An optical fiber sensor laying device
By introducing a combination of a geared motor and an electric push rod into the fiber optic sensor deployment device, the device can be moved and its position adjusted electrically, solving the problem of inconvenient device transfer in the prior art and improving the ease of deployment and the effect of adhesive application.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGSU XINYUAN SENSING TECH CO LTD
- Filing Date
- 2025-08-08
- Publication Date
- 2026-07-07
Smart Images

Figure CN224463078U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of fiber optic sensing technology, specifically to a fiber optic sensor deployment device. Background Technology
[0002] Fiber optic sensors have been widely used in many fields due to their advantages such as high sensitivity, resistance to electromagnetic interference, and distributed measurement. However, in the actual deployment process, they face many challenges, resulting in unsatisfactory deployment effects and affecting the accuracy and reliability of monitoring data. In order to apply adhesive to the installation platform and then attach the fiber optic sensor, it is particularly important to develop a fiber optic sensor deployment device.
[0003] A rapid fiber optic sensor deployment device, referenced in announcement CN210386358U, includes a housing support, a roller assembly, and a glue-applying device. The lower end of the housing support has two inclined support rods connected to the roller assembly via slots. The bottom surface of the housing support has four pin holes. An glue-applying funnel is installed inside the housing support, with a guide tube at its lower end and a flow-guiding ball at its bottom. The roller assembly includes two forward rollers, one flow-guiding roller, and a roller rod. The glue-applying device has a glue-applying surface on its lower side, with its front end contacting the flow-guiding roller and its rear end having a limiting hole. This device's structure is convenient to operate, enabling rapid and uniform adhesion of optical fibers to structural surfaces, improving adhesion speed, and ensuring even glue application and processing quality. However, while this device has good application potential, it is generally not convenient for electric drive devices to move the entire device, causing inconvenience during transport and frequently bothering users. Utility Model Content
[0004] The purpose of this utility model is to provide a fiber optic sensor deployment device to solve the problem that although the device proposed in the background art can be applied well, it is usually not convenient for the electric drive device to move the whole device, so that there are still some inconveniences in the process of moving the device.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a fiber optic sensor deployment device, comprising a base, two second geared motors mounted on one side of the bottom end of the base via a bracket, each second geared motor having a rear roller mounted on one end; two L-shaped wheel frames rotatably mounted on the other side of the bottom end of the base, a first geared motor mounted on the inner wall of the L-shaped wheel frames, one end of the first geared motor extending to the outside of the L-shaped wheel frames and having a front roller mounted thereon; a stand mounted on one side of the top end of the base, and a third geared motor mounted on the other side of the top end of the base, the bottom end of the third geared motor penetrating the base and having a drive arm; two linkage arms rotatably mounted on the end of the drive arm away from the third geared motor, the end of the linkage arm away from the drive arm being movably connected to the top end of the L-shaped wheel frames; a PLC controller located at the top of the base between the third geared motor and the stand, the output terminal of the microcontroller inside the PLC controller being electrically connected to the input terminals of the first geared motor, the third geared motor, and the second geared motors respectively.
[0006] Preferably, the upper end of the support frame is provided with a first transmission frame, the surface of the first transmission frame is provided with a first guide rail, and a second transmission frame is slidably connected to one side of the surface of the first guide rail. The first guide rail is provided to limit the movement range of the second transmission frame.
[0007] Preferably, the surface of the second transmission frame is provided with a second guide rail, and a lifting seat is slidably connected to the surface of the second guide rail. A placement seat is installed on the surface of the lifting seat. The second guide rail is provided to limit the movement range of the lifting seat.
[0008] Preferably, a third transmission frame is provided at the end of the placement seat away from the lifting seat. The surface of the third transmission frame is provided with a third guide rail. A linkage frame is slidably connected to one side of the surface of the third guide rail. A glue gun is mounted on one end of the linkage frame via a bracket. A third electric push rod is installed on the outer wall of one side of the third transmission frame. The input end of the third electric push rod is electrically connected to the output end of the microcontroller inside the PLC controller. One end of the third electric push rod is connected to the outer wall of the linkage frame. The third electric push rod is provided to drive the linkage frame to move horizontally.
[0009] Preferably, a first electric push rod is installed on the outer wall of one side of the first transmission frame. The input end of the first electric push rod is electrically connected to the output end of the microcontroller inside the PLC controller. One end of the first electric push rod is connected to the outer wall of the second transmission frame. The first electric push rod is configured to drive the second transmission frame to move horizontally.
[0010] Preferably, a second electric push rod is installed at the top of the second transmission frame. The input end of the second electric push rod is electrically connected to the output end of the microcontroller inside the PLC controller, and the bottom end of the second electric push rod is connected to the top of the lifting seat. The second electric push rod is configured to drive the lifting seat to move up and down.
[0011] Compared with the prior art, the beneficial effects of this utility model are: the fiber optic sensor deployment device not only improves the convenience of the deployment device during transportation, but also expands the applicability of the deployment device, and ensures the adhesive application effect when the deployment device is used.
[0012] (1) The rear roller is driven to rotate by the second geared motor and the front roller is driven to rotate by the first geared motor, so that the entire electric drive device can be moved. Then, the drive arm is driven to rotate slightly by the third geared motor, so that the drive arm drives the two L-shaped wheel frames located at the bottom of the base to rotate in the same direction via the linkage arm. The direction of the front roller can be adjusted to turn the entire device. Because it is easy to move the entire device electrically, the convenience of moving the device is improved.
[0013] (2) The second transmission frame is driven to slide on the surface of the first guide rail by the first electric push rod, and the lifting seat is driven to slide on the surface of the second guide rail by the second electric push rod. The position of the glue gun can be adjusted back and forth, and the height of the glue gun can be adjusted up and down, so as to facilitate glue application operations at different heights and areas, thereby improving the applicability of the application device.
[0014] (3) The linkage frame is driven by the third electric push rod to slide on the outer wall of the third guide rail, so that the linkage frame drives the glue gun to move smoothly. The position of the glue gun can be further adjusted back and forth so that the glue gun can be further attached to the area to be installed for glue application, thereby ensuring the glue application effect when the installation device is used. Attached Figure Description
[0015] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0016] Figure 2 This utility model Figure 1 Enlarged structural diagram at point A in the middle;
[0017] Figure 3 This is a bottom view of the base structure of this utility model;
[0018] Figure 4 This utility model Figure 3 Enlarged structural diagram at point B.
[0019] In the diagram: 1. Base; 2. Rear roller; 3. Front roller; 4. L-shaped wheel frame; 5. First geared motor; 6. Third geared motor; 7. PLC controller; 8. Stand; 9. First transmission frame; 10. First electric push rod; 11. Second transmission frame; 12. Second electric push rod; 13. Glue gun; 14. First guide rail; 15. Second guide rail; 16. Lifting seat; 17. Component holder; 18. Third transmission frame; 19. Third electric push rod; 20. Third guide rail; 21. Linkage frame; 22. Second geared motor; 23. Drive arm; 24. Linkage arm. Detailed Implementation
[0020] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the scope of protection of the present utility model.
[0021] Please see Figure 1-4 An embodiment of this utility model provides: a fiber optic sensor deployment device, including a base 1, two second reduction motors 22 are mounted on one side of the bottom end of the base 1 via a bracket, and a rear roller 2 is mounted on one end of each of the second reduction motors 22. Two L-shaped wheel frames 4 are rotatably mounted on the other side of the bottom end of the base 1. A first reduction motor 5 is mounted on the inner wall of the L-shaped wheel frame 4. One end of the first reduction motor 5 extends to the outside of the L-shaped wheel frame 4 and is mounted with a front roller 3. A stand 8 is mounted on one side of the top end of the base 1. A first transmission frame 9 is provided on the upper end of the surface of the stand 8. A first guide rail 14 is provided on the surface of the first transmission frame 9. A second transmission frame 11 is slidably connected to one side of the surface of the first guide rail 14.
[0022] In use, the first guide rail 14 is set to limit the movement range of the second transmission frame 11;
[0023] The surface of the second transmission frame 11 is provided with a second guide rail 15, and a lifting seat 16 is slidably connected to the surface of the second guide rail 15. A placement seat 17 is installed on the surface of the lifting seat 16.
[0024] In use, the movement range of the lifting seat 16 is limited by the setting of the second guide rail 15;
[0025] A third transmission frame 18 is provided at the end of the placement seat 17 away from the lifting seat 16. A third guide rail 20 is provided on the surface of the third transmission frame 18. A linkage frame 21 is slidably connected to one side of the surface of the third guide rail 20. A glue gun 13 is installed at one end of the linkage frame 21 through a bracket. A third electric push rod 19 is installed on the outer wall of one side of the third transmission frame 18. The input end of the third electric push rod 19 is electrically connected to the output end of the microcontroller inside the PLC controller 7. One end of the third electric push rod 19 is connected to the outer wall of the linkage frame 21.
[0026] In use, the third electric push rod 19 is set to drive the linkage frame 21 to move horizontally;
[0027] A first electric push rod 10 is installed on the outer wall of one side of the first transmission frame 9. The input end of the first electric push rod 10 is electrically connected to the output end of the microcontroller inside the PLC controller 7. One end of the first electric push rod 10 is connected to the outer wall of the second transmission frame 11.
[0028] In use, the first electric push rod 10 is set to drive the second transmission frame 11 to move horizontally;
[0029] The top of the second transmission frame 11 is equipped with a second electric push rod 12. The input end of the second electric push rod 12 is electrically connected to the output end of the microcontroller inside the PLC controller 7, and the bottom end of the second electric push rod 12 is connected to the top of the lifting seat 16.
[0030] In use, the second electric push rod 12 is used to drive the lifting seat 16 to move up and down.
[0031] A third geared motor 6 is installed on the other side of the top of the base 1. The bottom end of the third geared motor 6 passes through the base 1 and is provided with a drive arm 23. Two linkage arms 24 are rotatably installed on the end of the drive arm 23 away from the third geared motor 6. The end of the linkage arm 24 away from the drive arm 23 is movably connected to the top of the L-shaped wheel frame 4. A PLC controller 7 is provided on the top of the base 1 between the third geared motor 6 and the upright frame 8. The output terminal of the microcontroller inside the PLC controller 7 is electrically connected to the input terminals of the first geared motor 5, the third geared motor 6 and the second geared motor 22 respectively.
[0032] In this embodiment, the rear roller 2 is first driven to rotate by the second reduction motor 22, and the front roller 3 is driven to rotate by the first reduction motor 5, thus moving the entire electrically driven device. Then, the drive arm 23 is slightly rotated by the third reduction motor 6, causing the drive arm 23 to drive the two L-shaped wheel frames 4, located at the bottom of the base 1, to rotate in the same direction via the linkage arm 24. This adjusts the direction of the front roller 3, enabling electrically assisted steering of the entire device. Afterwards, the second transmission frame 11 slides on the surface of the first guide rail 14 via the first electric push rod 10, and the lifting seat 16 slides on the surface of the second guide rail 15 via the second electric push rod 12. The position of the glue gun 13 can be adjusted forward and backward, and its height can be adjusted up and down to facilitate glue application to different heights and areas. Finally, the linkage frame 21 is driven by the third electric push rod 19 to slide on the outer wall of the third guide rail 20, so that the linkage frame 21 drives the glue gun 13 to move smoothly. The position of the glue gun 13 can be further adjusted forward and backward to make the glue gun 13 fit closer to the area to be installed for glue application, so as to ensure the glue application effect of the installation device. In addition, when the glue is applied to the installation platform or the installation wall, the fiber optic sensor component is attached to the glue application area to install the fiber optic sensor, thereby completing the use of the installation device.
Claims
1. A fiber optic sensor deployment device, characterized in that: The base includes a base (1). Two second geared motors (22) are mounted on one side of the bottom of the base (1) via a bracket. Each second geared motor (22) has a rear roller (2) mounted on one end. Two L-shaped wheel frames (4) are rotatably mounted on the other side of the bottom of the base (1). A first geared motor (5) is mounted on the inner wall of the L-shaped wheel frame (4). One end of the first geared motor (5) extends to the outside of the L-shaped wheel frame (4) and is mounted with a front roller (3). A stand (8) is mounted on one side of the top of the base (1), and a third geared motor (6) is mounted on the other side of the top of the base (1). The bottom end of the third geared motor (6) passes through the base (1) and is provided with a drive arm (23). Two linkage arms (24) are rotatably installed at the end of the drive arm (23) away from the third geared motor (6). The end of the linkage arm (24) away from the drive arm (23) is movably connected to the top of the L-shaped wheel frame (4). A PLC controller (7) is provided at the top of the base (1) between the third geared motor (6) and the upright frame (8). The output end of the microcontroller inside the PLC controller (7) is electrically connected to the input end of the first geared motor (5), the third geared motor (6) and the second geared motor (22).
2. The fiber optic sensor deployment device according to claim 1, characterized in that: The upper end of the surface of the stand (8) is provided with a first transmission frame (9), the surface of the first transmission frame (9) is provided with a first guide rail (14), and a second transmission frame (11) is slidably connected to one side of the surface of the first guide rail (14).
3. The fiber optic sensor deployment device according to claim 2, characterized in that: The surface of the second transmission frame (11) is provided with a second guide rail (15), and a lifting seat (16) is slidably connected to the surface of the second guide rail (15). A placement seat (17) is installed on the surface of the lifting seat (16).
4. The fiber optic sensor deployment device according to claim 3, characterized in that: The placement seat (17) is provided with a third transmission frame (18) at one end away from the lifting seat (16). The surface of the third transmission frame (18) is provided with a third guide rail (20). A linkage frame (21) is slidably connected to one side of the surface of the third guide rail (20). A glue gun (13) is installed at one end of the linkage frame (21) through a bracket. A third electric push rod (19) is installed on the outer wall of one side of the third transmission frame (18). The input end of the third electric push rod (19) is electrically connected to the output end of the microcontroller inside the PLC controller (7). One end of the third electric push rod (19) is connected to the outer wall of the linkage frame (21).
5. The fiber optic sensor deployment device according to claim 2, characterized in that: A first electric push rod (10) is installed on the outer wall of one side of the first transmission frame (9). The input end of the first electric push rod (10) is electrically connected to the output end of the microcontroller inside the PLC controller (7). One end of the first electric push rod (10) is connected to the outer wall of the second transmission frame (11).
6. The fiber optic sensor deployment device according to claim 3, characterized in that: The second transmission frame (11) is equipped with a second electric push rod (12) at its top end. The input end of the second electric push rod (12) is electrically connected to the output end of the microcontroller inside the PLC controller (7). The bottom end of the second electric push rod (12) is connected to the top end of the lifting seat (16).