A dynamic pipeline arrangement method
By using a dynamic pipeline layout device and computer simulation technology, combined with height adjustment and buffering mechanisms, the problems of entanglement and wear caused by loose pipelines are solved, enabling stable and adaptive pipeline layout in dynamic environments, and improving the operational stability and overall layout capability of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- SINOHYRDO ENG BUREAU 3 CO LTD
- Filing Date
- 2023-10-16
- Publication Date
- 2026-06-12
AI Technical Summary
Existing dynamic pipeline layout methods have insufficient structures for storing redundant pipelines, resulting in loose pipelines that are prone to tangling, twisting, scratching, and wear, affecting the normal operation of equipment. Furthermore, the overall layout capacity is insufficient and cannot meet the needs of multiple pipeline layouts.
A dynamic pipeline layout device is adopted, which acquires environmental data through sensors, plans the path using computer simulation technology, and combines dynamic adjustment and manual layout. It uses height adjustment, buffering and lateral slowing mechanisms to ensure that the pipeline remains taut during dynamic movement. Buffering and lateral slowing mechanisms are set up for buffer protection to adapt to different heights and working conditions.
It improves pipeline stability, avoids tangling and twisting, enhances the stability and adaptability of wiring, and ensures smooth operation and overall layout capability of the pipeline system.
Smart Images

Figure CN117212594B_ABST
Abstract
Description
Technical Field
[0001] This application relates to the technical field of pipeline layout, and in particular to a dynamic pipeline layout method. Background Technology
[0002] Pipeline layout refers to the process of installing and arranging various pipelines (such as water pipes, cables, gas pipelines, etc.) according to a certain plan and layout in a building or engineering project, based on design requirements and actual needs. The purpose of pipeline layout is to ensure the normal operation and use of pipelines, while minimizing pipeline conflicts, intersections, and interference, and ensuring the convenience of construction and maintenance.
[0003] Static hydraulic piping is typically arranged by using fixed clamps along the flow of the working medium inside the piping to secure it. Dynamic hydraulic piping is usually arranged by using fixed clamps to constrain the piping flow past the center of the moving point or by fixing only the two ends of the piping. When the piping not only rotates around an axis but also expands or contracts along a plane perpendicular to the axis of rotation, traditional piping arrangements can lead to entanglement, twisting, and scraping during operation, affecting the piping's lifespan.
[0004] A search revealed Chinese Patent Publication No. CN113090818B, which discloses a dynamic pipeline arrangement method. The pipeline exhibits rotational motion around a rotation axis and telescopic motion along a plane perpendicular to the rotation axis. A telescopic structure for the telescopic motion is mounted on a rotational structure, constraining at least one point of the pipeline using pipe clamps. These pipe clamps can be fixed or movable and are independent of both the rotational and telescopic structures. The pipe clamps include a first clamp and a second clamp. The use of the first and second clamps prevents the pipeline from tangling, twisting, or scraping during rotation and telescopic processes. Furthermore, the pipeline allowance generated during telescopic motion is controlled within the length range from the telescopic structure to the first clamp. This ensures that the pipeline rotates along with the main structure when the rotational structure rotates around the rotation axis, preventing twisting and bending, ensuring a reasonable bending radius, and facilitating smooth flow of the working medium within the pipeline.
[0005] Regarding the aforementioned technologies, the inventors have discovered the following deficiencies;
[0006] The aforementioned equipment lacks a structure for storing excess pipelines during use, resulting in loose pipelines that are prone to becoming tangled, twisted, or worn. This can severely impact the normal operation of the equipment. Furthermore, the pipelines are susceptible to twisting, scratching, or breakage, leading to insufficient stability in the overall pipeline layout. Additionally, the equipment can only manage single-group pipelines at a time, exhibiting poor overall layout capabilities. In contrast, dynamic wiring often requires the layout of numerous pipelines, highlighting the equipment's inadequate overall adaptability. Therefore, improvements are necessary. Summary of the Invention
[0007] To improve wiring stability, avoid wire tangling and twisting, and enhance wiring capabilities, this application provides a dynamic pipeline layout method.
[0008] This application provides a dynamic pipeline layout method, which adopts the following technical solution:
[0009] Includes the following steps:
[0010] Step 1: Collect environmental data: Obtain data on the equipment pipeline layout area through sensors or by using field measurement equipment;
[0011] Step 2: Pipeline planning: Based on the collected environmental data, computer simulation technology is used to plan the pipeline and determine the optimal layout path for the equipment;
[0012] Step 3: Pipeline Layout: Based on the pipeline planning results, use a dynamic pipeline layout device in conjunction with manual labor to lay out the pipelines;
[0013] Step 4: Dynamic Adjustment: During the pipeline layout process, dynamic adjustments are made according to the actual situation, including adjusting the layout path, changing the pipeline type, and adjusting the pipeline layout length, etc.
[0014] Step 5: Complete the pipeline system: After completing the pipeline layout, conduct system testing and debugging to ensure the normal operation of the pipeline system.
[0015] Optionally, the dynamic pipeline layout device includes a base, a fixed platform is fixedly installed on the top of the base, a support rod is rotatably connected to the top of the fixed platform, a hexagonal base rod is fixedly installed on the top of the support rod, a height adjustment mechanism is fixedly installed at equal intervals on the outer side of the hexagonal base rod, a buffer mechanism is fixedly installed on the outer side of the height adjustment mechanism, a wiring mechanism is fixedly installed in the middle of the outer side of the buffer mechanism, and side buffer mechanisms are fixedly installed at the top and bottom of the outer side of the buffer mechanism. Mounting holes are provided at the four corners of the top of the base, and the mounting holes penetrate the base.
[0016] Optionally, the height adjustment mechanism includes support plates, which are fixedly installed in a circular pattern at equal intervals on the outside of the hexagonal base rod. The support plates are configured in six groups. A guide rail is fixedly installed on the outside of the support plates. A lead screw is rotatably connected inside the guide rail. The bottom of the lead screw passes through the guide rail. A slider is threaded onto the outer surface of the lead screw. A concave seat is fixedly installed on the outside of the slider. The inner side of the concave seat is connected to a buffer mechanism by bolts.
[0017] Optionally, a turntable is fixedly installed at the bottom of the lead screw through the guide rail, and a crank handle is rotatably connected to one side of the bottom of the turntable.
[0018] Optionally, a disc is fixedly installed at the bottom of the guide rail, the lower end of the lead screw passes through the disc, a limiting screw is threaded to the outer top of the disc, and the bottom of the limiting screw passes through the circular plate and is fitted to the top of the turntable.
[0019] Optionally, the buffer mechanism includes an outer rail, which is bolted to the inner side of the concave seat. Buffer springs are fixedly installed at the top and bottom of the outer rail. A moving block is fixedly installed at the inner end of each buffer spring. The outer side of the moving block is fixedly connected to the inner side of the wiring mechanism. An inner damper is fixedly installed at the top and bottom of the outer rail. The inner end of the inner damper is fixedly connected to both sides of the moving block. The side buffer mechanism is fixedly installed at the top and bottom of the outer rail.
[0020] Optionally, a support shaft is fixedly installed on the top of the hexagonal base rod, a top plate is rotatably connected to the top of the support shaft, and guide tubes are fixedly installed at equal intervals on the top of the top plate.
[0021] Optionally, the wiring mechanism includes a fixed frame, which is fixedly installed on the outside of the movable block. The fixed frame has a U-shaped top view. Elastic reset components are fixedly installed on both sides of the front end of the fixed frame. A wiring shaft is rotatably connected to the inside of the fixed frame. A wiring hole is opened in the middle of the wiring shaft, and the wiring hole passes through the wiring shaft.
[0022] Optionally, the elastic reset assembly includes an outer frame, which is fixedly installed on the outside of the fixed frame. A torsion spring is fixedly installed on the inner side of the outer frame. A connecting shaft is rotatably connected to the outer side of the outer frame. The inner end of the connecting shaft passes through the outer frame and is fixedly connected to the inner end of the torsion spring. The inner end of the connecting shaft is fixedly connected to the outer end of the wiring shaft. An adjusting knob is fixedly installed on the outer end of the connecting shaft.
[0023] Optionally, the side damping mechanism includes a wedge block, a side damping spring fixedly mounted on the outer side of the wedge block, a guide seat fixedly mounted on the outer end of the side damping spring, a guide wheel rotatably connected to the inner side of the guide seat, a guide hole provided in the middle of the guide wheel, a guide shaft rotatably connected to the inner end of the inner side of the guide seat, and an external damper fixedly mounted on the outer side of the wedge block located inside the side damping spring, the outer side of the external damper being fixedly connected to the inner side of the guide seat.
[0024] In summary, this application includes the following beneficial technical effects:
[0025] 1. During the use of this cabling device, the cable moves dynamically as the equipment operates. During this movement, the cable is pulled, which drives the cable shaft and torsion spring to rotate. When the cable becomes loose, the torsion spring resets, which drives the cable shaft to reverse, thereby quickly tightening the excess cable. This ensures that the dynamic cable laid out using this cabling device remains taut throughout the entire operation, preventing the cable from becoming loose and causing tangling, twisting, scratching, or being cut, thus improving the stability of the cabling process.
[0026] 2. When the track is in a dynamic moving state, the initial movement of the track, due to its extension and retraction, will cause the moving block to slide on the inner side of the outer rail. The moving block will then contact the inner damper and the buffer spring, providing initial buffering. During this period, as the track extends and retracts, it will inevitably contact the guide wheel and guide shaft. At this time, the guide seat will be forced to compress the side spring and the outer damper, thus applying the force of the buffer spring and the side spring to the track. This results in a better overall buffering effect for the track. Furthermore, the damper further enhances the stability of the buffer spring and the side spring, while reducing their extension and retraction range, thereby improving the buffering and protection effect. This makes the entire track layout more stable and the wiring smoother and more orderly after installation.
[0027] 3. This equipment adopts a fixed platform with a rotating support rod at the top, which allows the support rod to adapt to the dynamic movement of the pipeline. It is easy to adapt to the rotation around the axis and also has the working state of extension and contraction along the plane perpendicular to the rotation axis. During use, the crank can be pulled to drive the turntable to rotate the lead screw, which in turn drives the slider to slide on the inside of the guide rail. The slider drives the concave seat to move, so the height of each group of wiring mechanisms can be flexibly adjusted to facilitate wiring at different heights. Attached Figure Description
[0028] Figure 1 This is a schematic diagram of the overall structure in an embodiment of this application;
[0029] Figure 2 This is a top view of the structure in an embodiment of this application;
[0030] Figure 3This is a schematic diagram of the height adjustment mechanism, wiring mechanism, and buffer mechanism in the embodiments of this application;
[0031] Figure 4 This is a schematic diagram of the height adjustment mechanism in an embodiment of this application;
[0032] Figure 5 This is a schematic diagram of the wiring mechanism, buffer mechanism, and side buffer mechanism in the embodiments of this application;
[0033] Figure 6 This is a schematic diagram of the buffer mechanism and the side buffer mechanism in the embodiments of this application;
[0034] Figure 7 This is a schematic diagram of the side buffer mechanism in an embodiment of this application.
[0035] Reference numerals: 1. Base; 2. Fixed platform; 3. Support rod; 4. Hexagonal base rod; 5. Height adjustment mechanism; 51. Support plate; 52. Guide rail; 53. Lead screw; 54. Slider; 55. Concave seat; 56. Turntable; 57. Crank handle; 58. Disc; 59. Limiting screw; 6. Buffer mechanism; 61. Outer rail; 62. Buffer spring; 63. Moving block; 64. Internal damper; 7. Wiring mechanism; 71. 72. Fixed frame; 72. Elastic reset assembly; 721. Outer frame; 722. Torsion spring; 723. Coupling shaft; 724. Adjusting knob; 73. Wiring shaft; 74. Wiring hole; 8. Side damping mechanism; 81. Inclined block; 82. Side damping spring; 83. Guide seat; 84. Guide shaft; 85. Guide hole; 86. External damper; 87. Guide wheel; 9. Mounting hole; 10. Support shaft; 11. Top plate; 12. Guide tube. Detailed Implementation
[0036] The following is in conjunction with the appendix Figure 1-7 This application will be described in further detail.
[0037] This application discloses a dynamic pipeline layout method. For example... Figure 1 As shown, it includes the following steps:
[0038] Step 1: Collect environmental data: Obtain data on the equipment pipeline layout area through sensors or by using field measurement equipment;
[0039] Step 2: Pipeline planning: Based on the collected environmental data, computer simulation technology is used to plan the pipeline and determine the optimal layout path for the equipment;
[0040] Step 3: Pipeline Layout: Based on the pipeline planning results, use a dynamic pipeline layout device in conjunction with manual labor to lay out the pipelines;
[0041] Step 4: Dynamic Adjustment: During the pipeline layout process, dynamic adjustments are made according to the actual situation, including adjusting the layout path, changing the pipeline type, and adjusting the pipeline layout length, etc.
[0042] Step 5: Complete the pipeline system: After completing the pipeline layout, conduct system testing and debugging to ensure the normal operation of the pipeline system.
[0043] Please refer to Figures 1-7 The dynamic pipeline layout device includes a base 1, a fixed platform 2 fixedly installed on the top of the base 1, a support rod 3 rotatably connected to the top of the fixed platform 2, a hexagonal base rod 4 fixedly installed on the top of the support rod 3, height adjustment mechanisms 5 fixedly installed at equal intervals on the outer side of the hexagonal base rod 4, a buffer mechanism 6 fixedly installed on the outer side of the height adjustment mechanism 5, a wiring mechanism 7 fixedly installed in the middle of the outer side of the buffer mechanism 6, and side buffer mechanisms 8 fixedly installed on the top and bottom of the outer side of the buffer mechanism 6. Mounting holes 9 are provided at the four corners of the top of the base 1, and the mounting holes 9 penetrate the base 1. By setting the height adjustment mechanism 5, the wiring height can be adjusted as needed. The buffer mechanism 6 and the side buffer mechanism 8 can provide buffer protection during the dynamic movement of the line. Simultaneously, the wiring mechanism 7 ensures that the laid-out line remains taut during the layout process, exhibiting good stability.
[0044] Please refer to Figures 1-4 The height adjustment mechanism 5 includes support plates 51, which are fixedly installed in a circular pattern at equal intervals on the outside of the hexagonal base rod 4. There are six sets of support plates 51. A guide rail 52 is fixedly installed on the outside of the support plates 51. A lead screw 53 is rotatably connected inside the guide rail 52. The bottom of the lead screw 53 passes through the guide rail 52. A slider 54 is threadedly connected to the outer surface of the lead screw 53. A concave seat 55 is fixedly installed on the outside of the slider 54. The inner side of the concave seat 55 is connected to the buffer mechanism 6 by bolts. By setting the height adjustment mechanism 5, the height of the wiring mechanism 7 can be adjusted by adjusting the lead screw 53 to drive the slider 54 to slide on the inner side of the guide rail 52 during use. This facilitates the adjustment of the wiring height and adapts to wiring needs of different heights.
[0045] Please refer to Figures 1-4 A turntable 56 is fixedly installed at the bottom of the lead screw 53 through the guide rail 52. A crank handle 57 is rotatably connected to one side of the bottom of the turntable 56. By setting the turntable 56, the turntable 56 can be rotated by pulling the crank handle 57 during use, which facilitates the quick adjustment of the rotation of the lead screw 53 and makes it convenient to adjust and use this device.
[0046] Please refer to Figures 1-4A disc 58 is fixedly installed at the bottom of the guide rail 52. The lower end of the lead screw 53 passes through the disc 58. A limiting screw 59 is threadedly connected to the top outer side of the disc 58. The bottom of the limiting screw 59 passes through the circular plate and is fitted to the top of the turntable 56. By setting the disc 58, the device can be moved down by twisting the limiting screw 59 on the disc 58 during use. At this time, the limiting screw 59 abuts against the fixed turntable 56, which can quickly lock the lead screw 53.
[0047] Please refer to Figures 1-3 , Figure 5 and Figure 6 The buffer mechanism 6 includes an outer rail 61, which is bolted to the inner side of the concave seat 55. Buffer springs 62 are fixedly installed at the top and bottom of the outer rail 61. A moving block 63 is fixedly installed at the inner end of the buffer spring 62. The outer side of the moving block 63 is fixedly connected to the inner side of the wiring mechanism 7. An inner damper 64 is fixedly installed at the top and bottom of the outer rail 61. The inner end of the inner damper 64 is fixedly connected to both sides of the moving block 63. A side buffer mechanism 8 is fixedly installed at the top and bottom of the outer rail 61. By setting the buffer mechanism 6, when the line is in a dynamic movement state during use, the line drives the moving block 63 to slide inside the outer rail 61. At this time, the buffer spring 62 resists the extension and contraction, and the spring force of the buffer spring 62 provides buffering. The damper can also dampen the buffer spring 62, making the overall wiring of the device more stable.
[0048] Please refer to Figures 1-2 A support shaft 10 is fixedly installed on the top of the hexagonal base rod 4. A top plate 11 is rotatably connected to the top of the support shaft 10. Guide tubes 12 are fixedly installed at equal intervals on the top of the top plate 11. By setting the support shaft 10, during use, the lines arranged by the wiring mechanism 7 can be inserted into the inside of the guide tubes 12 on the top of the top plate 11, which facilitates the convergence of the lines in one direction and allows for centralized guidance and positioning of the ends of the lines.
[0049] Please refer to Figure 5 The wiring mechanism 7 includes a fixed frame 71, which is fixedly installed on the outside of the movable block 63. The fixed frame 71 has a U-shaped top view. Elastic reset components 72 are fixedly installed on both sides of the front end of the fixed frame 71. A wiring shaft 73 is rotatably connected to the inside of the fixed frame 71. A wiring hole 74 is opened in the middle of the wiring shaft 73, and the wiring hole 74 passes through the wiring shaft 73. By setting up the wiring mechanism 7, during the use of this device, the wire can be inserted into the wiring hole 74 of the wiring shaft 73. By contracting the elastic reset component 72, the wiring shaft 73 can be driven to wind up the wire. During use, the elastic reset component 72 can elastically wind up the wire, which can play a role in tightening and buffering the wire, making the overall stability of the wire stronger.
[0050] Please refer to Figure 5 The elastic reset component 72 includes an outer frame 721, which is fixedly installed on the outside of the fixed frame 71. A torsion spring 722 is fixedly installed on the inner side of the outer frame 721. A connecting shaft 723 is rotatably connected to the outer side of the outer frame 721. The inner end of the connecting shaft 723 passes through the outer frame 721 and is fixedly connected to the inner end of the torsion spring 722. The inner end of the connecting shaft 723 is fixedly connected to the outer end of the wiring shaft 73. An adjusting knob 724 is fixedly installed on the outer end of the connecting shaft 723. By setting the elastic reset component 72, the device can be rotated under force and reset when the torsion spring 722 is not under force during use. This allows the wiring shaft 73 to be driven to extend and retract the wire, enabling the wire to extend and retract freely while remaining in a taut state at all times, resulting in strong overall stability of the wiring after installation.
[0051] Please refer to Figure 1-3 and Figures 5-7 The side buffer mechanism 8 includes a wedge block 81, a side buffer spring 82 fixedly mounted on the outer side of the wedge block 81, a guide seat 83 fixedly mounted on the outer end of the side buffer spring 82, a guide wheel 87 rotatably connected to the inner side of the guide seat 83, a guide hole 85 opened in the middle of the guide wheel 87, a guide shaft 84 rotatably connected to the inner end of the inner side of the guide seat 83, and an external damper 86 fixedly mounted on the outer side of the wedge block 81 and the inner side of the guide seat 83. By setting the side buffer mechanism 8, during use, the outer end of the line can be inserted into the guide hole 85. During use, the line can be repositioned by the guide wheel 87 and the guide shaft 84. At the same time, during the dynamic movement of the line, the side buffer spring 82 and the external damper 86 can provide damping and buffering, which can further improve the overall wiring stability of the device.
[0052] The implementation principle of the dynamic pipeline layout method in this application embodiment is as follows: During use, the base 1 is installed using mounting holes 9 and bolts. After installation, the wire can be passed through the wiring hole 74 on the wiring shaft 73. Then, the adjustment is turned to cause the torsion spring 722 to retract. The wire is then passed through the inner sides of the top and bottom side buffer mechanisms 8 respectively. Finally, the wire at the top is inserted into the guide tube 12. During use, as the equipment operates, the wire also moves dynamically. During the movement, the wire is pulled, which causes the wiring shaft 73 and the torsion spring 722 to rotate. When the wire becomes loose, the torsion spring 722 resets, which causes the wiring shaft 73 to reverse, thereby quickly tightening the excess wire. This ensures that the dynamic wiring arranged by this wiring device operates smoothly. Both can be kept taut, preventing the wires from becoming tangled, twisted, scratched, or cut, thus improving stability during wiring. By incorporating a side buffer mechanism 8 and a buffer mechanism 6, during wiring, the two ends of the wire remaining after being wound by the wiring shaft 73 can be inserted into the guide holes 85 on the guide wheel 87. Further guidance from the guide shaft 84, guide holes 85, and guide seat 83 connects the two ends of the wire externally. During use, when the wire is in a dynamic movement state, the extension and retraction of the wire initially triggers the moving block 63 to slide inside the outer rail 61. The moving block 63 then contacts the inner damper 64 and the buffer spring 62, providing initial buffering and damping. During the extension and retraction of the cable, the cable will inevitably come into contact with the guide wheel 87 and guide shaft 84. At this time, the guide seat 83 is compressed by the force of the side damping spring 82 and the external damper 86, thus extending and retracting. The forces of the buffer spring 62 and the side damping spring 82 are now applied to the cable, resulting in a better overall buffering effect. Furthermore, the internal damper 64 and the external damper 86 enhance the stability of the buffer spring 62 and the side damping spring 82, while reducing their extension and retraction amplitude, thereby improving the buffering and protection effect. This makes the entire cable layout more stable, resulting in a smoother and more orderly wiring process. The height adjustment mechanism 5 allows for flexible installation of the wiring mechanism 7 according to different wiring requirements during use. Specifically, during use, the use of bolts and concave seats… The concave seat 55 is fitted with a buffer mechanism 6, which is installed inside the concave seat 55. Therefore, different numbers of wiring mechanisms 7 can be flexibly installed according to wiring requirements. For example, if the existing equipment requires a single set of wiring, only a single set of buffer mechanisms 6 needs to be installed. During use, due to the rotating setting of the support rod 3 on the top of the fixed platform 2, the support rod 3 can adapt to the dynamic movement of the pipeline, which is convenient for adapting to rotation around the axis and also has the working state of extension and contraction along the plane of the vertical rotation axis. In addition, during use, the turntable 56 can be driven by pulling the crank handle 57 to drive the lead screw 53 to rotate. Then, the lead screw 53 can drive the slider 54 to slide inside the guide rail 52. The slider 54 drives the concave seat 55 to move, so the height of each set of wiring mechanisms 7 can be flexibly adjusted to facilitate wiring at different heights.After the wiring height is adjusted, tightening the limiting screw 59 to contact the disc 58 locks the turntable 56. Fixing the turntable 56 then fixes the lead screw 53, improving the stability of the wiring after adjustment.
[0053] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.
Claims
1. A dynamic pipeline layout method, characterized in that: Includes the following steps: Step 1: Collect environmental data: Obtain data on the equipment pipeline layout area through sensors or by using field measurement equipment; Step 2: Pipeline planning: Based on the collected environmental data, computer simulation technology is used to plan the pipeline and determine the optimal layout path for the equipment; Step 3: Pipeline Layout: Based on the pipeline planning results, use a dynamic pipeline layout device in conjunction with manual labor to lay out the pipelines; Step 4: Dynamic Adjustment: During the pipeline layout process, dynamic adjustments are made according to the actual situation, including adjusting the layout path, changing the pipeline type, and adjusting the pipeline layout length. Step 5: Complete the pipeline system: After completing the pipeline layout, conduct system testing and debugging to ensure the normal operation of the pipeline system; The dynamic pipeline layout device includes a base (1), a fixed platform (2) is fixedly installed on the top of the base (1), a support rod (3) is rotatably connected to the top of the fixed platform (2), a hexagonal base rod (4) is fixedly installed on the top of the support rod (3), a height adjustment mechanism (5) is fixedly installed at equal intervals on the outer side of the hexagonal base rod (4), a buffer mechanism (6) is fixedly installed on the outer side of the height adjustment mechanism (5), a wiring mechanism (7) is fixedly installed in the middle of the outer side of the buffer mechanism (6), a side buffer mechanism (8) is fixedly installed on the top and bottom of the outer side of the buffer mechanism (6), and mounting holes (9) are opened at the four corners of the top of the base (1), and the mounting holes (9) penetrate the base (1). The height adjustment mechanism (5) includes a support plate (51), which is fixedly installed in a circular pattern at equal intervals on the outside of the hexagonal base rod (4). The support plate (51) is set in six groups. A guide rail (52) is fixedly installed on the outside of the support plate (51). A lead screw (53) is rotatably connected inside the guide rail (52). The bottom of the lead screw (53) passes through the guide rail (52). A slider (54) is threadedly connected to the outer surface of the lead screw (53). A concave seat (55) is fixedly installed on the outside of the slider (54). The inner side of the concave seat (55) is connected to the buffer mechanism (6) by bolts. The buffer mechanism (6) includes an outer rail (61), which is bolted to the inner side of the concave seat (55). Buffer springs (62) are fixedly installed at the top and bottom of the outer rail (61). A moving block (63) is fixedly installed at the inner end of the buffer spring (62). The outer side of the moving block (63) is fixedly connected to the inner side of the wiring mechanism (7). An inner damper (64) is fixedly installed at the top and bottom of the outer rail (61). The inner end of the inner damper (64) is fixedly connected to both sides of the moving block (63). The side buffer mechanism (8) is fixedly installed at the top and bottom of the outer rail (61). The wiring mechanism (7) includes a fixing frame (71), which is fixedly installed on the outside of the movable block (63). The fixing frame (71) has a U-shaped top view. Elastic reset components (72) are fixedly installed on both sides of the front end of the fixing frame (71). A wiring shaft (73) is rotatably connected to the inside of the fixing frame (71). A wiring hole (74) is opened in the middle of the wiring shaft (73), and the wiring hole (74) passes through the wiring shaft (73). The side damping mechanism (8) includes a wedge (81), a side damping spring (82) is fixedly installed on the outer side of the wedge (81), a guide seat (83) is fixedly installed on the outer end of the side damping spring (82), a guide wheel (87) is rotatably connected to the inner side of the guide seat (83), a guide hole (85) is opened in the middle of the guide wheel (87), a guide shaft (84) is rotatably connected to the inner end of the inner side of the guide seat (83), an external damper (86) is fixedly installed on the outer side of the wedge (81) located on the inner side of the side damping spring (82), and the outer side of the external damper (86) is fixedly connected to the inner side of the guide seat (83).
2. The dynamic pipeline layout method according to claim 1, characterized in that: The bottom of the lead screw (53) is fixedly mounted on the guide rail (52), and a crank handle (57) is rotatably connected to one side of the bottom of the turntable (56).
3. The dynamic pipeline layout method according to claim 2, characterized in that: A disc (58) is fixedly installed at the bottom of the guide rail (52). The lower end of the lead screw (53) passes through the disc (58). A limiting screw (59) is threadedly connected to the outer top of the disc (58). The bottom of the limiting screw (59) passes through the circular plate and is fitted to the top of the turntable (56).
4. The dynamic pipeline layout method according to claim 3, characterized in that: A support shaft (10) is fixedly installed on the top of the hexagonal base rod (4), and a top plate (11) is rotatably connected to the top of the support shaft (10). Guide tubes (12) are fixedly installed at equal intervals on the top of the top plate (11).
5. The dynamic pipeline layout method according to claim 4, characterized in that: The elastic reset assembly (72) includes an outer frame (721), which is fixedly installed on the outside of the fixed frame (71). A torsion spring (722) is fixedly installed on the inner side of the outer frame (721). A connecting shaft (723) is rotatably connected to the outer side of the outer frame (721). The inner end of the connecting shaft (723) passes through the outer frame (721) and is fixedly connected to the inner end of the torsion spring (722). The inner end of the connecting shaft (723) is fixedly connected to the outer end of the wiring shaft (73). An adjusting knob (724) is fixedly installed on the outer end of the connecting shaft (723).