Mounting bracket for automated instruments used in oil pipeline laying

By designing a combined clamping structure of support base plate and mounting platform, the problem of existing brackets needing to be customized was solved, achieving stable clamping of cooling devices of different sizes, reducing costs and shortening the installation cycle.

CN224433965UActive Publication Date: 2026-06-30XINJIANG ZHUNDONG OIL FIELD ENG TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
XINJIANG ZHUNDONG OIL FIELD ENG TECH CO LTD
Filing Date
2025-08-07
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing automated instrument mounting brackets for oil pipeline laying require customization based on the specific dimensions of the pipeline and instruments, resulting in high costs and long installation cycles. Furthermore, the limit blocks and clamping mechanisms cannot effectively secure cooling devices of different sizes.

Method used

A mounting bracket including a support base plate, a mounting platform, a clamping plate, and a limiting plate is designed. The cooling device can be adjusted and stabilized in multiple directions through a threaded rod and a turntable mechanism. It can adapt to cooling devices of different widths, and the combination of the limiting plate and the clamping plate can improve the stabilization effect.

Benefits of technology

It achieves stable clamping of cooling devices of different sizes, shortens the installation cycle, reduces costs, and improves installation flexibility and stability.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model relates to the field of oil pipeline technology and discloses a mounting bracket for automated instruments used in oil pipeline laying. The bracket includes a support base plate, a cooling device, and a mounting platform. The mounting platform is fixedly mounted directly above the top of the support base plate. A mounting groove is formed on the top of the mounting platform, and a limiting groove is formed in the middle of the mounting groove. The cooling device is located within the limiting groove, and its two sides are in contact with the inner wall of the opposite side of the limiting groove. The two mounting brackets of this utility model utilize two first movable grooves that cooperate to drive two guide blocks to move relative to each other. The two guide grooves that cooperate to drive two support rods to move relative to each other. The two support rods drive two clamping plates to move relative to each other until the two clamping plates are tightly fitted against the outer walls of the two sides of the cooling device, achieving a secure clamping effect. This method can secure cooling devices of different widths and is suitable for widespread application.
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Description

Technical Field

[0001] This utility model belongs to the field of oil pipeline technology, specifically, it relates to an installation bracket for automated instruments used in oil pipeline laying. Background Technology

[0002] Oil pipeline laying is a crucial step in the petroleum industry, and automated instruments play a key role in the monitoring and control of oil pipeline operations. In the field of oil pipeline laying, there are various types of existing automated instrument mounting technologies.

[0003] Currently, common mounting brackets employ a fixed structure design. These brackets require customization based on the specific dimensions of the pipeline and the specifications of the instruments used during installation. In practice, oil pipelines come in various diameters, and different automated instruments have different dimensions and installation requirements. For fixed-structure mounting brackets, any change in pipeline diameter or instrument specifications necessitates redesigning and manufacturing new brackets, which not only increases costs but also extends the installation cycle.

[0004] However, through exploration, the inventors have discovered that in current automated instruments used for oil pipeline laying, the cooling device is limited by a limiting block. After the cooling device is limited, it is clamped and stabilized by a clamping mechanism. However, the limiting block is fixed and can only limit the cooling device of a fixed width. Furthermore, the clamping mechanism can only clamp the side of the cooling device, and the top of the cooling device cannot be effectively limited.

[0005] In view of the above, this utility model is hereby proposed. Utility Model Content

[0006] To solve the above-mentioned technical problems, the basic concept of the technical solution adopted by this utility model is as follows:

[0007] An installation bracket for automated instruments used in oil pipeline laying includes a support base plate, a cooling device, and an installation platform. The installation platform is fixedly installed directly above the top of the support base plate. An installation groove is formed on the top of the installation platform, and a limiting groove is formed in the middle of the installation groove. The cooling device is located within the limiting groove, and its two sides are in contact with the inner walls of opposite sides of the limiting groove. Symmetrically arranged clamping plates are slidably connected to both ends of the installation groove. Two clamping plates are symmetrically arranged on both sides of the cooling device. Symmetrically arranged limiting plates are bolted to the top outer walls of the two clamping plates. The bottom outer walls of the two limiting plates are in contact with the top outer walls of the cooling device on both sides. Symmetrically arranged guide grooves are formed on the bottom inner wall of the installation groove. Support rods are slidably connected to the inner walls of both guide grooves, and the top ends of the two support rods are fixedly connected to the bottom outer walls of the two clamping plates.

[0008] In a preferred embodiment, the mounting platform has symmetrically arranged through holes on both sides, and guide rods are slidably connected to the inner walls of the through holes. The two guide rods are respectively fixedly connected to the outer walls of one side of the two clamping plates at opposite ends.

[0009] In a preferred embodiment, symmetrically arranged stabilizing brackets are fixedly connected to both sides of the top of the support base plate, and the top ends of the two stabilizing brackets are symmetrically fixed to the bottom outer wall of the mounting platform.

[0010] In a preferred embodiment, the top outer wall of the support base plate is provided with symmetrically arranged first movable grooves, and the inner walls of the two first movable grooves are slidably connected with guide blocks. The bottom ends of the two support rods are respectively fixedly connected to the top outer walls of the two guide blocks. The top outer walls of the two guide blocks are fixedly connected with mounting brackets, and the two mounting brackets are rotatably mounted with connecting rods at opposite ends.

[0011] In a preferred embodiment, a second movable groove is provided on the outer wall of the top center of the support base plate, a sliding seat is slidably disposed on the inner wall of the second movable groove, a connecting frame is fixedly connected to the top outer wall of the sliding seat, and two connecting rods are rotatably connected to the two ends of the connecting frame at opposite ends.

[0012] In a preferred embodiment, a mounting plate is fixedly connected to the outer wall of the top right side of the support base plate, and a threaded rod is rotatably mounted on one side of the mounting plate. A threaded hole is provided on the sliding seat, and the threaded rod is screwed onto the inner wall of the threaded hole.

[0013] In a preferred embodiment, a fixing plate is fixedly connected to the outer wall of the top left side of the support base plate. The fixing plate has a mounting hole, and a rotating rod is rotatably mounted on the inner wall of the mounting hole. The rotating rod is fixedly connected to one end opposite to the threaded rod, and a turntable is fixedly connected to the end of the rotating rod away from the threaded rod.

[0014] Compared with the prior art, the present invention has the following advantages:

[0015] This invention places the cooling device in the center of the mounting groove, so that both sides of the cooling device contact the inner wall of the opposite side of the limiting groove, thereby limiting the cooling device. After the cooling device is limited, the rotating rod is rotated by the set turntable, which drives the threaded rod to rotate. The threaded rod, in conjunction with the set second movable groove, drives the sliding seat to move laterally. The sliding seat drives one end of the connecting frame laterally. The two mounting brackets set with the connecting frame drive the two connecting rods to rotate, so that the two first movable grooves set with the two mounting brackets drive the two guide blocks to move relative to each other. The two guide grooves set with the two guide blocks drive the two support rods to move relative to each other. The two support rods drive the two clamping plates to move relative to each other until the two clamping plates are tightly attached to the outer walls of both sides of the cooling device, thereby achieving a clamping and stabilizing effect on the cooling device. It can stabilize cooling devices of different widths. After the two sides of the cooling device are clamped, the two limiting plates are fixed to the top position of the two clamping plates with bolts, so that the bottom outer walls of the two limiting plates contact the top outer walls of the two sides of the cooling device, thereby limiting the top position of the cooling device and further improving the stabilizing effect of the cooling device.

[0016] The specific embodiments of this utility model will be described in further detail below with reference to the accompanying drawings. Attached Figure Description

[0017] In the attached diagram:

[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0019] Figure 2 This is a schematic diagram of the mounting platform structure of this utility model;

[0020] Figure 3 This is a side view of the connection between the substrate and the mounting platform of this utility model.

[0021] Figure 4 This is a schematic diagram of the substrate structure of this utility model.

[0022] In the diagram: 1. Support base plate; 2. Cooling device; 3. Mounting platform; 4. Mounting groove; 5. Clamping plate; 6. Limiting plate; 7. Limiting groove; 8. Stabilizing bracket; 9. Guide rod; 10. Threaded rod; 11. Fixing plate; 12. Guide groove; 13. Support rod; 14. First movable groove; 15. Guide block; 16. Mounting frame; 17. Sliding seat; 18. Connecting frame; 19. Connecting rod; 20. Turntable; 21. Mounting plate; 22. Second movable groove; 23. Rotating rod. Detailed Implementation

[0023] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions in the embodiments will be clearly and completely described below with reference to the accompanying drawings. The following embodiments are used to illustrate this utility model.

[0024] like Figures 1 to 4 As shown

[0025] A mounting bracket for automated instruments used in oil pipeline laying includes a support base plate 1, a cooling device 2, and a mounting platform 3. The mounting platform 3 is fixedly installed directly above the top of the support base plate 1. A mounting groove 4 is formed on the top of the mounting platform 3, and a limiting groove 7 is formed in the middle of the mounting groove 4. The cooling device 2 is located within the limiting groove 7, with its two sides contacting the inner walls of the limiting groove 7 on opposite sides. Placing the cooling device 2 in the middle position within the mounting groove 4, so that its two sides contact the inner walls of the limiting groove 7 on opposite sides, achieves a limiting effect on the cooling device 2. Two symmetrically arranged clamping plates 5 are slidably connected to both ends of the mounting groove 4, symmetrically positioned on both sides of the cooling device 2. The top outer wall of the 5 is bolted with symmetrically arranged limiting plates 6. The bottom outer walls of the two limiting plates 6 are in contact with the top outer walls of the cooling device 2 on both sides. After the cooling device 2 is clamped on both sides, the two limiting plates 6 are fixedly installed on the top position of the two clamping plates 5 with bolts, so that the bottom outer walls of the two limiting plates 6 are in contact with the top outer walls of the cooling device 2 on both sides, thereby limiting the position of the top of the cooling device 2 and further improving the stability of the cooling device 2. The bottom inner wall of the mounting groove 4 is provided with symmetrically arranged guide grooves 12. The inner walls of the two guide grooves 12 are slidably connected with support rods 13. The top ends of the two support rods 13 are fixedly connected to the bottom outer walls of the two clamping plates 5.

[0026] In a specific embodiment, the top outer wall of the support base plate 1 has symmetrically arranged first movable grooves 14. Guide blocks 15 are slidably connected to the inner walls of both first movable grooves 14. The bottom ends of two support rods 13 are respectively fixedly connected to the top outer walls of the two guide blocks 15. Mounting brackets 16 are fixedly connected to the top outer walls of both guide blocks 15. Connecting rods 19 are rotatably mounted on opposite ends of the two mounting brackets 16. The top middle outer wall of the support base plate 1 has a second movable groove 22. A sliding seat 17 is slidably arranged on the inner wall of the second movable groove 22. A connecting bracket 18 is fixedly connected to the top outer wall of the sliding seat 17. The opposite ends of the two connecting rods 19 are rotatably connected to the two ends of the connecting bracket 18. A mounting plate 21 is fixedly connected to the top right outer wall of the support base plate 1. A threaded rod 10 is rotatably mounted on one side of the mounting plate 21. A threaded hole is opened on the sliding seat 17, and the threaded rod 10 is screwed onto the inner wall of the threaded hole. A fixing plate 11 is fixedly connected to the top left outer wall of the support base plate 1. A mounting hole is opened on the fixing plate 11, and the inner wall of the mounting hole is rotatable. A rotating rod 23 is installed, and the opposite end of the rotating rod 23 is fixedly connected to the threaded rod 10. The end of the rotating rod 23 away from the threaded rod 10 is fixedly connected to a turntable 20. When the cooling device 2 is in a limited position, the rotating rod 23 is rotated by the turntable 20, which causes the rotating rod 23 to drive the threaded rod 10 to rotate. The threaded rod 10, in conjunction with the second movable groove 22, drives the sliding seat 17 to move laterally. The sliding seat 17 drives the connecting frame 18 to move laterally at one end. The two mounting brackets 16 of the connecting frame 18 drive the two connecting rods 19 to rotate, which causes the two first movable grooves 14 of the two mounting brackets 16 to drive the two guide blocks 15 to move relative to each other. The two guide grooves 12 of the two guide blocks 15 drive the two support rods 13 to move relative to each other. The two support rods 13 drive the two clamping plates 5 to move relative to each other until the two clamping plates 5 are tightly attached to the outer walls of both sides of the cooling device 2, thereby achieving a clamping and stabilizing effect on the cooling device 2 and stabilizing cooling devices 2 of different widths.

[0027] Furthermore, the mounting platform 3 has symmetrically arranged through holes on both sides, and guide rods 9 are slidably connected to the inner walls of the through holes. The two guide rods 9 are respectively fixedly connected to the outer walls of one side of the two clamping plates 5. The top two sides of the support base plate 1 are fixedly connected to symmetrically arranged stabilizing brackets 8. The tops of the two stabilizing brackets 8 are symmetrically fixed to the bottom outer wall of the mounting platform 3. The bottom two sides of the support base plate 1 are fixedly installed with symmetrically arranged mounting ears. After the cooling device 2 is stably installed, the support base plate 1 is placed in the position of the new energy vehicle cooling device 2. Then, the support base plate 1 is fixedly installed by the mounting ears at the bottom of the support base plate 1 and the screws that match the mounting ears, so as to achieve the fixed support of the whole device.

[0028] The implementation principle of the mounting bracket for automated instruments used in oil pipeline laying in this embodiment is as follows: In specific use, the cooling device 2 is placed in the middle position in the mounting groove 4, so that both sides of the cooling device 2 are in contact with the inner wall of the opposite side of the limiting groove 7, thereby limiting the cooling device 2. After the cooling device 2 is limited, the rotating rod 23 is rotated by the set turntable 20, so that the rotating rod 23 drives the threaded rod 10 to rotate. The threaded rod 10, in conjunction with the set second movable groove 22, drives the sliding seat 17 to move laterally. The sliding seat 17 drives the connecting frame 18 to move laterally at one end. The two mounting brackets 16 set in conjunction with the connecting frame 18 drive the two connecting rods 19 to rotate, so that the two first movable grooves 14 set in conjunction with the two mounting brackets 16 drive the two guide blocks 15 to move relative to each other. The two guide grooves 12 set in conjunction with the two guide blocks 15 drive the two support rods 13 to move relative to each other. Two support rods 13 drive two clamping plates 5 to move relative to each other until the two clamping plates 5 are tightly attached to the outer walls of both sides of the cooling device 2, thereby achieving a clamping and stabilizing effect on the cooling device 2 and stabilizing cooling devices 2 of different widths. After the two sides of the cooling device 2 are clamped, two limiting plates 6 are fixedly installed at the top position of the two clamping plates 5 with bolts, so that the bottom outer walls of the two limiting plates 6 contact the top two outer walls of the cooling device 2, thereby limiting the top position of the cooling device 2 and further improving the stabilizing effect of the cooling device 2. After the cooling device 2 is stably installed, the support base plate 1 is placed in the position of the new energy vehicle to install the cooling device 2, and then the support base plate 1 is fixedly installed by the mounting ears at the bottom position of the support base plate 1 and the screws that match the mounting ears, thereby achieving the fixed support of the entire device.

Claims

1. A mounting bracket for automated instruments used in oil pipeline laying, comprising a support base plate (1), a cooling device (2), and a mounting platform (3), characterized in that, The mounting platform (3) is fixedly installed directly above the top of the support base plate (1). The mounting platform (3) has a mounting groove (4) on its top. A limiting groove (7) is opened in the middle of the mounting groove (4). The cooling device (2) is located in the limiting groove (7). The two sides of the cooling device (2) are in contact with the inner wall of the opposite side of the limiting groove (7). The mounting groove (4) is slidably connected to the two ends of the mounting plate (4). The two clamping plates (5) are symmetrically arranged on both sides of the cooling device (2). The outer walls of the top of the two clamping plates (5) are bolted with symmetrically arranged limiting plates (6). The outer walls of the bottom of the two limiting plates (6) are in contact with the outer walls of the top two sides of the cooling device (2). The inner wall of the bottom of the mounting groove (4) has symmetrically arranged guide grooves (12). The inner walls of the two guide grooves (12) are slidably connected with support rods (13). The top ends of the two support rods (13) are fixedly connected to the outer walls of the bottom of the two clamping plates (5).

2. The mounting bracket for automated instruments used in oil pipeline laying according to claim 1, characterized in that, The mounting platform (3) has symmetrically arranged through holes on both sides, and guide rods (9) are slidably connected to the inner walls of the through holes. The two guide rods (9) are fixedly connected to the outer walls of one side of the two clamping plates (5) at opposite ends.

3. The mounting bracket for automated instruments used in oil pipeline laying according to claim 1, characterized in that, The top two sides of the support base plate (1) are fixedly connected with symmetrically arranged stabilizing brackets (8), and the top ends of the two stabilizing brackets (8) are symmetrically fixed on the bottom outer wall of the mounting platform (3).

4. The mounting bracket for automated instruments used in oil pipeline laying according to claim 1, characterized in that, The top outer wall of the support base plate (1) is provided with symmetrically arranged first movable grooves (14), and the inner walls of the two first movable grooves (14) are slidably connected with guide blocks (15). The bottom ends of the two support rods (13) are respectively fixedly connected to the top outer walls of the two guide blocks (15). The top outer walls of the two guide blocks (15) are fixedly connected with mounting brackets (16), and the two mounting brackets (16) are rotatably mounted with connecting rods (19) at opposite ends.

5. The mounting bracket for automated instruments used in oil pipeline laying according to claim 4, characterized in that, The support base plate (1) has a second movable groove (22) on the outer wall of the top center. A sliding seat (17) is slidably provided on the inner wall of the second movable groove (22). A connecting frame (18) is fixedly connected to the top outer wall of the sliding seat (17). Two connecting rods (19) are rotatably connected to the two ends of the connecting frame (18) respectively.

6. The mounting bracket for automated instruments used in oil pipeline laying according to claim 5, characterized in that, A mounting plate (21) is fixedly connected to the outer wall of the top right side of the support base plate (1). A threaded rod (10) is rotatably mounted on one side of the mounting plate (21). A threaded hole is opened on the sliding seat (17), and the threaded rod (10) is screwed onto the inner wall of the threaded hole.

7. The mounting bracket for automated instruments used in oil pipeline laying according to claim 6, characterized in that, A fixing plate (11) is fixedly connected to the outer wall of the top left side of the support base plate (1). The fixing plate (11) has an installation hole, and a rotating rod (23) is rotatably installed on the inner wall of the installation hole. The rotating rod (23) is fixedly connected to one end of the threaded rod (10), and a turntable (20) is fixedly connected to one end of the rotating rod (23) away from the threaded rod (10).