High-efficiency pipeline maintenance structure for telecommunications engineering construction

By using an adjustable-height optical cable route detector and a rotating baffle design, the problems of inconvenient operation and difficulty in reading information under strong light caused by fixed equipment height are solved, improving the convenience of communication engineering construction and the clarity of data reading.

CN224439004UActive Publication Date: 2026-06-30SHENZHEN ZHONGTONG INTERNET TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN ZHONGTONG INTERNET TECHNOLOGY CO LTD
Filing Date
2025-09-01
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

The existing pipeline maintenance structure used in communication engineering construction has fixed equipment height, which makes it inconvenient for operators of different heights to use, easily causes fatigue, and affects the quality and progress of the work.

Method used

The device employs an adjustable-height optical cable route detector, which allows for flexible height adjustment by pushing a push plate and a transmission mechanism. It is also equipped with a rotatable baffle to protect the display screen in strong light environments, enhancing operational comfort and data reading clarity.

Benefits of technology

This design achieves a balance between equipment height and operator height, reducing operator fatigue and enhancing the equipment's convenience and practicality in various environments.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model relates to the field of communication engineering construction equipment technology, and discloses a high-efficiency pipeline maintenance structure for communication engineering construction, including an optical cable route detector. The optical cable route detector has a probe head at its bottom and an adjustment component installed at its top. A handle and a support plate are fixedly connected to one side of the optical cable route detector, and a controller is fixedly connected to one side of the handle and support plate. A display screen is fixedly connected to the top of the controller. The adjustment component includes a sliding plate, the bottom of which is fixedly connected to the top of the probe head. The sliding plate is slidably connected inside the optical cable route detector, and a fixing plate is fixedly connected to one side of the optical cable route detector. In this utility model, the operator only needs to easily push the push plate to retract the locking column through the transmission mechanism, achieving smooth adjustment of the equipment height. After adjustment, the locking column automatically resets and locks under the action of spring force, enhancing convenience and comfort during long-term operation.
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Description

Technical Field

[0001] This utility model relates to the field of communication engineering construction equipment technology, and in particular to a high-efficiency pipeline maintenance structure for communication engineering construction. Background Technology

[0002] In pipeline maintenance during telecommunications engineering construction, tasks such as tracing the route of underground pipelines, determining their burial depth, and identifying anomalies are crucial for ensuring the continuous operation of communication lines. These tasks often require operators to use handheld or structured tools in complex environments such as the field and beneath urban roads, placing special demands on the maintenance structures supporting these tools. High-efficiency pipeline maintenance structures for telecommunications engineering construction are designed specifically for these inspection tasks. They must stably support tools to ensure the accuracy of inspection data, facilitate flexible operation by personnel, and adapt to different work sites. Their performance directly affects the efficiency of pipeline maintenance and the reliability of inspection results. As the scope of telecommunications pipeline laying expands and the working environment becomes increasingly diverse, the requirements for the flexibility, adaptability, and ease of operation of these maintenance structures are also increasing.

[0003] Existing pipeline maintenance structures for communication engineering construction operate on the principle of static load-bearing and rigid support. They utilize the tight fit between the base and the ground to generate sufficient friction and counterweight to counteract minor vibrations from tool operation and external impact forces, thus ensuring the stability of the overall structure during operation.

[0004] However, existing pipeline maintenance structures have significant limitations. Due to the fixed height of the work platform, it is difficult for operators of different heights to find a comfortable working posture. Taller operators need to bend over and lower their heads for long periods of time, while shorter operators need to frequently tiptoe or use props. This not only causes back pain and limb fatigue in a short time, but also affects the stability of the operation due to unnatural body posture, which in turn has an adverse impact on the quality and progress of pipeline maintenance work. Therefore, an efficient pipeline maintenance structure for communication engineering construction is proposed to solve the above problems. Utility Model Content

[0005] To overcome the above shortcomings, this utility model provides a high-efficiency pipeline maintenance structure for communication engineering construction, which aims to improve the problem of inconvenience and fatigue for users of different heights due to the fixed height of the equipment.

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

[0007] A high-efficiency pipeline maintenance structure for communication engineering construction includes an optical cable route detector. The optical cable route detector has a probe head at its bottom and an adjustment component at its top. A handle and a support plate are fixedly connected to one side of the optical cable route detector. A controller is fixedly connected to one side of the handle and support plate, and a display screen is fixedly connected to the top of the controller.

[0008] The adjustment assembly includes a sliding plate, the bottom of which is fixedly connected to the top of the probe head. The sliding plate is slidably connected to the inside of the optical cable route detector. A fixing plate is fixedly connected to one side of the optical cable route detector. Multiple fixing shells are fixedly connected inside the fixing plate. A transmission column and a locking column are slidably connected inside each fixing shell. One end of each transmission column is fixedly connected to the outer wall of the locking column. Multiple locking columns extend through into the inside of the optical cable route detector and engage with a groove on one side of the sliding plate. A pushing assembly is installed on the outer wall of each transmission column.

[0009] As a further description of the above technical solution:

[0010] Each of the aforementioned actuation components includes a connecting shaft, each connecting shaft extending through and to the outside of the drive column, and each connecting shaft having a drive housing rotatably connected to its outer wall.

[0011] As a further description of the above technical solution:

[0012] A push plate is fixedly connected to one side of each of the transmission housings, and multiple rolling balls are fixedly connected to the other side of each of the transmission housings.

[0013] As a further description of the above technical solution:

[0014] Multiple balls are attached to one side of the fixed plate. Each transmission column is provided with a second spring on its outer wall. One end of each second spring is fixedly connected to the outer wall of the locking column, and the other end of each second spring is fixedly connected to one side of the inner wall of the fixed shell. A shielding component is installed on the outer wall of the display screen.

[0015] As a further description of the above technical solution:

[0016] The shielding component includes a baffle located on one side of the display screen, and a plurality of fixing blocks are fixedly connected to one side of the controller.

[0017] As a further description of the above technical solution:

[0018] A fixed shaft is fixedly connected between the multiple fixed blocks, and a connecting ring is fixedly connected to both sides of the baffle.

[0019] As a further description of the above technical solution:

[0020] The baffle and multiple connecting rings are rotatably connected to the outer wall of the fixed shaft. Multiple grooves are provided on the outer wall of the fixed shaft, and multiple locking balls are slidably connected inside each connecting ring.

[0021] As a further description of the above technical solution:

[0022] Each of the connecting rings is provided with a plurality of springs, one end of each spring is fixedly connected to the outer wall of the retaining ball, and the other end of the plurality of springs is fixedly connected to the inside of the connecting ring. The plurality of retaining balls are engaged with the groove on the outer wall of the fixed shaft.

[0023] This utility model has the following beneficial effects:

[0024] 1. In this utility model, the operator only needs to push the push plate to retract the locking column through the transmission mechanism, so as to realize the smooth adjustment of the equipment height. After the adjustment is completed, the locking column will automatically reset and lock under the action of spring force. This solves the problem of inconvenience and fatigue for users of different heights due to the fixed equipment height, and enhances the convenience and comfort during long-term operation.

[0025] 2. In this utility model, the rotatable baffle with a spring-loaded ball positioning structure can be easily suspended at any angle, effectively solving the problem of the screen being difficult to read due to reflection in strong outdoor light environments, enhancing the clarity of data reading. In addition, the baffle can also protect the screen when stored, with the dual effects of light blocking and protection, improving the overall practicality and environmental adaptability of the device. Attached Figure Description

[0026] Figure 1 This is a three-dimensional schematic diagram of the high-efficiency pipeline maintenance structure for communication engineering construction proposed in this utility model.

[0027] Figure 2 A schematic diagram of the pusher plate structure of the high-efficiency pipeline maintenance structure for communication engineering construction proposed in this utility model;

[0028] Figure 3 A schematic diagram of the locking post structure for the high-efficiency pipeline maintenance structure for communication engineering construction proposed in this utility model;

[0029] Figure 4 This is a schematic diagram of the baffle structure of the high-efficiency pipeline maintenance structure for communication engineering construction proposed in this utility model.

[0030] Figure 5 This is a schematic diagram of the ball-operated structure of the high-efficiency pipeline maintenance structure for communication engineering construction proposed in this utility model.

[0031] Legend:

[0032] 1. Optical cable route detector; 2. Handle; 3. Support plate; 4. Controller; 5. Detector head; 6. Slide plate; 7. Fixing plate; 8. Fixing shell; 9. Transmission column; 10. Connecting shaft; 11. Transmission shell; 12. Push plate; 13. Rolling ball; 14. Clamping column; 15. Display screen; 16. Baffle; 17. Fixing shaft; 18. Fixing block; 19. Connecting ring; 20. Spring 1; 21. Clamping ball; 22. Spring 2. Detailed Implementation

[0033] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0034] Reference Figures 1-3 This utility model provides an embodiment of a high-efficiency pipeline maintenance structure for communication engineering construction, including an optical cable route detector 1. When in use, the transmitter injects a specific signal into the optical cable, and the receiver receives the signal. Based on the signal strength and direction, the receiver tracks the optical cable path, determines the burial depth, etc., to complete the detection. This is prior art and will not be described in detail here. The bottom of the optical cable route detector 1 is equipped with a detection head 5, and the top of the detection head 5 is equipped with an adjustment component. The detection head 5 is used to move along the pipeline path and perform signal detection, and is the core working component for pipeline maintenance. A handle 2 and a support plate 3 are fixedly connected to one side of the optical cable route detector 1. The handle 2 and the support plate 3 provide stable grip and support points for the operator, ensuring comfort and detection stability during long-term operation. A controller 4 is fixedly connected to one side of the handle 2 and the support plate 3, and a display screen 15 is fixedly connected to the top of the controller 4. The controller 4 serves as the central processing unit of the entire device, processing the signal data from the detection head 5 and visualizing the results. The display screen 15 clearly displays the detected optical cable route information in real time, allowing the operator to intuitively grasp the on-site situation.

[0035] The adjustment component is the core mechanism for achieving personalized height adjustment of the equipment. This component includes a sliding plate 6, whose bottom is fixedly connected to the top of the probe head 5. The sliding plate 6 is slidably connected inside the fiber optic cable route detector 1. The sliding plate 6 smoothly slides up and down in conjunction with the sliding groove inside the fiber optic cable route detector 1, changing the position of the probe head 5 relative to the body, thereby adjusting the overall height of the equipment. A fixed plate 7 is fixedly connected to one side of the fiber optic cable route detector 1. Multiple fixed shells 8 are fixedly connected inside the fixed plate 7. Each fixed shell 8 has a slidably connected transmission column 9 and locking column 14. One end of each transmission column 9 is fixedly connected to the outer wall of the locking column 14. Multiple locking columns 14 extend through into the interior of the fiber optic cable route detector 1 and engage with a groove on one side of the sliding plate 6. The locking columns 14 engage or disengage with the groove on the side wall of the sliding plate 6, achieving the effect of locking or unlocking the equipment height. A pushing component is installed on the outer wall of each transmission column 9, providing a convenient and effortless unlocking method. The operator can use this component... The components can easily retract the locking post 14. Each push component includes a connecting shaft 10, which extends through to the outside of the transmission post 9. The outer wall of each connecting shaft 10 is rotatably connected to a transmission housing 11. A push plate 12 is fixedly connected to one side of each transmission housing 11, and multiple balls 13 are fixedly connected to the other side of each transmission housing 11. The balls 13 are made of GGr15 bearing steel. The balls 13 roll in conjunction with the flat surface of the fixed plate 7, which reduces rotational friction and makes the unlocking operation smoother and less strenuous. The multiple balls 13 fit against one side of the fixed plate 7. A second spring 22 is provided on the outer wall of each transmission post 9. One end of each second spring 22 is fixedly connected to the outer wall of the locking post 14, and the other end of each second spring 22 is fixedly connected to the inner wall of the fixed housing 8. The second spring 22 is used to provide a restoring force to ensure that the locking post 14 can automatically and reliably lock into the groove after the push component is released, which enhances the stability of the high locking. A shielding component is installed on the outer wall of the display screen 15.

[0036] Reference Figures 4-5The shielding assembly is used to block light from the display screen 15 in strong light environments, solving the problem of screen glare and poor visibility. The shielding assembly includes a baffle 16, located on one side of the display screen 15. The baffle 16 is made of lightweight ABS engineering plastic with a matte finish and is used to directly block ambient light from above or the side, thereby improving the visibility of the screen content. Multiple fixing blocks 18 are fixedly connected to one side of the controller 4, and a fixing shaft 17 is fixedly connected between the fixing blocks 18. The fixing blocks 18 securely mount the fixing shaft 17 onto the controller 4, providing a stable support for the rotation of the baffle 16. Connecting rings 19 are fixedly connected to both sides of the baffle 16. The baffle 16 and the multiple connecting rings 19 are rotatably connected to the outer wall of the fixing shaft 17. The connecting rings 19 rotate in coordination with the fixing shaft 17, allowing the baffle 16 to open and close freely to adapt to different lighting angles. Multiple grooves are provided on the outer wall of the fixing shaft 17, and multiple retaining balls 21 are slidably connected inside each connecting ring 19.

[0037] Each connecting ring 19 is equipped with multiple springs 20 inside. One end of each spring 20 is fixedly connected to the outer wall of the retaining ball 21, and the other end of the multiple springs 20 is fixedly connected to the inside of the connecting ring 19. The springs 20 are made of 304 stainless steel compression springs, which are used to continuously apply a pushing force to the retaining ball 21 to ensure the reliability of the positioning. The multiple retaining balls 21 engage with the groove on the outer wall of the fixed shaft 17. The retaining balls 21 engage with the groove on the outer wall of the fixed shaft 17. The elastic force provided by the springs 20 enables the baffle 16 to be suspended and positioned at a specific angle, achieving the effect of reliable fixation at multiple angles.

[0038] Working principle: First, when the equipment height needs to be adjusted, the operator pushes the push plate 12. The push plate 12 drives multiple balls 13 to rotate on the surface of the fixed plate 7 through the transmission housing 11. Since the connecting shaft 10 is located on one side of the center point between the transmission housing 11 and the push plate 12, the transmission housing 11 rotates while driving the transmission column 9 through the connecting shaft 10. The transmission column 9 then pulls the locking pin 14 at one end, causing the locking pin 14 to slide out of the groove on one side of the slide plate 6. During the sliding process, the spring 22 is compressed. At this time, the equipment is in the unlocked state, and the operator can push or Pulling the probe head 5 causes the slide plate 6 on top of the probe head 5 to slide inside the optical cable route detector 1, thereby adjusting the overall height of the device. After the device height is adjusted, push the push plate 12 in the opposite direction to reset it. Under the rebound force of the spring 22, the locking pin 14 will slide again on the inner wall of the fixed shell 8 until it engages with the groove on one side of the slide plate 6, thereby locking the height. This function allows the device height to match the height of different users, solving the problem of inconvenience and fatigue caused by height mismatch, and enhancing the convenience and comfort of using the device.

[0039] Secondly, there is the display screen's light-shielding function. When used in strong outdoor light, to clearly see the information on the display screen 15, the baffle 16 can be pushed. The baffle 16 rotates around the fixed shaft 17 via the connecting rings 19 on both sides. During the rotation, the retaining ball 21, which was originally engaged with the groove on the outer wall of the fixed shaft 17, is pushed by the smooth surface of the fixed shaft 17, thus moving inward into the connecting ring 19 and compressing the spring 20. When the baffle 16 rotates to the appropriate light-shielding angle, the retaining ball 21 will be aligned with another groove on the fixed shaft 17. At this time, the rebound force of the spring 20 will push the retaining ball 21 to engage with the groove, thereby fixing the angle of the baffle 16. The baffle 16 effectively blocks the light shining on the surface of the display screen 15, solving the problem of unclear screen content under strong light and enhancing the clarity of information reading. When not in use, the baffle 16 can also be rotated to a state parallel to the display screen 15 to protect the surface of the display screen 15, achieving the functions of light shielding and protection, thus facilitating the use of the device.

Claims

1. A high-efficiency pipeline maintenance structure for communication engineering construction, including an optical cable route detector (1), characterized in that: The optical cable route detector (1) is provided with a probe head (5) at the bottom, and an adjustment component is installed on the top of the probe head (5). A handle (2) and a support plate (3) are fixedly connected to one side of the optical cable route detector (1). A controller (4) is fixedly connected to one side of the handle (2) and the support plate (3). A display screen (15) is fixedly connected to the top of the controller (4). The adjustment assembly includes a sliding plate (6), the bottom of which is fixedly connected to the top of the probe head (5). The sliding plate (6) is slidably connected to the inside of the optical cable route detector (1). A fixing plate (7) is fixedly connected to one side of the optical cable route detector (1). Multiple fixing shells (8) are fixedly connected inside the fixing plate (7). A transmission column (9) and a locking column (14) are slidably connected inside each fixing shell (8). One end of each transmission column (9) is fixedly connected to the outer wall of the locking column (14). Multiple locking columns (14) extend through into the inside of the optical cable route detector (1) and engage with the groove on one side of the sliding plate (6). A pushing assembly is installed on the outer wall of each transmission column (9).

2. The high-efficiency pipeline maintenance structure for communication engineering construction according to claim 1, characterized in that: Each of the aforementioned actuation components includes a connecting shaft (10), each connecting shaft (10) extending through to the outside of the drive column (9), and each connecting shaft (10) having a drive housing (11) rotatably connected to its outer wall.

3. The high-efficiency pipeline maintenance structure for communication engineering construction according to claim 2, characterized in that: Each of the transmission housings (11) has a push plate (12) fixedly connected to one side, and a plurality of rolling balls (13) fixedly connected to the other side of each of the transmission housings (11).

4. The high-efficiency pipeline maintenance structure for communication engineering construction according to claim 3, characterized in that: Multiple balls (13) are attached to one side of the fixed plate (7). Each transmission column (9) is provided with a second spring (22) on its outer wall. One end of each second spring (22) is fixedly connected to the outer wall of the card column (14), and the other end of each second spring (22) is fixedly connected to one side of the inner wall of the fixed shell (8). The outer wall of the display screen (15) is equipped with a shielding component.

5. The high-efficiency pipeline maintenance structure for communication engineering construction according to claim 4, characterized in that: The shielding assembly includes a baffle (16) located on one side of the display screen (15), and a plurality of fixing blocks (18) are fixedly connected to one side of the controller (4).

6. The high-efficiency pipeline maintenance structure for communication engineering construction according to claim 5, characterized in that: A fixed shaft (17) is fixedly connected between multiple fixed blocks (18), and a connecting ring (19) is fixedly connected to both sides of the baffle (16).

7. The high-efficiency pipeline maintenance structure for communication engineering construction according to claim 6, characterized in that: The baffle (16) and multiple connecting rings (19) are rotatably connected to the outer wall of the fixed shaft (17). Multiple grooves are provided on the outer wall of the fixed shaft (17), and multiple locking balls (21) are slidably connected inside each connecting ring (19).

8. The high-efficiency pipeline maintenance structure for communication engineering construction according to claim 7, characterized in that: Each of the connecting rings (19) is provided with a plurality of springs (20) inside. One end of each spring (20) is fixedly connected to the outer wall of the ball (21), and the other end of the plurality of springs (20) is fixedly connected to the inside of the connecting ring (19). The plurality of balls (21) are engaged with the groove on the outer wall of the fixed shaft (17).