for the device to move within the communication control area. The device is also provided with a power source for automatically driving the device to move. In actual use, a corresponding driver's cab can be set on the base 1 so that communication personnel can operate the device to move and carry out deployment work from the driver's cab.

[0051] In actual use, multiple wooden stakes can be arranged on the base 1 through the limiting mechanism. The equipment moves intermittently at equal intervals within the communication control area. When the power drive mechanism is working, it will drive the lifting cylinder 2 to keep rotating and at the same time drive the lifting cylinder 2 to perform a lifting action to form a deep hole for pile driving on the bottom surface of the communication control area.

[0052] Subsequently, the equipment moves so that the limiting mechanism aligns with the deep hole, and the lifting cylinder 2 moves to the next opening. When the power drive mechanism works again, it performs a second opening. During the latter part of the upward stroke of the lifting cylinder 2, the intermittent pushing mechanism is triggered, pushing the wooden stake in the limiting mechanism into a deep hole on the ground. Finally, the workers can then compact the wooden stake (by hammering and filling it with soil).

[0053] This cycle repeats itself, and during the physical construction of the communication operation and control system, the cooperation between various mechanisms and components in the equipment enables effective deployment assistance functions, accelerates the rapid division of the communication control area, and significantly improves work efficiency.

[0054] Please refer to it again. Figure 1 and Figure 8 The power drive mechanism includes a power component mounted on the base 1 and a lifting actuator connected to the power component. The power component includes a drive shaft 4 rotatably mounted on the base 1 and a drive motor 3 mounted on the base 1. The output end of the drive motor 3 is connected to the drive shaft 4. The drive shaft 4 is slidably fitted with the lifting cylinder 2 through a snap-fit ​​structure and is connected to the lifting actuator.

[0055] In detail, the engaging structure includes a plurality of strip-shaped protrusions 401 fixed at equal intervals along the circumference on the outer periphery of the drive shaft 4 and a plurality of strip-shaped grooves 201 opened at equal intervals along the circumference on the inner wall of the lifting cylinder 2. The strip-shaped grooves 201 are slidably adapted to the strip-shaped protrusions 401, and both are parallel to the central axis of the drive shaft 4 and the lifting cylinder 2.

[0056] The lifting execution component cooperates with the sensing and control mechanism and is connected to the intermittent pushing mechanism. The lifting execution component includes a first lead screw 5 rotatably mounted on the base 1 and a threaded sleeve 6 disposed on and threadedly connected to the first lead screw 5.

[0057] The threaded sleeve 6 has two protrusions 601 fixed on it, and each of the two protrusions 601 is rotatably mounted with a push-pull rod 8. One end of the first lead screw 5 is connected to the drive shaft 4 through the third bevel gear set 39, and a connecting plate 7 is rotatably mounted on the lifting cylinder 2. The connecting plate 7 is rotatably connected to the end of the two push-pull rods 8 away from the protrusions 601.

[0058] Specifically, the third bevel gear set 39 includes a fifth bevel gear fixedly mounted on the drive shaft 4 and a sixth bevel gear fixed to one end of the first lead screw 5 facing the drive shaft 4, and the sixth bevel gear meshes with the fifth bevel gear;

[0059] In addition, it should be noted that the drive motor 3 is a servo motor with bidirectional output, and adopts the 4IK / 80YYJT model motor. This model of motor has stable performance. Other models of motors can also be used as long as they meet the drive requirements. This application does not make specific limitations in this regard.

[0060] Secondly, two rollers are also installed on the threaded sleeve 6, and the rollers roll in contact with the bottom of the base 1 to act as guides for the threaded sleeve 6 when the first lead screw 5 rotates.

[0061] When the drive motor 3 drives the drive shaft 4 to rotate in the forward direction, the drive shaft 4 will drive the lifting cylinder 2 to rotate through the strip-shaped protrusion 401 on its outer periphery and the strip-shaped groove 201 on the inner wall of the lifting cylinder 2. At the same time, the drive shaft 4 drives the first lead screw 5 to rotate in the forward direction through the third bevel gear set 39. Then, the threaded sleeve 6 will gradually move towards the drive shaft 4 through the threaded engagement with the first lead screw 5. Correspondingly, the threaded sleeve 6 will push the lifting cylinder 2 to slide downward on the drive shaft 4 through the push-pull rod 8 to perform the opening action on the bottom surface of the communication control area. Subsequently, the sensor control mechanism will control the drive motor 3 to drive the drive shaft 4 to rotate in the reverse direction. Then, the threaded sleeve 6 will again engage with the first lead screw 5 through the thread and gradually move away from the drive shaft 4. And the push-pull rod 8 will pull the lifting cylinder 2 to slide upward on the drive shaft 4 to retract.

[0062] In summary, through the cooperation between the various components, the effective opening action of the lifting cylinder 2 is achieved, and the lifting movement of the lifting cylinder 2 is driven by the first lead screw 5. The first lead screw 5 has high driving accuracy and good stability.

[0063] Please refer to it again. Figure 2 , Figure 4 as well as Figure 7 The limiting mechanism includes a horizontal clamping structure mounted on the base 1 and an elastic pressing structure disposed on the base 1, and the elastic pressing structure is connected to the sensing and control mechanism.

[0064] The horizontal clamping structure includes multiple straight rods 29 fixed to the base 1 by protrusions 28 and a clamping plate 31 slidably disposed on the multiple straight rods 29. Two first columnar springs 30 are also sleeved on the outer periphery of the straight rods 29, and the two ends of the first columnar springs 30 are respectively connected to the clamping plate 31 and the protrusions 28.

[0065] It should be noted that a lug 101 is also fixedly provided on the side of the base 1 facing the lifting cylinder 2. The lug 101 has a round hole for the wooden stake to fall, and the line connecting the center point of the round hole and the center point of the lifting cylinder 2 is parallel to the base 1.

[0066] The elastic pressure-resistant structure includes two stepped shafts 32 slidably mounted on the base 1, a horizontal plate 34 fixedly mounted on the upper ends of the two stepped shafts 32, and second cylindrical springs 33 respectively sleeved on the outer periphery of the two stepped shafts 32. A parting surface is provided at the end of each stepped shaft 32 away from the horizontal plate 34, and the two ends of the second cylindrical springs 33 are respectively connected to the base 1 and the parting surface.

[0067] In general, the stepped shaft 32 includes a first rod that is slidably connected to the base 1 and fixed to the horizontal plate 34, and a second rod that is fixed to the end of the first rod away from the horizontal plate 34. The diameter of the second rod is larger than the diameter of the first rod, so that the parting surface is formed at the connection between the two, so as to facilitate the connection of the second columnar spring 33.

[0068] Please refer to it again. Figure 2 , Figure 7 as well as Figure 8 The sensing and control mechanism includes a gear transmission structure and a connecting structure mounted on the base 1 and connected to the horizontal plate 34. The connecting structure includes two drive wheels 13 rotatably mounted on the base 1, a connecting piece 14 that rolls between the two drive wheels 13, two guide rods 11 fixed on the base 1, and a transverse plate 12 slidably mounted on the two guide rods 11 and connected to the connecting piece 14. A fixing rod 9 is fixed on the threaded sleeve 6. A pressure sensor 10 is mounted on the side of the transverse plate 12 facing the fixing rod 9. The pressure sensor 10 communicates with the drive motor 3.

[0069] The gear transmission structure includes a rack plate 35 fixedly mounted on the horizontal plate 34 and a transmission shaft 37 and a second gear 36 rotatably mounted on the bottom of the base 1. The second gear 36 meshes with the rack plate 35. One end of the transmission shaft 37 is connected to the rotating shaft of the second gear 36 through a second transmission belt 40, and the other end is connected to the rotating shaft of one of the drive wheels 13 through a second bevel gear set 38.

[0070] Similarly, the second bevel gear set 38 includes a third bevel gear fixedly mounted on the end of the transmission shaft 37 and a fourth bevel gear fixedly mounted coaxially with one of the drive wheels 13, and the fourth bevel gear meshes with the third bevel gear;

[0071] Secondly, it should be noted that the base 1 is provided with a strip-shaped through groove for the fixed rod 9 to move, and also with an opening for the rack plate 35 to move.

[0072] During preparation, the two clamping plates 31 are separated, and then wooden stakes are placed between the two clamping plates 31. Under the action of the first columnar spring 30, the two clamping plates 31 can clamp and limit the wooden stakes. At the same time, when placing the wooden stakes, the horizontal plate 34 needs to be lifted, so that under the action of the second columnar spring 33, the horizontal plate 34 limits the wooden stakes in the vertical direction.

[0073] As the horizontal plate 34 is raised, the rack plate 35 will move upward along with it, and drive the second gear 36 to rotate. Then, the rotation shaft of the second gear 36 drives the transmission shaft 37 to rotate through the second transmission belt 40. The transmission shaft 37 drives the drive wheel 13 through the second bevel gear set 38, so that the connecting piece 14 drives the horizontal plate 12 to gradually slide away from the fixed rod 9 on the two guide rods 11, and the distance between the pressure sensor 10 and the fixed rod 9 increases.

[0074] In summary, the greater the length of the wooden stake, the higher the horizontal plate 34 is raised. Correspondingly, the greater the stroke of the connecting piece 14 driving the horizontal sliding plate 12 to slide on the two guide rods 11, which in turn increases the distance between the fixed rod 9 and the pressure sensor 10. Therefore, when the drive motor 3 works, the threaded sleeve 6 drives the fixed rod 9 to contact the pressure sensor 10. The pressure sensor 10 is triggered and sends a control signal to the drive motor 3, causing the drive motor 3 to drive the drive shaft 4 to rotate in the opposite direction. The threaded sleeve 6 moves away from the drive shaft 4 to reset. In this way, the higher the wooden stake, the greater the stroke of the threaded sleeve 6 driving the lifting cylinder 2 to move up and down through the push-pull rod 8. As a result, the deeper the hole formed on the ground, the more stable the wooden stake is after falling into the deep hole, preventing the wooden stake from being difficult to stand upright in the deep hole due to the hole being too shallow.

[0075] Please refer to it again. Figure 5 , Figure 6 as well as Figure 9 The intermittent ejection mechanism includes a one-way triggering structure connected to the threaded sleeve 6 and a circumferential drive assembly mounted on the base 1 and connected to the one-way triggering structure.

[0076] The one-way triggering structure includes a long bar 15 fixedly installed on the end of the protrusion 601 away from the threaded sleeve 6 and a ratchet 16 rotatably installed on the bottom of the base 1. The bottom of the long bar 15 is provided with a plurality of inclined grooves at equal intervals along its length direction, and each inclined groove is hinged with a pawl that cooperates with the ratchet 16.

[0077] When the threaded sleeve 6 moves toward the drive shaft 4, the pawl at the bottom of the long rod 15 will flip in the inclined groove at the bottom of the long rod 15 as it passes the ratchet 16, and the ratchet 16 will not rotate. However, when the threaded sleeve 6 moves away from the drive shaft 4, the inclined groove at the bottom of the long rod 15 will limit the pawl as it passes the ratchet 16, preventing it from flipping. Consequently, the pawl will drive the ratchet 16 to rotate, and the rotation shaft of the ratchet 16 will drive the circumferential drive assembly to move, causing the circumferential drive assembly to perform a pushing action on the wooden stake.

[0078] The circumferential drive assembly includes an elastic sliding structure mounted on the base 1 and a rotating structure connected to the elastic sliding structure, and the rotating structure is connected to the rotating shaft of the ratchet 16.

[0079] The elastic sliding structure includes two long rods 26 fixedly mounted on the base 1 via a vertical plate 25, a reciprocating plate 27 slidably disposed on the two long rods 26, and two third columnar springs 41 respectively sleeved on the outer periphery of the two long rods 26. The two ends of the third columnar springs 41 are respectively connected to the reciprocating plate 27 and the vertical plate 25. Two push rods 2701 are fixed on one side of the reciprocating plate 27, and a strip rod 2702 is fixed on the other side. The strip rod 2702 is connected to the rotating structure.

[0080] The rotating structure includes a rotating plate 18 rotatably mounted on the base 1 and a pulley 19 movably disposed on the rotating plate 18 and abutting against the bar 2702. The rotating shaft of the rotating plate 18 is connected to the rotating shaft of the ratchet 16 through a first transmission belt 17.

[0081] A second lead screw 20 is rotatably mounted on the rotating plate 18. The second lead screw 20 is provided with a threaded block 21 that is threadedly connected to it. The pulley 19 is rotatably mounted on the side of the threaded block 21 that is away from the rotating plate 18.

[0082] A first gear 23 is rotatably mounted on the rotating plate 18. The rotating shaft of the first gear 23 is connected to the second lead screw 20 through the first bevel gear set 22. An arc-shaped component 24 is also fixedly mounted on the base 1. The inner wall of the arc-shaped component 24 is provided with teeth that cooperate with the first gear 23.

[0083] It should be emphasized that the threaded block 21 is slidably attached to the rotating plate 18 on the side facing the rotating plate 18. This arrangement is so that when the second lead screw 20 rotates, the threaded block 21 can play a guiding role, ensuring that the threaded block 21 can smoothly engage with the second lead screw 20.

[0084] The first bevel gear set 22 includes a first bevel gear fixedly mounted coaxially with the first gear 23 and a second bevel gear fixedly mounted on the end of the second lead screw 20 facing the first gear 23, and the second bevel gear meshes with the first bevel gear;

[0085] Furthermore, the central axes of the arc-shaped component 24 and the rotating shaft of the rotating plate 18 coincide, so that when the rotating plate 18 drives the first gear 23 to make a circular motion, the first gear 23 can mesh with the teeth on the inner wall of the arc-shaped component 24 and rotate.

[0086] During the rotation of the ratchet 16, its rotating shaft drives the rotating plate 18 to rotate one revolution via the first transmission belt 17, and drives the pulley 19 to perform circular motion. During the first half of the rotation of the rotating plate 18, the first gear 23 meshes with the teeth on the inner wall of the arc-shaped component 24, causing it to rotate. The rotating shaft of the first gear 23 then drives the second lead screw 20 to rotate via the first bevel gear set 22, causing the threaded block 21 to engage with the second lead screw 20, and the pulley 19 to move a certain distance. Thus, during the next revolution of the rotating plate 18, the radius of the circular motion trajectory of the pulley 19 increases, and the stroke of the push rod 2701 increases, thereby achieving the desired effect. The continuous pushing of the wooden stakes continues, and as the rotating plate 18 continues to rotate 90°, the pulley 19 will roll on the strip rod 2702, causing the strip rod 2702 to give way. Correspondingly, the reciprocating plate 27 slides away from the vertical plate 25 on the two long rods 26. The third columnar spring 41 is stretched, and the two push rods 2701 push the multiple wooden stakes arranged in a row, so that the wooden stakes away from the two push rods 2701 fall from the base 1 into the deep hole in the ground. Subsequently, as the rotating plate 18 continues to rotate 90°, the strip rod 2702 and the pulley 19 remain in contact, the third columnar spring 41 gradually elastically recovers, and the two push rods 2701 reset.

[0087] After the equipment finishes working, the staff needs to add wooden stakes between the two clamping plates 31 and manually rotate the second lead screw 20 so that the threaded block 21 drives the pulley 19 to reset.

[0088] A method for using the deployment equipment of the intelligent communication operation management and control system includes the following steps:

[0089] Step 1: Determine the communication operation and control area, and move the equipment to the periphery of the area;

[0090] Step 2: Add wooden stakes into the limiting mechanism and check whether the communication between the sensing and control mechanism and the power drive mechanism is normal.

[0091] Step 3: The power drive mechanism works and communicates with the sensor control mechanism to drive the lifting cylinder 2 to perform the opening action, and the intermittent pushing mechanism performs the pushing action on the wooden pile, so that the wooden pile falls into the deep hole on the ground.

[0092] Step four: After the equipment moves a certain distance, the power drive mechanism works again, and the cycle repeats to complete the deployment of communication operation and control.

[0093] When the intelligent communication operation and control system is deployed, and the drive motor 3 drives the drive shaft 4 to rotate in the forward direction, the drive shaft 4 will drive the lifting cylinder 2 to rotate through the strip-shaped protrusion 401 on its outer periphery and the strip-shaped groove 201 on the inner wall of the lifting cylinder 2. At the same time, the drive shaft 4 drives the first lead screw 5 to rotate in the forward direction through the third bevel gear set 39. As a result, the threaded sleeve 6 gradually moves towards the drive shaft 4 by engaging with the first lead screw 5 through a threaded connection. Correspondingly, the threaded sleeve 6 pushes the lifting cylinder 2 in the forward direction through the push-pull rod 8. The drive shaft 4 slides downward to perform an opening action on the bottom surface of the communication control area. Then the drive shaft 4 rotates in the opposite direction. As a result, the threaded sleeve 6 will once again engage with the first lead screw 5 and gradually move away from the drive shaft 4. The push-pull rod 8 pulls the lifting cylinder 2 to slide upward and retract on the drive shaft 4. Through the cooperation between the various components, the effective opening action of the lifting cylinder 2 is achieved. The lifting movement of the lifting cylinder 2 is driven by the first lead screw 5. The first lead screw 5 has high driving accuracy and good stability.

[0094] During preparation, the two clamping plates 31 are separated, and then wooden stakes are placed between the two clamping plates 31. Under the action of the first columnar spring 30, the two clamping plates 31 can clamp and limit the wooden stakes. At the same time, when placing the wooden stakes, the horizontal plate 34 needs to be lifted, so that under the action of the second columnar spring 33, the horizontal plate 34 limits the wooden stakes in the vertical direction.

[0095] As the horizontal plate 34 is raised, the rack plate 35 will move upward along with it, and drive the second gear 36 to rotate. Then, the rotation shaft of the second gear 36 drives the transmission shaft 37 to rotate through the second transmission belt 40. The transmission shaft 37 drives the drive wheel 13 through the second bevel gear set 38, so that the connecting piece 14 drives the horizontal plate 12 to gradually slide away from the fixed rod 9 on the two guide rods 11, and the distance between the pressure sensor 10 and the fixed rod 9 increases.

[0096] In summary, the greater the length of the wooden stake, the higher the horizontal plate 34 is raised. Correspondingly, the greater the stroke of the connecting piece 14 driving the horizontal plate 12 to slide on the two guide rods 11, which in turn increases the distance between the fixed rod 9 and the pressure sensor 10. Therefore, when the drive motor 3 works, the threaded sleeve 6 drives the fixed rod 9 to contact the pressure sensor 10. The pressure sensor 10 is triggered and sends a control signal to the drive motor 3, causing the drive motor 3 to drive the drive shaft 4 to rotate in the opposite direction. The threaded sleeve 6 moves away from the drive shaft 4 to reset. In this way, the higher the wooden stake, the greater the stroke of the threaded sleeve 6 driving the lifting cylinder 2 to move up and down through the push-pull rod 8. As a result, the deeper the hole formed on the ground, the more stable the wooden stake is after it falls into the hole, preventing the wooden stake from being difficult to stand upright in the hole due to the hole being too shallow.

[0097] When the threaded sleeve 6 moves toward the drive shaft 4, the pawl at the bottom of the long rod 15 will flip in the inclined groove at the bottom of the long rod 15 as it passes the ratchet 16, and the ratchet 16 will not rotate. However, when the threaded sleeve 6 moves away from the drive shaft 4, the inclined groove at the bottom of the long rod 15 will limit the pawl as it passes the ratchet 16, preventing the pawl from flipping. Consequently, the pawl will drive the ratchet 16 to rotate.

[0098] During the rotation of the ratchet 16, its rotating shaft drives the rotating plate 18 to rotate one revolution via the first transmission belt 17, and drives the pulley 19 to perform circular motion. During the first 90° rotation of the rotating plate 18, the pulley 19 rolls on the bar 2702, causing the bar 2702 to move aside. Correspondingly, the reciprocating plate 27 slides away from the vertical plate 25 on the two long rods 26. The third columnar spring 41 is stretched, and the two push rods 2701 push the multiple wooden stakes arranged in a row, causing the wooden stakes away from the two push rods 2701 to fall from the base 1 into the deep hole in the ground. Subsequently, as the rotating plate 18 continues to rotate 90°, the bar 2702... While maintaining contact with the pulley 19, the third cylindrical spring 41 gradually recovers its elasticity, and the two push rods 2701 reset. Finally, as the rotating plate 18 continues to rotate 180°, the first gear 23 will mesh with the teeth on the inner wall of the arc-shaped part 24 and rotate. Thus, the rotating shaft of the first gear 23 drives the second lead screw 20 to rotate through the first bevel gear set 22, causing the threaded block 21 to engage with the second lead screw 20 and the pulley 19 to move a certain distance. In this way, during the next rotation of the rotating plate 18, the radius of the circular motion trajectory of the pulley 19 increases, and the stroke of the push rod 2701 increases, so as to achieve the continuity of pushing the wooden stake.

[0099] It will be apparent to those skilled in the art that the present invention is not limited to the details of the exemplary embodiments described above, and that the invention can be implemented in other specific forms without departing from its spirit or essential characteristics. Therefore, the embodiments should be considered in all respects as exemplary and non-limiting, and the scope of the invention is defined by the appended claims rather than the foregoing description. Thus, all variations falling within the meaning and scope of equivalents of the claims are intended to be included within the present invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

[0100] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claims

1. A deployment device for an intelligent communication operation and control system, used to assist in the regional division of the communication operation and control system. The industry is characterized by, Including the base (1), it also includes: The lifting cylinder (2) is movably mounted on the base (1), and has spiral blades on its outer periphery. It is connected to a power drive mechanism mounted on the base (1). The power drive mechanism is used to drive the lifting cylinder (2) to maintain rotation and perform lifting actions so that the lifting cylinder (2) forms a deep hole in the ground of the controlled area through the spiral blades. A limiting mechanism is installed on the base (1) to limit the wooden stakes arranged at equal intervals. The limiting mechanism is connected to a sensing and control mechanism installed on the base (1). The sensing and control mechanism communicates with the power drive mechanism. An intermittent ejection mechanism is installed on the base (1) and connected to the power drive mechanism. The intermittent ejection mechanism is triggered during the latter part of the upward stroke of the lifting cylinder (2) and performs an ejection action on the wooden pile so that the wooden pile enters the deep hole. The power drive mechanism includes a power component mounted on the base (1) and a lifting execution component connected to the power component. The power component includes a drive shaft (4) rotatably mounted on the base (1) and a drive motor (3) mounted on the base (1). The output end of the drive motor (3) is connected to the drive shaft (4), the drive shaft (4) is slidably fitted with the lifting cylinder (2) through a snap-fit ​​structure, and is connected to the lifting execution component; The lifting and lowering actuator cooperates with the sensing and control mechanism and is connected to the intermittent ejection mechanism. The lifting and lowering actuator includes a first lead screw (5) rotatably mounted on the base (1) and a threaded sleeve (6) provided on the first lead screw (5) and threadedly connected thereto. The threaded sleeve (6) has two protrusions (601) fixed on it, and each of the two protrusions (601) has a push-pull rod (8) rotatably mounted on it. One end of the first screw (5) is connected to the drive shaft (4) through the third bevel gear set (39). A connecting plate (7) is rotatably mounted on the lifting cylinder (2). The connecting plate (7) is rotatably connected to the end of the two push-pull rods (8) away from the protrusions (601). The limiting mechanism includes a horizontal clamping structure mounted on the base (1) and an elastic pressing structure provided on the base (1), and the elastic pressing structure is connected to the sensing and control mechanism. The horizontal clamping structure includes multiple straight rods (29) fixed to the base (1) by protrusions (28) and a clamping plate (31) slidably disposed on the multiple straight rods (29). Two first columnar springs (30) are also sleeved on the outer periphery of the straight rods (29). The two ends of the first columnar springs (30) are respectively connected to the clamping plate (31) and the protrusions (28). The elastic pressure-resistant structure includes two stepped shafts (32) slidably disposed on the base (1), a horizontal plate (34) fixedly installed on the upper end of the two stepped shafts (32), and a second columnar spring (33) respectively sleeved on the outer periphery of the two stepped shafts (32). The stepped shaft (32) has a parting surface at one end away from the horizontal plate (34), and the two ends of the second cylindrical spring (33) are respectively connected to the base (1) and the parting surface; The sensing and control mechanism includes a gear transmission structure and a connection structure mounted on the base (1) and connected to the cross plate (34). The connection structure includes two drive wheels (13) rotatably mounted on the base (1), a connector (14) rollingly connecting the two drive wheels (13), two guide rods (11) fixed on the base (1), and a transverse plate (12) slidably mounted on the two guide rods (11) and connected to the connector (14). A fixing rod (9) is fixed on the threaded sleeve (6). A pressure sensor (10) is mounted on the side of the transverse plate (12) facing the fixing rod (9). The pressure sensor (10) communicates with the drive motor (3). The gear transmission structure includes a rack plate (35) fixedly mounted on the horizontal plate (34) and a transmission shaft (37) and a second gear (36) rotatably mounted on the bottom of the base (1). The second gear (36) meshes with the rack plate (35). One end of the transmission shaft (37) is connected to the rotating shaft of the second gear (36) through a second transmission belt (40), and the other end is connected to the rotating shaft of one of the drive wheels (13) through a second bevel gear set (38). The intermittent ejection mechanism includes a one-way triggering structure connected to the threaded sleeve (6) and a circumferential drive assembly mounted on the base (1) and connected to the one-way triggering structure. The one-way triggering structure includes a long bar (15) fixedly installed on the end of the protrusion (601) away from the threaded sleeve (6) and a ratchet (16) rotatably installed on the bottom of the base (1). The bottom of the long bar (15) is provided with a plurality of inclined slots at equal intervals along its length direction, and each inclined slot is hinged with a pawl that cooperates with the ratchet (16). The circumferential drive assembly includes an elastic sliding structure mounted on the base (1) and a rotating structure connected to the elastic sliding structure, and the rotating structure is connected to the rotating shaft of the ratchet (16). The elastic sliding structure includes two long rods (26) fixedly installed on the base (1) by a vertical plate (25), a reciprocating plate (27) slidably disposed on the two long rods (26), and two third columnar springs (41) respectively sleeved on the outer periphery of the two long rods (26); The third columnar spring (41) is connected to the reciprocating plate (27) and the vertical plate (25) at both ends respectively. Two push rods (2701) are fixed on one side of the reciprocating plate (27), and a strip rod (2702) is fixed on the other side. The strip rod (2702) is connected to the rotating structure. The rotating structure includes a rotating plate (18) rotatably mounted on the base (1) and a pulley (19) movably disposed on the rotating plate (18) and abutting against the bar (2702). The rotating shaft of the rotating plate (18) is connected to the rotating shaft of the ratchet (16) through a first transmission belt (17). A second lead screw (20) is rotatably mounted on the rotating plate (18). The second lead screw (20) is provided with a threaded block (21) threadedly connected to it. The pulley (19) is rotatably mounted on the side of the threaded block (21) away from the rotating plate (18). A first gear (23) is rotatably mounted on the rotating plate (18). The rotating shaft of the first gear (23) is connected to the second lead screw (20) through the first bevel gear set (22). An arc-shaped part (24) is also fixedly mounted on the base (1). The inner wall of the arc-shaped part (24) is provided with teeth that cooperate with the first gear (23).

2. A method of using the deployment equipment of the intelligent communication operation management and control system as described in claim 1, characterized in that, Includes the following steps: Step 1: Determine the communication operation and control area, and move the equipment to the periphery of the area; Step 2: Add wooden stakes into the limiting mechanism and check whether the communication between the sensing and control mechanism and the power drive mechanism is normal. Step 3: The power drive mechanism works and communicates with the sensor control mechanism to drive the lifting cylinder (2) to perform the opening action, and the intermittent pushing mechanism pushes the wooden pile to make the wooden pile fall into the deep hole on the ground. Step four: After the equipment moves a certain distance, the power drive mechanism works again, and the cycle repeats to complete the deployment of communication operation and control.