A porous buried pipeline laying construction spacer device
By using a multi-hole buried pipeline installation separator device to fix the pipeline position in the foundation pit, the problem of low efficiency in formwork erection was solved, and efficient construction was achieved during the backfilling process.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHAANXI ROAD & BRIDGE GRP ROAD SURFACE CONSTR
- Filing Date
- 2025-08-09
- Publication Date
- 2026-07-14
AI Technical Summary
During the backfilling process of multi-hole buried pipeline foundation pits, large-area formwork needs to be erected for fixation, resulting in a large investment of manpower and material resources. Furthermore, the backfilling and formwork erection work need to be carried out separately, which affects construction efficiency.
A multi-hole buried pipeline installation separator device is adopted, which fixes the pipeline position in the foundation pit by means of traction rods and separator plates, reducing the need for formwork support and achieving stable traction of the pipeline during the backfilling process.
It eliminates the need for large-scale formwork support, reduces manpower and material resources, improves backfilling efficiency, and enables stable traction and synchronous construction of pipelines.
Smart Images

Figure CN224497725U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the technical field of underground pipeline construction equipment for municipal engineering, specifically a multi-hole underground pipeline layout construction separator device. Background Technology
[0002] Multi-hole buried pipelines are underground pipe network systems with multiple independent channels. They are widely used in urban water supply, drainage, communication, power, gas and other infrastructure fields. After laying multi-hole buried pipelines in the foundation pit, the foundation pit needs to be backfilled. In order to ensure the quality of backfilling, the position of the pipeline needs to be fixed during the backfilling process to avoid pipeline displacement and uneven backfilling between pipelines.
[0003] Currently, when backfilling the foundation pit for laying multi-hole buried pipelines, it is usually necessary to support and fix the pipeline over a large area using formwork, which requires a lot of manpower and resources. Furthermore, the backfilling work and the formwork support work need to be carried out separately, which affects the efficiency of the backfilling construction. Utility Model Content
[0004] To address the shortcomings of existing technologies, this application provides a multi-hole buried pipeline laying construction separator device. This device eliminates the need for large-area formwork support and fixing of the pipeline during backfilling, reducing manpower and material resources. It also provides stable traction of the pipeline position and allows for simultaneous traction of the pipeline position during backfilling, improving construction efficiency. This solution addresses the current problem that backfilling foundation pits for multi-hole buried pipelines typically requires large-area formwork support and fixing of the pipeline, necessitating significant manpower and material resources, and requires backfilling and formwork support to be carried out separately, thus impacting construction efficiency.
[0005] To achieve the goals of eliminating the need for large-area formwork support and fixing of pipelines during backfilling, reducing the input of manpower and materials, enabling stable traction of pipeline positions, and improving backfilling construction efficiency by traction of pipeline positions during backfilling work, this application provides the following technical solution: a multi-hole buried pipeline layout construction separator device, including a traction rod, one end of which is provided with a fixing plate, the fixing plate being located at the top of a connecting frame, and multiple separator plates being provided below the connecting frame.
[0006] The connecting frame has a vertically extending groove in the middle. The top of the partition plate is provided with a connecting component, which includes a rotating disk. The top of the rotating disk is provided with an adjusting component, which includes a slider. The slider is slidably disposed inside the groove, and the size of the slider is adapted to the size of the inner wall of the groove.
[0007] The above-described method involves workers holding a traction rod to place two adjacent partition plates on either side of the pipeline within the foundation pit. These partition plates then pull and fix the pipeline in place within the pit. By continuously moving the traction rod, the partition plates maintain the pipeline's position throughout the backfilling process. This eliminates the need for extensive formwork support during backfilling, reducing manpower and material costs. The method also ensures stable pipeline positioning and improves backfilling efficiency by allowing for simultaneous traction during the backfilling process.
[0008] Furthermore, a limiting plate is provided above the connecting frame, the limiting plate is located at the top of the slider, and the length of the limiting plate is greater than the width of the slide groove. An abutting block is provided below the connecting frame, the abutting block is located at the end of the top outer surface of the partition plate, and the width of the partition plate is greater than the width of the slide groove.
[0009] The above solution uses a limiting plate above the connecting frame and an abutting block below the connecting frame to abut against the upper and lower surfaces of the connecting frame, which can fix the position of the slider inside the groove, thereby fixing the position of the partition plate below the connecting frame.
[0010] Furthermore, a threaded rod is threadedly connected to the inner wall of the middle part of the slider, and one end of the threaded rod is located at the top of the rotating disk.
[0011] With the above solution, by rotating the threaded rod, the position of the threaded rod on the inner wall of the middle of the slider can be adjusted, thereby allowing the threaded rod to adjust the distance between the partition plate and the connecting frame through the connecting assembly. This allows control over the contact relationship between the abutting block and the lower surface of the connecting frame, and facilitates the release of the fixed position of the slider and the partition plate. It also allows adjustment of the position between multiple partition plates, so that the distance between multiple partition plates can adapt to different pipe diameters and different pipe laying positions.
[0012] Furthermore, the rotating disk is rotatably disposed within the inner wall of the middle part of the positioning frame, and the positioning frame is disposed on the top of the partition plate.
[0013] The above solution allows the rotating disk to rotate within the inner wall of the positioning frame, preventing the partition plate from affecting the rotation of the threaded rod. It also allows the partition plate to rotate below the slider, adjusting the angle between the partition plate and the slide groove so that the partition plate can pass through the slide groove. This allows for easy adjustment and installation of the corresponding number of partition plates according to the number of perforated pipes.
[0014] Furthermore, a limiting ring is provided at the top of the positioning frame, and the diameter of the inner wall of the limiting ring is smaller than the diameter of the rotating disk.
[0015] The above solution restricts the position of the rotating disk inside the positioning frame by setting a limit ring, preventing the rotating disk from falling out of the positioning frame and improving the stability of the rotating disk when it rotates inside the positioning frame.
[0016] Furthermore, an anti-slip pad is provided between the abutment block and the connecting frame, and the anti-slip pad is located on the top of the abutment block.
[0017] The above solution increases the friction between the abutment block and the lower surface of the connecting frame by adding anti-slip pads, thereby improving the stability of the abutment between the abutment block and the connecting frame and thus ensuring the stable fixation of the partition plate.
[0018] Furthermore, the top of the partition plate is provided with two limiting rods, which are located on both sides of the threaded rod above the partition plate. The two limiting rods are inserted into the interior of two limiting holes, which are opened on the slider.
[0019] The above solution allows the limiting rod to slide within the limiting hole, thereby fixing the angle at which the partition plate moves up and down when rotated by the threaded rod, thus improving the stability of the partition plate when the threaded rod is rotated.
[0020] Furthermore, two reinforcing rods are provided on both sides of one end of the traction rod, with the ends of the two reinforcing rods away from the traction rod located at both ends of the top outer surface of the fixed plate, and the two reinforcing rods are inclined and symmetrically arranged.
[0021] The above solution improves the stability of the connection between the traction rod and the fixed plate by adding a reinforcing rod, supports the traction rod and the fixed plate, and fixes the angle between the traction rod and the fixed plate.
[0022] Compared with the prior art, the technical solution of this application has the following beneficial effects:
[0023] This multi-hole buried pipeline installation separator device allows workers to hold a traction rod and place two adjacent separator plates on either side of the pipeline within the foundation pit. The two separator plates then pull and fix the pipeline's position within the pit. By continuously moving the traction rod, the separator plates maintain the pipeline's position during backfilling, eliminating the need for large-area formwork support during backfilling. This reduces manpower and material costs, provides stable pipeline positioning, and allows for simultaneous pipeline positioning during backfilling, thus improving construction efficiency. Attached Figure Description
[0024] Figure 1 This is a three-dimensional structural diagram of this application;
[0025] Figure 2This is a schematic diagram of the structure on the right side of this application;
[0026] Figure 3 This is a top view of the structure of this application;
[0027] Figure 4 This is a schematic diagram of the front structure of this application;
[0028] Figure 5 This is a frontal view of a partial structural section of this application;
[0029] Figure 6 This is a three-dimensional schematic diagram showing a partial structural cross-section of this application.
[0030] In the picture:
[0031] 1. Traction rod; 2. Fixing plate; 3. Connecting frame; 4. Divider plate; 5. Adjusting assembly; 501. Slider; 502. Threaded rod; 6. Slide groove; 7. Connecting assembly; 701. Positioning frame; 702. Rotating disk; 703. Limiting ring; 8. Limiting plate; 9. Abutment block; 10. Anti-slip pad; 11. Limiting rod; 12. Limiting hole; 13. Reinforcing rod. Detailed Implementation
[0032] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.
[0033] Please see Figure 1 , Figure 2 and Figure 3 The multi-hole buried pipeline installation construction separator device in this embodiment includes a traction rod 1, a fixing plate 2 at one end of the traction rod 1, the fixing plate 2 being located on the top of the connecting frame 3, and multiple separator plates 4 being located below the connecting frame 3.
[0034] Please see Figure 1 , Figure 3 and Figure 4 The middle of the connecting frame 3 is provided with a vertically penetrating groove 6. The top of the partition plate 4 is provided with a connecting component 7. The connecting component 7 includes a rotating disk 702. The top of the rotating disk 702 is provided with an adjusting component 5. The adjusting component 5 includes a slider 501. The slider 501 is slidably disposed inside the groove 6. The size of the slider 501 is adapted to the size of the inner wall of the groove 6.
[0035] Please see Figure 1 , Figure 3 and Figure 4A limiting plate 8 is provided above the connecting frame 3. The limiting plate 8 is located on the top of the slider 501. The length of the limiting plate 8 is greater than the width of the slide groove 6. An abutting block 9 is provided below the connecting frame 3. The abutting block 9 is located at the end of the top outer surface of the partition plate 4. The width of the partition plate 4 is greater than the width of the slide groove 6. The limiting plate 8 above the connecting frame 3 and the abutting block 9 below the connecting frame 3 abut against the upper and lower surfaces of the connecting frame 3, which can fix the position of the slider 501 inside the slide groove 6, thereby fixing the position of the partition plate 4 below the connecting frame 3.
[0036] Please see Figure 1 , Figure 5 and Figure 6 A threaded rod 502 is threadedly connected to the inner wall of the middle part of the slider 501. One end of the threaded rod 502 is set at the top of the rotating disk 702. By rotating the threaded rod 502, the position of the threaded rod 502 on the inner wall of the middle part of the slider 501 can be adjusted. This allows the threaded rod 502 to adjust the distance between the partition plate 4 and the connecting frame 3 through the connecting assembly 7. This controls the contact relationship between the abutting block 9 and the lower surface of the connecting frame 3. It also allows for easy release of the fixed position of the slider 501 and the partition plate 4. The position between multiple partition plates 4 can be adjusted, so that the distance between multiple partition plates 4 can adapt to different pipe diameters and different pipe laying positions.
[0037] Please see Figure 4 , Figure 5 and Figure 6 The rotating disk 702 is rotatably disposed within the inner wall of the middle part of the positioning frame 701, which is located on top of the partition plate 4. By rotating the rotating disk 702 within the inner wall of the middle part of the positioning frame 701, the partition plate 4 can be prevented from affecting the rotation of the threaded rod 502. Furthermore, the partition plate 4 can be rotated below the slider 501, adjusting the angle between the partition plate 4 and the slide groove 6 so that the partition plate 4 can pass through the slide groove 6. This allows for convenient adjustment and installation of the corresponding number of partition plates 4 according to the number of perforated pipes.
[0038] Please see Figure 5 and Figure 6 A limiting ring 703 is provided at the top of the positioning frame 701. The diameter of the inner wall of the limiting ring 703 is smaller than the diameter of the rotating disk 702. The limiting ring 703 can restrict the position of the rotating disk 702 inside the positioning frame 701, prevent the rotating disk 702 from falling out of the positioning frame 701, and improve the stability of the rotating disk 702 when rotating inside the positioning frame 701.
[0039] Please see Figure 2 , Figure 4 and Figure 5An anti-slip pad 10 is provided between the abutting block 9 and the connecting frame 3. The anti-slip pad 10 is set on the top of the abutting block 9. The anti-slip pad 10 can increase the friction between the abutting block 9 and the lower surface of the connecting frame 3, improve the stability of the abutting between the abutting block 9 and the connecting frame 3, and thus fix the position of the partition plate 4 stably.
[0040] Please see Figure 3 , Figure 5 and Figure 6 Two limiting rods 11 are provided on the top of the partition plate 4. The two limiting rods 11 are located on both sides of the threaded rod 502 above the partition plate 4. The two limiting rods 11 are inserted into the interior of two limiting holes 12. The limiting holes 12 are opened on the slider 501. By sliding the limiting rods 11 in the limiting holes 12, the angle of the partition plate 4 moving up and down when rotating through the threaded rod 502 can be fixed, thereby improving the stability of the partition plate 4 when rotating through the threaded rod 502.
[0041] Please see Figure 1 , Figure 2 and Figure 3 Two reinforcing rods 13 are provided on both sides of one end of the traction rod 1. The ends of the two reinforcing rods 13 away from the traction rod 1 are located at both ends of the top outer surface of the fixed plate 2. The two reinforcing rods 13 are inclined and symmetrically arranged. The setting of the reinforcing rods 13 can improve the stability of the connection between the traction rod 1 and the fixed plate 2, support the traction rod 1 and the fixed plate 2, and fix the angle between the traction rod 1 and the fixed plate 2.
[0042] This embodiment of a multi-hole buried pipeline installation construction separator device allows workers to hold a traction rod 1 and place two adjacent separator plates 4 on both sides of the pipeline within the foundation pit. The two adjacent separator plates 4 then pull and fix the pipeline's position within the pit. By continuously moving the traction rod 1, the separator plates 4 continuously pull and fix the pipeline's position during backfilling. This eliminates the need for large-area formwork support during backfilling, reducing manpower and material costs. It provides stable pipeline positioning and improves construction efficiency by simultaneously pulling the pipeline's position during backfilling.
[0043] The working principle of the above embodiment is as follows: When the number of partition plates 4 needs to be increased according to the number of porous pipes, the threaded rod 502 is rotated, causing the threaded rod 502 to drive the connecting assembly 7 to move through the slider 501, which in turn drives the partition plate 4 to move, increasing the distance between the partition plate 4 and the slider 501. This causes the partition plate 4 to pull the limiting rod 11 out of the limiting hole 12. The partition plate 4 is then rotated, causing the rotating disk 702 to rotate within the positioning frame 701. The angle of the partition plate 4 below the slider 501 is adjusted so that the partition plate 4 can smoothly pass through the slide groove 6, allowing the slider 501 to slide into the interior of the slide groove 6. Subsequently, the angle of the partition plate 4 below the slider 501 is reset, and the threaded rod 502 is rotated again, causing the partition plate 4 to move through the slide groove 6. The movable partition plate 4 moves upward, causing the limiting rod 11 to re-insert into the limiting hole 12. According to the diameter and position of the pipe, the slider 501 slides in the groove 6 to adjust the distance between the multiple partition plates 4. After adjustment, the threaded rod 502 is rotated to move the partition plate 4 upward, so that the abutting block 9 abuts against the lower surface of the connecting frame 3. The limiting plate 8 is used to fix the position of the slider 501 and the partition plate 4. The worker holds the traction rod 1 and places two adjacent partition plates 4 on both sides of the pipe in the pit to pull and fix the position of the pipe in the pit. During the backfilling process, the worker holds the traction rod 1 and moves it so that the partition plate 4 continuously pulls and fixes the position of the pipe in the pit.
[0044] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Without further limitations, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes said element.
[0045] Although embodiments of this application have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and variations can be made to these embodiments without departing from the principles and spirit of this application, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A multi-hole buried pipeline installation construction separator device, comprising a traction rod (1), characterized in that: One end of the traction rod (1) is provided with a fixing plate (2), the fixing plate (2) is located on the top of the connecting frame (3), and multiple partition plates (4) are provided below the connecting frame (3). The connecting frame (3) has a vertically extending groove (6) in the middle. The top of the partition plate (4) is provided with a connecting component (7). The connecting component (7) includes a rotating disk (702). The top of the rotating disk (702) is provided with an adjusting component (5). The adjusting component (5) includes a slider (501). The slider (501) is slidably disposed inside the groove (6). The size of the slider (501) is adapted to the size of the inner wall of the groove (6).
2. The porous buried pipeline installation construction separator device according to claim 1, characterized in that: A limiting plate (8) is provided above the connecting frame (3). The limiting plate (8) is located at the top of the slider (501). The length of the limiting plate (8) is greater than the width of the slide groove (6). An abutting block (9) is provided below the connecting frame (3). The abutting block (9) is located at the end of the top outer surface of the partition plate (4). The width of the partition plate (4) is greater than the width of the slide groove (6).
3. The porous buried pipeline installation construction separator device according to claim 1, characterized in that: The slider (501) has a threaded rod (502) threadedly connected to the inner wall of the middle part, and one end of the threaded rod (502) is located at the top of the rotating disk (702).
4. The porous buried pipeline installation construction separator device according to claim 1, characterized in that: The rotating disk (702) is rotatably disposed within the inner wall of the middle part of the positioning frame (701), and the positioning frame (701) is disposed on the top of the partition plate (4).
5. A porous buried pipeline installation construction separator device according to claim 4, characterized in that: The top of the positioning frame (701) is provided with a limiting ring (703), and the diameter of the inner wall of the limiting ring (703) is smaller than the diameter of the rotating disk (702).
6. The porous buried pipeline installation construction separator device according to claim 2, characterized in that: An anti-slip pad (10) is provided between the abutment block (9) and the connecting frame (3), and the anti-slip pad (10) is located on the top of the abutment block (9).
7. The porous buried pipeline installation construction separator device according to claim 1, characterized in that: The top of the partition plate (4) is provided with two limiting rods (11). The two limiting rods (11) are located on both sides of the threaded rod (502) above the partition plate (4). The two limiting rods (11) are inserted into the interior of two limiting holes (12). The limiting holes (12) are opened on the slider (501).
8. The porous buried pipeline installation construction separator device according to claim 1, characterized in that: Two reinforcing rods (13) are provided on both sides of one end of the traction rod (1). The ends of the two reinforcing rods (13) away from the traction rod (1) are located at both ends of the top outer surface of the fixing plate (2). The two reinforcing rods (13) are inclined and symmetrically arranged.